Society of Thoracic Surgeons (STS): Annual Meeting

PHOENIX – A blood lactate dehydrogenase level of at least 1,150 IU/L may be the best cutoff for identifying pump thrombosis in patients who have received a left ventricular assist device based on findings from a combined series of 502 pump recipients.

Using this cutoff correlated with a positive predictive value of 74% and a negative predictive value of 92%, Dr. Vikram Sood said at the annual meeting of the Society of Thoracic Surgeons.

Mitchel L. Zoler/Frontline Medical News

Results from several prior studies had established an elevated blood level of lactate dehydrogenase (LDH) as perhaps the best early flag of significant thrombus inside of a left ventricular assist device (LVAD), a condition called pump thrombosis. But prior studies had not identified a specific cutoff value to use that could confidently diagnose pump thrombosis. A level of 1,150 IU/L is about five times the upper limit of normal, noted Dr. Francis D. Pagani, professor of surgery and surgical director of adult heart transplantation at the University of Michigan, Ann Arbor, and a senior author on this report.

Dr. Sood and his associates reviewed records for 502 patients who received a HeartMate II LVAD at either the University of Michigan or at the Mayo Clinic in Rochester, Minn., during 2004-2014. During that time, 58 of the patients required a total of 70 LVAD explants. Fifty-two of the explants were for suspected pump thrombosis, 12 for infection, and 6 for lead fracture. The average time from LVAD placement to explant was 12 months.

Among the 52 LVADs explanted for suspected pump thrombosis, 47 actually had thrombosis. In addition, six of the LVADs that were explanted for other reasons also had a significant amount of thrombus, resulting in 53 total explanted LVAD with confirmed pump thrombosis.

The researchers analyzed blood levels of LDH during the 6 months prior to explant. Among the patients with the 53 LVADs explanted with confirmed pump thrombosis, the median of all LDH levels during the period was 1,061 IU/L and the median maximum LDH level for each patient was 1,940 IU/L, reported Dr. Sood, a cardiac surgeon at the University of Michigan. In contrast, among the patients who had a total of 17 LVADs explanted without pump thrombosis, the median value for all LDH measures during the 6 months prior to explant was 533 IU/L, and their medium maximum level was 504 IU/L.

Analysis of LDH levels prior to explant and subsequent confirmation of pump thrombosis identified a cut off of 1,150 IU/L as able to identify pump thrombosis with a sensitivity of 78% and a specificity of 90%, Dr. Sood reported.

mzoler@frontlinemedcom.com

On Twitter @mitchelzoler

PHOENIX – A blood lactate dehydrogenase level of at least 1,150 IU/L may be the best cutoff for identifying pump thrombosis in patients who have received a left ventricular assist device based on findings from a combined series of 502 pump recipients.

Using this cutoff correlated with a positive predictive value of 74% and a negative predictive value of 92%, Dr. Vikram Sood said at the annual meeting of the Society of Thoracic Surgeons.

Mitchel L. Zoler/Frontline Medical News

Results from several prior studies had established an elevated blood level of lactate dehydrogenase (LDH) as perhaps the best early flag of significant thrombus inside of a left ventricular assist device (LVAD), a condition called pump thrombosis. But prior studies had not identified a specific cutoff value to use that could confidently diagnose pump thrombosis. A level of 1,150 IU/L is about five times the upper limit of normal, noted Dr. Francis D. Pagani, professor of surgery and surgical director of adult heart transplantation at the University of Michigan, Ann Arbor, and a senior author on this report.

Dr. Sood and his associates reviewed records for 502 patients who received a HeartMate II LVAD at either the University of Michigan or at the Mayo Clinic in Rochester, Minn., during 2004-2014. During that time, 58 of the patients required a total of 70 LVAD explants. Fifty-two of the explants were for suspected pump thrombosis, 12 for infection, and 6 for lead fracture. The average time from LVAD placement to explant was 12 months.

Among the 52 LVADs explanted for suspected pump thrombosis, 47 actually had thrombosis. In addition, six of the LVADs that were explanted for other reasons also had a significant amount of thrombus, resulting in 53 total explanted LVAD with confirmed pump thrombosis.

The researchers analyzed blood levels of LDH during the 6 months prior to explant. Among the patients with the 53 LVADs explanted with confirmed pump thrombosis, the median of all LDH levels during the period was 1,061 IU/L and the median maximum LDH level for each patient was 1,940 IU/L, reported Dr. Sood, a cardiac surgeon at the University of Michigan. In contrast, among the patients who had a total of 17 LVADs explanted without pump thrombosis, the median value for all LDH measures during the 6 months prior to explant was 533 IU/L, and their medium maximum level was 504 IU/L.

Analysis of LDH levels prior to explant and subsequent confirmation of pump thrombosis identified a cut off of 1,150 IU/L as able to identify pump thrombosis with a sensitivity of 78% and a specificity of 90%, Dr. Sood reported.

mzoler@frontlinemedcom.com

On Twitter @mitchelzoler

PHOENIX – A blood lactate dehydrogenase level of at least 1,150 IU/L may be the best cutoff for identifying pump thrombosis in patients who have received a left ventricular assist device based on findings from a combined series of 502 pump recipients.

Using this cutoff correlated with a positive predictive value of 74% and a negative predictive value of 92%, Dr. Vikram Sood said at the annual meeting of the Society of Thoracic Surgeons.

Mitchel L. Zoler/Frontline Medical News

Results from several prior studies had established an elevated blood level of lactate dehydrogenase (LDH) as perhaps the best early flag of significant thrombus inside of a left ventricular assist device (LVAD), a condition called pump thrombosis. But prior studies had not identified a specific cutoff value to use that could confidently diagnose pump thrombosis. A level of 1,150 IU/L is about five times the upper limit of normal, noted Dr. Francis D. Pagani, professor of surgery and surgical director of adult heart transplantation at the University of Michigan, Ann Arbor, and a senior author on this report.

Dr. Sood and his associates reviewed records for 502 patients who received a HeartMate II LVAD at either the University of Michigan or at the Mayo Clinic in Rochester, Minn., during 2004-2014. During that time, 58 of the patients required a total of 70 LVAD explants. Fifty-two of the explants were for suspected pump thrombosis, 12 for infection, and 6 for lead fracture. The average time from LVAD placement to explant was 12 months.

Among the 52 LVADs explanted for suspected pump thrombosis, 47 actually had thrombosis. In addition, six of the LVADs that were explanted for other reasons also had a significant amount of thrombus, resulting in 53 total explanted LVAD with confirmed pump thrombosis.

The researchers analyzed blood levels of LDH during the 6 months prior to explant. Among the patients with the 53 LVADs explanted with confirmed pump thrombosis, the median of all LDH levels during the period was 1,061 IU/L and the median maximum LDH level for each patient was 1,940 IU/L, reported Dr. Sood, a cardiac surgeon at the University of Michigan. In contrast, among the patients who had a total of 17 LVADs explanted without pump thrombosis, the median value for all LDH measures during the 6 months prior to explant was 533 IU/L, and their medium maximum level was 504 IU/L.

Analysis of LDH levels prior to explant and subsequent confirmation of pump thrombosis identified a cut off of 1,150 IU/L as able to identify pump thrombosis with a sensitivity of 78% and a specificity of 90%, Dr. Sood reported.

mzoler@frontlinemedcom.com

On Twitter @mitchelzoler

PHOENIX – In the clinical opinion of Dr. Nevin M. Katz, caring for critical care patients after cardiothoracic surgery requires a multidisciplinary team.

“It used to be just the surgeons and the residents and anesthesiologists, but in this era, it’s a broad team,” Dr. Katz said at the annual meeting of the Society of Thoracic Surgeons. “Coordination of the team, which includes surgeons, anesthesiologists, physician assistants, bedside nurses, nurse practitioners, perfusionists, pharmacists, respiratory therapists, and nutritionists is very important, and it’s important that members of the team be on the same page.”

Dr. Katz, a cardiovascular surgeon/intensivist at Johns Hopkins University, Baltimore, went on to offer tips for managing right ventricular failure in cardiac surgical patients. He recommends that clinicians consider five basic parameters of hemodynamic management: the heart rate and rhythm; the preload; the afterload; contractility; and the surgical result, including the potential for an anatomic problem and the risk of cardiac tamponade. “One must also consider a cardiac assist device,” he said.

He recommended that the cardiac index goal for cardiovascular patients in the ICU be in the range of 2.2-4.4 L per min/m². The recommended hemodynamic goals also included systemic blood pressure ranges with a systolic pressure of 90-140 mm Hg and a mean arterial pressure of 70-90 mm Hg; a left arterial pressure or pulmonary capillary wedge pressure of 5-18 mm Hg, a right arterial pressure or central venous pressure of 5-15 mm Hg, and a systemic vascular resistance of 800-1,200 dynes per sec/cm⁵. “When treating right ventricular failure or complex patients, I think advanced PA [pulmonary artery] catheters are valuable, although they’re not absolutely necessary,” he said.

Complementary technologies available in most ICUs can help clinicians manage these patients, particularly ultrasound. With ultrasound, “we can determine where the patient is on the ventricular function curve, regional versus global dysfunction, right ventricular versus left ventricular dysfunction, valve dysfunction, and cardiac tamponade,” said Dr. Katz, who also created the Foundation for the Advancement of Cardiothoracic Care, also known as FACTS-Care. “It’s a very important monitoring modality.”

An important goal in managing patients with right ventricular failure is to establish an optimal heart rate and rhythm. “We have modalities to treat bradycardia and heart block,” he said. “Loss of atrial contraction is very important. If we can avoid atrial fibrillation, that’s good. Ventricular arrhythmias can be a problem, and nowadays we can treat atrioventricular and ventricular dyssynchrony.”

Optimal preload requires a focus on volume responsiveness, Dr. Katz continued. “Where is the patient on that ventricular function curve?” he asked. “With the advanced PA catheters, there are ways to look at that. You would like to be on the ascending part of that curve.” Clinicians can also use pulsus paradoxus, a variation of systemic arterial pulse volume. “That will indicate that perhaps you’re low in volume, but you can use stroke volume variation with an advanced PA catheter,” he said. “If your stroke volume variation is greater than 15% you’re on the ascending part of the curve. But if your stroke volume variation is less than 15%, your volume is probably optimal and you’re not going to be volume responsive.”

Clinicians who lack the benefit of an advanced PA catheter can assess volume responsiveness with passive leg raising.

Low preload causes of RV failure include hypovolemia, bleeding, third-spacing, high urine output, and cardiac tamponade. High preload can be a problem, too, from excess fluid administration, tricuspid or pulmonary valve regurgitation, or from left to right shunting.

Overall, optimal management of RV failure depends on the coordination of the multidisciplinary critical care team.

Dr. Katz reported having no financial disclosures.

dbrunk@frontlinemedcom.com

PHOENIX – In the clinical opinion of Dr. Nevin M. Katz, caring for critical care patients after cardiothoracic surgery requires a multidisciplinary team.

“It used to be just the surgeons and the residents and anesthesiologists, but in this era, it’s a broad team,” Dr. Katz said at the annual meeting of the Society of Thoracic Surgeons. “Coordination of the team, which includes surgeons, anesthesiologists, physician assistants, bedside nurses, nurse practitioners, perfusionists, pharmacists, respiratory therapists, and nutritionists is very important, and it’s important that members of the team be on the same page.”

Dr. Katz, a cardiovascular surgeon/intensivist at Johns Hopkins University, Baltimore, went on to offer tips for managing right ventricular failure in cardiac surgical patients. He recommends that clinicians consider five basic parameters of hemodynamic management: the heart rate and rhythm; the preload; the afterload; contractility; and the surgical result, including the potential for an anatomic problem and the risk of cardiac tamponade. “One must also consider a cardiac assist device,” he said.

He recommended that the cardiac index goal for cardiovascular patients in the ICU be in the range of 2.2-4.4 L per min/m². The recommended hemodynamic goals also included systemic blood pressure ranges with a systolic pressure of 90-140 mm Hg and a mean arterial pressure of 70-90 mm Hg; a left arterial pressure or pulmonary capillary wedge pressure of 5-18 mm Hg, a right arterial pressure or central venous pressure of 5-15 mm Hg, and a systemic vascular resistance of 800-1,200 dynes per sec/cm⁵. “When treating right ventricular failure or complex patients, I think advanced PA [pulmonary artery] catheters are valuable, although they’re not absolutely necessary,” he said.

Complementary technologies available in most ICUs can help clinicians manage these patients, particularly ultrasound. With ultrasound, “we can determine where the patient is on the ventricular function curve, regional versus global dysfunction, right ventricular versus left ventricular dysfunction, valve dysfunction, and cardiac tamponade,” said Dr. Katz, who also created the Foundation for the Advancement of Cardiothoracic Care, also known as FACTS-Care. “It’s a very important monitoring modality.”

An important goal in managing patients with right ventricular failure is to establish an optimal heart rate and rhythm. “We have modalities to treat bradycardia and heart block,” he said. “Loss of atrial contraction is very important. If we can avoid atrial fibrillation, that’s good. Ventricular arrhythmias can be a problem, and nowadays we can treat atrioventricular and ventricular dyssynchrony.”

Optimal preload requires a focus on volume responsiveness, Dr. Katz continued. “Where is the patient on that ventricular function curve?” he asked. “With the advanced PA catheters, there are ways to look at that. You would like to be on the ascending part of that curve.” Clinicians can also use pulsus paradoxus, a variation of systemic arterial pulse volume. “That will indicate that perhaps you’re low in volume, but you can use stroke volume variation with an advanced PA catheter,” he said. “If your stroke volume variation is greater than 15% you’re on the ascending part of the curve. But if your stroke volume variation is less than 15%, your volume is probably optimal and you’re not going to be volume responsive.”

Clinicians who lack the benefit of an advanced PA catheter can assess volume responsiveness with passive leg raising.

Low preload causes of RV failure include hypovolemia, bleeding, third-spacing, high urine output, and cardiac tamponade. High preload can be a problem, too, from excess fluid administration, tricuspid or pulmonary valve regurgitation, or from left to right shunting.

Overall, optimal management of RV failure depends on the coordination of the multidisciplinary critical care team.

Dr. Katz reported having no financial disclosures.

dbrunk@frontlinemedcom.com

PHOENIX – In the clinical opinion of Dr. Nevin M. Katz, caring for critical care patients after cardiothoracic surgery requires a multidisciplinary team.

“It used to be just the surgeons and the residents and anesthesiologists, but in this era, it’s a broad team,” Dr. Katz said at the annual meeting of the Society of Thoracic Surgeons. “Coordination of the team, which includes surgeons, anesthesiologists, physician assistants, bedside nurses, nurse practitioners, perfusionists, pharmacists, respiratory therapists, and nutritionists is very important, and it’s important that members of the team be on the same page.”

Dr. Katz, a cardiovascular surgeon/intensivist at Johns Hopkins University, Baltimore, went on to offer tips for managing right ventricular failure in cardiac surgical patients. He recommends that clinicians consider five basic parameters of hemodynamic management: the heart rate and rhythm; the preload; the afterload; contractility; and the surgical result, including the potential for an anatomic problem and the risk of cardiac tamponade. “One must also consider a cardiac assist device,” he said.

He recommended that the cardiac index goal for cardiovascular patients in the ICU be in the range of 2.2-4.4 L per min/m². The recommended hemodynamic goals also included systemic blood pressure ranges with a systolic pressure of 90-140 mm Hg and a mean arterial pressure of 70-90 mm Hg; a left arterial pressure or pulmonary capillary wedge pressure of 5-18 mm Hg, a right arterial pressure or central venous pressure of 5-15 mm Hg, and a systemic vascular resistance of 800-1,200 dynes per sec/cm⁵. “When treating right ventricular failure or complex patients, I think advanced PA [pulmonary artery] catheters are valuable, although they’re not absolutely necessary,” he said.

Complementary technologies available in most ICUs can help clinicians manage these patients, particularly ultrasound. With ultrasound, “we can determine where the patient is on the ventricular function curve, regional versus global dysfunction, right ventricular versus left ventricular dysfunction, valve dysfunction, and cardiac tamponade,” said Dr. Katz, who also created the Foundation for the Advancement of Cardiothoracic Care, also known as FACTS-Care. “It’s a very important monitoring modality.”

An important goal in managing patients with right ventricular failure is to establish an optimal heart rate and rhythm. “We have modalities to treat bradycardia and heart block,” he said. “Loss of atrial contraction is very important. If we can avoid atrial fibrillation, that’s good. Ventricular arrhythmias can be a problem, and nowadays we can treat atrioventricular and ventricular dyssynchrony.”

Optimal preload requires a focus on volume responsiveness, Dr. Katz continued. “Where is the patient on that ventricular function curve?” he asked. “With the advanced PA catheters, there are ways to look at that. You would like to be on the ascending part of that curve.” Clinicians can also use pulsus paradoxus, a variation of systemic arterial pulse volume. “That will indicate that perhaps you’re low in volume, but you can use stroke volume variation with an advanced PA catheter,” he said. “If your stroke volume variation is greater than 15% you’re on the ascending part of the curve. But if your stroke volume variation is less than 15%, your volume is probably optimal and you’re not going to be volume responsive.”

Clinicians who lack the benefit of an advanced PA catheter can assess volume responsiveness with passive leg raising.

Low preload causes of RV failure include hypovolemia, bleeding, third-spacing, high urine output, and cardiac tamponade. High preload can be a problem, too, from excess fluid administration, tricuspid or pulmonary valve regurgitation, or from left to right shunting.

Overall, optimal management of RV failure depends on the coordination of the multidisciplinary critical care team.

Dr. Katz reported having no financial disclosures.

dbrunk@frontlinemedcom.com

PHOENIX – Patients with a history of head and neck, lung, bladder, and hematologic malignancies had increased rates of subsequent non–small cell lung cancer (NSCLC), a large analysis of national data found.

“It is unclear to what extent the higher rate of primary NSCLC in these patients may be attributed to smoking, previous cancer history, or other lung cancer risk factors,” researchers led by Dr. Geena Wu wrote in an abstract presented during a poster session at the annual meeting of the Society of Thoracic Surgeons. “Further research using individual smoking data may better delineate who is at increased risk of NSCLC based on prior cancer site and smoking history.”

Doug Brunk/Frontline Medical News

In a study that Dr. Wu led during a research fellowship at the City of Hope National Medical Center, Duarte, Calif., she and her associates used the Surveillance, Epidemiology, and End Results (SEER) 1992-2007 dataset to identify 32,058 patients with a prior malignancy who subsequently developed primary lung cancer at 6 months or more after their initial cancer. They calculated standardized incidence ratios (SIRs) for NSCLC as a rate of observed to expected NSCLC cases adjusted by person-years at risk, age, gender, and time of diagnosis.

The researchers found that patients with a history of the following cancers had higher rates of second primary NSCLC than expected: head and neck (SIR, 4.00), colon and rectum (SIR, 1.16), pancreas (SIR, 1.44), lung (SIR, 4.88), bladder (SIR, 1.97), kidney (SIR, 1.21), breast (SIR, 1.09), and leukemia or lymphoma (SIR, 1.40).

At the same time, patients with a history of pancreatic or breast cancer who were treated with radiation had a higher incidence of second primary NSCLC (SIR of 2.54 and SIR of 1.14, respectively), while those who were not treated with radiation did not.

Although the SEER database does not contain information about patient smoking history, the researchers evaluated adult smoking rates by state by using a national map from the Centers for Disease Control and Prevention’s 2013 Behavioral Risk Factor Surveillance System. Smoking rates were low (defined as 13.7% or less) in California, Hawaii, and Utah, and were higher in all other states, especially in Southeastern states. Dr. Wu and her associates found that patients from high smoking areas who had previous cancers of the colon and rectum, pancreas, kidney, thyroid, and breast had higher rates of a primary NSCLC, while those from low smoking areas did not. Interestingly, patients from high smoking areas who previously had uterine cancer, prostate, or melanoma had did not have higher rates of a primary NSCLC.

“Just because someone has a previous history of cancer, they’re not necessarily at increased risk of a second lung cancer,” Dr. Wu, who is now a fourth-year general surgery resident at Maricopa County Hospital in Phoenix said in an interview at the meeting. “You have to look at what kind of cancer they had and what their smoking history is – whether or not they continue to smoke, because smoking is such an important risk factor.”

Another limitation of the SEER database is that it lacks details about the type of chemotherapy patients receive, “so whether or not chemotherapy plays an impact in the elevated risk of lung cancer we can’t say.”

Dr. Wu reported having no financial disclosures.

dbrunk@frontlinemedcom.com

PHOENIX – Patients with a history of head and neck, lung, bladder, and hematologic malignancies had increased rates of subsequent non–small cell lung cancer (NSCLC), a large analysis of national data found.

“It is unclear to what extent the higher rate of primary NSCLC in these patients may be attributed to smoking, previous cancer history, or other lung cancer risk factors,” researchers led by Dr. Geena Wu wrote in an abstract presented during a poster session at the annual meeting of the Society of Thoracic Surgeons. “Further research using individual smoking data may better delineate who is at increased risk of NSCLC based on prior cancer site and smoking history.”

Doug Brunk/Frontline Medical News

In a study that Dr. Wu led during a research fellowship at the City of Hope National Medical Center, Duarte, Calif., she and her associates used the Surveillance, Epidemiology, and End Results (SEER) 1992-2007 dataset to identify 32,058 patients with a prior malignancy who subsequently developed primary lung cancer at 6 months or more after their initial cancer. They calculated standardized incidence ratios (SIRs) for NSCLC as a rate of observed to expected NSCLC cases adjusted by person-years at risk, age, gender, and time of diagnosis.

The researchers found that patients with a history of the following cancers had higher rates of second primary NSCLC than expected: head and neck (SIR, 4.00), colon and rectum (SIR, 1.16), pancreas (SIR, 1.44), lung (SIR, 4.88), bladder (SIR, 1.97), kidney (SIR, 1.21), breast (SIR, 1.09), and leukemia or lymphoma (SIR, 1.40).

At the same time, patients with a history of pancreatic or breast cancer who were treated with radiation had a higher incidence of second primary NSCLC (SIR of 2.54 and SIR of 1.14, respectively), while those who were not treated with radiation did not.

Although the SEER database does not contain information about patient smoking history, the researchers evaluated adult smoking rates by state by using a national map from the Centers for Disease Control and Prevention’s 2013 Behavioral Risk Factor Surveillance System. Smoking rates were low (defined as 13.7% or less) in California, Hawaii, and Utah, and were higher in all other states, especially in Southeastern states. Dr. Wu and her associates found that patients from high smoking areas who had previous cancers of the colon and rectum, pancreas, kidney, thyroid, and breast had higher rates of a primary NSCLC, while those from low smoking areas did not. Interestingly, patients from high smoking areas who previously had uterine cancer, prostate, or melanoma had did not have higher rates of a primary NSCLC.

“Just because someone has a previous history of cancer, they’re not necessarily at increased risk of a second lung cancer,” Dr. Wu, who is now a fourth-year general surgery resident at Maricopa County Hospital in Phoenix said in an interview at the meeting. “You have to look at what kind of cancer they had and what their smoking history is – whether or not they continue to smoke, because smoking is such an important risk factor.”

Another limitation of the SEER database is that it lacks details about the type of chemotherapy patients receive, “so whether or not chemotherapy plays an impact in the elevated risk of lung cancer we can’t say.”

Dr. Wu reported having no financial disclosures.

dbrunk@frontlinemedcom.com

PHOENIX – Patients with a history of head and neck, lung, bladder, and hematologic malignancies had increased rates of subsequent non–small cell lung cancer (NSCLC), a large analysis of national data found.

“It is unclear to what extent the higher rate of primary NSCLC in these patients may be attributed to smoking, previous cancer history, or other lung cancer risk factors,” researchers led by Dr. Geena Wu wrote in an abstract presented during a poster session at the annual meeting of the Society of Thoracic Surgeons. “Further research using individual smoking data may better delineate who is at increased risk of NSCLC based on prior cancer site and smoking history.”

Doug Brunk/Frontline Medical News

In a study that Dr. Wu led during a research fellowship at the City of Hope National Medical Center, Duarte, Calif., she and her associates used the Surveillance, Epidemiology, and End Results (SEER) 1992-2007 dataset to identify 32,058 patients with a prior malignancy who subsequently developed primary lung cancer at 6 months or more after their initial cancer. They calculated standardized incidence ratios (SIRs) for NSCLC as a rate of observed to expected NSCLC cases adjusted by person-years at risk, age, gender, and time of diagnosis.

The researchers found that patients with a history of the following cancers had higher rates of second primary NSCLC than expected: head and neck (SIR, 4.00), colon and rectum (SIR, 1.16), pancreas (SIR, 1.44), lung (SIR, 4.88), bladder (SIR, 1.97), kidney (SIR, 1.21), breast (SIR, 1.09), and leukemia or lymphoma (SIR, 1.40).

At the same time, patients with a history of pancreatic or breast cancer who were treated with radiation had a higher incidence of second primary NSCLC (SIR of 2.54 and SIR of 1.14, respectively), while those who were not treated with radiation did not.

Although the SEER database does not contain information about patient smoking history, the researchers evaluated adult smoking rates by state by using a national map from the Centers for Disease Control and Prevention’s 2013 Behavioral Risk Factor Surveillance System. Smoking rates were low (defined as 13.7% or less) in California, Hawaii, and Utah, and were higher in all other states, especially in Southeastern states. Dr. Wu and her associates found that patients from high smoking areas who had previous cancers of the colon and rectum, pancreas, kidney, thyroid, and breast had higher rates of a primary NSCLC, while those from low smoking areas did not. Interestingly, patients from high smoking areas who previously had uterine cancer, prostate, or melanoma had did not have higher rates of a primary NSCLC.

“Just because someone has a previous history of cancer, they’re not necessarily at increased risk of a second lung cancer,” Dr. Wu, who is now a fourth-year general surgery resident at Maricopa County Hospital in Phoenix said in an interview at the meeting. “You have to look at what kind of cancer they had and what their smoking history is – whether or not they continue to smoke, because smoking is such an important risk factor.”

Another limitation of the SEER database is that it lacks details about the type of chemotherapy patients receive, “so whether or not chemotherapy plays an impact in the elevated risk of lung cancer we can’t say.”

Dr. Wu reported having no financial disclosures.

dbrunk@frontlinemedcom.com

PHOENIX – Over the past 11 years, fewer general surgery residents have participated in important types of general thoracic surgery cases, a retrospective review found.

“These findings may be the result of the work-hours reduction causing less exposure to general thoracic surgery and/or a reluctance to allow general surgery residents to perform the increasingly common minimally invasive procedures,” researchers led by Dr. William S. Ragalie wrote in an abstract presented during a poster session at the annual meeting of the Society of Thoracic Surgeons.

Dr. Ragalie of the Medical College of Wisconsin, Milwaukee, and his associates retrospectively reviewed the Accreditation Council for Graduate Medical Education resident case log database for the most recent 11 years in an effort to quantify and trend the operative experience among general surgery residents. They categorized cases by year, level of resident participation, and level of complexity. Major general thoracic cases were defined as esophagectomy, pneumonectomy, and lobectomy, while cases that did not involve hilar dissection were classified as “other thoracic.”

The researchers found that the 90th percentile of first assist thoracic surgery cases decreased significantly over the study period by an average of 1.46 cases per year (P = .0012). Decreased case volumes in pneumonectomy were also noted at the junior level (–0.012 cases per year; P less than .0001) and at the chief resident level (–0.31 cases per year; P less than .001). This was also true of open lobectomy cases (–0.14 cases per year at the junior level; P less than .001, and –3.41 cases per year at the chief resident level; P less than .0001).

As for video-assisted thoracoscopic surgery (VATS) lobectomy, the researchers observed an increase in average case volume at the junior surgeon level of .13 cases per year, but a decrease at the chief resident level of one case per year (P less than .001 for both).

©monkeybusinessimages/Thinkstock.com

Dr. Ragalie and his associates also observed a decrease in the following procedures performed by chief residents: open exploratory thoracoscopy (–3.17 cases per year; P less than .001), VATS exploratory thoracoscopy (–2.95 cases per year; P less than .0001), open wedge resection (–1.52 cases per year; P less than .0227), VATS wedge resection (–2.72 cases per year; P less than .0002), “other thoracic” (–6.3 cases per year; P = .0001), and thoracoscopic pleurodesis (–2.09 cases per year; P less than .0001).

At the same time, a significant trend of decreased case volume at the junior surgeon level was noted for open exploratory thoracoscopy (–0.10 cases per year; P less than .0001) and open wedge resection (–0.22 cases per year; P = . 0115).

The researchers reported having no financial disclosures.

dbrunk@frontlinemedcom.com

PHOENIX – Over the past 11 years, fewer general surgery residents have participated in important types of general thoracic surgery cases, a retrospective review found.

“These findings may be the result of the work-hours reduction causing less exposure to general thoracic surgery and/or a reluctance to allow general surgery residents to perform the increasingly common minimally invasive procedures,” researchers led by Dr. William S. Ragalie wrote in an abstract presented during a poster session at the annual meeting of the Society of Thoracic Surgeons.

Dr. Ragalie of the Medical College of Wisconsin, Milwaukee, and his associates retrospectively reviewed the Accreditation Council for Graduate Medical Education resident case log database for the most recent 11 years in an effort to quantify and trend the operative experience among general surgery residents. They categorized cases by year, level of resident participation, and level of complexity. Major general thoracic cases were defined as esophagectomy, pneumonectomy, and lobectomy, while cases that did not involve hilar dissection were classified as “other thoracic.”

The researchers found that the 90th percentile of first assist thoracic surgery cases decreased significantly over the study period by an average of 1.46 cases per year (P = .0012). Decreased case volumes in pneumonectomy were also noted at the junior level (–0.012 cases per year; P less than .0001) and at the chief resident level (–0.31 cases per year; P less than .001). This was also true of open lobectomy cases (–0.14 cases per year at the junior level; P less than .001, and –3.41 cases per year at the chief resident level; P less than .0001).

As for video-assisted thoracoscopic surgery (VATS) lobectomy, the researchers observed an increase in average case volume at the junior surgeon level of .13 cases per year, but a decrease at the chief resident level of one case per year (P less than .001 for both).

©monkeybusinessimages/Thinkstock.com

Dr. Ragalie and his associates also observed a decrease in the following procedures performed by chief residents: open exploratory thoracoscopy (–3.17 cases per year; P less than .001), VATS exploratory thoracoscopy (–2.95 cases per year; P less than .0001), open wedge resection (–1.52 cases per year; P less than .0227), VATS wedge resection (–2.72 cases per year; P less than .0002), “other thoracic” (–6.3 cases per year; P = .0001), and thoracoscopic pleurodesis (–2.09 cases per year; P less than .0001).

At the same time, a significant trend of decreased case volume at the junior surgeon level was noted for open exploratory thoracoscopy (–0.10 cases per year; P less than .0001) and open wedge resection (–0.22 cases per year; P = . 0115).

The researchers reported having no financial disclosures.

dbrunk@frontlinemedcom.com

PHOENIX – Over the past 11 years, fewer general surgery residents have participated in important types of general thoracic surgery cases, a retrospective review found.

“These findings may be the result of the work-hours reduction causing less exposure to general thoracic surgery and/or a reluctance to allow general surgery residents to perform the increasingly common minimally invasive procedures,” researchers led by Dr. William S. Ragalie wrote in an abstract presented during a poster session at the annual meeting of the Society of Thoracic Surgeons.

Dr. Ragalie of the Medical College of Wisconsin, Milwaukee, and his associates retrospectively reviewed the Accreditation Council for Graduate Medical Education resident case log database for the most recent 11 years in an effort to quantify and trend the operative experience among general surgery residents. They categorized cases by year, level of resident participation, and level of complexity. Major general thoracic cases were defined as esophagectomy, pneumonectomy, and lobectomy, while cases that did not involve hilar dissection were classified as “other thoracic.”

The researchers found that the 90th percentile of first assist thoracic surgery cases decreased significantly over the study period by an average of 1.46 cases per year (P = .0012). Decreased case volumes in pneumonectomy were also noted at the junior level (–0.012 cases per year; P less than .0001) and at the chief resident level (–0.31 cases per year; P less than .001). This was also true of open lobectomy cases (–0.14 cases per year at the junior level; P less than .001, and –3.41 cases per year at the chief resident level; P less than .0001).

As for video-assisted thoracoscopic surgery (VATS) lobectomy, the researchers observed an increase in average case volume at the junior surgeon level of .13 cases per year, but a decrease at the chief resident level of one case per year (P less than .001 for both).

©monkeybusinessimages/Thinkstock.com

Dr. Ragalie and his associates also observed a decrease in the following procedures performed by chief residents: open exploratory thoracoscopy (–3.17 cases per year; P less than .001), VATS exploratory thoracoscopy (–2.95 cases per year; P less than .0001), open wedge resection (–1.52 cases per year; P less than .0227), VATS wedge resection (–2.72 cases per year; P less than .0002), “other thoracic” (–6.3 cases per year; P = .0001), and thoracoscopic pleurodesis (–2.09 cases per year; P less than .0001).

At the same time, a significant trend of decreased case volume at the junior surgeon level was noted for open exploratory thoracoscopy (–0.10 cases per year; P less than .0001) and open wedge resection (–0.22 cases per year; P = . 0115).

The researchers reported having no financial disclosures.

dbrunk@frontlinemedcom.com

PHOENIX – A simple, five-element formula can help identify the patients undergoing heart surgery who face the greatest risk for a hospital readmission within 30 days following discharge from their index hospitalization.

The surgeons who developed this formula hope to use it in an investigational program that will target intensified management resources in postsurgical patients who face the highest readmission risk, to cut rehospitalizations and better improve their clinical status and quality of life.

Mitchel L. Zoler/Frontline Medical News

The analysis that produced this formula also documented that the worst offender for triggering rehospitalizations following heart surgery is fluid overload, the proximate readmission cause for 23% of postsurgical patients, Dr. Arman Kilic said at the annual meeting of the Society of Thoracic Surgeons. The next most common cause was infection, which led to 20% of readmissions, followed by arrhythmias, responsible for 8% of readmissions, said Dr. Kilic, a thoracic surgeon at the University of Pennsylvania in Philadelphia.

Because fluid overload, often in the form of pleural effusion, is such an important driver of rehospitalizations, a more targeted management program would include better titration of diuretic treatment to patients following heart surgery, thoracentesis, and closer monitoring of clinical features that flag fluid overload such as weight.

“The volume overload issue is where the money is. If we can reduce that, it could really impact readmissions,” Dr. Kilic said in an interview.

An investigational program to target rehospitalization risk in heart surgery patients is planned at Johns Hopkins Hospital in Baltimore, where Dr. Kilic worked when he performed this analysis. Surgeons at Johns Hopkins are now in the process of getting funding for this pilot program, said Dr. John V. Conte Jr., professor of surgery and director of mechanical circulatory support at Johns Hopkins and a collaborator with Dr. Kilic on developing the risk formula.

“We’ll tailor postoperative follow-up. We’ll get high-risk patients back to the clinic sooner, and we’ll send nurse practitioners to see them to make sure they’re taking their medications and are getting weighed daily,” Dr. Conte said in an interview. “When a patient has heart surgery, they typically retain about 5-10 pounds of fluid. Patients with good renal function give up that fluid easily, but others are difficult to diurese. Many patients go home before they have been fully diuresed, and we need to follow these patients and transition them better to out-of-hospital care.”

He noted that other situations also come up that unnecessarily drive patients back to the hospital when an alternative and less expensive intervention might be equally effective. For example, some patients return to the hospital out of concern for how their chest wound is healing. Instead of being rehospitalized, such patients could be reassured by having them send a nurse a photo of their wound or by coming to an outpatient clinic.

“We need to engage more often with recently discharged patients,” Dr. Conte said in an interview. “Discharging them doesn’t mean separating them from the health care system; it should mean interacting with patients in a different way” that produces better outcomes and patient satisfaction for less money. Developing improved ways to manage recent heart surgery patients following discharge becomes even more critical later this year when, in July, the Centers for Medicare & Medicaid Services adds 30-day readmissions following coronary artery bypass grafting (CABG) to its list of procedures that can generate a penalty to hospitals if they exceed U.S. norms for readmission rates.

The risk model developed by Dr. Kilic, Dr. Conte, and their associates used data collected from 5,360 heart surgery patients treated at Johns Hopkins during 2008-2013. Nearly half the patients underwent isolated CABG, and 20% had isolated valve surgery. Overall, 585 patients (11%) had a hospital readmission within 30 days of their index discharge. One limitation of the analysis was it used data only on readmissions back to Johns Hopkins Hospital.

The researchers used data from three-quarters of the database to derive the risk formula, and from the remaining 25% of the database to validate the formula. A multivariate analysis of demographic and clinical characteristics that significantly linked with an elevated risk for readmissions identified five factors that independently made a significant contribution to readmission risk. The researchers assigned each of these five factors points depending on its relative contribution to readmission risk in the adjusted model: Severe chronic lung disease received 6 points; placement of a ventricular assist device received 5 points, while other types of heart surgery that was not CABG or valve surgery received 4 points (isolated CABG, isolated valve, or combined CABG and valve surgery received 0 points); development of acute renal failure postoperatively but before index discharge received 4 points; an index length of stay beyond 7 days received 4 points; and African American race received 3 points. The maximum number of points a patient could receive was 22.

Patients with a score of 0 had a 6% rate of a 30-day readmission; those with a score of 22 had a 63% readmission rate. For simplicity, Dr. Kilic suggested dividing patients into three categories based on their readmission risk score: Low-risk patients with a score of 0 had a readmission risk of 6%, medium-risk patients with a score of 1-10 had a readmission risk of 12%, and high-risk patients with a score of 11 or more had a readmission risk of 31%. The researchers found a 96% correlation when comparing these predicted readmission risk rates based on the derivation-subgroup analysis with the actual readmission rates seen in the validation subgroup of their database. The targeted risk-management program planned by Dr. Conte would primarily focus on high-risk patients.

Dr. Kilic and Dr. Conte said they had no relevant financial disclosures.

PHOENIX – A simple, five-element formula can help identify the patients undergoing heart surgery who face the greatest risk for a hospital readmission within 30 days following discharge from their index hospitalization.

The surgeons who developed this formula hope to use it in an investigational program that will target intensified management resources in postsurgical patients who face the highest readmission risk, to cut rehospitalizations and better improve their clinical status and quality of life.

Mitchel L. Zoler/Frontline Medical News

The analysis that produced this formula also documented that the worst offender for triggering rehospitalizations following heart surgery is fluid overload, the proximate readmission cause for 23% of postsurgical patients, Dr. Arman Kilic said at the annual meeting of the Society of Thoracic Surgeons. The next most common cause was infection, which led to 20% of readmissions, followed by arrhythmias, responsible for 8% of readmissions, said Dr. Kilic, a thoracic surgeon at the University of Pennsylvania in Philadelphia.

Because fluid overload, often in the form of pleural effusion, is such an important driver of rehospitalizations, a more targeted management program would include better titration of diuretic treatment to patients following heart surgery, thoracentesis, and closer monitoring of clinical features that flag fluid overload such as weight.

“The volume overload issue is where the money is. If we can reduce that, it could really impact readmissions,” Dr. Kilic said in an interview.

An investigational program to target rehospitalization risk in heart surgery patients is planned at Johns Hopkins Hospital in Baltimore, where Dr. Kilic worked when he performed this analysis. Surgeons at Johns Hopkins are now in the process of getting funding for this pilot program, said Dr. John V. Conte Jr., professor of surgery and director of mechanical circulatory support at Johns Hopkins and a collaborator with Dr. Kilic on developing the risk formula.

“We’ll tailor postoperative follow-up. We’ll get high-risk patients back to the clinic sooner, and we’ll send nurse practitioners to see them to make sure they’re taking their medications and are getting weighed daily,” Dr. Conte said in an interview. “When a patient has heart surgery, they typically retain about 5-10 pounds of fluid. Patients with good renal function give up that fluid easily, but others are difficult to diurese. Many patients go home before they have been fully diuresed, and we need to follow these patients and transition them better to out-of-hospital care.”

He noted that other situations also come up that unnecessarily drive patients back to the hospital when an alternative and less expensive intervention might be equally effective. For example, some patients return to the hospital out of concern for how their chest wound is healing. Instead of being rehospitalized, such patients could be reassured by having them send a nurse a photo of their wound or by coming to an outpatient clinic.

“We need to engage more often with recently discharged patients,” Dr. Conte said in an interview. “Discharging them doesn’t mean separating them from the health care system; it should mean interacting with patients in a different way” that produces better outcomes and patient satisfaction for less money. Developing improved ways to manage recent heart surgery patients following discharge becomes even more critical later this year when, in July, the Centers for Medicare & Medicaid Services adds 30-day readmissions following coronary artery bypass grafting (CABG) to its list of procedures that can generate a penalty to hospitals if they exceed U.S. norms for readmission rates.

The risk model developed by Dr. Kilic, Dr. Conte, and their associates used data collected from 5,360 heart surgery patients treated at Johns Hopkins during 2008-2013. Nearly half the patients underwent isolated CABG, and 20% had isolated valve surgery. Overall, 585 patients (11%) had a hospital readmission within 30 days of their index discharge. One limitation of the analysis was it used data only on readmissions back to Johns Hopkins Hospital.

The researchers used data from three-quarters of the database to derive the risk formula, and from the remaining 25% of the database to validate the formula. A multivariate analysis of demographic and clinical characteristics that significantly linked with an elevated risk for readmissions identified five factors that independently made a significant contribution to readmission risk. The researchers assigned each of these five factors points depending on its relative contribution to readmission risk in the adjusted model: Severe chronic lung disease received 6 points; placement of a ventricular assist device received 5 points, while other types of heart surgery that was not CABG or valve surgery received 4 points (isolated CABG, isolated valve, or combined CABG and valve surgery received 0 points); development of acute renal failure postoperatively but before index discharge received 4 points; an index length of stay beyond 7 days received 4 points; and African American race received 3 points. The maximum number of points a patient could receive was 22.

Patients with a score of 0 had a 6% rate of a 30-day readmission; those with a score of 22 had a 63% readmission rate. For simplicity, Dr. Kilic suggested dividing patients into three categories based on their readmission risk score: Low-risk patients with a score of 0 had a readmission risk of 6%, medium-risk patients with a score of 1-10 had a readmission risk of 12%, and high-risk patients with a score of 11 or more had a readmission risk of 31%. The researchers found a 96% correlation when comparing these predicted readmission risk rates based on the derivation-subgroup analysis with the actual readmission rates seen in the validation subgroup of their database. The targeted risk-management program planned by Dr. Conte would primarily focus on high-risk patients.

Dr. Kilic and Dr. Conte said they had no relevant financial disclosures.

PHOENIX – A simple, five-element formula can help identify the patients undergoing heart surgery who face the greatest risk for a hospital readmission within 30 days following discharge from their index hospitalization.

The surgeons who developed this formula hope to use it in an investigational program that will target intensified management resources in postsurgical patients who face the highest readmission risk, to cut rehospitalizations and better improve their clinical status and quality of life.

Mitchel L. Zoler/Frontline Medical News

The analysis that produced this formula also documented that the worst offender for triggering rehospitalizations following heart surgery is fluid overload, the proximate readmission cause for 23% of postsurgical patients, Dr. Arman Kilic said at the annual meeting of the Society of Thoracic Surgeons. The next most common cause was infection, which led to 20% of readmissions, followed by arrhythmias, responsible for 8% of readmissions, said Dr. Kilic, a thoracic surgeon at the University of Pennsylvania in Philadelphia.

Because fluid overload, often in the form of pleural effusion, is such an important driver of rehospitalizations, a more targeted management program would include better titration of diuretic treatment to patients following heart surgery, thoracentesis, and closer monitoring of clinical features that flag fluid overload such as weight.

“The volume overload issue is where the money is. If we can reduce that, it could really impact readmissions,” Dr. Kilic said in an interview.

An investigational program to target rehospitalization risk in heart surgery patients is planned at Johns Hopkins Hospital in Baltimore, where Dr. Kilic worked when he performed this analysis. Surgeons at Johns Hopkins are now in the process of getting funding for this pilot program, said Dr. John V. Conte Jr., professor of surgery and director of mechanical circulatory support at Johns Hopkins and a collaborator with Dr. Kilic on developing the risk formula.

“We’ll tailor postoperative follow-up. We’ll get high-risk patients back to the clinic sooner, and we’ll send nurse practitioners to see them to make sure they’re taking their medications and are getting weighed daily,” Dr. Conte said in an interview. “When a patient has heart surgery, they typically retain about 5-10 pounds of fluid. Patients with good renal function give up that fluid easily, but others are difficult to diurese. Many patients go home before they have been fully diuresed, and we need to follow these patients and transition them better to out-of-hospital care.”

He noted that other situations also come up that unnecessarily drive patients back to the hospital when an alternative and less expensive intervention might be equally effective. For example, some patients return to the hospital out of concern for how their chest wound is healing. Instead of being rehospitalized, such patients could be reassured by having them send a nurse a photo of their wound or by coming to an outpatient clinic.

“We need to engage more often with recently discharged patients,” Dr. Conte said in an interview. “Discharging them doesn’t mean separating them from the health care system; it should mean interacting with patients in a different way” that produces better outcomes and patient satisfaction for less money. Developing improved ways to manage recent heart surgery patients following discharge becomes even more critical later this year when, in July, the Centers for Medicare & Medicaid Services adds 30-day readmissions following coronary artery bypass grafting (CABG) to its list of procedures that can generate a penalty to hospitals if they exceed U.S. norms for readmission rates.

The risk model developed by Dr. Kilic, Dr. Conte, and their associates used data collected from 5,360 heart surgery patients treated at Johns Hopkins during 2008-2013. Nearly half the patients underwent isolated CABG, and 20% had isolated valve surgery. Overall, 585 patients (11%) had a hospital readmission within 30 days of their index discharge. One limitation of the analysis was it used data only on readmissions back to Johns Hopkins Hospital.

The researchers used data from three-quarters of the database to derive the risk formula, and from the remaining 25% of the database to validate the formula. A multivariate analysis of demographic and clinical characteristics that significantly linked with an elevated risk for readmissions identified five factors that independently made a significant contribution to readmission risk. The researchers assigned each of these five factors points depending on its relative contribution to readmission risk in the adjusted model: Severe chronic lung disease received 6 points; placement of a ventricular assist device received 5 points, while other types of heart surgery that was not CABG or valve surgery received 4 points (isolated CABG, isolated valve, or combined CABG and valve surgery received 0 points); development of acute renal failure postoperatively but before index discharge received 4 points; an index length of stay beyond 7 days received 4 points; and African American race received 3 points. The maximum number of points a patient could receive was 22.

Patients with a score of 0 had a 6% rate of a 30-day readmission; those with a score of 22 had a 63% readmission rate. For simplicity, Dr. Kilic suggested dividing patients into three categories based on their readmission risk score: Low-risk patients with a score of 0 had a readmission risk of 6%, medium-risk patients with a score of 1-10 had a readmission risk of 12%, and high-risk patients with a score of 11 or more had a readmission risk of 31%. The researchers found a 96% correlation when comparing these predicted readmission risk rates based on the derivation-subgroup analysis with the actual readmission rates seen in the validation subgroup of their database. The targeted risk-management program planned by Dr. Conte would primarily focus on high-risk patients.

Dr. Kilic and Dr. Conte said they had no relevant financial disclosures.

PHOENIX – A simple, five-element formula can help identify the patients undergoing heart surgery who face the greatest risk for a hospital readmission within 30 days following discharge from their index hospitalization.

The surgeons who developed this formula hope to use it in an investigational program that will target intensified management resources in postsurgical patients who face the highest readmission risk, to cut rehospitalizations and better improve their clinical status and quality of life.

The analysis that produced this formula also documented that the worst offender for triggering rehospitalizations following heart surgery is fluid overload, the proximate readmission cause for 23% of postsurgical patients, Dr. Arman Kilic said at the annual meeting of the Society of Thoracic Surgeons. The next most common cause was infection, which led to 20% of readmissions, followed by arrhythmias, responsible for 8% of readmissions, said Dr. Kilic, a thoracic surgeon at the University of Pennsylvania in Philadelphia.

Mitchel L. Zoler/Frontline Medical News

Because fluid overload, often in the form of pleural effusion, is such an important driver of rehospitalizations, a more targeted management program would include better titration of diuretic treatment to patients following heart surgery, thoracentesis, and closer monitoring of clinical features that flag fluid overload such as weight.

“The volume overload issue is where the money is. If we can reduce that, it could really impact readmissions,” Dr. Kilic said in an interview.

An investigational program to target rehospitalization risk in heart surgery patients is planned at Johns Hopkins Hospital in Baltimore, where Dr. Kilic worked when he performed this analysis. Surgeons at Johns Hopkins are now in the process of getting funding for this pilot program, said Dr. John V. Conte Jr., professor of surgery and director of mechanical circulatory support at Johns Hopkins and a collaborator with Dr. Kilic on developing the risk formula.

“We’ll tailor postoperative follow-up. We’ll get high-risk patients back to the clinic sooner, and we’ll send nurse practitioners to see them to make sure they’re taking their medications and are getting weighed daily,” Dr. Conte said in an interview. “When a patient has heart surgery, they typically retain about 5-10 pounds of fluid. Patients with good renal function give up that fluid easily, but others are difficult to diurese. Many patients go home before they have been fully diuresed, and we need to follow these patients and transition them better to out-of-hospital care.”

He noted that other situations also come up that unnecessarily drive patients back to the hospital when an alternative and less expensive intervention might be equally effective. For example, some patients return to the hospital out of concern for how their chest wound is healing. Instead of being rehospitalized, such patients could be reassured by having them send a nurse a photo of their wound or by coming to an outpatient clinic.

“We need to engage more often with recently discharged patients,” Dr. Conte said in an interview. “Discharging them doesn’t mean separating them from the health care system; it should mean interacting with patients in a different way” that produces better outcomes and patient satisfaction for less money. Developing improved ways to manage recent heart surgery patients following discharge becomes even more critical later this year when, in July, the Centers for Medicare & Medicaid Services adds 30-day readmissions following coronary artery bypass grafting (CABG) to its list of procedures that can generate a penalty to hospitals if they exceed U.S. norms for readmission rates.

The risk model developed by Dr. Kilic, Dr. Conte, and their associates used data collected from 5,360 heart surgery patients treated at Johns Hopkins during 2008-2013. Nearly half the patients underwent isolated CABG, and 20% had isolated valve surgery. Overall, 585 patients (11%) had a hospital readmission within 30 days of their index discharge. One limitation of the analysis was it used data only on readmissions back to Johns Hopkins Hospital.

The researchers used data from three-quarters of the database to derive the risk formula, and from the remaining 25% of the database to validate the formula. A multivariate analysis of demographic and clinical characteristics that significantly linked with an elevated risk for readmissions identified five factors that independently made a significant contribution to readmission risk. The researchers assigned each of these five factors points depending on its relative contribution to readmission risk in the adjusted model: Severe chronic lung disease received 6 points; placement of a ventricular assist device received 5 points, while other types of heart surgery that was not CABG or valve surgery received 4 points (isolated CABG, isolated valve, or combined CABG and valve surgery received 0 points); development of acute renal failure postoperatively but before index discharge received 4 points; an index length of stay beyond 7 days received 4 points; and African American race received 3 points. The maximum number of points a patient could receive was 22.

Patients with a score of 0 had a 6% rate of a 30-day readmission; those with a score of 22 had a 63% readmission rate. For simplicity, Dr. Kilic suggested dividing patients into three categories based on their readmission risk score: Low-risk patients with a score of 0 had a readmission risk of 6%, medium-risk patients with a score of 1-10 had a readmission risk of 12%, and high-risk patients with a score of 11 or more had a readmission risk of 31%. The researchers found a 96% correlation when comparing these predicted readmission risk rates based on the derivation-subgroup analysis with the actual readmission rates seen in the validation subgroup of their database. The targeted risk-management program planned by Dr. Conte would primarily focus on high-risk patients.

Dr. Kilic and Dr. Conte said they had no relevant financial disclosures.

mzoler@frontlinemedcom.com

On Twitter@mitchelzoler

PHOENIX – A simple, five-element formula can help identify the patients undergoing heart surgery who face the greatest risk for a hospital readmission within 30 days following discharge from their index hospitalization.

The surgeons who developed this formula hope to use it in an investigational program that will target intensified management resources in postsurgical patients who face the highest readmission risk, to cut rehospitalizations and better improve their clinical status and quality of life.

The analysis that produced this formula also documented that the worst offender for triggering rehospitalizations following heart surgery is fluid overload, the proximate readmission cause for 23% of postsurgical patients, Dr. Arman Kilic said at the annual meeting of the Society of Thoracic Surgeons. The next most common cause was infection, which led to 20% of readmissions, followed by arrhythmias, responsible for 8% of readmissions, said Dr. Kilic, a thoracic surgeon at the University of Pennsylvania in Philadelphia.

Mitchel L. Zoler/Frontline Medical News

Because fluid overload, often in the form of pleural effusion, is such an important driver of rehospitalizations, a more targeted management program would include better titration of diuretic treatment to patients following heart surgery, thoracentesis, and closer monitoring of clinical features that flag fluid overload such as weight.

“The volume overload issue is where the money is. If we can reduce that, it could really impact readmissions,” Dr. Kilic said in an interview.

An investigational program to target rehospitalization risk in heart surgery patients is planned at Johns Hopkins Hospital in Baltimore, where Dr. Kilic worked when he performed this analysis. Surgeons at Johns Hopkins are now in the process of getting funding for this pilot program, said Dr. John V. Conte Jr., professor of surgery and director of mechanical circulatory support at Johns Hopkins and a collaborator with Dr. Kilic on developing the risk formula.

“We’ll tailor postoperative follow-up. We’ll get high-risk patients back to the clinic sooner, and we’ll send nurse practitioners to see them to make sure they’re taking their medications and are getting weighed daily,” Dr. Conte said in an interview. “When a patient has heart surgery, they typically retain about 5-10 pounds of fluid. Patients with good renal function give up that fluid easily, but others are difficult to diurese. Many patients go home before they have been fully diuresed, and we need to follow these patients and transition them better to out-of-hospital care.”

He noted that other situations also come up that unnecessarily drive patients back to the hospital when an alternative and less expensive intervention might be equally effective. For example, some patients return to the hospital out of concern for how their chest wound is healing. Instead of being rehospitalized, such patients could be reassured by having them send a nurse a photo of their wound or by coming to an outpatient clinic.

“We need to engage more often with recently discharged patients,” Dr. Conte said in an interview. “Discharging them doesn’t mean separating them from the health care system; it should mean interacting with patients in a different way” that produces better outcomes and patient satisfaction for less money. Developing improved ways to manage recent heart surgery patients following discharge becomes even more critical later this year when, in July, the Centers for Medicare & Medicaid Services adds 30-day readmissions following coronary artery bypass grafting (CABG) to its list of procedures that can generate a penalty to hospitals if they exceed U.S. norms for readmission rates.

The risk model developed by Dr. Kilic, Dr. Conte, and their associates used data collected from 5,360 heart surgery patients treated at Johns Hopkins during 2008-2013. Nearly half the patients underwent isolated CABG, and 20% had isolated valve surgery. Overall, 585 patients (11%) had a hospital readmission within 30 days of their index discharge. One limitation of the analysis was it used data only on readmissions back to Johns Hopkins Hospital.

The researchers used data from three-quarters of the database to derive the risk formula, and from the remaining 25% of the database to validate the formula. A multivariate analysis of demographic and clinical characteristics that significantly linked with an elevated risk for readmissions identified five factors that independently made a significant contribution to readmission risk. The researchers assigned each of these five factors points depending on its relative contribution to readmission risk in the adjusted model: Severe chronic lung disease received 6 points; placement of a ventricular assist device received 5 points, while other types of heart surgery that was not CABG or valve surgery received 4 points (isolated CABG, isolated valve, or combined CABG and valve surgery received 0 points); development of acute renal failure postoperatively but before index discharge received 4 points; an index length of stay beyond 7 days received 4 points; and African American race received 3 points. The maximum number of points a patient could receive was 22.

Patients with a score of 0 had a 6% rate of a 30-day readmission; those with a score of 22 had a 63% readmission rate. For simplicity, Dr. Kilic suggested dividing patients into three categories based on their readmission risk score: Low-risk patients with a score of 0 had a readmission risk of 6%, medium-risk patients with a score of 1-10 had a readmission risk of 12%, and high-risk patients with a score of 11 or more had a readmission risk of 31%. The researchers found a 96% correlation when comparing these predicted readmission risk rates based on the derivation-subgroup analysis with the actual readmission rates seen in the validation subgroup of their database. The targeted risk-management program planned by Dr. Conte would primarily focus on high-risk patients.

Dr. Kilic and Dr. Conte said they had no relevant financial disclosures.

mzoler@frontlinemedcom.com

On Twitter@mitchelzoler

PHOENIX – A simple, five-element formula can help identify the patients undergoing heart surgery who face the greatest risk for a hospital readmission within 30 days following discharge from their index hospitalization.

The surgeons who developed this formula hope to use it in an investigational program that will target intensified management resources in postsurgical patients who face the highest readmission risk, to cut rehospitalizations and better improve their clinical status and quality of life.

The analysis that produced this formula also documented that the worst offender for triggering rehospitalizations following heart surgery is fluid overload, the proximate readmission cause for 23% of postsurgical patients, Dr. Arman Kilic said at the annual meeting of the Society of Thoracic Surgeons. The next most common cause was infection, which led to 20% of readmissions, followed by arrhythmias, responsible for 8% of readmissions, said Dr. Kilic, a thoracic surgeon at the University of Pennsylvania in Philadelphia.

Mitchel L. Zoler/Frontline Medical News

Because fluid overload, often in the form of pleural effusion, is such an important driver of rehospitalizations, a more targeted management program would include better titration of diuretic treatment to patients following heart surgery, thoracentesis, and closer monitoring of clinical features that flag fluid overload such as weight.

“The volume overload issue is where the money is. If we can reduce that, it could really impact readmissions,” Dr. Kilic said in an interview.

An investigational program to target rehospitalization risk in heart surgery patients is planned at Johns Hopkins Hospital in Baltimore, where Dr. Kilic worked when he performed this analysis. Surgeons at Johns Hopkins are now in the process of getting funding for this pilot program, said Dr. John V. Conte Jr., professor of surgery and director of mechanical circulatory support at Johns Hopkins and a collaborator with Dr. Kilic on developing the risk formula.

“We’ll tailor postoperative follow-up. We’ll get high-risk patients back to the clinic sooner, and we’ll send nurse practitioners to see them to make sure they’re taking their medications and are getting weighed daily,” Dr. Conte said in an interview. “When a patient has heart surgery, they typically retain about 5-10 pounds of fluid. Patients with good renal function give up that fluid easily, but others are difficult to diurese. Many patients go home before they have been fully diuresed, and we need to follow these patients and transition them better to out-of-hospital care.”

He noted that other situations also come up that unnecessarily drive patients back to the hospital when an alternative and less expensive intervention might be equally effective. For example, some patients return to the hospital out of concern for how their chest wound is healing. Instead of being rehospitalized, such patients could be reassured by having them send a nurse a photo of their wound or by coming to an outpatient clinic.

“We need to engage more often with recently discharged patients,” Dr. Conte said in an interview. “Discharging them doesn’t mean separating them from the health care system; it should mean interacting with patients in a different way” that produces better outcomes and patient satisfaction for less money. Developing improved ways to manage recent heart surgery patients following discharge becomes even more critical later this year when, in July, the Centers for Medicare & Medicaid Services adds 30-day readmissions following coronary artery bypass grafting (CABG) to its list of procedures that can generate a penalty to hospitals if they exceed U.S. norms for readmission rates.

The risk model developed by Dr. Kilic, Dr. Conte, and their associates used data collected from 5,360 heart surgery patients treated at Johns Hopkins during 2008-2013. Nearly half the patients underwent isolated CABG, and 20% had isolated valve surgery. Overall, 585 patients (11%) had a hospital readmission within 30 days of their index discharge. One limitation of the analysis was it used data only on readmissions back to Johns Hopkins Hospital.

The researchers used data from three-quarters of the database to derive the risk formula, and from the remaining 25% of the database to validate the formula. A multivariate analysis of demographic and clinical characteristics that significantly linked with an elevated risk for readmissions identified five factors that independently made a significant contribution to readmission risk. The researchers assigned each of these five factors points depending on its relative contribution to readmission risk in the adjusted model: Severe chronic lung disease received 6 points; placement of a ventricular assist device received 5 points, while other types of heart surgery that was not CABG or valve surgery received 4 points (isolated CABG, isolated valve, or combined CABG and valve surgery received 0 points); development of acute renal failure postoperatively but before index discharge received 4 points; an index length of stay beyond 7 days received 4 points; and African American race received 3 points. The maximum number of points a patient could receive was 22.

Patients with a score of 0 had a 6% rate of a 30-day readmission; those with a score of 22 had a 63% readmission rate. For simplicity, Dr. Kilic suggested dividing patients into three categories based on their readmission risk score: Low-risk patients with a score of 0 had a readmission risk of 6%, medium-risk patients with a score of 1-10 had a readmission risk of 12%, and high-risk patients with a score of 11 or more had a readmission risk of 31%. The researchers found a 96% correlation when comparing these predicted readmission risk rates based on the derivation-subgroup analysis with the actual readmission rates seen in the validation subgroup of their database. The targeted risk-management program planned by Dr. Conte would primarily focus on high-risk patients.

Dr. Kilic and Dr. Conte said they had no relevant financial disclosures.

mzoler@frontlinemedcom.com

On Twitter@mitchelzoler