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The Implications of Power Mobility on Body Weight in a Veteran Population
The Veterans Health Administration (VHA) clinical practice recommendations endorse a power mobility device (PMD) for individuals with adequate judgment, cognitive ability, and vision who are unable to propel a manual wheelchair or walk community distances despite standard medical and rehabilitative interventions.1 VHA supports the use of a PMD in order to access medical care and accomplish activities of daily living, both at home and in the community for veterans with mobility limitations secondary to cardiovascular disease, neurologic disorders, pulmonary disease, or musculoskeletal disorders. The goal of a PMD use is increased participation in community and social life, improved health maintenance via enhanced access to medical facilities, and an overall enhanced quality of life. However, there is a common concern among health care providers that prescribing a PMD may decrease physical activity, in turn, leading to obesity and increasing morbidity. 2
The prevalence of obesity is increasing in the United States. In the past decade 35.0% of men and 36.8% of women were classified as obese (body mass index [BMI], ≥ 30).3 Recent figures from the Centers for Disease Control and Prevention estimate that the overall prevalence of obesity in Americans is closer to 42.4%.4 The veteran population is not immune to this; a 2014 study of nearly 5 million veterans reported that the prevalence of obesity in this population was 41%.5,6 In addition to obesity being implicated in exacerbating many medical problems, such as osteoarthritis, insulin resistance, and heart disease, obesity also is associated with a significant decrease in lifespan.7 Almost half of adults who report ambulatory dysfunction are obese.8 Given the increased morbidity and mortality as a result of obesity, interventions that may promote weight gain need to be appropriately identified and minimized.
In a retrospective study of 89 veterans, Yang and colleagues demonstrated no significant weight change 1 year after initial PMD prescription.2 Another study of 102 patients noted no significant weight changes 1 year after PMD prescription.9 This study analyzes the effect of PMD prescriptions over a 2-year period on BMI and body weight in a larger population of veterans both as a whole and in BMI/age subgroups.
Methods
The institutional review board at Hunter Holmes McGuire Veterans Affairs Medical Center in Richmond, Virginia, reviewed and approved this study. A waiver of participant consent was approved due to the nature of the research (medical records of patients, some of whom were deceased) and the type of data collected (retrospective data). In addition, each individual was assigned a sequential code to de-identify any personal information. Prosthetics department medical records of consecutive veterans who received PMDs for the first time between January 1, 2011 and June 30, 2012, were reviewed.
Data extracted from the electronic health record (EHR) included demographics, indication for power mobility, weight at time of PMD prescription, weight at 2-years postprescription, and height. Weight readings were considered valid if weight was taken within 3 months of initial prescription and then again within 3 months at the 2-year interval. Individuals without weights recorded in these time frames were excluded. In addition, we excluded medical conditions that might significantly affect body weight, including amyotrophic lateral sclerosis (ALS), amputation during the study period, or history of weight loss surgery. Cancer diagnoses were excluded as they were not an indication for power mobility in the VHA. ALS, though variable in its disease course, was specifically excluded given the likelihood of these patients dying of the natural progression of the disease before the 2-year follow-up period: Median survival times in patients diagnosed with ALS aged > 60 years was < 15 months. 10-12
The EHRs of 399 individuals who received a PMD during the period were reviewed, and 185 veterans met criteria for data analysis. Subject exclusions in the weight and BMI analysis included death during the follow-up period (89), missing data (68), prior PMD users who came in for replacements (53), and ALS (4) (Figure 1). Patients were not excluded based on the presence or absence of intentional weight loss efforts as this information was not readily available through chart review.
Statistical Analysis
The primary outcome measure was the change in BMI and body weight from time 1 (date of PMD prescription) to time 2 (2 years later). Analyses were performed using IBM SPSS Statistics, Version 21. BMI was calculated using the weight (lb) x 703/ (height [inches]).2 Dichotomization of BMI was performed using the conventional cut scores: < 30.0, not obese; and ≥ 30.0, obese. Paired t tests and SPSS general linear model (repeated measures) were used to examine change of BMI from time 1 to time 2. The exact McNemar test was used to examine change in obesity classification across time 1 and time 2. Correlating with Yang’s retrospective observational study, data were analyzed separately for aged < 65 years and aged≥ 65 years.2
Results
Of the 185 veterans, 181 were male (98%); mean age was 67.3 years (range, 26-90); and 55% were aged ≥ 65 years. Musculoskeletal disorders (41.6%) were the most common primary indication for a PMD, followed by pulmonary disorders (25.4%) and cardiovascular disorders (23.8%) (Table 1).
There was a significant decrease in BMI in the first 2 years after receiving a PMD prescription for the first time (estimated marginal means: 31.5 to 30.9 , P = .02). However, age moderated the relationship between BMI and time F[1, 183] = 12.14, P = .001, partial η2 = .06 (Table 2). The 101 subjects aged > 65 years experienced a significant decrease in BMI (estimated marginal means: 30.3 to 29.1, P < .001), whereas the 84 patients aged < 65 years experienced a slight and nonsignificant increase in BMI (estimated marginal means: 32.9 to 33.1, P = .45). BMI was significantly higher for subjects aged < 65 years at Time 1 (F[1, 183] = 4.32, P = .04, partial η2 = .02) and at Time 2 (F[1, 183] = 11.04, P = .001, partial η2 = .06).
Similarly, there was a significant decrease in weight in the first year after receiving a PMD prescription with a change in mean weight from 219.0 to 215.3 lb (P = .3). Again, age moderated the relationship between weight and time (F = 12.81; P < .001; partial η2 = .07). Individuals aged ≥ 65 years experienced a significant decrease in weight (estimated marginal means = 209.4 to 200.9; P < .001), whereas those aged < 65 years experienced a slight and nonsignificant increase in weight (230.6 to 232.6; P = .36). Weight was significantly higher for individuals aged < 65 years at time 1 (F = 5.34; P = .02; partial η2 = .03) and at time 2 (F = 12.18; P = .001; partial η2 = .06).
The percentage of those who were obese (BMI ≥ 30) at time 1 (49.7%) did not significantly change at time 2 (46.5%) (exact McNemar test, P = .26). Similarly, there was no significant change in obesity from time 1 to time 2 for those aged < 65 years (exact McNemar test P = .69) or for those aged ≥ 65 years (exact McNemar test P = .06). Obesity at time 2 was significantly more common in those aged < 65 years (56.0%) than those aged ≥ 65 years (38.6%), χ2 [1] = 5.54; P = .02. Obesity at time 1 did not differ between those aged < 65 years (53.6%) and aged ≥ 65 years (46.5%), η2 [1] = 0.9; P = .34. Obesity moderated the relationship between weight and time (F = 5.10; P = .03; partial η2= .03) in that obese individuals experienced a significant decrease in weight with estimated marginal means (SE) = 264.5 (4.51) to 257.4 (4.97); F = 11.32; P < .001; partial η2 = .06), whereas nonobese individuals had no weight change with estimated marginal means (SE) = 174.0 (4.48) to 173.61 (4.94); F = .03; P < .86; partial η2< .01).
Discussion
This study demonstrated a significant decrease in both weight and BMI at 2 years after the initiation of a PMD in patients aged < 65 years. No significant change was found for obesity rates. However, veterans who met criteria for obesity at the time of PMD prescription saw a significant decrease in their weight at 2 years compared with those who were nonobese.
VHA supports power mobility when there is a clear functional need that cannot be met by rehabilitation, surgical, or medical interventions to enhance veterans’ abilities to access medical care, accomplish necessary tasks of daily living, and to have greater access to their communities. Though limited by strength of association, studies involving PMD users generally found improvement in reported functional outcomes and overall satisfaction with PMD use based on a systematic review.13 Nonetheless, there is an implicit concern among providers that a PMD prescription, by limiting physical activity, may exacerbate obesity trends in potentially high-risk individuals.
However, a controversy exists about whether increasing physical activity alone leads to weight loss. A 2007 study followed 102 sedentary men and 100 women over 1 year randomized to moderately intensive exercise for 60 minutes, 6 days a week vs no intervention.14 The men lost an average of 4 pounds, and women lost an average of 3 pounds after 1 year. The Women’s Health Study divided 39,876 women into high, medium, and low levels of exercise groups. After 10 years, the intense exercise group did not have any significant weight loss.15
Our study was consistent with existing literature in that a PMD prescription did not correlate with weight gain.2,9 In our veteran population aged ≥ 65 years, we observed an opposite trend of weight loss after PMD prescription. Of note, studies have shown that peak body weight occurs in the sixth decade, remains stable until about aged 70 years, and then slowly decreases thereafter, at a rate of 0.1 to 0.2 kg per year.16 This likely explains some of the weight loss trend we observed in our study of veterans aged ≥ 65 years. Possible additional explanations include improved access to health care and to more nutritional foods that promote general health and well-being.
Limitations
The data were gathered from a predominantly male veteran population, potentially limiting generalizability. The health of any individual is determined by the interaction of factors of which body weight is just a single, isolated component. As such, the effect of powered mobility on body weight is not a direct reflection on the effect on overall health. Additionally, there are many factors that may affect an individual’s body weight, such as optimal management of medical comorbidities, which could not be controlled for in this study. Also, while these values can be compared with other veteran populations, this study had no true control group.
Conclusions
Based on the findings of this study with aforementioned limitations, PMD use does not seem to be associated with significant weight changes. Further studies using control groups and assessing comorbidities are needed.
1. Perlin J. Clinical practice recommendations for motorized wheeled mobility devices: scooters, pushrim-activated power-assist wheelchairs, power wheelchairs, and power wheelchairs with enhanced function. Published 2004. Accessed August 12, 2021. https://www.prosthetics.va.gov/Docs/Motorized_Wheeled_Mobility_Devices.pdf
2. Yang W, Wilson L, Oda I, Yan J. The effect of providing power mobility on weight change. Am J Phys Med Rehabil. 2007;86(9):746-753. doi:10.1097/PHM.0b013e31813e0645
3. Yang, L, Colditz GA. Prevalence of overweight and obesity in the United States, 2007-2012. JAMA Intern Med. 2015; 175(8):1412–1413. doi:10.1001/jamainternmed.2015.2405
4. Hales CM, Carroll MD, Fryar CD, Ogden CL. Prevalence of obesity and severe obesity among adults: United States, 2017-2018. NCHS Data Brief, no 360. Hyattsville, MD: National Center for Health Statistics; 2020.
5. Almond N, Kahwati L, Kinsinger L, Porterfield D. The prevalence of overweight and obesity among U.S. military veterans. Mil Med. 2008;173(6):544-549. doi:10.7205/milmed.173.6.544
6. Breland JY, Phibbs CS, Hoggatt KJ, et al. The obesity epidemic in the Veterans Health Administration: prevalence among key populations of women and men veterans. J Gen Intern Med. 2017;32(suppl 1):11-17. doi:10.1007/s11606-016-3962-1
7. Bray G. Medical consequences of obesity. Int J Clin Endocrinol Metab. 2004;89(6):2583-2589. doi:10.1210/jc.2004-0535
8. Fox MH, Witten MH, Lullo C. Reducing obesity among people with disabilities. J Disabil Policy Stud. 2014;25(3):175-185. doi:10.1177/1044207313494236
9. Zagol BW, Krasuski RA. Effect of motorized scooters on quality of life and cardiovascular risk. Am J Cardiol. 2010;105(5):672-676. doi:10.1016/j.amjcard.2009.10.049
10. Traxinger K, Kelly C, Johnson BA, Lyles RH, Glass JD. Prognosis and epidemiology of amyotrophic lateral sclerosis: analysis of a clinic population, 1997-2011. Neurol Clin Pract. 2013;3(4):313-320. doi:10.1212/cpj.0b013e3182a1b8ab
11. Wolf J, Safer A, Wöhrle J, et al. Factors predicting one-year mortality in amyotrophic lateral sclerosis patients—data from a population-based registry. BMC Neurol. 2014;14(1):197. doi:10.1186/s12883-014-0197-9
12. Körner S, Hendricks M, Kollewe K, et al. Weight loss, dysphagia and supplement intake in patients with amyotrophic lateral sclerosis (ALS): impact on quality of life and therapeutic options. BMC Neurol. 2013;13:84. doi: 10.1186/1471-2377-13-84
13. Auger CJ, Demers L, Gélinas I, et al. Powered mobility for middle-aged and older adults: systematic review of outcomes and appraisal of published evidence. Am J Phys Med Rehabil. 2008;87(8):666-680. doi:10.1097/PHM.0b013e31816de163
14. McTiernan A, Sorensen B, Irwin M, et al. Exercise effect on weight and body fat in men and women. Obesity (Silver Spring). 2007;15(6):1496-512. doi:10.1038/oby.2007.178
15. Lee IM, Djoussé L, Sesso H, Wang L, Buring JE . Physical activity and weight gain prevention, women’s health study. JAMA. 2010;303(12):1173-1179. doi:10.1001/jama.2010.312
16. Wallace J, Schwartz R. Epidemiology of weight loss in humans with special reference to wasting in the elderly. Int J Cardiol. 2002;85(1):15-21. doi:10.1016/s0167-5273(02)00246-2
The Veterans Health Administration (VHA) clinical practice recommendations endorse a power mobility device (PMD) for individuals with adequate judgment, cognitive ability, and vision who are unable to propel a manual wheelchair or walk community distances despite standard medical and rehabilitative interventions.1 VHA supports the use of a PMD in order to access medical care and accomplish activities of daily living, both at home and in the community for veterans with mobility limitations secondary to cardiovascular disease, neurologic disorders, pulmonary disease, or musculoskeletal disorders. The goal of a PMD use is increased participation in community and social life, improved health maintenance via enhanced access to medical facilities, and an overall enhanced quality of life. However, there is a common concern among health care providers that prescribing a PMD may decrease physical activity, in turn, leading to obesity and increasing morbidity. 2
The prevalence of obesity is increasing in the United States. In the past decade 35.0% of men and 36.8% of women were classified as obese (body mass index [BMI], ≥ 30).3 Recent figures from the Centers for Disease Control and Prevention estimate that the overall prevalence of obesity in Americans is closer to 42.4%.4 The veteran population is not immune to this; a 2014 study of nearly 5 million veterans reported that the prevalence of obesity in this population was 41%.5,6 In addition to obesity being implicated in exacerbating many medical problems, such as osteoarthritis, insulin resistance, and heart disease, obesity also is associated with a significant decrease in lifespan.7 Almost half of adults who report ambulatory dysfunction are obese.8 Given the increased morbidity and mortality as a result of obesity, interventions that may promote weight gain need to be appropriately identified and minimized.
In a retrospective study of 89 veterans, Yang and colleagues demonstrated no significant weight change 1 year after initial PMD prescription.2 Another study of 102 patients noted no significant weight changes 1 year after PMD prescription.9 This study analyzes the effect of PMD prescriptions over a 2-year period on BMI and body weight in a larger population of veterans both as a whole and in BMI/age subgroups.
Methods
The institutional review board at Hunter Holmes McGuire Veterans Affairs Medical Center in Richmond, Virginia, reviewed and approved this study. A waiver of participant consent was approved due to the nature of the research (medical records of patients, some of whom were deceased) and the type of data collected (retrospective data). In addition, each individual was assigned a sequential code to de-identify any personal information. Prosthetics department medical records of consecutive veterans who received PMDs for the first time between January 1, 2011 and June 30, 2012, were reviewed.
Data extracted from the electronic health record (EHR) included demographics, indication for power mobility, weight at time of PMD prescription, weight at 2-years postprescription, and height. Weight readings were considered valid if weight was taken within 3 months of initial prescription and then again within 3 months at the 2-year interval. Individuals without weights recorded in these time frames were excluded. In addition, we excluded medical conditions that might significantly affect body weight, including amyotrophic lateral sclerosis (ALS), amputation during the study period, or history of weight loss surgery. Cancer diagnoses were excluded as they were not an indication for power mobility in the VHA. ALS, though variable in its disease course, was specifically excluded given the likelihood of these patients dying of the natural progression of the disease before the 2-year follow-up period: Median survival times in patients diagnosed with ALS aged > 60 years was < 15 months. 10-12
The EHRs of 399 individuals who received a PMD during the period were reviewed, and 185 veterans met criteria for data analysis. Subject exclusions in the weight and BMI analysis included death during the follow-up period (89), missing data (68), prior PMD users who came in for replacements (53), and ALS (4) (Figure 1). Patients were not excluded based on the presence or absence of intentional weight loss efforts as this information was not readily available through chart review.
Statistical Analysis
The primary outcome measure was the change in BMI and body weight from time 1 (date of PMD prescription) to time 2 (2 years later). Analyses were performed using IBM SPSS Statistics, Version 21. BMI was calculated using the weight (lb) x 703/ (height [inches]).2 Dichotomization of BMI was performed using the conventional cut scores: < 30.0, not obese; and ≥ 30.0, obese. Paired t tests and SPSS general linear model (repeated measures) were used to examine change of BMI from time 1 to time 2. The exact McNemar test was used to examine change in obesity classification across time 1 and time 2. Correlating with Yang’s retrospective observational study, data were analyzed separately for aged < 65 years and aged≥ 65 years.2
Results
Of the 185 veterans, 181 were male (98%); mean age was 67.3 years (range, 26-90); and 55% were aged ≥ 65 years. Musculoskeletal disorders (41.6%) were the most common primary indication for a PMD, followed by pulmonary disorders (25.4%) and cardiovascular disorders (23.8%) (Table 1).
There was a significant decrease in BMI in the first 2 years after receiving a PMD prescription for the first time (estimated marginal means: 31.5 to 30.9 , P = .02). However, age moderated the relationship between BMI and time F[1, 183] = 12.14, P = .001, partial η2 = .06 (Table 2). The 101 subjects aged > 65 years experienced a significant decrease in BMI (estimated marginal means: 30.3 to 29.1, P < .001), whereas the 84 patients aged < 65 years experienced a slight and nonsignificant increase in BMI (estimated marginal means: 32.9 to 33.1, P = .45). BMI was significantly higher for subjects aged < 65 years at Time 1 (F[1, 183] = 4.32, P = .04, partial η2 = .02) and at Time 2 (F[1, 183] = 11.04, P = .001, partial η2 = .06).
Similarly, there was a significant decrease in weight in the first year after receiving a PMD prescription with a change in mean weight from 219.0 to 215.3 lb (P = .3). Again, age moderated the relationship between weight and time (F = 12.81; P < .001; partial η2 = .07). Individuals aged ≥ 65 years experienced a significant decrease in weight (estimated marginal means = 209.4 to 200.9; P < .001), whereas those aged < 65 years experienced a slight and nonsignificant increase in weight (230.6 to 232.6; P = .36). Weight was significantly higher for individuals aged < 65 years at time 1 (F = 5.34; P = .02; partial η2 = .03) and at time 2 (F = 12.18; P = .001; partial η2 = .06).
The percentage of those who were obese (BMI ≥ 30) at time 1 (49.7%) did not significantly change at time 2 (46.5%) (exact McNemar test, P = .26). Similarly, there was no significant change in obesity from time 1 to time 2 for those aged < 65 years (exact McNemar test P = .69) or for those aged ≥ 65 years (exact McNemar test P = .06). Obesity at time 2 was significantly more common in those aged < 65 years (56.0%) than those aged ≥ 65 years (38.6%), χ2 [1] = 5.54; P = .02. Obesity at time 1 did not differ between those aged < 65 years (53.6%) and aged ≥ 65 years (46.5%), η2 [1] = 0.9; P = .34. Obesity moderated the relationship between weight and time (F = 5.10; P = .03; partial η2= .03) in that obese individuals experienced a significant decrease in weight with estimated marginal means (SE) = 264.5 (4.51) to 257.4 (4.97); F = 11.32; P < .001; partial η2 = .06), whereas nonobese individuals had no weight change with estimated marginal means (SE) = 174.0 (4.48) to 173.61 (4.94); F = .03; P < .86; partial η2< .01).
Discussion
This study demonstrated a significant decrease in both weight and BMI at 2 years after the initiation of a PMD in patients aged < 65 years. No significant change was found for obesity rates. However, veterans who met criteria for obesity at the time of PMD prescription saw a significant decrease in their weight at 2 years compared with those who were nonobese.
VHA supports power mobility when there is a clear functional need that cannot be met by rehabilitation, surgical, or medical interventions to enhance veterans’ abilities to access medical care, accomplish necessary tasks of daily living, and to have greater access to their communities. Though limited by strength of association, studies involving PMD users generally found improvement in reported functional outcomes and overall satisfaction with PMD use based on a systematic review.13 Nonetheless, there is an implicit concern among providers that a PMD prescription, by limiting physical activity, may exacerbate obesity trends in potentially high-risk individuals.
However, a controversy exists about whether increasing physical activity alone leads to weight loss. A 2007 study followed 102 sedentary men and 100 women over 1 year randomized to moderately intensive exercise for 60 minutes, 6 days a week vs no intervention.14 The men lost an average of 4 pounds, and women lost an average of 3 pounds after 1 year. The Women’s Health Study divided 39,876 women into high, medium, and low levels of exercise groups. After 10 years, the intense exercise group did not have any significant weight loss.15
Our study was consistent with existing literature in that a PMD prescription did not correlate with weight gain.2,9 In our veteran population aged ≥ 65 years, we observed an opposite trend of weight loss after PMD prescription. Of note, studies have shown that peak body weight occurs in the sixth decade, remains stable until about aged 70 years, and then slowly decreases thereafter, at a rate of 0.1 to 0.2 kg per year.16 This likely explains some of the weight loss trend we observed in our study of veterans aged ≥ 65 years. Possible additional explanations include improved access to health care and to more nutritional foods that promote general health and well-being.
Limitations
The data were gathered from a predominantly male veteran population, potentially limiting generalizability. The health of any individual is determined by the interaction of factors of which body weight is just a single, isolated component. As such, the effect of powered mobility on body weight is not a direct reflection on the effect on overall health. Additionally, there are many factors that may affect an individual’s body weight, such as optimal management of medical comorbidities, which could not be controlled for in this study. Also, while these values can be compared with other veteran populations, this study had no true control group.
Conclusions
Based on the findings of this study with aforementioned limitations, PMD use does not seem to be associated with significant weight changes. Further studies using control groups and assessing comorbidities are needed.
The Veterans Health Administration (VHA) clinical practice recommendations endorse a power mobility device (PMD) for individuals with adequate judgment, cognitive ability, and vision who are unable to propel a manual wheelchair or walk community distances despite standard medical and rehabilitative interventions.1 VHA supports the use of a PMD in order to access medical care and accomplish activities of daily living, both at home and in the community for veterans with mobility limitations secondary to cardiovascular disease, neurologic disorders, pulmonary disease, or musculoskeletal disorders. The goal of a PMD use is increased participation in community and social life, improved health maintenance via enhanced access to medical facilities, and an overall enhanced quality of life. However, there is a common concern among health care providers that prescribing a PMD may decrease physical activity, in turn, leading to obesity and increasing morbidity. 2
The prevalence of obesity is increasing in the United States. In the past decade 35.0% of men and 36.8% of women were classified as obese (body mass index [BMI], ≥ 30).3 Recent figures from the Centers for Disease Control and Prevention estimate that the overall prevalence of obesity in Americans is closer to 42.4%.4 The veteran population is not immune to this; a 2014 study of nearly 5 million veterans reported that the prevalence of obesity in this population was 41%.5,6 In addition to obesity being implicated in exacerbating many medical problems, such as osteoarthritis, insulin resistance, and heart disease, obesity also is associated with a significant decrease in lifespan.7 Almost half of adults who report ambulatory dysfunction are obese.8 Given the increased morbidity and mortality as a result of obesity, interventions that may promote weight gain need to be appropriately identified and minimized.
In a retrospective study of 89 veterans, Yang and colleagues demonstrated no significant weight change 1 year after initial PMD prescription.2 Another study of 102 patients noted no significant weight changes 1 year after PMD prescription.9 This study analyzes the effect of PMD prescriptions over a 2-year period on BMI and body weight in a larger population of veterans both as a whole and in BMI/age subgroups.
Methods
The institutional review board at Hunter Holmes McGuire Veterans Affairs Medical Center in Richmond, Virginia, reviewed and approved this study. A waiver of participant consent was approved due to the nature of the research (medical records of patients, some of whom were deceased) and the type of data collected (retrospective data). In addition, each individual was assigned a sequential code to de-identify any personal information. Prosthetics department medical records of consecutive veterans who received PMDs for the first time between January 1, 2011 and June 30, 2012, were reviewed.
Data extracted from the electronic health record (EHR) included demographics, indication for power mobility, weight at time of PMD prescription, weight at 2-years postprescription, and height. Weight readings were considered valid if weight was taken within 3 months of initial prescription and then again within 3 months at the 2-year interval. Individuals without weights recorded in these time frames were excluded. In addition, we excluded medical conditions that might significantly affect body weight, including amyotrophic lateral sclerosis (ALS), amputation during the study period, or history of weight loss surgery. Cancer diagnoses were excluded as they were not an indication for power mobility in the VHA. ALS, though variable in its disease course, was specifically excluded given the likelihood of these patients dying of the natural progression of the disease before the 2-year follow-up period: Median survival times in patients diagnosed with ALS aged > 60 years was < 15 months. 10-12
The EHRs of 399 individuals who received a PMD during the period were reviewed, and 185 veterans met criteria for data analysis. Subject exclusions in the weight and BMI analysis included death during the follow-up period (89), missing data (68), prior PMD users who came in for replacements (53), and ALS (4) (Figure 1). Patients were not excluded based on the presence or absence of intentional weight loss efforts as this information was not readily available through chart review.
Statistical Analysis
The primary outcome measure was the change in BMI and body weight from time 1 (date of PMD prescription) to time 2 (2 years later). Analyses were performed using IBM SPSS Statistics, Version 21. BMI was calculated using the weight (lb) x 703/ (height [inches]).2 Dichotomization of BMI was performed using the conventional cut scores: < 30.0, not obese; and ≥ 30.0, obese. Paired t tests and SPSS general linear model (repeated measures) were used to examine change of BMI from time 1 to time 2. The exact McNemar test was used to examine change in obesity classification across time 1 and time 2. Correlating with Yang’s retrospective observational study, data were analyzed separately for aged < 65 years and aged≥ 65 years.2
Results
Of the 185 veterans, 181 were male (98%); mean age was 67.3 years (range, 26-90); and 55% were aged ≥ 65 years. Musculoskeletal disorders (41.6%) were the most common primary indication for a PMD, followed by pulmonary disorders (25.4%) and cardiovascular disorders (23.8%) (Table 1).
There was a significant decrease in BMI in the first 2 years after receiving a PMD prescription for the first time (estimated marginal means: 31.5 to 30.9 , P = .02). However, age moderated the relationship between BMI and time F[1, 183] = 12.14, P = .001, partial η2 = .06 (Table 2). The 101 subjects aged > 65 years experienced a significant decrease in BMI (estimated marginal means: 30.3 to 29.1, P < .001), whereas the 84 patients aged < 65 years experienced a slight and nonsignificant increase in BMI (estimated marginal means: 32.9 to 33.1, P = .45). BMI was significantly higher for subjects aged < 65 years at Time 1 (F[1, 183] = 4.32, P = .04, partial η2 = .02) and at Time 2 (F[1, 183] = 11.04, P = .001, partial η2 = .06).
Similarly, there was a significant decrease in weight in the first year after receiving a PMD prescription with a change in mean weight from 219.0 to 215.3 lb (P = .3). Again, age moderated the relationship between weight and time (F = 12.81; P < .001; partial η2 = .07). Individuals aged ≥ 65 years experienced a significant decrease in weight (estimated marginal means = 209.4 to 200.9; P < .001), whereas those aged < 65 years experienced a slight and nonsignificant increase in weight (230.6 to 232.6; P = .36). Weight was significantly higher for individuals aged < 65 years at time 1 (F = 5.34; P = .02; partial η2 = .03) and at time 2 (F = 12.18; P = .001; partial η2 = .06).
The percentage of those who were obese (BMI ≥ 30) at time 1 (49.7%) did not significantly change at time 2 (46.5%) (exact McNemar test, P = .26). Similarly, there was no significant change in obesity from time 1 to time 2 for those aged < 65 years (exact McNemar test P = .69) or for those aged ≥ 65 years (exact McNemar test P = .06). Obesity at time 2 was significantly more common in those aged < 65 years (56.0%) than those aged ≥ 65 years (38.6%), χ2 [1] = 5.54; P = .02. Obesity at time 1 did not differ between those aged < 65 years (53.6%) and aged ≥ 65 years (46.5%), η2 [1] = 0.9; P = .34. Obesity moderated the relationship between weight and time (F = 5.10; P = .03; partial η2= .03) in that obese individuals experienced a significant decrease in weight with estimated marginal means (SE) = 264.5 (4.51) to 257.4 (4.97); F = 11.32; P < .001; partial η2 = .06), whereas nonobese individuals had no weight change with estimated marginal means (SE) = 174.0 (4.48) to 173.61 (4.94); F = .03; P < .86; partial η2< .01).
Discussion
This study demonstrated a significant decrease in both weight and BMI at 2 years after the initiation of a PMD in patients aged < 65 years. No significant change was found for obesity rates. However, veterans who met criteria for obesity at the time of PMD prescription saw a significant decrease in their weight at 2 years compared with those who were nonobese.
VHA supports power mobility when there is a clear functional need that cannot be met by rehabilitation, surgical, or medical interventions to enhance veterans’ abilities to access medical care, accomplish necessary tasks of daily living, and to have greater access to their communities. Though limited by strength of association, studies involving PMD users generally found improvement in reported functional outcomes and overall satisfaction with PMD use based on a systematic review.13 Nonetheless, there is an implicit concern among providers that a PMD prescription, by limiting physical activity, may exacerbate obesity trends in potentially high-risk individuals.
However, a controversy exists about whether increasing physical activity alone leads to weight loss. A 2007 study followed 102 sedentary men and 100 women over 1 year randomized to moderately intensive exercise for 60 minutes, 6 days a week vs no intervention.14 The men lost an average of 4 pounds, and women lost an average of 3 pounds after 1 year. The Women’s Health Study divided 39,876 women into high, medium, and low levels of exercise groups. After 10 years, the intense exercise group did not have any significant weight loss.15
Our study was consistent with existing literature in that a PMD prescription did not correlate with weight gain.2,9 In our veteran population aged ≥ 65 years, we observed an opposite trend of weight loss after PMD prescription. Of note, studies have shown that peak body weight occurs in the sixth decade, remains stable until about aged 70 years, and then slowly decreases thereafter, at a rate of 0.1 to 0.2 kg per year.16 This likely explains some of the weight loss trend we observed in our study of veterans aged ≥ 65 years. Possible additional explanations include improved access to health care and to more nutritional foods that promote general health and well-being.
Limitations
The data were gathered from a predominantly male veteran population, potentially limiting generalizability. The health of any individual is determined by the interaction of factors of which body weight is just a single, isolated component. As such, the effect of powered mobility on body weight is not a direct reflection on the effect on overall health. Additionally, there are many factors that may affect an individual’s body weight, such as optimal management of medical comorbidities, which could not be controlled for in this study. Also, while these values can be compared with other veteran populations, this study had no true control group.
Conclusions
Based on the findings of this study with aforementioned limitations, PMD use does not seem to be associated with significant weight changes. Further studies using control groups and assessing comorbidities are needed.
1. Perlin J. Clinical practice recommendations for motorized wheeled mobility devices: scooters, pushrim-activated power-assist wheelchairs, power wheelchairs, and power wheelchairs with enhanced function. Published 2004. Accessed August 12, 2021. https://www.prosthetics.va.gov/Docs/Motorized_Wheeled_Mobility_Devices.pdf
2. Yang W, Wilson L, Oda I, Yan J. The effect of providing power mobility on weight change. Am J Phys Med Rehabil. 2007;86(9):746-753. doi:10.1097/PHM.0b013e31813e0645
3. Yang, L, Colditz GA. Prevalence of overweight and obesity in the United States, 2007-2012. JAMA Intern Med. 2015; 175(8):1412–1413. doi:10.1001/jamainternmed.2015.2405
4. Hales CM, Carroll MD, Fryar CD, Ogden CL. Prevalence of obesity and severe obesity among adults: United States, 2017-2018. NCHS Data Brief, no 360. Hyattsville, MD: National Center for Health Statistics; 2020.
5. Almond N, Kahwati L, Kinsinger L, Porterfield D. The prevalence of overweight and obesity among U.S. military veterans. Mil Med. 2008;173(6):544-549. doi:10.7205/milmed.173.6.544
6. Breland JY, Phibbs CS, Hoggatt KJ, et al. The obesity epidemic in the Veterans Health Administration: prevalence among key populations of women and men veterans. J Gen Intern Med. 2017;32(suppl 1):11-17. doi:10.1007/s11606-016-3962-1
7. Bray G. Medical consequences of obesity. Int J Clin Endocrinol Metab. 2004;89(6):2583-2589. doi:10.1210/jc.2004-0535
8. Fox MH, Witten MH, Lullo C. Reducing obesity among people with disabilities. J Disabil Policy Stud. 2014;25(3):175-185. doi:10.1177/1044207313494236
9. Zagol BW, Krasuski RA. Effect of motorized scooters on quality of life and cardiovascular risk. Am J Cardiol. 2010;105(5):672-676. doi:10.1016/j.amjcard.2009.10.049
10. Traxinger K, Kelly C, Johnson BA, Lyles RH, Glass JD. Prognosis and epidemiology of amyotrophic lateral sclerosis: analysis of a clinic population, 1997-2011. Neurol Clin Pract. 2013;3(4):313-320. doi:10.1212/cpj.0b013e3182a1b8ab
11. Wolf J, Safer A, Wöhrle J, et al. Factors predicting one-year mortality in amyotrophic lateral sclerosis patients—data from a population-based registry. BMC Neurol. 2014;14(1):197. doi:10.1186/s12883-014-0197-9
12. Körner S, Hendricks M, Kollewe K, et al. Weight loss, dysphagia and supplement intake in patients with amyotrophic lateral sclerosis (ALS): impact on quality of life and therapeutic options. BMC Neurol. 2013;13:84. doi: 10.1186/1471-2377-13-84
13. Auger CJ, Demers L, Gélinas I, et al. Powered mobility for middle-aged and older adults: systematic review of outcomes and appraisal of published evidence. Am J Phys Med Rehabil. 2008;87(8):666-680. doi:10.1097/PHM.0b013e31816de163
14. McTiernan A, Sorensen B, Irwin M, et al. Exercise effect on weight and body fat in men and women. Obesity (Silver Spring). 2007;15(6):1496-512. doi:10.1038/oby.2007.178
15. Lee IM, Djoussé L, Sesso H, Wang L, Buring JE . Physical activity and weight gain prevention, women’s health study. JAMA. 2010;303(12):1173-1179. doi:10.1001/jama.2010.312
16. Wallace J, Schwartz R. Epidemiology of weight loss in humans with special reference to wasting in the elderly. Int J Cardiol. 2002;85(1):15-21. doi:10.1016/s0167-5273(02)00246-2
1. Perlin J. Clinical practice recommendations for motorized wheeled mobility devices: scooters, pushrim-activated power-assist wheelchairs, power wheelchairs, and power wheelchairs with enhanced function. Published 2004. Accessed August 12, 2021. https://www.prosthetics.va.gov/Docs/Motorized_Wheeled_Mobility_Devices.pdf
2. Yang W, Wilson L, Oda I, Yan J. The effect of providing power mobility on weight change. Am J Phys Med Rehabil. 2007;86(9):746-753. doi:10.1097/PHM.0b013e31813e0645
3. Yang, L, Colditz GA. Prevalence of overweight and obesity in the United States, 2007-2012. JAMA Intern Med. 2015; 175(8):1412–1413. doi:10.1001/jamainternmed.2015.2405
4. Hales CM, Carroll MD, Fryar CD, Ogden CL. Prevalence of obesity and severe obesity among adults: United States, 2017-2018. NCHS Data Brief, no 360. Hyattsville, MD: National Center for Health Statistics; 2020.
5. Almond N, Kahwati L, Kinsinger L, Porterfield D. The prevalence of overweight and obesity among U.S. military veterans. Mil Med. 2008;173(6):544-549. doi:10.7205/milmed.173.6.544
6. Breland JY, Phibbs CS, Hoggatt KJ, et al. The obesity epidemic in the Veterans Health Administration: prevalence among key populations of women and men veterans. J Gen Intern Med. 2017;32(suppl 1):11-17. doi:10.1007/s11606-016-3962-1
7. Bray G. Medical consequences of obesity. Int J Clin Endocrinol Metab. 2004;89(6):2583-2589. doi:10.1210/jc.2004-0535
8. Fox MH, Witten MH, Lullo C. Reducing obesity among people with disabilities. J Disabil Policy Stud. 2014;25(3):175-185. doi:10.1177/1044207313494236
9. Zagol BW, Krasuski RA. Effect of motorized scooters on quality of life and cardiovascular risk. Am J Cardiol. 2010;105(5):672-676. doi:10.1016/j.amjcard.2009.10.049
10. Traxinger K, Kelly C, Johnson BA, Lyles RH, Glass JD. Prognosis and epidemiology of amyotrophic lateral sclerosis: analysis of a clinic population, 1997-2011. Neurol Clin Pract. 2013;3(4):313-320. doi:10.1212/cpj.0b013e3182a1b8ab
11. Wolf J, Safer A, Wöhrle J, et al. Factors predicting one-year mortality in amyotrophic lateral sclerosis patients—data from a population-based registry. BMC Neurol. 2014;14(1):197. doi:10.1186/s12883-014-0197-9
12. Körner S, Hendricks M, Kollewe K, et al. Weight loss, dysphagia and supplement intake in patients with amyotrophic lateral sclerosis (ALS): impact on quality of life and therapeutic options. BMC Neurol. 2013;13:84. doi: 10.1186/1471-2377-13-84
13. Auger CJ, Demers L, Gélinas I, et al. Powered mobility for middle-aged and older adults: systematic review of outcomes and appraisal of published evidence. Am J Phys Med Rehabil. 2008;87(8):666-680. doi:10.1097/PHM.0b013e31816de163
14. McTiernan A, Sorensen B, Irwin M, et al. Exercise effect on weight and body fat in men and women. Obesity (Silver Spring). 2007;15(6):1496-512. doi:10.1038/oby.2007.178
15. Lee IM, Djoussé L, Sesso H, Wang L, Buring JE . Physical activity and weight gain prevention, women’s health study. JAMA. 2010;303(12):1173-1179. doi:10.1001/jama.2010.312
16. Wallace J, Schwartz R. Epidemiology of weight loss in humans with special reference to wasting in the elderly. Int J Cardiol. 2002;85(1):15-21. doi:10.1016/s0167-5273(02)00246-2
New guidance on preventing cutaneous SCC in solid organ transplant patients
An expert panel of 48 dermatologists from 13 countries has developed recommendations to guide efforts aimed at preventing cutaneous squamous cell carcinoma (CSCC) in solid organ transplant recipients.
The recommendations were published online on Sept. 1 in JAMA Dermatology.
Because of lifelong immunosuppression, solid organ transplant recipients (SOTRs) have a risk of CSCC that is 20-200 times higher than in the general population and despite a growing literature on prevention of CSCC in these patients, uncertainty remains regarding best practices for various patient scenarios.
Paul Massey, MD, MPH, of the department of dermatology, Brigham and Women’s Hospital, Boston, and colleagues used a Delphi process to identify consensus-based medical management recommendations for prevention of CSCC in SOTRs.
The survey design was guided by a novel actinic damage and skin cancer index (AD-SCI) made up of six ordinal stages corresponding to an increasing burden of actinic damage and CSCC.
The AD-SCI stage-based recommendations were established when consensus was reached (80% or higher concordance) or near consensus was reached (70%-80% concordance) among panel members.
For five of the six AD-SCI stages, the panel was able to make recommendations. Key recommendations include:
- Cryotherapy for scattered AK.
- Field therapy for AK when grouped in one site, unless AKs are thick, in which case field therapy and cryotherapy are recommended.
- Combination lesion-directed and field therapy with fluorouracil for field cancerized skin.
- Initiation of acitretin therapy and discussion of immunosuppression reduction or modification for patients who develop multiple CSCCs at a high rate (10 per year) or develop high-risk CSCC (defined by a tumor with roughly ≥20% risk of nodal metastasis). The panel did not make a recommendation as to the best immunosuppression modification strategy to pursue.
Lingering questions
The panel was unable to reach consensus on a recommendation for SOTRs with a first low-risk CSCC, reflecting “clinical equipoise” in this situation and the need for further study in this clinical scenario, they say.
The panel did not make a recommendation for use of nicotinamide or capecitabine in any of the six stages, which is “notable,” they acknowledge, given results of a double-blind randomized controlled trial in immunocompetent patients demonstrating benefit in preventing AKs and CSCCs, as reported previously.
Nearly three-quarters of the panel felt that a lack of efficacy data specifically for the SOTR population limited their use of nicotinamide. “Given the low cost, high safety, and demonstration of CSCC reduction in non-SOTRs, nicotinamide administration may be an area for further consideration and expanded study,” the panel wrote.
As for capecitabine, the panel notes that case series in SOTRs have found efficacy for chemoprevention, but randomized controlled studies are lacking. More than half of the panel noted that they did not have routine access to capecitabine in their practice.
The panel recommended routine skin surveillance and sunscreen use for all patients.
“These recommendations reflect consensus among expert transplant dermatologists and the incorporation of limited and sometimes contradictory evidence into real-world clinical experience across a range of CSCC disease severity,” the panel said.
“Areas of consensus may aid physicians in establishing best practices regarding prevention of CSCC in SOTRs in the setting of limited high level of evidence data in this population,” they added.
This research had no specific funding. Author disclosures included serving as a consultant to Regeneron, Sanofi, and receiving research funding from Castle Biosciences, Regeneron, Novartis, and Genentech. A complete list of disclosures for panel members is available with the original article.
An expert panel of 48 dermatologists from 13 countries has developed recommendations to guide efforts aimed at preventing cutaneous squamous cell carcinoma (CSCC) in solid organ transplant recipients.
The recommendations were published online on Sept. 1 in JAMA Dermatology.
Because of lifelong immunosuppression, solid organ transplant recipients (SOTRs) have a risk of CSCC that is 20-200 times higher than in the general population and despite a growing literature on prevention of CSCC in these patients, uncertainty remains regarding best practices for various patient scenarios.
Paul Massey, MD, MPH, of the department of dermatology, Brigham and Women’s Hospital, Boston, and colleagues used a Delphi process to identify consensus-based medical management recommendations for prevention of CSCC in SOTRs.
The survey design was guided by a novel actinic damage and skin cancer index (AD-SCI) made up of six ordinal stages corresponding to an increasing burden of actinic damage and CSCC.
The AD-SCI stage-based recommendations were established when consensus was reached (80% or higher concordance) or near consensus was reached (70%-80% concordance) among panel members.
For five of the six AD-SCI stages, the panel was able to make recommendations. Key recommendations include:
- Cryotherapy for scattered AK.
- Field therapy for AK when grouped in one site, unless AKs are thick, in which case field therapy and cryotherapy are recommended.
- Combination lesion-directed and field therapy with fluorouracil for field cancerized skin.
- Initiation of acitretin therapy and discussion of immunosuppression reduction or modification for patients who develop multiple CSCCs at a high rate (10 per year) or develop high-risk CSCC (defined by a tumor with roughly ≥20% risk of nodal metastasis). The panel did not make a recommendation as to the best immunosuppression modification strategy to pursue.
Lingering questions
The panel was unable to reach consensus on a recommendation for SOTRs with a first low-risk CSCC, reflecting “clinical equipoise” in this situation and the need for further study in this clinical scenario, they say.
The panel did not make a recommendation for use of nicotinamide or capecitabine in any of the six stages, which is “notable,” they acknowledge, given results of a double-blind randomized controlled trial in immunocompetent patients demonstrating benefit in preventing AKs and CSCCs, as reported previously.
Nearly three-quarters of the panel felt that a lack of efficacy data specifically for the SOTR population limited their use of nicotinamide. “Given the low cost, high safety, and demonstration of CSCC reduction in non-SOTRs, nicotinamide administration may be an area for further consideration and expanded study,” the panel wrote.
As for capecitabine, the panel notes that case series in SOTRs have found efficacy for chemoprevention, but randomized controlled studies are lacking. More than half of the panel noted that they did not have routine access to capecitabine in their practice.
The panel recommended routine skin surveillance and sunscreen use for all patients.
“These recommendations reflect consensus among expert transplant dermatologists and the incorporation of limited and sometimes contradictory evidence into real-world clinical experience across a range of CSCC disease severity,” the panel said.
“Areas of consensus may aid physicians in establishing best practices regarding prevention of CSCC in SOTRs in the setting of limited high level of evidence data in this population,” they added.
This research had no specific funding. Author disclosures included serving as a consultant to Regeneron, Sanofi, and receiving research funding from Castle Biosciences, Regeneron, Novartis, and Genentech. A complete list of disclosures for panel members is available with the original article.
An expert panel of 48 dermatologists from 13 countries has developed recommendations to guide efforts aimed at preventing cutaneous squamous cell carcinoma (CSCC) in solid organ transplant recipients.
The recommendations were published online on Sept. 1 in JAMA Dermatology.
Because of lifelong immunosuppression, solid organ transplant recipients (SOTRs) have a risk of CSCC that is 20-200 times higher than in the general population and despite a growing literature on prevention of CSCC in these patients, uncertainty remains regarding best practices for various patient scenarios.
Paul Massey, MD, MPH, of the department of dermatology, Brigham and Women’s Hospital, Boston, and colleagues used a Delphi process to identify consensus-based medical management recommendations for prevention of CSCC in SOTRs.
The survey design was guided by a novel actinic damage and skin cancer index (AD-SCI) made up of six ordinal stages corresponding to an increasing burden of actinic damage and CSCC.
The AD-SCI stage-based recommendations were established when consensus was reached (80% or higher concordance) or near consensus was reached (70%-80% concordance) among panel members.
For five of the six AD-SCI stages, the panel was able to make recommendations. Key recommendations include:
- Cryotherapy for scattered AK.
- Field therapy for AK when grouped in one site, unless AKs are thick, in which case field therapy and cryotherapy are recommended.
- Combination lesion-directed and field therapy with fluorouracil for field cancerized skin.
- Initiation of acitretin therapy and discussion of immunosuppression reduction or modification for patients who develop multiple CSCCs at a high rate (10 per year) or develop high-risk CSCC (defined by a tumor with roughly ≥20% risk of nodal metastasis). The panel did not make a recommendation as to the best immunosuppression modification strategy to pursue.
Lingering questions
The panel was unable to reach consensus on a recommendation for SOTRs with a first low-risk CSCC, reflecting “clinical equipoise” in this situation and the need for further study in this clinical scenario, they say.
The panel did not make a recommendation for use of nicotinamide or capecitabine in any of the six stages, which is “notable,” they acknowledge, given results of a double-blind randomized controlled trial in immunocompetent patients demonstrating benefit in preventing AKs and CSCCs, as reported previously.
Nearly three-quarters of the panel felt that a lack of efficacy data specifically for the SOTR population limited their use of nicotinamide. “Given the low cost, high safety, and demonstration of CSCC reduction in non-SOTRs, nicotinamide administration may be an area for further consideration and expanded study,” the panel wrote.
As for capecitabine, the panel notes that case series in SOTRs have found efficacy for chemoprevention, but randomized controlled studies are lacking. More than half of the panel noted that they did not have routine access to capecitabine in their practice.
The panel recommended routine skin surveillance and sunscreen use for all patients.
“These recommendations reflect consensus among expert transplant dermatologists and the incorporation of limited and sometimes contradictory evidence into real-world clinical experience across a range of CSCC disease severity,” the panel said.
“Areas of consensus may aid physicians in establishing best practices regarding prevention of CSCC in SOTRs in the setting of limited high level of evidence data in this population,” they added.
This research had no specific funding. Author disclosures included serving as a consultant to Regeneron, Sanofi, and receiving research funding from Castle Biosciences, Regeneron, Novartis, and Genentech. A complete list of disclosures for panel members is available with the original article.
Transgender individuals twice as likely to die as general population
Mortality is consistently twice as high in transgender people receiving hormone treatment, compared with cisgender individuals in the general population and has not decreased over time, results of a 5 decades–long study from the Netherlands indicate.
Particularly concerning is that trans women (male to female) had a mortality risk nearly double that of cis men (born and remain male) in the general Dutch population (standardized mortality ratio, 1.8), while it was nearly triple that of cis women (SMR, 2.8).
Compared with cisgender women, transgender women were more than twice as likely to die from heart disease, three times more likely to die from lung cancer, and almost nine times more likely to die from infection. HIV-related disease mortality risk was nearly 50 times higher for trans women than cis women, and the risk of suicide was almost seven times greater.
Suicide and other nonnatural causes of death were more common in trans men, compared with cis women.
The report, by Christel J.M. de Blok, MD, of Amsterdam University Medical Center and colleagues, was published online Sept. 2 in The Lancet Diabetes & Endocrinology.
The study included trans men who received testosterone to transition from female to male and trans women who received estrogen plus an antiandrogen to transition from male to female.
Is gender-affirming hormone therapy associated with increased mortality?
Senior author Martin den Heijer, MD, also of Amsterdam University Medical Center, said: “The findings of our large, nationwide study highlight a substantially increased mortality risk among transgender people that has persisted for decades.”
But he pointed out that, overall, the data do not appear to suggest the premature deaths were related to gender-affirming hormone treatment.
However, he conceded that more work is needed on this aspect of care. “There is insufficient evidence at present to determine long-term safety of [gender-affirming hormone treatment]. More research is needed to fully establish whether it in any way affects mortality risk for transgender people,” said Dr. den Heijer.
Endocrinologist Will Malone, MD, of Twin Falls, Idaho, told this news organization, “The study confirms, like others before it, that individuals taking cross-sex hormones are more likely to die prematurely from a number of causes.”
“While the authors speculate that this higher mortality rate is not connected to cross-sex hormones, the study was not designed to be able to make such a claim,” he said, pointing to limited follow-up times.
In an accompanying commentary, Vin Tangpricha, MD, PhD, an endocrinologist from Emory University, Atlanta, noted: “Transgender men do not appear to have as significantly increased comorbidity following receipt of gender-affirming hormone therapy when compared with transgender women.”
Dr. Tangpricha added future studies should examine which factors – hormone regimen, hormone concentrations, access to health care, or other biological factors – explain the higher increased risk of morbidity and mortality observed in trans women as opposed to trans men.
However, Dr. de Blok and colleagues note that, as there were relatively few deaths among transgender men in the cohort, analysis on cause of death in this group is limited.
Transgender individuals more likely to die younger
For their study, Dutch researchers retrospectively examined data from 4,568 transgender people attending their clinic (2,927 transgender women and 1,641 transgender men) treated in 1972-2018. People were excluded if they started treatment before the age of 17 or if they had received puberty-blocking drugs.
Data on age at start of hormone treatment, type of treatment, smoking habits, medical history, and last date of follow-up were gathered from medical records. Where possible, SMRs were determined for deaths among trans men and trans women, compared with rates for the adult Dutch general population.
Median age at the start of cross-sex hormone treatment was 30 years in transgender women and 23 years in transgender men. But the median follow-up time was only 11 years in transgender women and 5 years in transgender men.
A total of 317 (10.8%) trans women died, and 44 (2.7%) trans men died. The findings were higher than expected, compared with the general population of cisgender women (SMR, 1.8) but not cisgender men (SMR 1.2).
Mortality risk did increase more in transgender people who started gender-affirming hormone treatment in the past 2 decades compared with earlier, a fact that Dr. de Blok said was surprising.
Trans men, for example, compared with cis women, had an SMR of 2.1-2.4 in 2000-2018 (compared with 1.8 overall).
“This may be due to changes in clinical practice. ... In the past, health care providers were reluctant to provide hormone treatment to people with a history of comorbidities such as cardiovascular disease. However, because of the many benefits of enabling people to access hormone therapy, nowadays this rarely results in treatment being denied,” Dr. de Blok noted.
More research needed, especially in trans-identifying youth
Dr. Malone remarked that previous studies have shown associations between taking cross-sex hormones and elevated mortality, while also “not designed to detect causality,” have “generally accepted that natal males who take estrogen have estrogen-related increases in the rates of heart disease, stroke, and deep venous thrombosis.”
He added that the risks of testosterone use in natal females were less well established, “but testosterone is also felt to increase their risk of heart disease.”
He stressed the limited follow-up times in the study by Dr. de Blok and colleagues.
This “strongly suggests that the rate of elevated mortality far exceeds the doubling measured by the study, especially for natal females.”
Dr. Malone is one of several clinicians and researchers who has formed the Society for Evidence-Based Gender Medicine, a nonprofit organization that now has at least 100 physician members. SEGM is concerned about the lack of quality evidence for the use of hormonal and surgical interventions as first-line treatment, especially for young people with gender dysphoria.
Dr. Tangpricha also highlighted that the findings do not apply to transgender people who began treatment before age 17 years or those who had taken puberty blockers before gender-affirming hormone treatment.
There are no long-term data on transgender individuals who have received gender-affirming hormone therapies close to the time of puberty.
These data, such as those from the Trans Youth Care study, should be available in the future, he added.
The authors have reported no relevant financial relationships. Dr. Tangpricha has reported receiving funding from the National Institutes of Health and served as past president of the World Professional Association for Transgender Health. He is editor-in-chief of Endocrine Practice and has provided expert testimony for Kirkland and Ellis.
A version of this article first appeared on Medscape.com.
Mortality is consistently twice as high in transgender people receiving hormone treatment, compared with cisgender individuals in the general population and has not decreased over time, results of a 5 decades–long study from the Netherlands indicate.
Particularly concerning is that trans women (male to female) had a mortality risk nearly double that of cis men (born and remain male) in the general Dutch population (standardized mortality ratio, 1.8), while it was nearly triple that of cis women (SMR, 2.8).
Compared with cisgender women, transgender women were more than twice as likely to die from heart disease, three times more likely to die from lung cancer, and almost nine times more likely to die from infection. HIV-related disease mortality risk was nearly 50 times higher for trans women than cis women, and the risk of suicide was almost seven times greater.
Suicide and other nonnatural causes of death were more common in trans men, compared with cis women.
The report, by Christel J.M. de Blok, MD, of Amsterdam University Medical Center and colleagues, was published online Sept. 2 in The Lancet Diabetes & Endocrinology.
The study included trans men who received testosterone to transition from female to male and trans women who received estrogen plus an antiandrogen to transition from male to female.
Is gender-affirming hormone therapy associated with increased mortality?
Senior author Martin den Heijer, MD, also of Amsterdam University Medical Center, said: “The findings of our large, nationwide study highlight a substantially increased mortality risk among transgender people that has persisted for decades.”
But he pointed out that, overall, the data do not appear to suggest the premature deaths were related to gender-affirming hormone treatment.
However, he conceded that more work is needed on this aspect of care. “There is insufficient evidence at present to determine long-term safety of [gender-affirming hormone treatment]. More research is needed to fully establish whether it in any way affects mortality risk for transgender people,” said Dr. den Heijer.
Endocrinologist Will Malone, MD, of Twin Falls, Idaho, told this news organization, “The study confirms, like others before it, that individuals taking cross-sex hormones are more likely to die prematurely from a number of causes.”
“While the authors speculate that this higher mortality rate is not connected to cross-sex hormones, the study was not designed to be able to make such a claim,” he said, pointing to limited follow-up times.
In an accompanying commentary, Vin Tangpricha, MD, PhD, an endocrinologist from Emory University, Atlanta, noted: “Transgender men do not appear to have as significantly increased comorbidity following receipt of gender-affirming hormone therapy when compared with transgender women.”
Dr. Tangpricha added future studies should examine which factors – hormone regimen, hormone concentrations, access to health care, or other biological factors – explain the higher increased risk of morbidity and mortality observed in trans women as opposed to trans men.
However, Dr. de Blok and colleagues note that, as there were relatively few deaths among transgender men in the cohort, analysis on cause of death in this group is limited.
Transgender individuals more likely to die younger
For their study, Dutch researchers retrospectively examined data from 4,568 transgender people attending their clinic (2,927 transgender women and 1,641 transgender men) treated in 1972-2018. People were excluded if they started treatment before the age of 17 or if they had received puberty-blocking drugs.
Data on age at start of hormone treatment, type of treatment, smoking habits, medical history, and last date of follow-up were gathered from medical records. Where possible, SMRs were determined for deaths among trans men and trans women, compared with rates for the adult Dutch general population.
Median age at the start of cross-sex hormone treatment was 30 years in transgender women and 23 years in transgender men. But the median follow-up time was only 11 years in transgender women and 5 years in transgender men.
A total of 317 (10.8%) trans women died, and 44 (2.7%) trans men died. The findings were higher than expected, compared with the general population of cisgender women (SMR, 1.8) but not cisgender men (SMR 1.2).
Mortality risk did increase more in transgender people who started gender-affirming hormone treatment in the past 2 decades compared with earlier, a fact that Dr. de Blok said was surprising.
Trans men, for example, compared with cis women, had an SMR of 2.1-2.4 in 2000-2018 (compared with 1.8 overall).
“This may be due to changes in clinical practice. ... In the past, health care providers were reluctant to provide hormone treatment to people with a history of comorbidities such as cardiovascular disease. However, because of the many benefits of enabling people to access hormone therapy, nowadays this rarely results in treatment being denied,” Dr. de Blok noted.
More research needed, especially in trans-identifying youth
Dr. Malone remarked that previous studies have shown associations between taking cross-sex hormones and elevated mortality, while also “not designed to detect causality,” have “generally accepted that natal males who take estrogen have estrogen-related increases in the rates of heart disease, stroke, and deep venous thrombosis.”
He added that the risks of testosterone use in natal females were less well established, “but testosterone is also felt to increase their risk of heart disease.”
He stressed the limited follow-up times in the study by Dr. de Blok and colleagues.
This “strongly suggests that the rate of elevated mortality far exceeds the doubling measured by the study, especially for natal females.”
Dr. Malone is one of several clinicians and researchers who has formed the Society for Evidence-Based Gender Medicine, a nonprofit organization that now has at least 100 physician members. SEGM is concerned about the lack of quality evidence for the use of hormonal and surgical interventions as first-line treatment, especially for young people with gender dysphoria.
Dr. Tangpricha also highlighted that the findings do not apply to transgender people who began treatment before age 17 years or those who had taken puberty blockers before gender-affirming hormone treatment.
There are no long-term data on transgender individuals who have received gender-affirming hormone therapies close to the time of puberty.
These data, such as those from the Trans Youth Care study, should be available in the future, he added.
The authors have reported no relevant financial relationships. Dr. Tangpricha has reported receiving funding from the National Institutes of Health and served as past president of the World Professional Association for Transgender Health. He is editor-in-chief of Endocrine Practice and has provided expert testimony for Kirkland and Ellis.
A version of this article first appeared on Medscape.com.
Mortality is consistently twice as high in transgender people receiving hormone treatment, compared with cisgender individuals in the general population and has not decreased over time, results of a 5 decades–long study from the Netherlands indicate.
Particularly concerning is that trans women (male to female) had a mortality risk nearly double that of cis men (born and remain male) in the general Dutch population (standardized mortality ratio, 1.8), while it was nearly triple that of cis women (SMR, 2.8).
Compared with cisgender women, transgender women were more than twice as likely to die from heart disease, three times more likely to die from lung cancer, and almost nine times more likely to die from infection. HIV-related disease mortality risk was nearly 50 times higher for trans women than cis women, and the risk of suicide was almost seven times greater.
Suicide and other nonnatural causes of death were more common in trans men, compared with cis women.
The report, by Christel J.M. de Blok, MD, of Amsterdam University Medical Center and colleagues, was published online Sept. 2 in The Lancet Diabetes & Endocrinology.
The study included trans men who received testosterone to transition from female to male and trans women who received estrogen plus an antiandrogen to transition from male to female.
Is gender-affirming hormone therapy associated with increased mortality?
Senior author Martin den Heijer, MD, also of Amsterdam University Medical Center, said: “The findings of our large, nationwide study highlight a substantially increased mortality risk among transgender people that has persisted for decades.”
But he pointed out that, overall, the data do not appear to suggest the premature deaths were related to gender-affirming hormone treatment.
However, he conceded that more work is needed on this aspect of care. “There is insufficient evidence at present to determine long-term safety of [gender-affirming hormone treatment]. More research is needed to fully establish whether it in any way affects mortality risk for transgender people,” said Dr. den Heijer.
Endocrinologist Will Malone, MD, of Twin Falls, Idaho, told this news organization, “The study confirms, like others before it, that individuals taking cross-sex hormones are more likely to die prematurely from a number of causes.”
“While the authors speculate that this higher mortality rate is not connected to cross-sex hormones, the study was not designed to be able to make such a claim,” he said, pointing to limited follow-up times.
In an accompanying commentary, Vin Tangpricha, MD, PhD, an endocrinologist from Emory University, Atlanta, noted: “Transgender men do not appear to have as significantly increased comorbidity following receipt of gender-affirming hormone therapy when compared with transgender women.”
Dr. Tangpricha added future studies should examine which factors – hormone regimen, hormone concentrations, access to health care, or other biological factors – explain the higher increased risk of morbidity and mortality observed in trans women as opposed to trans men.
However, Dr. de Blok and colleagues note that, as there were relatively few deaths among transgender men in the cohort, analysis on cause of death in this group is limited.
Transgender individuals more likely to die younger
For their study, Dutch researchers retrospectively examined data from 4,568 transgender people attending their clinic (2,927 transgender women and 1,641 transgender men) treated in 1972-2018. People were excluded if they started treatment before the age of 17 or if they had received puberty-blocking drugs.
Data on age at start of hormone treatment, type of treatment, smoking habits, medical history, and last date of follow-up were gathered from medical records. Where possible, SMRs were determined for deaths among trans men and trans women, compared with rates for the adult Dutch general population.
Median age at the start of cross-sex hormone treatment was 30 years in transgender women and 23 years in transgender men. But the median follow-up time was only 11 years in transgender women and 5 years in transgender men.
A total of 317 (10.8%) trans women died, and 44 (2.7%) trans men died. The findings were higher than expected, compared with the general population of cisgender women (SMR, 1.8) but not cisgender men (SMR 1.2).
Mortality risk did increase more in transgender people who started gender-affirming hormone treatment in the past 2 decades compared with earlier, a fact that Dr. de Blok said was surprising.
Trans men, for example, compared with cis women, had an SMR of 2.1-2.4 in 2000-2018 (compared with 1.8 overall).
“This may be due to changes in clinical practice. ... In the past, health care providers were reluctant to provide hormone treatment to people with a history of comorbidities such as cardiovascular disease. However, because of the many benefits of enabling people to access hormone therapy, nowadays this rarely results in treatment being denied,” Dr. de Blok noted.
More research needed, especially in trans-identifying youth
Dr. Malone remarked that previous studies have shown associations between taking cross-sex hormones and elevated mortality, while also “not designed to detect causality,” have “generally accepted that natal males who take estrogen have estrogen-related increases in the rates of heart disease, stroke, and deep venous thrombosis.”
He added that the risks of testosterone use in natal females were less well established, “but testosterone is also felt to increase their risk of heart disease.”
He stressed the limited follow-up times in the study by Dr. de Blok and colleagues.
This “strongly suggests that the rate of elevated mortality far exceeds the doubling measured by the study, especially for natal females.”
Dr. Malone is one of several clinicians and researchers who has formed the Society for Evidence-Based Gender Medicine, a nonprofit organization that now has at least 100 physician members. SEGM is concerned about the lack of quality evidence for the use of hormonal and surgical interventions as first-line treatment, especially for young people with gender dysphoria.
Dr. Tangpricha also highlighted that the findings do not apply to transgender people who began treatment before age 17 years or those who had taken puberty blockers before gender-affirming hormone treatment.
There are no long-term data on transgender individuals who have received gender-affirming hormone therapies close to the time of puberty.
These data, such as those from the Trans Youth Care study, should be available in the future, he added.
The authors have reported no relevant financial relationships. Dr. Tangpricha has reported receiving funding from the National Institutes of Health and served as past president of the World Professional Association for Transgender Health. He is editor-in-chief of Endocrine Practice and has provided expert testimony for Kirkland and Ellis.
A version of this article first appeared on Medscape.com.
Elderly mice receive the gift of warmth
Steal from the warm, give to the cold
If there’s one constant in life other than taxes, it’s elderly people moving to Florida. The Sunshine State’s reputation as a giant retirement home needs no elaboration, but why do senior citizens gravitate there? Well, many reasons, but a big one is that, the older you get, the more susceptible and sensitive you are to the cold. And now, according to a new study, we may have identified a culprit.
Researchers from Yale University examined a group of mice and found that the older ones lacked ICL2 cells in their fatty tissue. These cells, at least in younger mice, help restore body heat when exposed to cold temperatures. Lacking these cells meant that older mice had a limited ability to burn their fat and raise their temperature in response to cold.
Well, job done, all we need to do now is stimulate production of ICL2 cells in elderly people, and they’ll be able to go outside in 80-degree weather without a sweater again. Except there’s a problem. In a cruel twist of fate, when the elderly mice were given a molecule to boost ICL2 cell production, they actually became less tolerant of the cold than at baseline. Oops.
The scientists didn’t give up though, and gave their elderly mice ICL2 cells from young mice. This finally did the trick, though we have to admit, if that treatment does eventually scale up to humans, the prospect of a bunch of senior citizens taking ICL2 cells from young people to stay warm does sound a bit like a bad vampire movie premise. “I vant to suck your immune cell group 2 innate lymphoid cells!” Not the most pithy catch phrase in the world.
Grocery store tapping your subconscious? It’s a good thing
We all know there’s marketing and functionality elements to grocery stores and how they’re set up for your shopping pleasure. But what if I told you that the good old supermarket subconscious trick works on how healthy food decisions are?
In a recent study, researchers at the University of Southampton in England found that if you placed a wider selection of fruits and vegetables near the entrances and more nonfood items near checkouts, sales decreased on the sweets and increased on the produce. “The findings of our study suggest that a healthier store layout could lead to nearly 10,000 extra portions of fruit and vegetables and approximately 1,500 fewer portions of confectionery being sold on a weekly basis in each store,” lead author Dr. Christina Vogel explained.
You’re probably thinking that food placement studies aren’t new. That’s true, but this one went above and beyond. Instead of just looking at the influence placement has on purchase, this one took it further by trying to reduce the consumers’ “calorie opportunities” and examining the effect on sales. Also, customer loyalty, patterns, and diets were taken into account across multiple household members.
The researchers think shifting the layouts in grocery stores could shift people’s food choices, producing a domino effect on the population’s overall diet. With obesity, diabetes, and cardiology concerns always looming, swaying consumers toward healthier food choices makes for better public health overall.
So if you feel like you’re being subconsciously assaulted by veggies every time you walk into Trader Joe’s, just know it’s for your own good.
TikTokers take on tics
We know TikTok is what makes a lot of teens and young adults tick, but what if TikTokers are actually catching tic disorders from other TikTokers?
TikTok blew up during the pandemic. Many people were stuck at home and had nothing better to do than make and watch TikTok videos. The pandemic brought isolation, uncertainty, and anxiety. The stress that followed may have caused many people, mostly women and young girls, to develop tic disorders.
There’s a TikTok for everything, whether it’s a new dance or a recipe. Many people even use TikTok to speak out about their illnesses. Several TikTokers have Tourette’s syndrome and show their tics on their videos. It appears that some audience members actually “catch” the tics from watching the videos and are then unable to stop certain jerking movements or saying specific words.
Neurologists at the University of Calgary (Alta.), who were hearing from colleagues and getting referrals of such patients, called it “an epidemic within the pandemic.” The behavior is not actually Tourette’s, they told Vice, but the patients “cannot stop, and we have absolutely witnessed that.”
There is, of course, controversy over the issue. One individual with the condition said, “I feel like there’s a lot of really weird, backwards stigma on TikTok about tic disorders. Like, you aren’t allowed to have one unless it’s this one.”
Who would have guessed that people would disagree over stuff on the Internet?
Look on the bright side: Obesity edition
The pandemic may have postponed “Top Gun: Maverick” and “The Marvelous Mrs. Maisel” until who-knows-when, but we here at LOTME are happy to announce the nearly-as-anticipated return of Bacteria vs. the World.
As you may recall from our last edition of BVTW, bacteria battled the ghost of Charles Darwin, who had taken the earthly form of antibiotics capable of stopping bacterial evolution. Tonight, our prokaryotic protagonists take on an equally relentless and ubiquitous challenger: obesity.
Specifically, we’re putting bacteria up against the obesity survival paradox, that phenomenon in which obesity and overweight seem to protect against – yes, you guessed it – bacterial infections.
A Swedish research team observed a group of 2,196 individual adults who received care for suspected severe bacterial infection at Skaraborg Hospital in Skövde. One year after hospitalization, 26% of normal-weight (body mass index, 18.5-24.99) patients were dead, compared with 17% of overweight (BMI, 25.0-29.99), 16% of obese (BMI, 30.0-34.99), and 9% of very obese (BMI >35) patients.
These results confirm the obesity survival paradox, but “what we don’t know is how being overweight can benefit the patient with a bacterial infection, or whether it’s connected with functions in the immune system and how they’re regulated,” lead author Dr. Åsa Alsiö said in a written statement.
A spokes-cell for the bacteria disputed the results and challenged the legitimacy of the investigators. When asked if there should be some sort of reexamination of the findings, he/she/it replied: “You bet your flagella.” We then pointed out that humans don’t have flagellum, and the representative raised his/her/its flagella in what could only be considered an obscene gesture.
Steal from the warm, give to the cold
If there’s one constant in life other than taxes, it’s elderly people moving to Florida. The Sunshine State’s reputation as a giant retirement home needs no elaboration, but why do senior citizens gravitate there? Well, many reasons, but a big one is that, the older you get, the more susceptible and sensitive you are to the cold. And now, according to a new study, we may have identified a culprit.
Researchers from Yale University examined a group of mice and found that the older ones lacked ICL2 cells in their fatty tissue. These cells, at least in younger mice, help restore body heat when exposed to cold temperatures. Lacking these cells meant that older mice had a limited ability to burn their fat and raise their temperature in response to cold.
Well, job done, all we need to do now is stimulate production of ICL2 cells in elderly people, and they’ll be able to go outside in 80-degree weather without a sweater again. Except there’s a problem. In a cruel twist of fate, when the elderly mice were given a molecule to boost ICL2 cell production, they actually became less tolerant of the cold than at baseline. Oops.
The scientists didn’t give up though, and gave their elderly mice ICL2 cells from young mice. This finally did the trick, though we have to admit, if that treatment does eventually scale up to humans, the prospect of a bunch of senior citizens taking ICL2 cells from young people to stay warm does sound a bit like a bad vampire movie premise. “I vant to suck your immune cell group 2 innate lymphoid cells!” Not the most pithy catch phrase in the world.
Grocery store tapping your subconscious? It’s a good thing
We all know there’s marketing and functionality elements to grocery stores and how they’re set up for your shopping pleasure. But what if I told you that the good old supermarket subconscious trick works on how healthy food decisions are?
In a recent study, researchers at the University of Southampton in England found that if you placed a wider selection of fruits and vegetables near the entrances and more nonfood items near checkouts, sales decreased on the sweets and increased on the produce. “The findings of our study suggest that a healthier store layout could lead to nearly 10,000 extra portions of fruit and vegetables and approximately 1,500 fewer portions of confectionery being sold on a weekly basis in each store,” lead author Dr. Christina Vogel explained.
You’re probably thinking that food placement studies aren’t new. That’s true, but this one went above and beyond. Instead of just looking at the influence placement has on purchase, this one took it further by trying to reduce the consumers’ “calorie opportunities” and examining the effect on sales. Also, customer loyalty, patterns, and diets were taken into account across multiple household members.
The researchers think shifting the layouts in grocery stores could shift people’s food choices, producing a domino effect on the population’s overall diet. With obesity, diabetes, and cardiology concerns always looming, swaying consumers toward healthier food choices makes for better public health overall.
So if you feel like you’re being subconsciously assaulted by veggies every time you walk into Trader Joe’s, just know it’s for your own good.
TikTokers take on tics
We know TikTok is what makes a lot of teens and young adults tick, but what if TikTokers are actually catching tic disorders from other TikTokers?
TikTok blew up during the pandemic. Many people were stuck at home and had nothing better to do than make and watch TikTok videos. The pandemic brought isolation, uncertainty, and anxiety. The stress that followed may have caused many people, mostly women and young girls, to develop tic disorders.
There’s a TikTok for everything, whether it’s a new dance or a recipe. Many people even use TikTok to speak out about their illnesses. Several TikTokers have Tourette’s syndrome and show their tics on their videos. It appears that some audience members actually “catch” the tics from watching the videos and are then unable to stop certain jerking movements or saying specific words.
Neurologists at the University of Calgary (Alta.), who were hearing from colleagues and getting referrals of such patients, called it “an epidemic within the pandemic.” The behavior is not actually Tourette’s, they told Vice, but the patients “cannot stop, and we have absolutely witnessed that.”
There is, of course, controversy over the issue. One individual with the condition said, “I feel like there’s a lot of really weird, backwards stigma on TikTok about tic disorders. Like, you aren’t allowed to have one unless it’s this one.”
Who would have guessed that people would disagree over stuff on the Internet?
Look on the bright side: Obesity edition
The pandemic may have postponed “Top Gun: Maverick” and “The Marvelous Mrs. Maisel” until who-knows-when, but we here at LOTME are happy to announce the nearly-as-anticipated return of Bacteria vs. the World.
As you may recall from our last edition of BVTW, bacteria battled the ghost of Charles Darwin, who had taken the earthly form of antibiotics capable of stopping bacterial evolution. Tonight, our prokaryotic protagonists take on an equally relentless and ubiquitous challenger: obesity.
Specifically, we’re putting bacteria up against the obesity survival paradox, that phenomenon in which obesity and overweight seem to protect against – yes, you guessed it – bacterial infections.
A Swedish research team observed a group of 2,196 individual adults who received care for suspected severe bacterial infection at Skaraborg Hospital in Skövde. One year after hospitalization, 26% of normal-weight (body mass index, 18.5-24.99) patients were dead, compared with 17% of overweight (BMI, 25.0-29.99), 16% of obese (BMI, 30.0-34.99), and 9% of very obese (BMI >35) patients.
These results confirm the obesity survival paradox, but “what we don’t know is how being overweight can benefit the patient with a bacterial infection, or whether it’s connected with functions in the immune system and how they’re regulated,” lead author Dr. Åsa Alsiö said in a written statement.
A spokes-cell for the bacteria disputed the results and challenged the legitimacy of the investigators. When asked if there should be some sort of reexamination of the findings, he/she/it replied: “You bet your flagella.” We then pointed out that humans don’t have flagellum, and the representative raised his/her/its flagella in what could only be considered an obscene gesture.
Steal from the warm, give to the cold
If there’s one constant in life other than taxes, it’s elderly people moving to Florida. The Sunshine State’s reputation as a giant retirement home needs no elaboration, but why do senior citizens gravitate there? Well, many reasons, but a big one is that, the older you get, the more susceptible and sensitive you are to the cold. And now, according to a new study, we may have identified a culprit.
Researchers from Yale University examined a group of mice and found that the older ones lacked ICL2 cells in their fatty tissue. These cells, at least in younger mice, help restore body heat when exposed to cold temperatures. Lacking these cells meant that older mice had a limited ability to burn their fat and raise their temperature in response to cold.
Well, job done, all we need to do now is stimulate production of ICL2 cells in elderly people, and they’ll be able to go outside in 80-degree weather without a sweater again. Except there’s a problem. In a cruel twist of fate, when the elderly mice were given a molecule to boost ICL2 cell production, they actually became less tolerant of the cold than at baseline. Oops.
The scientists didn’t give up though, and gave their elderly mice ICL2 cells from young mice. This finally did the trick, though we have to admit, if that treatment does eventually scale up to humans, the prospect of a bunch of senior citizens taking ICL2 cells from young people to stay warm does sound a bit like a bad vampire movie premise. “I vant to suck your immune cell group 2 innate lymphoid cells!” Not the most pithy catch phrase in the world.
Grocery store tapping your subconscious? It’s a good thing
We all know there’s marketing and functionality elements to grocery stores and how they’re set up for your shopping pleasure. But what if I told you that the good old supermarket subconscious trick works on how healthy food decisions are?
In a recent study, researchers at the University of Southampton in England found that if you placed a wider selection of fruits and vegetables near the entrances and more nonfood items near checkouts, sales decreased on the sweets and increased on the produce. “The findings of our study suggest that a healthier store layout could lead to nearly 10,000 extra portions of fruit and vegetables and approximately 1,500 fewer portions of confectionery being sold on a weekly basis in each store,” lead author Dr. Christina Vogel explained.
You’re probably thinking that food placement studies aren’t new. That’s true, but this one went above and beyond. Instead of just looking at the influence placement has on purchase, this one took it further by trying to reduce the consumers’ “calorie opportunities” and examining the effect on sales. Also, customer loyalty, patterns, and diets were taken into account across multiple household members.
The researchers think shifting the layouts in grocery stores could shift people’s food choices, producing a domino effect on the population’s overall diet. With obesity, diabetes, and cardiology concerns always looming, swaying consumers toward healthier food choices makes for better public health overall.
So if you feel like you’re being subconsciously assaulted by veggies every time you walk into Trader Joe’s, just know it’s for your own good.
TikTokers take on tics
We know TikTok is what makes a lot of teens and young adults tick, but what if TikTokers are actually catching tic disorders from other TikTokers?
TikTok blew up during the pandemic. Many people were stuck at home and had nothing better to do than make and watch TikTok videos. The pandemic brought isolation, uncertainty, and anxiety. The stress that followed may have caused many people, mostly women and young girls, to develop tic disorders.
There’s a TikTok for everything, whether it’s a new dance or a recipe. Many people even use TikTok to speak out about their illnesses. Several TikTokers have Tourette’s syndrome and show their tics on their videos. It appears that some audience members actually “catch” the tics from watching the videos and are then unable to stop certain jerking movements or saying specific words.
Neurologists at the University of Calgary (Alta.), who were hearing from colleagues and getting referrals of such patients, called it “an epidemic within the pandemic.” The behavior is not actually Tourette’s, they told Vice, but the patients “cannot stop, and we have absolutely witnessed that.”
There is, of course, controversy over the issue. One individual with the condition said, “I feel like there’s a lot of really weird, backwards stigma on TikTok about tic disorders. Like, you aren’t allowed to have one unless it’s this one.”
Who would have guessed that people would disagree over stuff on the Internet?
Look on the bright side: Obesity edition
The pandemic may have postponed “Top Gun: Maverick” and “The Marvelous Mrs. Maisel” until who-knows-when, but we here at LOTME are happy to announce the nearly-as-anticipated return of Bacteria vs. the World.
As you may recall from our last edition of BVTW, bacteria battled the ghost of Charles Darwin, who had taken the earthly form of antibiotics capable of stopping bacterial evolution. Tonight, our prokaryotic protagonists take on an equally relentless and ubiquitous challenger: obesity.
Specifically, we’re putting bacteria up against the obesity survival paradox, that phenomenon in which obesity and overweight seem to protect against – yes, you guessed it – bacterial infections.
A Swedish research team observed a group of 2,196 individual adults who received care for suspected severe bacterial infection at Skaraborg Hospital in Skövde. One year after hospitalization, 26% of normal-weight (body mass index, 18.5-24.99) patients were dead, compared with 17% of overweight (BMI, 25.0-29.99), 16% of obese (BMI, 30.0-34.99), and 9% of very obese (BMI >35) patients.
These results confirm the obesity survival paradox, but “what we don’t know is how being overweight can benefit the patient with a bacterial infection, or whether it’s connected with functions in the immune system and how they’re regulated,” lead author Dr. Åsa Alsiö said in a written statement.
A spokes-cell for the bacteria disputed the results and challenged the legitimacy of the investigators. When asked if there should be some sort of reexamination of the findings, he/she/it replied: “You bet your flagella.” We then pointed out that humans don’t have flagellum, and the representative raised his/her/its flagella in what could only be considered an obscene gesture.
Medical education must takes broader view of disabilities
“All physicians, regardless of specialty, will work with patients with disabilities,” Corrie Harris, MD, of the University of Louisville (Ky.), said in a plenary session presentation at the 2021 virtual Pediatric Hospital Medicine conference.
Disabilities vary in their visibility, from cognitive and sensory impairments that are not immediately obvious to an obvious physical disability, she said.
One in four adults and one in six children in the United States has a disability, said Dr. Harris. The prevalence of disability increases with age, but occurs across the lifespan, and will likely increase in the future with greater improvements in health care overall.
Dr. Harris reviewed the current conceptual model that forms the basis for the World Health Organization definition of functioning disability. This “functional model” defines disability as caused by interactions between health conditions and the environment, and the response is to “prioritize function to meet patient goals,” Dr. Harris said at the meeting, sponsored by the Society of Hospital Medicine, the American Academy of Pediatrics, and the Academic Pediatric Association.
This model is based on collaboration between health care providers and their patients with disabilities, and training is important to help providers make this collaboration successful, said Dr. Harris. Without training, physicians may be ineffective in communicating with patients with disabilities by not speaking directly to the patient, not speaking in a way the patient can understand clearly, and not providing accessible patient education materials. Physicians also tend to minimize the extent of the patient’s expertise in their own condition based on their lived experiences, and tend to underestimate the abilities of patients with disabilities.
However, direct experience with disabled patients and an understanding of the health disparities they endure can help physicians look at these patients “through a more intersectional lens,” that also takes into account social determinants of health, Dr. Harris said. “I have found that people with disabilities are the best teachers about disability, because they have expertise that comes from their lived experience.”
Patients are the best teachers
Several initiatives are helping physicians to bridge this gap in understanding and reduce disparities in care. One such program is FRAME: Faces Redefining the Art of Medical Education. FRAME is a web-based film library designed to present medical information to health care providers in training, clinicians, families, and communities in a dignified and humanizing way. FRAME was developed in part by fashion photographer Rick Guidotti, who was inspired after meeting a young woman with albinism to create Positive Exposure, an ongoing project featuring children and adolescents with various disabilities.
FRAME films are “short films presenting all the basic hallmark characteristics of a certain genetic condition, but presented by somebody living with that condition,” said Mr. Guidotti in his presentation during the session.
The National Curriculum Initiative in Developmental Medicine (NCIDM) is designed to incorporate care for individuals with disabilities into medical education. NCIDM is a project created by the American Academy of Developmental Medicine and Dentistry (AADMD).
“The need for this program is that there is no U.S. requirement for medical schools to teach about intellectual and developmental disabilities,” Priya Chandan, MD, also of the University of Louisville, said in her presentation during the session. “Approximately 81% of graduating medical students have no training in caring for adults with disabilities,” said Dr. Chandan, who serves as director of the NCIDM.
The current NCIDM was created as a 5-year partnership between the AADMD and Special Olympics, supported in part by the Centers for Disease Control and Prevention, Dr. Chandan said. The purpose was to provide training to medical students in the field of developmental medicine, meaning the care of individuals with intellectual/developmental disabilities (IDD) across the lifespan. The AADMD has expanded to 26 medical schools in the United States and will reach approximately 4,000 medical students by the conclusion of the current initiative.
One challenge in medical education is getting past the idea that people living with disabilities need to be fixed, said Dr. Chandan. The NCIDM approach reflects Mr. Guidotti’s approach in both the FRAME initiatives and his Positive Exposure foundation, with a focus on treating people as people, and letting individuals with disabilities represent themselves.
Dr. Chandan described the NCIDM curriculum as allowing for flexible teaching methodologies and materials, as long as they meet the NCIDM-created learning goals and objectives. The curriculum also includes standardized evaluations. Each NCIDM program in a participating medical school includes a faculty champion, and the curriculum supports meeting people with IDD not only inside medical settings, but also outside in the community.
NCIDM embraces the idea of community-engaged scholarship, which Dr. Chandan defined as “a form of scholarship that directly benefits the community and is consistent with university and unit missions.” This method combined teaching and conducting research while providing a service to the community.
The next steps for the current NCIDM initiative are to complete collection of data and course evaluations from participating schools by early 2022, followed by continued dissemination and collaboration through AADMD.
Overall, the content of the curriculum explores how and where IDD fits into clinical care, Dr. Chandan said, who also emphasized the implications of communication. “How we think affects how we communicate,” she added. Be mindful of the language used to talk to and about patients with disabilities, both to colleagues and to learners.
When talking to the patient, find something in common, beyond the diagnosis, said Dr. Chandan. Remember that some disabilities are visible and some are not. “Treat people with respect, because you won’t know what their functional level is just by looking,” she concluded.
The presenters had no financial conflicts to disclose.
“All physicians, regardless of specialty, will work with patients with disabilities,” Corrie Harris, MD, of the University of Louisville (Ky.), said in a plenary session presentation at the 2021 virtual Pediatric Hospital Medicine conference.
Disabilities vary in their visibility, from cognitive and sensory impairments that are not immediately obvious to an obvious physical disability, she said.
One in four adults and one in six children in the United States has a disability, said Dr. Harris. The prevalence of disability increases with age, but occurs across the lifespan, and will likely increase in the future with greater improvements in health care overall.
Dr. Harris reviewed the current conceptual model that forms the basis for the World Health Organization definition of functioning disability. This “functional model” defines disability as caused by interactions between health conditions and the environment, and the response is to “prioritize function to meet patient goals,” Dr. Harris said at the meeting, sponsored by the Society of Hospital Medicine, the American Academy of Pediatrics, and the Academic Pediatric Association.
This model is based on collaboration between health care providers and their patients with disabilities, and training is important to help providers make this collaboration successful, said Dr. Harris. Without training, physicians may be ineffective in communicating with patients with disabilities by not speaking directly to the patient, not speaking in a way the patient can understand clearly, and not providing accessible patient education materials. Physicians also tend to minimize the extent of the patient’s expertise in their own condition based on their lived experiences, and tend to underestimate the abilities of patients with disabilities.
However, direct experience with disabled patients and an understanding of the health disparities they endure can help physicians look at these patients “through a more intersectional lens,” that also takes into account social determinants of health, Dr. Harris said. “I have found that people with disabilities are the best teachers about disability, because they have expertise that comes from their lived experience.”
Patients are the best teachers
Several initiatives are helping physicians to bridge this gap in understanding and reduce disparities in care. One such program is FRAME: Faces Redefining the Art of Medical Education. FRAME is a web-based film library designed to present medical information to health care providers in training, clinicians, families, and communities in a dignified and humanizing way. FRAME was developed in part by fashion photographer Rick Guidotti, who was inspired after meeting a young woman with albinism to create Positive Exposure, an ongoing project featuring children and adolescents with various disabilities.
FRAME films are “short films presenting all the basic hallmark characteristics of a certain genetic condition, but presented by somebody living with that condition,” said Mr. Guidotti in his presentation during the session.
The National Curriculum Initiative in Developmental Medicine (NCIDM) is designed to incorporate care for individuals with disabilities into medical education. NCIDM is a project created by the American Academy of Developmental Medicine and Dentistry (AADMD).
“The need for this program is that there is no U.S. requirement for medical schools to teach about intellectual and developmental disabilities,” Priya Chandan, MD, also of the University of Louisville, said in her presentation during the session. “Approximately 81% of graduating medical students have no training in caring for adults with disabilities,” said Dr. Chandan, who serves as director of the NCIDM.
The current NCIDM was created as a 5-year partnership between the AADMD and Special Olympics, supported in part by the Centers for Disease Control and Prevention, Dr. Chandan said. The purpose was to provide training to medical students in the field of developmental medicine, meaning the care of individuals with intellectual/developmental disabilities (IDD) across the lifespan. The AADMD has expanded to 26 medical schools in the United States and will reach approximately 4,000 medical students by the conclusion of the current initiative.
One challenge in medical education is getting past the idea that people living with disabilities need to be fixed, said Dr. Chandan. The NCIDM approach reflects Mr. Guidotti’s approach in both the FRAME initiatives and his Positive Exposure foundation, with a focus on treating people as people, and letting individuals with disabilities represent themselves.
Dr. Chandan described the NCIDM curriculum as allowing for flexible teaching methodologies and materials, as long as they meet the NCIDM-created learning goals and objectives. The curriculum also includes standardized evaluations. Each NCIDM program in a participating medical school includes a faculty champion, and the curriculum supports meeting people with IDD not only inside medical settings, but also outside in the community.
NCIDM embraces the idea of community-engaged scholarship, which Dr. Chandan defined as “a form of scholarship that directly benefits the community and is consistent with university and unit missions.” This method combined teaching and conducting research while providing a service to the community.
The next steps for the current NCIDM initiative are to complete collection of data and course evaluations from participating schools by early 2022, followed by continued dissemination and collaboration through AADMD.
Overall, the content of the curriculum explores how and where IDD fits into clinical care, Dr. Chandan said, who also emphasized the implications of communication. “How we think affects how we communicate,” she added. Be mindful of the language used to talk to and about patients with disabilities, both to colleagues and to learners.
When talking to the patient, find something in common, beyond the diagnosis, said Dr. Chandan. Remember that some disabilities are visible and some are not. “Treat people with respect, because you won’t know what their functional level is just by looking,” she concluded.
The presenters had no financial conflicts to disclose.
“All physicians, regardless of specialty, will work with patients with disabilities,” Corrie Harris, MD, of the University of Louisville (Ky.), said in a plenary session presentation at the 2021 virtual Pediatric Hospital Medicine conference.
Disabilities vary in their visibility, from cognitive and sensory impairments that are not immediately obvious to an obvious physical disability, she said.
One in four adults and one in six children in the United States has a disability, said Dr. Harris. The prevalence of disability increases with age, but occurs across the lifespan, and will likely increase in the future with greater improvements in health care overall.
Dr. Harris reviewed the current conceptual model that forms the basis for the World Health Organization definition of functioning disability. This “functional model” defines disability as caused by interactions between health conditions and the environment, and the response is to “prioritize function to meet patient goals,” Dr. Harris said at the meeting, sponsored by the Society of Hospital Medicine, the American Academy of Pediatrics, and the Academic Pediatric Association.
This model is based on collaboration between health care providers and their patients with disabilities, and training is important to help providers make this collaboration successful, said Dr. Harris. Without training, physicians may be ineffective in communicating with patients with disabilities by not speaking directly to the patient, not speaking in a way the patient can understand clearly, and not providing accessible patient education materials. Physicians also tend to minimize the extent of the patient’s expertise in their own condition based on their lived experiences, and tend to underestimate the abilities of patients with disabilities.
However, direct experience with disabled patients and an understanding of the health disparities they endure can help physicians look at these patients “through a more intersectional lens,” that also takes into account social determinants of health, Dr. Harris said. “I have found that people with disabilities are the best teachers about disability, because they have expertise that comes from their lived experience.”
Patients are the best teachers
Several initiatives are helping physicians to bridge this gap in understanding and reduce disparities in care. One such program is FRAME: Faces Redefining the Art of Medical Education. FRAME is a web-based film library designed to present medical information to health care providers in training, clinicians, families, and communities in a dignified and humanizing way. FRAME was developed in part by fashion photographer Rick Guidotti, who was inspired after meeting a young woman with albinism to create Positive Exposure, an ongoing project featuring children and adolescents with various disabilities.
FRAME films are “short films presenting all the basic hallmark characteristics of a certain genetic condition, but presented by somebody living with that condition,” said Mr. Guidotti in his presentation during the session.
The National Curriculum Initiative in Developmental Medicine (NCIDM) is designed to incorporate care for individuals with disabilities into medical education. NCIDM is a project created by the American Academy of Developmental Medicine and Dentistry (AADMD).
“The need for this program is that there is no U.S. requirement for medical schools to teach about intellectual and developmental disabilities,” Priya Chandan, MD, also of the University of Louisville, said in her presentation during the session. “Approximately 81% of graduating medical students have no training in caring for adults with disabilities,” said Dr. Chandan, who serves as director of the NCIDM.
The current NCIDM was created as a 5-year partnership between the AADMD and Special Olympics, supported in part by the Centers for Disease Control and Prevention, Dr. Chandan said. The purpose was to provide training to medical students in the field of developmental medicine, meaning the care of individuals with intellectual/developmental disabilities (IDD) across the lifespan. The AADMD has expanded to 26 medical schools in the United States and will reach approximately 4,000 medical students by the conclusion of the current initiative.
One challenge in medical education is getting past the idea that people living with disabilities need to be fixed, said Dr. Chandan. The NCIDM approach reflects Mr. Guidotti’s approach in both the FRAME initiatives and his Positive Exposure foundation, with a focus on treating people as people, and letting individuals with disabilities represent themselves.
Dr. Chandan described the NCIDM curriculum as allowing for flexible teaching methodologies and materials, as long as they meet the NCIDM-created learning goals and objectives. The curriculum also includes standardized evaluations. Each NCIDM program in a participating medical school includes a faculty champion, and the curriculum supports meeting people with IDD not only inside medical settings, but also outside in the community.
NCIDM embraces the idea of community-engaged scholarship, which Dr. Chandan defined as “a form of scholarship that directly benefits the community and is consistent with university and unit missions.” This method combined teaching and conducting research while providing a service to the community.
The next steps for the current NCIDM initiative are to complete collection of data and course evaluations from participating schools by early 2022, followed by continued dissemination and collaboration through AADMD.
Overall, the content of the curriculum explores how and where IDD fits into clinical care, Dr. Chandan said, who also emphasized the implications of communication. “How we think affects how we communicate,” she added. Be mindful of the language used to talk to and about patients with disabilities, both to colleagues and to learners.
When talking to the patient, find something in common, beyond the diagnosis, said Dr. Chandan. Remember that some disabilities are visible and some are not. “Treat people with respect, because you won’t know what their functional level is just by looking,” she concluded.
The presenters had no financial conflicts to disclose.
FROM PHM 2021
Walking 7,000 steps per day may be enough to reduce mortality risk
based on prospective data from more than 2,000 people.
Findings were consistent regardless of race or sex, and step intensity had no impact on mortality risk, reported lead author Amanda E. Paluch, PhD, of the University of Massachusetts Amherst, and colleagues.
“In response to the need for empirical data on the associations of step volume and intensity with mortality in younger and diverse populations, we conducted a prospective study in middle-aged Black and White adults followed up for mortality for approximately 11 years,” the investigators wrote in JAMA Network Open. “The objectives of our study were to examine the associations of step volume and intensity with mortality overall and by race and sex.”
Steps per day is easy to communicate
Dr. Paluch noted that steps per day is a “very appealing metric to quantify activity,” for both researchers and laypeople.
“Steps per day is simple and easy to communicate in public health and clinical settings,” Dr. Paluch said in an interview. “Additionally, the dramatic growth of wearable devices measuring steps makes it appealing and broadens the reach of promoting physical activity to many individuals. Walking is an activity that most of the general population can pursue. It can also be accumulated throughout daily living and may seem more achievable to fit into busy lives than a structured exercise session.”
The present investigation was conducted as part of the Coronary Artery Risk Development in Young Adults (CARDIA) Study. The dataset included 2,110 participants ranging from 38-50 years of age, with a mean age of 45.2 years. A slightly higher proportion of the subjects were women (57.1%) and White (57.9%).
All participants wore an ActiGraph 7164 accelerometer for 1 week and were then followed for death of any cause, with a mean follow-up of 10.8 years. Multivariable-adjusted Cox proportional hazards models included a range of covariates, such as smoking history, body weight, alcohol intake, blood pressure, total cholesterol, and others. Step counts were grouped into low (less than 7,000 steps per day), moderate (7,000-9,999), and high (at least 10,000 steps per day) categories.
Compared with individuals who took less than 7,000 steps per day, those who took 7,000-9,000 steps per day had a 72% reduced risk of mortality (hazard ratio, 0.28; 95% confidence interval, 0.15-0.54). Going beyond 10,000 steps appeared to add no benefit, based on a 55% lower risk of all-cause mortality in the highly active group, compared with those taking less than 7,000 steps per day (HR, 0.45; 95% CI, 0.25-0.81).
Walking faster didn’t appear to help either, as stepping intensity was not associated with mortality risk; however, Dr. Paluch urged a cautious interpretation of this finding, calling it “inconclusive,” and suggesting that more research is needed.
“It is also important to note that this study only looked at premature all-cause mortality, and therefore the results may be different for other health outcomes, such as the risk of cardiovascular disease, or diabetes, cancer, or mental health outcomes,” Dr. Paluch said.
“The results from our study demonstrated that those who are least active have the most to gain,” Dr. Paluch said. “Even small incremental increases in steps per day are associated with a lower mortality risk during middle age. A walking plan that gradually works up toward 7,000-10,000 steps per day in middle-aged adults may have health benefits and lower the risk of premature mortality.”
Causality cannot be confirmed
According to Raed A. Joundi, MD, DPhil, of the University of Calgary (Alta.), the study size, diverse population, and length of follow-up should increase confidence in the findings, although a causal relationship remains elusive.
“As this study is observational, causality between step count and mortality cannot be confirmed; however, the authors accounted for many factors, and the association was consistent in different analyses and with prior literature,” Dr. Joundi said in an interview. “The authors did not assess the risk of other important events like stroke and heart attack, and these could be addressed in a future study.”
Dr. Joundi, who recently published a study linking exercise with a 50% reduction in mortality after stroke, noted that “physical activity has innumerable benefits, and it’s important that people engage in activity that can be regular and consistent, regardless of the type or intensity.”
To this end, he highlighted the use of “devices capable of monitoring step count, which can be an important motivational tool,” and suggested that these findings may bring a sigh of relief to step counters who come up a little short on a common daily goal.
“A target of 10,000 steps is often used for public health promotion, and this study now provides convincing observational evidence that it may be an optimal step count target for mortality reduction,” Dr. Joundi said. “However, if 10,000 steps per day is not feasible, 7,000 steps seems to be a very reasonable target given its association with markedly lower mortality in this study.”
Not all step counters are equal
Unfortunately, such recommendations are complicated by uncertainty in measurement, as widely used step counting devices, like smart watches, may not yield the same results as research-grade accelerometers, according to Nicole L. Spartano, PhD, of Boston University.
“Many comparison studies have been conducted in laboratory settings among young healthy adults, but these do not necessarily reflect real-life wear experiences that will be generalizable to the population as a whole,” Dr. Spartano wrote in an accompanying editorial.
She called for large-scale comparison studies to compare research-grade and consumer devices.
“The reason for conducting comparison studies is not to develop distinct guidelines for different devices or subgroups of the population, but rather to understand the variability so that we can develop one clear message that is most appropriate to the public,” Dr. Spartano wrote. “Some devices may have bias in terms of step measurement at different activity intensity and may not record steps as accurately in older adults or individuals with obesity or mobility disorders. For example, when adults who were obese wore an ActiGraph monitor in a laboratory setting, the device only recorded 80% of steps walked at a moderate pace, while other devices recorded close to 100% of steps walked. If we in the public health community are to move toward using these devices more for physical activity prescription, these details will need to be explored in more depth.”
CARDIA was conducted and supported by the National Heart, Lung, and Blood Institute in collaboration with the University of Alabama at Birmingham, Northwestern University, the University of Minnesota, and the Kaiser Foundation Research Institute. Some study authors received grants from the National Institutes of Health and the Kaiser Foundation Research Institute. Dr Spartano disclosed relationships with Novo Nordisk, the American Heart Association, the Alzheimer’s Association, and the National Institutes of Health. Dr. Joundi and Dr. Paluch disclosed no relevant financial relationships.
based on prospective data from more than 2,000 people.
Findings were consistent regardless of race or sex, and step intensity had no impact on mortality risk, reported lead author Amanda E. Paluch, PhD, of the University of Massachusetts Amherst, and colleagues.
“In response to the need for empirical data on the associations of step volume and intensity with mortality in younger and diverse populations, we conducted a prospective study in middle-aged Black and White adults followed up for mortality for approximately 11 years,” the investigators wrote in JAMA Network Open. “The objectives of our study were to examine the associations of step volume and intensity with mortality overall and by race and sex.”
Steps per day is easy to communicate
Dr. Paluch noted that steps per day is a “very appealing metric to quantify activity,” for both researchers and laypeople.
“Steps per day is simple and easy to communicate in public health and clinical settings,” Dr. Paluch said in an interview. “Additionally, the dramatic growth of wearable devices measuring steps makes it appealing and broadens the reach of promoting physical activity to many individuals. Walking is an activity that most of the general population can pursue. It can also be accumulated throughout daily living and may seem more achievable to fit into busy lives than a structured exercise session.”
The present investigation was conducted as part of the Coronary Artery Risk Development in Young Adults (CARDIA) Study. The dataset included 2,110 participants ranging from 38-50 years of age, with a mean age of 45.2 years. A slightly higher proportion of the subjects were women (57.1%) and White (57.9%).
All participants wore an ActiGraph 7164 accelerometer for 1 week and were then followed for death of any cause, with a mean follow-up of 10.8 years. Multivariable-adjusted Cox proportional hazards models included a range of covariates, such as smoking history, body weight, alcohol intake, blood pressure, total cholesterol, and others. Step counts were grouped into low (less than 7,000 steps per day), moderate (7,000-9,999), and high (at least 10,000 steps per day) categories.
Compared with individuals who took less than 7,000 steps per day, those who took 7,000-9,000 steps per day had a 72% reduced risk of mortality (hazard ratio, 0.28; 95% confidence interval, 0.15-0.54). Going beyond 10,000 steps appeared to add no benefit, based on a 55% lower risk of all-cause mortality in the highly active group, compared with those taking less than 7,000 steps per day (HR, 0.45; 95% CI, 0.25-0.81).
Walking faster didn’t appear to help either, as stepping intensity was not associated with mortality risk; however, Dr. Paluch urged a cautious interpretation of this finding, calling it “inconclusive,” and suggesting that more research is needed.
“It is also important to note that this study only looked at premature all-cause mortality, and therefore the results may be different for other health outcomes, such as the risk of cardiovascular disease, or diabetes, cancer, or mental health outcomes,” Dr. Paluch said.
“The results from our study demonstrated that those who are least active have the most to gain,” Dr. Paluch said. “Even small incremental increases in steps per day are associated with a lower mortality risk during middle age. A walking plan that gradually works up toward 7,000-10,000 steps per day in middle-aged adults may have health benefits and lower the risk of premature mortality.”
Causality cannot be confirmed
According to Raed A. Joundi, MD, DPhil, of the University of Calgary (Alta.), the study size, diverse population, and length of follow-up should increase confidence in the findings, although a causal relationship remains elusive.
“As this study is observational, causality between step count and mortality cannot be confirmed; however, the authors accounted for many factors, and the association was consistent in different analyses and with prior literature,” Dr. Joundi said in an interview. “The authors did not assess the risk of other important events like stroke and heart attack, and these could be addressed in a future study.”
Dr. Joundi, who recently published a study linking exercise with a 50% reduction in mortality after stroke, noted that “physical activity has innumerable benefits, and it’s important that people engage in activity that can be regular and consistent, regardless of the type or intensity.”
To this end, he highlighted the use of “devices capable of monitoring step count, which can be an important motivational tool,” and suggested that these findings may bring a sigh of relief to step counters who come up a little short on a common daily goal.
“A target of 10,000 steps is often used for public health promotion, and this study now provides convincing observational evidence that it may be an optimal step count target for mortality reduction,” Dr. Joundi said. “However, if 10,000 steps per day is not feasible, 7,000 steps seems to be a very reasonable target given its association with markedly lower mortality in this study.”
Not all step counters are equal
Unfortunately, such recommendations are complicated by uncertainty in measurement, as widely used step counting devices, like smart watches, may not yield the same results as research-grade accelerometers, according to Nicole L. Spartano, PhD, of Boston University.
“Many comparison studies have been conducted in laboratory settings among young healthy adults, but these do not necessarily reflect real-life wear experiences that will be generalizable to the population as a whole,” Dr. Spartano wrote in an accompanying editorial.
She called for large-scale comparison studies to compare research-grade and consumer devices.
“The reason for conducting comparison studies is not to develop distinct guidelines for different devices or subgroups of the population, but rather to understand the variability so that we can develop one clear message that is most appropriate to the public,” Dr. Spartano wrote. “Some devices may have bias in terms of step measurement at different activity intensity and may not record steps as accurately in older adults or individuals with obesity or mobility disorders. For example, when adults who were obese wore an ActiGraph monitor in a laboratory setting, the device only recorded 80% of steps walked at a moderate pace, while other devices recorded close to 100% of steps walked. If we in the public health community are to move toward using these devices more for physical activity prescription, these details will need to be explored in more depth.”
CARDIA was conducted and supported by the National Heart, Lung, and Blood Institute in collaboration with the University of Alabama at Birmingham, Northwestern University, the University of Minnesota, and the Kaiser Foundation Research Institute. Some study authors received grants from the National Institutes of Health and the Kaiser Foundation Research Institute. Dr Spartano disclosed relationships with Novo Nordisk, the American Heart Association, the Alzheimer’s Association, and the National Institutes of Health. Dr. Joundi and Dr. Paluch disclosed no relevant financial relationships.
based on prospective data from more than 2,000 people.
Findings were consistent regardless of race or sex, and step intensity had no impact on mortality risk, reported lead author Amanda E. Paluch, PhD, of the University of Massachusetts Amherst, and colleagues.
“In response to the need for empirical data on the associations of step volume and intensity with mortality in younger and diverse populations, we conducted a prospective study in middle-aged Black and White adults followed up for mortality for approximately 11 years,” the investigators wrote in JAMA Network Open. “The objectives of our study were to examine the associations of step volume and intensity with mortality overall and by race and sex.”
Steps per day is easy to communicate
Dr. Paluch noted that steps per day is a “very appealing metric to quantify activity,” for both researchers and laypeople.
“Steps per day is simple and easy to communicate in public health and clinical settings,” Dr. Paluch said in an interview. “Additionally, the dramatic growth of wearable devices measuring steps makes it appealing and broadens the reach of promoting physical activity to many individuals. Walking is an activity that most of the general population can pursue. It can also be accumulated throughout daily living and may seem more achievable to fit into busy lives than a structured exercise session.”
The present investigation was conducted as part of the Coronary Artery Risk Development in Young Adults (CARDIA) Study. The dataset included 2,110 participants ranging from 38-50 years of age, with a mean age of 45.2 years. A slightly higher proportion of the subjects were women (57.1%) and White (57.9%).
All participants wore an ActiGraph 7164 accelerometer for 1 week and were then followed for death of any cause, with a mean follow-up of 10.8 years. Multivariable-adjusted Cox proportional hazards models included a range of covariates, such as smoking history, body weight, alcohol intake, blood pressure, total cholesterol, and others. Step counts were grouped into low (less than 7,000 steps per day), moderate (7,000-9,999), and high (at least 10,000 steps per day) categories.
Compared with individuals who took less than 7,000 steps per day, those who took 7,000-9,000 steps per day had a 72% reduced risk of mortality (hazard ratio, 0.28; 95% confidence interval, 0.15-0.54). Going beyond 10,000 steps appeared to add no benefit, based on a 55% lower risk of all-cause mortality in the highly active group, compared with those taking less than 7,000 steps per day (HR, 0.45; 95% CI, 0.25-0.81).
Walking faster didn’t appear to help either, as stepping intensity was not associated with mortality risk; however, Dr. Paluch urged a cautious interpretation of this finding, calling it “inconclusive,” and suggesting that more research is needed.
“It is also important to note that this study only looked at premature all-cause mortality, and therefore the results may be different for other health outcomes, such as the risk of cardiovascular disease, or diabetes, cancer, or mental health outcomes,” Dr. Paluch said.
“The results from our study demonstrated that those who are least active have the most to gain,” Dr. Paluch said. “Even small incremental increases in steps per day are associated with a lower mortality risk during middle age. A walking plan that gradually works up toward 7,000-10,000 steps per day in middle-aged adults may have health benefits and lower the risk of premature mortality.”
Causality cannot be confirmed
According to Raed A. Joundi, MD, DPhil, of the University of Calgary (Alta.), the study size, diverse population, and length of follow-up should increase confidence in the findings, although a causal relationship remains elusive.
“As this study is observational, causality between step count and mortality cannot be confirmed; however, the authors accounted for many factors, and the association was consistent in different analyses and with prior literature,” Dr. Joundi said in an interview. “The authors did not assess the risk of other important events like stroke and heart attack, and these could be addressed in a future study.”
Dr. Joundi, who recently published a study linking exercise with a 50% reduction in mortality after stroke, noted that “physical activity has innumerable benefits, and it’s important that people engage in activity that can be regular and consistent, regardless of the type or intensity.”
To this end, he highlighted the use of “devices capable of monitoring step count, which can be an important motivational tool,” and suggested that these findings may bring a sigh of relief to step counters who come up a little short on a common daily goal.
“A target of 10,000 steps is often used for public health promotion, and this study now provides convincing observational evidence that it may be an optimal step count target for mortality reduction,” Dr. Joundi said. “However, if 10,000 steps per day is not feasible, 7,000 steps seems to be a very reasonable target given its association with markedly lower mortality in this study.”
Not all step counters are equal
Unfortunately, such recommendations are complicated by uncertainty in measurement, as widely used step counting devices, like smart watches, may not yield the same results as research-grade accelerometers, according to Nicole L. Spartano, PhD, of Boston University.
“Many comparison studies have been conducted in laboratory settings among young healthy adults, but these do not necessarily reflect real-life wear experiences that will be generalizable to the population as a whole,” Dr. Spartano wrote in an accompanying editorial.
She called for large-scale comparison studies to compare research-grade and consumer devices.
“The reason for conducting comparison studies is not to develop distinct guidelines for different devices or subgroups of the population, but rather to understand the variability so that we can develop one clear message that is most appropriate to the public,” Dr. Spartano wrote. “Some devices may have bias in terms of step measurement at different activity intensity and may not record steps as accurately in older adults or individuals with obesity or mobility disorders. For example, when adults who were obese wore an ActiGraph monitor in a laboratory setting, the device only recorded 80% of steps walked at a moderate pace, while other devices recorded close to 100% of steps walked. If we in the public health community are to move toward using these devices more for physical activity prescription, these details will need to be explored in more depth.”
CARDIA was conducted and supported by the National Heart, Lung, and Blood Institute in collaboration with the University of Alabama at Birmingham, Northwestern University, the University of Minnesota, and the Kaiser Foundation Research Institute. Some study authors received grants from the National Institutes of Health and the Kaiser Foundation Research Institute. Dr Spartano disclosed relationships with Novo Nordisk, the American Heart Association, the Alzheimer’s Association, and the National Institutes of Health. Dr. Joundi and Dr. Paluch disclosed no relevant financial relationships.
FROM JAMA NETWORK OPEN
Open notes: Legal issues
In July, I had my annual physical with my primary care physician, whose practice is based out of a large urban academic medical center. As she concluded my visit and directed me to the lab to have my blood work done, she said, “You’ll be receiving an automatic notice from MyChart by 9 am tomorrow that your medical records from today’s visit are available. I apologize if I have not yet had the opportunity to review them and enter my note, but you’ll get access to all of that, as well, as soon as it is in the system.”
This sort of interaction is increasingly common across the United States as health care institutions implement policies and procedures to comply with new regulations promulgated by the Office of the National Coordinator for Health Information Technology (ONC), which went into effect on April 5, 2021. These rules were promulgated in accordance with the 21st Century Cures Act of 2016 (Cures Act).1 The regulations, known as the Interoperability, Information Blocking, and the ONC Health IT Certification Program, implement provisions of the Cures Act intended to “support the access, exchange, and use of electronic health information.” The rule is considered a significant step in the “open notes” movement, which is intended to make health care more transparent by enabling patients to access their medical records. The drafters of the ONC regulations have carved out certain exceptions to the information blocking rule. For example, one exception allows some patient information to be withheld where making that information available might cause physical harm to the patient or another person.
Thus far, few patients have been informed about the new regulation.2 By forbidding “information blocking,” the rule enables patients to more easily access and control their health information. Records must be provided “without delay,” or at least as soon as the physician’s office receives an electronic copy. In 2022, it will be required that access to even more of a patient’s personal electronic health record be provided in real-time through a patient portal and that electronic health information be shareable across third-party apps.
The Cures Act and the regulations governing its implementation highlight the inherent tension between two core principles of bioethical inquiry: autonomy and beneficence. The first principle, autonomy, champions allowing patient access and control over their own personal information. Beneficence, which is often expressed as paternalism, ensures that the experts are able to analyze and interpret data so that patients are in the best position to then make informed decisions.
With these principles in mind, arguments against open notes have generally fallen into three related categories. First, critics worry that immediate access to one’s medical record will increase patient anxiety caused by feelings of being inundated with complex medical information that patients may be ill-equipped to analyze and understand. This is a common refrain any time policies are implemented to improve medical information sharing. For example, critics of direct-to-consumer genetic testing caution that permitting unfettered access to complex information, particularly without an intermediary to interpret the data, could lead to confusion and poor medical choices.
There may be validity to this claim. One study found that 3% of patients reported feeling very confused when granted access to their medical notes.3 Another study concluded that direct release of medical test results “sometimes leads to unnecessary anxiety.”4 While the drafters of the ONC regulations have carved out certain exceptions to the information blocking rule, those exceptions do not allow for withholding of information because of concerns about patient anxiety or psychological harms.
The second common critique of open notes is that requiring release of all clinical notes will lead to clinician self-censorship, effectively muzzling or silencing the experts whose responsibility it is to objectively interpret results in order to provide the best care for their patients. Some have expressed concern that clinicians will be forced to “code” their records to avoid addressing “sensitive” subjects that might make patients feel offended or judged. This, in turn, might lead to less complete, reliable, or useful clinician communication.3
In fact, open notes has led to changes in the documentation process for some clinicians. They have reported modifying the way they document patient visits by changing their use of critical language and sensitive information.5 One study found that open notes led physicians to adjust “their language to avoid being perceived as critical of patients; omitting certain terms, such as ‘noncompliant’ and ‘patient denies’; and modifying how they document sensitive information.”3
In response, experts recommend focusing on precise and empathetic patient notes; in other words, the clinician should not write something in the note that they would not say directly to the patient. For example, they recommend that clinicians use precise language (for example, identifying the patient’s BMI) rather than using terms that could be offensive (for example, labeling the patient as “obese”).6 The shift to more empathetic note-taking could be seen less as a burden and more as a valuable tool in the shared decision-making endeavor: It could allow physicians to document both their clinical judgments and the patient’s values and preferences, which could lead to better medical decision-making.
Third, critics of open notes point to concerns about the burden it places on clinicians’ already limited time. The ONC rule requires automatic release of test results regardless of whether the clinician has had the opportunity to review them and offer their interpretation and insight. Because physician interpretation of results has known benefits,4 this puts additional pressure on clinicians to review results and enter notes in a timely manner. But physicians have reported that often open notes necessitates that they spend more time on documentation than they would otherwise.5
Despite critiques of open notes, the benefits of allowing patients access to their medical records have been repeatedly demonstrated. And research has shown that patients benefit from accessing open notes by allowing them to access and control their own personal medical information.5 Patients report that they understand and value the information provided to them in their medical records,7 and they feel empowered to participate in their medical decision-making. In surveys, patients report that reading their doctors’ notes is useful for taking care of their health and for remembering their care plans, understanding why a medication was prescribed, and reinforcing the need to take their medications and adhere to treatment plans.8
Importantly, open notes can increase patient engagement and patients’ trust in their physicians,9 thereby improving the doctor-patient relationship.3 And allowing patients to share their medical records with care partners enables supported decision-making, particularly for older and chronically ill individuals.3 Additionally, it is predicted that open notes may, in fact, decrease legal liability.9 By improving both trust in the doctor-patient relationship and safety, some experts expect that legal claims against clinicians will, in turn, decrease.10
The modern practice of medicine necessitates a more empathetic approach to clinical note-taking, even in the absence of regulation requiring it. As the regulations implementing the Cures Act roll out, patients will have easier, and more immediate, access to their medical records. Despite earlier hesitancy, clinicians are steadily beginning to support sharing access to notes with patients.5 Change can be hard. But the change expected of clinicians because of these new regulations appears to be less onerous than originally anticipated.
Prof. Koch is codirector of Health Law & Policy Institute and assistant professor at the University of Houston Law Center, as well as director of law and ethics at the MacLean Center for Clinical Medical Ethics at the University of Chicago. She has no disclosures.
This article was updated Sept. 9, 2021.
References
1. Fed Regist. 2020 May;85(85):25642-961.
2. The Petrie-Flom Center Staff. “New Rule Puts Medical Data in Patients’ Hands.” Bill of Health. July 12, 2021. Accessed August 30, 2021. https://blog.petrieflom.law.harvard.edu/2021/07/12/new-rule-puts-medical-data-in-patients-hands/.
3. Blease C et al. Ann Intern Med. 2021 Jan;174(1):101-2.
4. Pillemer F et al. PLoS One. 2016 Jun. doi: 10.1371/journal.pone.0154743.
5. DesRoches CM et al. JAMA Netw Open. 2020 Mar. doi: 10.1001/jamanetworkopen.2020.1753.
6. Heath S. “Most Patients Understand Clinical Notes, Patient Data Access.” Patient Engagement HIT. July 29, 2020. Accessed August 30, 2021. https://patientengagementhit.com/news/most-patients-understand-clinical-notes-patient-data-access
7. Leveille SG et al. J Gen Intern Med. 2020 Dec;35(12):3510-6.
8. Walker J et al. J Med Internet Res. 2019 May. doi: 10.2196/13876.
9. Bell SK et al. BMJ Qual Saf. 2017 Apr;26(4):262-70.
10. Kachalia A, Mello MM. N Engl J Med. 2011 Apr;364(16):1564-72.
In July, I had my annual physical with my primary care physician, whose practice is based out of a large urban academic medical center. As she concluded my visit and directed me to the lab to have my blood work done, she said, “You’ll be receiving an automatic notice from MyChart by 9 am tomorrow that your medical records from today’s visit are available. I apologize if I have not yet had the opportunity to review them and enter my note, but you’ll get access to all of that, as well, as soon as it is in the system.”
This sort of interaction is increasingly common across the United States as health care institutions implement policies and procedures to comply with new regulations promulgated by the Office of the National Coordinator for Health Information Technology (ONC), which went into effect on April 5, 2021. These rules were promulgated in accordance with the 21st Century Cures Act of 2016 (Cures Act).1 The regulations, known as the Interoperability, Information Blocking, and the ONC Health IT Certification Program, implement provisions of the Cures Act intended to “support the access, exchange, and use of electronic health information.” The rule is considered a significant step in the “open notes” movement, which is intended to make health care more transparent by enabling patients to access their medical records. The drafters of the ONC regulations have carved out certain exceptions to the information blocking rule. For example, one exception allows some patient information to be withheld where making that information available might cause physical harm to the patient or another person.
Thus far, few patients have been informed about the new regulation.2 By forbidding “information blocking,” the rule enables patients to more easily access and control their health information. Records must be provided “without delay,” or at least as soon as the physician’s office receives an electronic copy. In 2022, it will be required that access to even more of a patient’s personal electronic health record be provided in real-time through a patient portal and that electronic health information be shareable across third-party apps.
The Cures Act and the regulations governing its implementation highlight the inherent tension between two core principles of bioethical inquiry: autonomy and beneficence. The first principle, autonomy, champions allowing patient access and control over their own personal information. Beneficence, which is often expressed as paternalism, ensures that the experts are able to analyze and interpret data so that patients are in the best position to then make informed decisions.
With these principles in mind, arguments against open notes have generally fallen into three related categories. First, critics worry that immediate access to one’s medical record will increase patient anxiety caused by feelings of being inundated with complex medical information that patients may be ill-equipped to analyze and understand. This is a common refrain any time policies are implemented to improve medical information sharing. For example, critics of direct-to-consumer genetic testing caution that permitting unfettered access to complex information, particularly without an intermediary to interpret the data, could lead to confusion and poor medical choices.
There may be validity to this claim. One study found that 3% of patients reported feeling very confused when granted access to their medical notes.3 Another study concluded that direct release of medical test results “sometimes leads to unnecessary anxiety.”4 While the drafters of the ONC regulations have carved out certain exceptions to the information blocking rule, those exceptions do not allow for withholding of information because of concerns about patient anxiety or psychological harms.
The second common critique of open notes is that requiring release of all clinical notes will lead to clinician self-censorship, effectively muzzling or silencing the experts whose responsibility it is to objectively interpret results in order to provide the best care for their patients. Some have expressed concern that clinicians will be forced to “code” their records to avoid addressing “sensitive” subjects that might make patients feel offended or judged. This, in turn, might lead to less complete, reliable, or useful clinician communication.3
In fact, open notes has led to changes in the documentation process for some clinicians. They have reported modifying the way they document patient visits by changing their use of critical language and sensitive information.5 One study found that open notes led physicians to adjust “their language to avoid being perceived as critical of patients; omitting certain terms, such as ‘noncompliant’ and ‘patient denies’; and modifying how they document sensitive information.”3
In response, experts recommend focusing on precise and empathetic patient notes; in other words, the clinician should not write something in the note that they would not say directly to the patient. For example, they recommend that clinicians use precise language (for example, identifying the patient’s BMI) rather than using terms that could be offensive (for example, labeling the patient as “obese”).6 The shift to more empathetic note-taking could be seen less as a burden and more as a valuable tool in the shared decision-making endeavor: It could allow physicians to document both their clinical judgments and the patient’s values and preferences, which could lead to better medical decision-making.
Third, critics of open notes point to concerns about the burden it places on clinicians’ already limited time. The ONC rule requires automatic release of test results regardless of whether the clinician has had the opportunity to review them and offer their interpretation and insight. Because physician interpretation of results has known benefits,4 this puts additional pressure on clinicians to review results and enter notes in a timely manner. But physicians have reported that often open notes necessitates that they spend more time on documentation than they would otherwise.5
Despite critiques of open notes, the benefits of allowing patients access to their medical records have been repeatedly demonstrated. And research has shown that patients benefit from accessing open notes by allowing them to access and control their own personal medical information.5 Patients report that they understand and value the information provided to them in their medical records,7 and they feel empowered to participate in their medical decision-making. In surveys, patients report that reading their doctors’ notes is useful for taking care of their health and for remembering their care plans, understanding why a medication was prescribed, and reinforcing the need to take their medications and adhere to treatment plans.8
Importantly, open notes can increase patient engagement and patients’ trust in their physicians,9 thereby improving the doctor-patient relationship.3 And allowing patients to share their medical records with care partners enables supported decision-making, particularly for older and chronically ill individuals.3 Additionally, it is predicted that open notes may, in fact, decrease legal liability.9 By improving both trust in the doctor-patient relationship and safety, some experts expect that legal claims against clinicians will, in turn, decrease.10
The modern practice of medicine necessitates a more empathetic approach to clinical note-taking, even in the absence of regulation requiring it. As the regulations implementing the Cures Act roll out, patients will have easier, and more immediate, access to their medical records. Despite earlier hesitancy, clinicians are steadily beginning to support sharing access to notes with patients.5 Change can be hard. But the change expected of clinicians because of these new regulations appears to be less onerous than originally anticipated.
Prof. Koch is codirector of Health Law & Policy Institute and assistant professor at the University of Houston Law Center, as well as director of law and ethics at the MacLean Center for Clinical Medical Ethics at the University of Chicago. She has no disclosures.
This article was updated Sept. 9, 2021.
References
1. Fed Regist. 2020 May;85(85):25642-961.
2. The Petrie-Flom Center Staff. “New Rule Puts Medical Data in Patients’ Hands.” Bill of Health. July 12, 2021. Accessed August 30, 2021. https://blog.petrieflom.law.harvard.edu/2021/07/12/new-rule-puts-medical-data-in-patients-hands/.
3. Blease C et al. Ann Intern Med. 2021 Jan;174(1):101-2.
4. Pillemer F et al. PLoS One. 2016 Jun. doi: 10.1371/journal.pone.0154743.
5. DesRoches CM et al. JAMA Netw Open. 2020 Mar. doi: 10.1001/jamanetworkopen.2020.1753.
6. Heath S. “Most Patients Understand Clinical Notes, Patient Data Access.” Patient Engagement HIT. July 29, 2020. Accessed August 30, 2021. https://patientengagementhit.com/news/most-patients-understand-clinical-notes-patient-data-access
7. Leveille SG et al. J Gen Intern Med. 2020 Dec;35(12):3510-6.
8. Walker J et al. J Med Internet Res. 2019 May. doi: 10.2196/13876.
9. Bell SK et al. BMJ Qual Saf. 2017 Apr;26(4):262-70.
10. Kachalia A, Mello MM. N Engl J Med. 2011 Apr;364(16):1564-72.
In July, I had my annual physical with my primary care physician, whose practice is based out of a large urban academic medical center. As she concluded my visit and directed me to the lab to have my blood work done, she said, “You’ll be receiving an automatic notice from MyChart by 9 am tomorrow that your medical records from today’s visit are available. I apologize if I have not yet had the opportunity to review them and enter my note, but you’ll get access to all of that, as well, as soon as it is in the system.”
This sort of interaction is increasingly common across the United States as health care institutions implement policies and procedures to comply with new regulations promulgated by the Office of the National Coordinator for Health Information Technology (ONC), which went into effect on April 5, 2021. These rules were promulgated in accordance with the 21st Century Cures Act of 2016 (Cures Act).1 The regulations, known as the Interoperability, Information Blocking, and the ONC Health IT Certification Program, implement provisions of the Cures Act intended to “support the access, exchange, and use of electronic health information.” The rule is considered a significant step in the “open notes” movement, which is intended to make health care more transparent by enabling patients to access their medical records. The drafters of the ONC regulations have carved out certain exceptions to the information blocking rule. For example, one exception allows some patient information to be withheld where making that information available might cause physical harm to the patient or another person.
Thus far, few patients have been informed about the new regulation.2 By forbidding “information blocking,” the rule enables patients to more easily access and control their health information. Records must be provided “without delay,” or at least as soon as the physician’s office receives an electronic copy. In 2022, it will be required that access to even more of a patient’s personal electronic health record be provided in real-time through a patient portal and that electronic health information be shareable across third-party apps.
The Cures Act and the regulations governing its implementation highlight the inherent tension between two core principles of bioethical inquiry: autonomy and beneficence. The first principle, autonomy, champions allowing patient access and control over their own personal information. Beneficence, which is often expressed as paternalism, ensures that the experts are able to analyze and interpret data so that patients are in the best position to then make informed decisions.
With these principles in mind, arguments against open notes have generally fallen into three related categories. First, critics worry that immediate access to one’s medical record will increase patient anxiety caused by feelings of being inundated with complex medical information that patients may be ill-equipped to analyze and understand. This is a common refrain any time policies are implemented to improve medical information sharing. For example, critics of direct-to-consumer genetic testing caution that permitting unfettered access to complex information, particularly without an intermediary to interpret the data, could lead to confusion and poor medical choices.
There may be validity to this claim. One study found that 3% of patients reported feeling very confused when granted access to their medical notes.3 Another study concluded that direct release of medical test results “sometimes leads to unnecessary anxiety.”4 While the drafters of the ONC regulations have carved out certain exceptions to the information blocking rule, those exceptions do not allow for withholding of information because of concerns about patient anxiety or psychological harms.
The second common critique of open notes is that requiring release of all clinical notes will lead to clinician self-censorship, effectively muzzling or silencing the experts whose responsibility it is to objectively interpret results in order to provide the best care for their patients. Some have expressed concern that clinicians will be forced to “code” their records to avoid addressing “sensitive” subjects that might make patients feel offended or judged. This, in turn, might lead to less complete, reliable, or useful clinician communication.3
In fact, open notes has led to changes in the documentation process for some clinicians. They have reported modifying the way they document patient visits by changing their use of critical language and sensitive information.5 One study found that open notes led physicians to adjust “their language to avoid being perceived as critical of patients; omitting certain terms, such as ‘noncompliant’ and ‘patient denies’; and modifying how they document sensitive information.”3
In response, experts recommend focusing on precise and empathetic patient notes; in other words, the clinician should not write something in the note that they would not say directly to the patient. For example, they recommend that clinicians use precise language (for example, identifying the patient’s BMI) rather than using terms that could be offensive (for example, labeling the patient as “obese”).6 The shift to more empathetic note-taking could be seen less as a burden and more as a valuable tool in the shared decision-making endeavor: It could allow physicians to document both their clinical judgments and the patient’s values and preferences, which could lead to better medical decision-making.
Third, critics of open notes point to concerns about the burden it places on clinicians’ already limited time. The ONC rule requires automatic release of test results regardless of whether the clinician has had the opportunity to review them and offer their interpretation and insight. Because physician interpretation of results has known benefits,4 this puts additional pressure on clinicians to review results and enter notes in a timely manner. But physicians have reported that often open notes necessitates that they spend more time on documentation than they would otherwise.5
Despite critiques of open notes, the benefits of allowing patients access to their medical records have been repeatedly demonstrated. And research has shown that patients benefit from accessing open notes by allowing them to access and control their own personal medical information.5 Patients report that they understand and value the information provided to them in their medical records,7 and they feel empowered to participate in their medical decision-making. In surveys, patients report that reading their doctors’ notes is useful for taking care of their health and for remembering their care plans, understanding why a medication was prescribed, and reinforcing the need to take their medications and adhere to treatment plans.8
Importantly, open notes can increase patient engagement and patients’ trust in their physicians,9 thereby improving the doctor-patient relationship.3 And allowing patients to share their medical records with care partners enables supported decision-making, particularly for older and chronically ill individuals.3 Additionally, it is predicted that open notes may, in fact, decrease legal liability.9 By improving both trust in the doctor-patient relationship and safety, some experts expect that legal claims against clinicians will, in turn, decrease.10
The modern practice of medicine necessitates a more empathetic approach to clinical note-taking, even in the absence of regulation requiring it. As the regulations implementing the Cures Act roll out, patients will have easier, and more immediate, access to their medical records. Despite earlier hesitancy, clinicians are steadily beginning to support sharing access to notes with patients.5 Change can be hard. But the change expected of clinicians because of these new regulations appears to be less onerous than originally anticipated.
Prof. Koch is codirector of Health Law & Policy Institute and assistant professor at the University of Houston Law Center, as well as director of law and ethics at the MacLean Center for Clinical Medical Ethics at the University of Chicago. She has no disclosures.
This article was updated Sept. 9, 2021.
References
1. Fed Regist. 2020 May;85(85):25642-961.
2. The Petrie-Flom Center Staff. “New Rule Puts Medical Data in Patients’ Hands.” Bill of Health. July 12, 2021. Accessed August 30, 2021. https://blog.petrieflom.law.harvard.edu/2021/07/12/new-rule-puts-medical-data-in-patients-hands/.
3. Blease C et al. Ann Intern Med. 2021 Jan;174(1):101-2.
4. Pillemer F et al. PLoS One. 2016 Jun. doi: 10.1371/journal.pone.0154743.
5. DesRoches CM et al. JAMA Netw Open. 2020 Mar. doi: 10.1001/jamanetworkopen.2020.1753.
6. Heath S. “Most Patients Understand Clinical Notes, Patient Data Access.” Patient Engagement HIT. July 29, 2020. Accessed August 30, 2021. https://patientengagementhit.com/news/most-patients-understand-clinical-notes-patient-data-access
7. Leveille SG et al. J Gen Intern Med. 2020 Dec;35(12):3510-6.
8. Walker J et al. J Med Internet Res. 2019 May. doi: 10.2196/13876.
9. Bell SK et al. BMJ Qual Saf. 2017 Apr;26(4):262-70.
10. Kachalia A, Mello MM. N Engl J Med. 2011 Apr;364(16):1564-72.
The postpandemic path forward for GI research
The National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK) recognizes the alarming impact of COVID-19 on the biomedical research community. The Institute has taken steps to address the pandemic’s immediate challenges, such as supporting COVID-19 research within its mission and implementing policies that ease grantees’ concerns about funding and lost time. The NIDDK has also sought to balance the needs brought about by the pandemic with its responsibility to continue research on the many diseases and conditions in the NIDDK’s purview.
The NIDDK continues to support most research through unsolicited R01 awards. It also continues to support organized consortia that aim to improve our understanding and treatment of digestive diseases; research centers that provide valuable sources of collaboration among researchers investigating digestive diseases and/or nutrition and obesity; and programs that encourage transitions to different career levels.
The pandemic has shown in stark relief the devastating impact of health disparities. Because many NIDDK mission diseases place disparate burdens on minority groups and people with limited resources, the NIDDK remains committed to combating health disparities, whether pandemic related or not. The Institute recruits diverse study cohorts inclusive of those most affected. It seeks to open doors for young people from underrepresented groups through training, support, and inspiration to pursue research careers, such as through partnerships with organizations like the American Gastroenterological Association. The NIDDK is also implementing strategies to promote participant engagement, not only as study volunteers, but also in study design, recruitment, and consent. And, importantly, the Institute is supporting research to identify the causes of health disparities, including research on social determinants of health.
This year, the NIDDK embarked on the development of a 5-year Strategic Plan to develop a broad vision for accelerating research on diseases and conditions across its mission. This plan is meant to be overarching and will complement the NIDDK’s disease-specific planning efforts. The first draft of the plan is currently being developed based on the input received from a Strategic Plan Working Group (which includes several AGA members), a public Request for Information, and NIDDK’s Advisory Council. The draft will be available through the NIDDK website (niddk.nih.gov) for public comment.
By taking these actions, the NIDDK aims to continue reducing the burden of digestive diseases and improving health for all people.
Dr. Rodgers is director of the National Institute of Diabetes and Digestive and Kidney Diseases at the National Institutes of Health. He has no conflicts. Dr. Rodgers made these comments during the AGA Institute Presidential Plenary at the annual Digestive Disease Week®.
The National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK) recognizes the alarming impact of COVID-19 on the biomedical research community. The Institute has taken steps to address the pandemic’s immediate challenges, such as supporting COVID-19 research within its mission and implementing policies that ease grantees’ concerns about funding and lost time. The NIDDK has also sought to balance the needs brought about by the pandemic with its responsibility to continue research on the many diseases and conditions in the NIDDK’s purview.
The NIDDK continues to support most research through unsolicited R01 awards. It also continues to support organized consortia that aim to improve our understanding and treatment of digestive diseases; research centers that provide valuable sources of collaboration among researchers investigating digestive diseases and/or nutrition and obesity; and programs that encourage transitions to different career levels.
The pandemic has shown in stark relief the devastating impact of health disparities. Because many NIDDK mission diseases place disparate burdens on minority groups and people with limited resources, the NIDDK remains committed to combating health disparities, whether pandemic related or not. The Institute recruits diverse study cohorts inclusive of those most affected. It seeks to open doors for young people from underrepresented groups through training, support, and inspiration to pursue research careers, such as through partnerships with organizations like the American Gastroenterological Association. The NIDDK is also implementing strategies to promote participant engagement, not only as study volunteers, but also in study design, recruitment, and consent. And, importantly, the Institute is supporting research to identify the causes of health disparities, including research on social determinants of health.
This year, the NIDDK embarked on the development of a 5-year Strategic Plan to develop a broad vision for accelerating research on diseases and conditions across its mission. This plan is meant to be overarching and will complement the NIDDK’s disease-specific planning efforts. The first draft of the plan is currently being developed based on the input received from a Strategic Plan Working Group (which includes several AGA members), a public Request for Information, and NIDDK’s Advisory Council. The draft will be available through the NIDDK website (niddk.nih.gov) for public comment.
By taking these actions, the NIDDK aims to continue reducing the burden of digestive diseases and improving health for all people.
Dr. Rodgers is director of the National Institute of Diabetes and Digestive and Kidney Diseases at the National Institutes of Health. He has no conflicts. Dr. Rodgers made these comments during the AGA Institute Presidential Plenary at the annual Digestive Disease Week®.
The National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK) recognizes the alarming impact of COVID-19 on the biomedical research community. The Institute has taken steps to address the pandemic’s immediate challenges, such as supporting COVID-19 research within its mission and implementing policies that ease grantees’ concerns about funding and lost time. The NIDDK has also sought to balance the needs brought about by the pandemic with its responsibility to continue research on the many diseases and conditions in the NIDDK’s purview.
The NIDDK continues to support most research through unsolicited R01 awards. It also continues to support organized consortia that aim to improve our understanding and treatment of digestive diseases; research centers that provide valuable sources of collaboration among researchers investigating digestive diseases and/or nutrition and obesity; and programs that encourage transitions to different career levels.
The pandemic has shown in stark relief the devastating impact of health disparities. Because many NIDDK mission diseases place disparate burdens on minority groups and people with limited resources, the NIDDK remains committed to combating health disparities, whether pandemic related or not. The Institute recruits diverse study cohorts inclusive of those most affected. It seeks to open doors for young people from underrepresented groups through training, support, and inspiration to pursue research careers, such as through partnerships with organizations like the American Gastroenterological Association. The NIDDK is also implementing strategies to promote participant engagement, not only as study volunteers, but also in study design, recruitment, and consent. And, importantly, the Institute is supporting research to identify the causes of health disparities, including research on social determinants of health.
This year, the NIDDK embarked on the development of a 5-year Strategic Plan to develop a broad vision for accelerating research on diseases and conditions across its mission. This plan is meant to be overarching and will complement the NIDDK’s disease-specific planning efforts. The first draft of the plan is currently being developed based on the input received from a Strategic Plan Working Group (which includes several AGA members), a public Request for Information, and NIDDK’s Advisory Council. The draft will be available through the NIDDK website (niddk.nih.gov) for public comment.
By taking these actions, the NIDDK aims to continue reducing the burden of digestive diseases and improving health for all people.
Dr. Rodgers is director of the National Institute of Diabetes and Digestive and Kidney Diseases at the National Institutes of Health. He has no conflicts. Dr. Rodgers made these comments during the AGA Institute Presidential Plenary at the annual Digestive Disease Week®.
The making of the Pfizer-BioNTech COVID-19 vaccine
Days after the World Health Organization declared the COVID-19 outbreak a global pandemic, Pfizer and BioNTech announced plans to codevelop a potential mRNA-based vaccine to help prevent COVID-19. The mRNA platform was selected given its potential for high potency and capacity for rapid development. A bold decision was made to invest in R&D and manufacturing at risk.
Two candidates, BNT162b1 and BNT162b2, quickly emerged as most promising. After extensive review of preclinical and early clinical data and in consultation with regulators, we advanced BNT162b2 into a global, Phase 2/3 efficacy trial in July 2020.
Enrollment was later expanded to increase diversity, and also to include adolescents 12 and older and people with chronic, stable HIV, Hepatitis C, or Hepatitis B.
In November 2020, we announced the results of our ongoing Phase 3 study with BNT162b2 demonstrating a vaccine efficacy rate of 95% against COVID-19 beginning 28 days after dose one. This result showed our ability to leverage decades of scientific expertise to execute a rigorous Phase 3 clinical program to make a potential vaccine available as quickly and safely as possible. The emergency use authorization that followed was a big step, but our research did not stop there.
Pfizer and BioNTech continue to evaluate data from the landmark trial, which ultimately enrolled 46,331 participants. We are also conducting trials in special populations, such as pregnant women and children under 12. To date, real-world evidence has demonstrated lower COVID-19 incidence in vaccinated individuals and has not shown escape of variant viruses from BNT162b2-mediated protection. Studies are ongoing to explore the effect of a third dose on immunity and to prepare in case a variant emerges that escapes protection.
We continue to identify improvements to increase production and are on track to deliver approximately 2.5 billion doses in 2021. Next generation ready-to-use and freeze-dried formulations are in development.
This pandemic sparked an unparalleled period of innovation, investment, and partnership with lessons learned that will help us prepare for future pandemics and accelerate R&D of therapeutic candidates for other debilitating and life-threatening conditions.
The Pfizer-BioNTech COVID-19 vaccine has not been approved or licensed by the U.S. Food and Drug Administration but has been authorized for emergency use to prevent COVID-19 in individuals 12+. See conditions of use: http://cvdvaccine.com
Dr. Dolsten is the Chief Scientific Officer and President of Worldwide Research, Development and Medical at Pfizer. He has no other conflicts. Dr. Dolsten made these comments during the AGA Institute Presidential Plenary at the annual Digestive Disease Week®.
Days after the World Health Organization declared the COVID-19 outbreak a global pandemic, Pfizer and BioNTech announced plans to codevelop a potential mRNA-based vaccine to help prevent COVID-19. The mRNA platform was selected given its potential for high potency and capacity for rapid development. A bold decision was made to invest in R&D and manufacturing at risk.
Two candidates, BNT162b1 and BNT162b2, quickly emerged as most promising. After extensive review of preclinical and early clinical data and in consultation with regulators, we advanced BNT162b2 into a global, Phase 2/3 efficacy trial in July 2020.
Enrollment was later expanded to increase diversity, and also to include adolescents 12 and older and people with chronic, stable HIV, Hepatitis C, or Hepatitis B.
In November 2020, we announced the results of our ongoing Phase 3 study with BNT162b2 demonstrating a vaccine efficacy rate of 95% against COVID-19 beginning 28 days after dose one. This result showed our ability to leverage decades of scientific expertise to execute a rigorous Phase 3 clinical program to make a potential vaccine available as quickly and safely as possible. The emergency use authorization that followed was a big step, but our research did not stop there.
Pfizer and BioNTech continue to evaluate data from the landmark trial, which ultimately enrolled 46,331 participants. We are also conducting trials in special populations, such as pregnant women and children under 12. To date, real-world evidence has demonstrated lower COVID-19 incidence in vaccinated individuals and has not shown escape of variant viruses from BNT162b2-mediated protection. Studies are ongoing to explore the effect of a third dose on immunity and to prepare in case a variant emerges that escapes protection.
We continue to identify improvements to increase production and are on track to deliver approximately 2.5 billion doses in 2021. Next generation ready-to-use and freeze-dried formulations are in development.
This pandemic sparked an unparalleled period of innovation, investment, and partnership with lessons learned that will help us prepare for future pandemics and accelerate R&D of therapeutic candidates for other debilitating and life-threatening conditions.
The Pfizer-BioNTech COVID-19 vaccine has not been approved or licensed by the U.S. Food and Drug Administration but has been authorized for emergency use to prevent COVID-19 in individuals 12+. See conditions of use: http://cvdvaccine.com
Dr. Dolsten is the Chief Scientific Officer and President of Worldwide Research, Development and Medical at Pfizer. He has no other conflicts. Dr. Dolsten made these comments during the AGA Institute Presidential Plenary at the annual Digestive Disease Week®.
Days after the World Health Organization declared the COVID-19 outbreak a global pandemic, Pfizer and BioNTech announced plans to codevelop a potential mRNA-based vaccine to help prevent COVID-19. The mRNA platform was selected given its potential for high potency and capacity for rapid development. A bold decision was made to invest in R&D and manufacturing at risk.
Two candidates, BNT162b1 and BNT162b2, quickly emerged as most promising. After extensive review of preclinical and early clinical data and in consultation with regulators, we advanced BNT162b2 into a global, Phase 2/3 efficacy trial in July 2020.
Enrollment was later expanded to increase diversity, and also to include adolescents 12 and older and people with chronic, stable HIV, Hepatitis C, or Hepatitis B.
In November 2020, we announced the results of our ongoing Phase 3 study with BNT162b2 demonstrating a vaccine efficacy rate of 95% against COVID-19 beginning 28 days after dose one. This result showed our ability to leverage decades of scientific expertise to execute a rigorous Phase 3 clinical program to make a potential vaccine available as quickly and safely as possible. The emergency use authorization that followed was a big step, but our research did not stop there.
Pfizer and BioNTech continue to evaluate data from the landmark trial, which ultimately enrolled 46,331 participants. We are also conducting trials in special populations, such as pregnant women and children under 12. To date, real-world evidence has demonstrated lower COVID-19 incidence in vaccinated individuals and has not shown escape of variant viruses from BNT162b2-mediated protection. Studies are ongoing to explore the effect of a third dose on immunity and to prepare in case a variant emerges that escapes protection.
We continue to identify improvements to increase production and are on track to deliver approximately 2.5 billion doses in 2021. Next generation ready-to-use and freeze-dried formulations are in development.
This pandemic sparked an unparalleled period of innovation, investment, and partnership with lessons learned that will help us prepare for future pandemics and accelerate R&D of therapeutic candidates for other debilitating and life-threatening conditions.
The Pfizer-BioNTech COVID-19 vaccine has not been approved or licensed by the U.S. Food and Drug Administration but has been authorized for emergency use to prevent COVID-19 in individuals 12+. See conditions of use: http://cvdvaccine.com
Dr. Dolsten is the Chief Scientific Officer and President of Worldwide Research, Development and Medical at Pfizer. He has no other conflicts. Dr. Dolsten made these comments during the AGA Institute Presidential Plenary at the annual Digestive Disease Week®.
Malaria study shows remarkable 70% reduction in severe disease and death
A new study from Africa shows a remarkable 70% reduction in malaria if two treatments — a vaccine and an antimalarial medication — are combined instead of giving them individually.
Malaria is endemic in the tropics. The World Health Organization (WHO) reports that in 2019, there were 229 million cases and 409,000 deaths from this parasitic infection. Most of the burden (94%) occurs in Africa, and children younger than age 5 account for 67% of the deaths.
In the Sahel region of Africa, a broad, sub-Saharan band that stretches across the continent, high malaria transmission is seasonal. Children in some countries there are treated with monthly courses of sulfadoxine-pyrimethamine and amodiaquine chemoprophylaxis during the four higher-risk months. Such seasonal malaria chemoprophylaxis (SMC) has been shown to reduce infections by up to 88% and costs an average of $3.43 per child per year.
This double-blind, randomized controlled trial enrolled young children (5-17 months old) in Burkina Faso and Mali, where SMC is the current treatment regimen. Nearly 6,000 children received either chemoprophylaxis, the RTS,S/AS01E malaria vaccine (RTS,S), or both treatments. The study, led by investigators at the London School of Hygiene and Tropical Medicine (LSHTM), was reported in the New England Journal of Medicine.
Co-lead investigator Daniel Chandramohan, MBBS, PhD, MSc, professor of public health at LSHTM, said in an interview that SMC administration is quite labor-intensive and that “we thought we can replace these four cycles of seasonal cure prevention with one seasonal vaccination like the flu vaccine ... and that there might be some additive benefit.”
Instead, the study found the combination reduces the incidence of malaria by 62% against clinical malaria infection, 70% against severe malaria, and 73% against death from malaria compared with SMC alone. “Not in our wildest dreams would I have hypothesized that this is a possibility,” Dr. Chandramohan said. He continued that this was unlikely a “freak result” because the findings are “consistent between both countries. Two, it is consistent across the years. Three, all the malaria outcomes ... are consistently showing the protective effect at the same level.”
To maintain the blinded study design, children received injections of rabies vaccine and hepatitis A vaccine instead of a placebo for RTS,S. Both were chosen to provide additional benefits by protecting children against those infections.
With so many children followed over years, accuracy in providing the correct treatment for each study arm can be difficult. Each child was given a QR code and picture identification to facilitate drug distribution each year in this study.
Miriam K. Laufer, MD, professor and associate director for malaria research at the University of Maryland, Baltimore, who was not involved in the study, said in an interview, “This is a spectacular result, you know, decreasing disease by 60%-70% using interventions that we already have.”
RTS,S is not a new vaccine; it was developed in 2001 by GlaxoSmithKline with Path’s Malaria Vaccine Initiative, then manufactured by GSK. The Gates Foundation has supported production. Dr. Chandramohan said GSK has transferred the technology to Bharat, in India, and that it will take 2-3 years to ramp up production. Until then, enough vaccine is available to supply Kenya, Malawi, and Ghana, where the pilot studies are being done.
Dr. Laufer stressed that the “group that got RTS,S did as well as the group that received SMC.” She noted that the use of SMC is limited to specific areas of the Sahel sub-region of Africa, with a brief transmission period. In other areas of Africa where malaria has a longer transmission period, SMC isn’t as effective. “RTS,S vaccine could really have an impact” there, she added.
Asked if RTS,S might be substituted for SMC to reduce the likelihood of resistance emerging, Dr. Laufer said, “Giving RTS,S vaccine is as good as using repeated treatment of malaria drugs during the malaria season. And that’s important for two reasons. One is that the advantage of a vaccine is that you’re not producing pressure of drugs that would enable drug resistance to emerge and spread. So maybe your vaccine efficacy could last longer than drug efficacy. We don’t know the answer to that.”
Hypothesizing about the unexpectedly good trial results, Dr. Laufer explained, “We know that RTS,S decreases the number of parasites that make it into the blood when a child is bitten by an infected mosquito. When drugs like sulfadoxine-pyrimethamine and amodiaquine that have moderate efficacy only have to kill off a small number of parasites, they can work better. Maybe that explains why the combination of RTS,S and SMC created such a positive outcome.”
Dr. Laufer echoed Chandramohan, saying, “Results were much more dramatic than anybody – certainly than I anticipated.” Both physicians anticipate that WHO will give full approval for this combination this fall.
Dr. Chandramohan and Dr. Laufer have disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
A new study from Africa shows a remarkable 70% reduction in malaria if two treatments — a vaccine and an antimalarial medication — are combined instead of giving them individually.
Malaria is endemic in the tropics. The World Health Organization (WHO) reports that in 2019, there were 229 million cases and 409,000 deaths from this parasitic infection. Most of the burden (94%) occurs in Africa, and children younger than age 5 account for 67% of the deaths.
In the Sahel region of Africa, a broad, sub-Saharan band that stretches across the continent, high malaria transmission is seasonal. Children in some countries there are treated with monthly courses of sulfadoxine-pyrimethamine and amodiaquine chemoprophylaxis during the four higher-risk months. Such seasonal malaria chemoprophylaxis (SMC) has been shown to reduce infections by up to 88% and costs an average of $3.43 per child per year.
This double-blind, randomized controlled trial enrolled young children (5-17 months old) in Burkina Faso and Mali, where SMC is the current treatment regimen. Nearly 6,000 children received either chemoprophylaxis, the RTS,S/AS01E malaria vaccine (RTS,S), or both treatments. The study, led by investigators at the London School of Hygiene and Tropical Medicine (LSHTM), was reported in the New England Journal of Medicine.
Co-lead investigator Daniel Chandramohan, MBBS, PhD, MSc, professor of public health at LSHTM, said in an interview that SMC administration is quite labor-intensive and that “we thought we can replace these four cycles of seasonal cure prevention with one seasonal vaccination like the flu vaccine ... and that there might be some additive benefit.”
Instead, the study found the combination reduces the incidence of malaria by 62% against clinical malaria infection, 70% against severe malaria, and 73% against death from malaria compared with SMC alone. “Not in our wildest dreams would I have hypothesized that this is a possibility,” Dr. Chandramohan said. He continued that this was unlikely a “freak result” because the findings are “consistent between both countries. Two, it is consistent across the years. Three, all the malaria outcomes ... are consistently showing the protective effect at the same level.”
To maintain the blinded study design, children received injections of rabies vaccine and hepatitis A vaccine instead of a placebo for RTS,S. Both were chosen to provide additional benefits by protecting children against those infections.
With so many children followed over years, accuracy in providing the correct treatment for each study arm can be difficult. Each child was given a QR code and picture identification to facilitate drug distribution each year in this study.
Miriam K. Laufer, MD, professor and associate director for malaria research at the University of Maryland, Baltimore, who was not involved in the study, said in an interview, “This is a spectacular result, you know, decreasing disease by 60%-70% using interventions that we already have.”
RTS,S is not a new vaccine; it was developed in 2001 by GlaxoSmithKline with Path’s Malaria Vaccine Initiative, then manufactured by GSK. The Gates Foundation has supported production. Dr. Chandramohan said GSK has transferred the technology to Bharat, in India, and that it will take 2-3 years to ramp up production. Until then, enough vaccine is available to supply Kenya, Malawi, and Ghana, where the pilot studies are being done.
Dr. Laufer stressed that the “group that got RTS,S did as well as the group that received SMC.” She noted that the use of SMC is limited to specific areas of the Sahel sub-region of Africa, with a brief transmission period. In other areas of Africa where malaria has a longer transmission period, SMC isn’t as effective. “RTS,S vaccine could really have an impact” there, she added.
Asked if RTS,S might be substituted for SMC to reduce the likelihood of resistance emerging, Dr. Laufer said, “Giving RTS,S vaccine is as good as using repeated treatment of malaria drugs during the malaria season. And that’s important for two reasons. One is that the advantage of a vaccine is that you’re not producing pressure of drugs that would enable drug resistance to emerge and spread. So maybe your vaccine efficacy could last longer than drug efficacy. We don’t know the answer to that.”
Hypothesizing about the unexpectedly good trial results, Dr. Laufer explained, “We know that RTS,S decreases the number of parasites that make it into the blood when a child is bitten by an infected mosquito. When drugs like sulfadoxine-pyrimethamine and amodiaquine that have moderate efficacy only have to kill off a small number of parasites, they can work better. Maybe that explains why the combination of RTS,S and SMC created such a positive outcome.”
Dr. Laufer echoed Chandramohan, saying, “Results were much more dramatic than anybody – certainly than I anticipated.” Both physicians anticipate that WHO will give full approval for this combination this fall.
Dr. Chandramohan and Dr. Laufer have disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
A new study from Africa shows a remarkable 70% reduction in malaria if two treatments — a vaccine and an antimalarial medication — are combined instead of giving them individually.
Malaria is endemic in the tropics. The World Health Organization (WHO) reports that in 2019, there were 229 million cases and 409,000 deaths from this parasitic infection. Most of the burden (94%) occurs in Africa, and children younger than age 5 account for 67% of the deaths.
In the Sahel region of Africa, a broad, sub-Saharan band that stretches across the continent, high malaria transmission is seasonal. Children in some countries there are treated with monthly courses of sulfadoxine-pyrimethamine and amodiaquine chemoprophylaxis during the four higher-risk months. Such seasonal malaria chemoprophylaxis (SMC) has been shown to reduce infections by up to 88% and costs an average of $3.43 per child per year.
This double-blind, randomized controlled trial enrolled young children (5-17 months old) in Burkina Faso and Mali, where SMC is the current treatment regimen. Nearly 6,000 children received either chemoprophylaxis, the RTS,S/AS01E malaria vaccine (RTS,S), or both treatments. The study, led by investigators at the London School of Hygiene and Tropical Medicine (LSHTM), was reported in the New England Journal of Medicine.
Co-lead investigator Daniel Chandramohan, MBBS, PhD, MSc, professor of public health at LSHTM, said in an interview that SMC administration is quite labor-intensive and that “we thought we can replace these four cycles of seasonal cure prevention with one seasonal vaccination like the flu vaccine ... and that there might be some additive benefit.”
Instead, the study found the combination reduces the incidence of malaria by 62% against clinical malaria infection, 70% against severe malaria, and 73% against death from malaria compared with SMC alone. “Not in our wildest dreams would I have hypothesized that this is a possibility,” Dr. Chandramohan said. He continued that this was unlikely a “freak result” because the findings are “consistent between both countries. Two, it is consistent across the years. Three, all the malaria outcomes ... are consistently showing the protective effect at the same level.”
To maintain the blinded study design, children received injections of rabies vaccine and hepatitis A vaccine instead of a placebo for RTS,S. Both were chosen to provide additional benefits by protecting children against those infections.
With so many children followed over years, accuracy in providing the correct treatment for each study arm can be difficult. Each child was given a QR code and picture identification to facilitate drug distribution each year in this study.
Miriam K. Laufer, MD, professor and associate director for malaria research at the University of Maryland, Baltimore, who was not involved in the study, said in an interview, “This is a spectacular result, you know, decreasing disease by 60%-70% using interventions that we already have.”
RTS,S is not a new vaccine; it was developed in 2001 by GlaxoSmithKline with Path’s Malaria Vaccine Initiative, then manufactured by GSK. The Gates Foundation has supported production. Dr. Chandramohan said GSK has transferred the technology to Bharat, in India, and that it will take 2-3 years to ramp up production. Until then, enough vaccine is available to supply Kenya, Malawi, and Ghana, where the pilot studies are being done.
Dr. Laufer stressed that the “group that got RTS,S did as well as the group that received SMC.” She noted that the use of SMC is limited to specific areas of the Sahel sub-region of Africa, with a brief transmission period. In other areas of Africa where malaria has a longer transmission period, SMC isn’t as effective. “RTS,S vaccine could really have an impact” there, she added.
Asked if RTS,S might be substituted for SMC to reduce the likelihood of resistance emerging, Dr. Laufer said, “Giving RTS,S vaccine is as good as using repeated treatment of malaria drugs during the malaria season. And that’s important for two reasons. One is that the advantage of a vaccine is that you’re not producing pressure of drugs that would enable drug resistance to emerge and spread. So maybe your vaccine efficacy could last longer than drug efficacy. We don’t know the answer to that.”
Hypothesizing about the unexpectedly good trial results, Dr. Laufer explained, “We know that RTS,S decreases the number of parasites that make it into the blood when a child is bitten by an infected mosquito. When drugs like sulfadoxine-pyrimethamine and amodiaquine that have moderate efficacy only have to kill off a small number of parasites, they can work better. Maybe that explains why the combination of RTS,S and SMC created such a positive outcome.”
Dr. Laufer echoed Chandramohan, saying, “Results were much more dramatic than anybody – certainly than I anticipated.” Both physicians anticipate that WHO will give full approval for this combination this fall.
Dr. Chandramohan and Dr. Laufer have disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.