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HM18: Tick-borne illnesses
Presenter
Andrew J. Hale, MD
University of Vermont Medical Center, Burlington
Session summary
With rising temperatures from climate change, tick territory – and therefore tick-borne illnesses – are being seen with increasing frequency.
Lyme disease manifests as early-localized, early-disseminated, and late disease. The diagnosis of Lyme can be challenging and the pretest probability is key (geographic distribution, time of year, consistent symptoms). Do not send serologies unless the pretest probability is high, since the sensitivity of the test is generally low.
Concerning early-localized disease, 20% of patients will not develop the classic “bullseye” erythema migrans rash. Only 25% of patients recall even getting a tick bite. Not everyone with a rash will have a classic appearance (prepare for heterogeneity).
Neurologic symptoms can appear early or late in Lyme disease (usually weeks to months, but sometimes in days). The manifestations can include lymphocytic meningitis (which can be hard to separate from viral meningitis), radiculopathies, and cranial nerve palsies.
Lyme carditis happens early in the disseminated phase with a variety of disease (palpitations, conduction abnormalities, pericarditis, myocarditis, left ventricular failure). For those who develop a high-grade atrioventricular block, a temporary pacer may be needed; a permanent pacemaker is unnecessary because patients often do well with a course of antibiotics.
Late Lyme develops months to years after infection. It often presents as arthritis of the knee, although other large joints such as the shoulders, ankles, and elbows can also be affected. Chronic neurologic effects such as peripheral neuropathy and encephalitis can also occur.
Treatment depends on how the disease manifests. If one has arthritis or mild carditis, 28 days of doxycycline is appropriate; for neurologic disease or “bad” carditis, give ceftriaxone for 28 days; for everything else, 14-21 days of doxycycline. Amoxicillin can be used for patients who cannot tolerate doxycycline.
Borrelia miyamotoi and B. mayonii are emerging infections. Compared with Lyme, B. miyamotoi will present with more joint pain and less rash. B. mayonii has a more diffuse rash, but is otherwise similar to Lyme. Serologies for Lyme for both will be negative, but they are treated the same as Lyme disease.
Anaplasma presents as a flu-like illness and can be difficult to distinguish from Lyme. Ehrlichia is similar, but has more headache and CNS findings. Diagnosis during the first week is best with a blood smear (looking for morulae) and polymerase chain reaction; in week 2, serology is a bit better; after 3 weeks, serologies are very sensitive. Treatment for both is doxycycline for 7-14 days. Rifampin is second-line treatment, but does not treat Lyme (both can happen simultaneously).
Babesia is found in the same distribution as Lyme disease. Incubation is 1-12 weeks. Mild disease consists of parasitemia of less than 4% while severe disease is greater than 4%. Being asplenic, having HIV, receiving tumor necrosis factor alpha blockers or rituximab increases risk for severe disease. A blood smear is sufficient to diagnose Babesia, but polymerase chain reaction is also available. Treatment is atovaquone and azithromycin for 7 days for mild disease; clindamycin and quinine for 7-10 days for severe. Exchange transfusion can also be done especially for those with high parasitemia or severe symptoms.
Powassan virus is seen in the northeastern United States and the Minnesota/Wisconsin region. It has a fatality rate of 10%. About 50% of patients have long-term neurologic sequelae. Heartland virus has symptoms similar to other tick-borne illnesses, but can be associated with nausea, headache, diarrhea, myalgias, arthralgias, and renal failure. Bourbon virus also behaves like most tick-borne illnesses, but patients can develop a rapid sepsis picture.
Key takeaways for HM
- Lyme disease can be seen in inpatient settings with cardiac, neurologic, and musculoskeletal manifestations.
- Several emerging tick-borne infections (tularemia, STARI [southern tick-associated rash illness]), relapsing fever (B. hermsii), B. miyamotoi, and B. mayonii should also be on clinicians’ radar.
- Ticks can also spread viruses that can have particularly deadly consequences such as Powassan, Heartland, and Bourbon.
- Climate change is good for ticks, but bad for humans.
Dr. Kim is assistant professor of medicine in the division of hospital medicine at Emory University, Atlanta.
Presenter
Andrew J. Hale, MD
University of Vermont Medical Center, Burlington
Session summary
With rising temperatures from climate change, tick territory – and therefore tick-borne illnesses – are being seen with increasing frequency.
Lyme disease manifests as early-localized, early-disseminated, and late disease. The diagnosis of Lyme can be challenging and the pretest probability is key (geographic distribution, time of year, consistent symptoms). Do not send serologies unless the pretest probability is high, since the sensitivity of the test is generally low.
Concerning early-localized disease, 20% of patients will not develop the classic “bullseye” erythema migrans rash. Only 25% of patients recall even getting a tick bite. Not everyone with a rash will have a classic appearance (prepare for heterogeneity).
Neurologic symptoms can appear early or late in Lyme disease (usually weeks to months, but sometimes in days). The manifestations can include lymphocytic meningitis (which can be hard to separate from viral meningitis), radiculopathies, and cranial nerve palsies.
Lyme carditis happens early in the disseminated phase with a variety of disease (palpitations, conduction abnormalities, pericarditis, myocarditis, left ventricular failure). For those who develop a high-grade atrioventricular block, a temporary pacer may be needed; a permanent pacemaker is unnecessary because patients often do well with a course of antibiotics.
Late Lyme develops months to years after infection. It often presents as arthritis of the knee, although other large joints such as the shoulders, ankles, and elbows can also be affected. Chronic neurologic effects such as peripheral neuropathy and encephalitis can also occur.
Treatment depends on how the disease manifests. If one has arthritis or mild carditis, 28 days of doxycycline is appropriate; for neurologic disease or “bad” carditis, give ceftriaxone for 28 days; for everything else, 14-21 days of doxycycline. Amoxicillin can be used for patients who cannot tolerate doxycycline.
Borrelia miyamotoi and B. mayonii are emerging infections. Compared with Lyme, B. miyamotoi will present with more joint pain and less rash. B. mayonii has a more diffuse rash, but is otherwise similar to Lyme. Serologies for Lyme for both will be negative, but they are treated the same as Lyme disease.
Anaplasma presents as a flu-like illness and can be difficult to distinguish from Lyme. Ehrlichia is similar, but has more headache and CNS findings. Diagnosis during the first week is best with a blood smear (looking for morulae) and polymerase chain reaction; in week 2, serology is a bit better; after 3 weeks, serologies are very sensitive. Treatment for both is doxycycline for 7-14 days. Rifampin is second-line treatment, but does not treat Lyme (both can happen simultaneously).
Babesia is found in the same distribution as Lyme disease. Incubation is 1-12 weeks. Mild disease consists of parasitemia of less than 4% while severe disease is greater than 4%. Being asplenic, having HIV, receiving tumor necrosis factor alpha blockers or rituximab increases risk for severe disease. A blood smear is sufficient to diagnose Babesia, but polymerase chain reaction is also available. Treatment is atovaquone and azithromycin for 7 days for mild disease; clindamycin and quinine for 7-10 days for severe. Exchange transfusion can also be done especially for those with high parasitemia or severe symptoms.
Powassan virus is seen in the northeastern United States and the Minnesota/Wisconsin region. It has a fatality rate of 10%. About 50% of patients have long-term neurologic sequelae. Heartland virus has symptoms similar to other tick-borne illnesses, but can be associated with nausea, headache, diarrhea, myalgias, arthralgias, and renal failure. Bourbon virus also behaves like most tick-borne illnesses, but patients can develop a rapid sepsis picture.
Key takeaways for HM
- Lyme disease can be seen in inpatient settings with cardiac, neurologic, and musculoskeletal manifestations.
- Several emerging tick-borne infections (tularemia, STARI [southern tick-associated rash illness]), relapsing fever (B. hermsii), B. miyamotoi, and B. mayonii should also be on clinicians’ radar.
- Ticks can also spread viruses that can have particularly deadly consequences such as Powassan, Heartland, and Bourbon.
- Climate change is good for ticks, but bad for humans.
Dr. Kim is assistant professor of medicine in the division of hospital medicine at Emory University, Atlanta.
Presenter
Andrew J. Hale, MD
University of Vermont Medical Center, Burlington
Session summary
With rising temperatures from climate change, tick territory – and therefore tick-borne illnesses – are being seen with increasing frequency.
Lyme disease manifests as early-localized, early-disseminated, and late disease. The diagnosis of Lyme can be challenging and the pretest probability is key (geographic distribution, time of year, consistent symptoms). Do not send serologies unless the pretest probability is high, since the sensitivity of the test is generally low.
Concerning early-localized disease, 20% of patients will not develop the classic “bullseye” erythema migrans rash. Only 25% of patients recall even getting a tick bite. Not everyone with a rash will have a classic appearance (prepare for heterogeneity).
Neurologic symptoms can appear early or late in Lyme disease (usually weeks to months, but sometimes in days). The manifestations can include lymphocytic meningitis (which can be hard to separate from viral meningitis), radiculopathies, and cranial nerve palsies.
Lyme carditis happens early in the disseminated phase with a variety of disease (palpitations, conduction abnormalities, pericarditis, myocarditis, left ventricular failure). For those who develop a high-grade atrioventricular block, a temporary pacer may be needed; a permanent pacemaker is unnecessary because patients often do well with a course of antibiotics.
Late Lyme develops months to years after infection. It often presents as arthritis of the knee, although other large joints such as the shoulders, ankles, and elbows can also be affected. Chronic neurologic effects such as peripheral neuropathy and encephalitis can also occur.
Treatment depends on how the disease manifests. If one has arthritis or mild carditis, 28 days of doxycycline is appropriate; for neurologic disease or “bad” carditis, give ceftriaxone for 28 days; for everything else, 14-21 days of doxycycline. Amoxicillin can be used for patients who cannot tolerate doxycycline.
Borrelia miyamotoi and B. mayonii are emerging infections. Compared with Lyme, B. miyamotoi will present with more joint pain and less rash. B. mayonii has a more diffuse rash, but is otherwise similar to Lyme. Serologies for Lyme for both will be negative, but they are treated the same as Lyme disease.
Anaplasma presents as a flu-like illness and can be difficult to distinguish from Lyme. Ehrlichia is similar, but has more headache and CNS findings. Diagnosis during the first week is best with a blood smear (looking for morulae) and polymerase chain reaction; in week 2, serology is a bit better; after 3 weeks, serologies are very sensitive. Treatment for both is doxycycline for 7-14 days. Rifampin is second-line treatment, but does not treat Lyme (both can happen simultaneously).
Babesia is found in the same distribution as Lyme disease. Incubation is 1-12 weeks. Mild disease consists of parasitemia of less than 4% while severe disease is greater than 4%. Being asplenic, having HIV, receiving tumor necrosis factor alpha blockers or rituximab increases risk for severe disease. A blood smear is sufficient to diagnose Babesia, but polymerase chain reaction is also available. Treatment is atovaquone and azithromycin for 7 days for mild disease; clindamycin and quinine for 7-10 days for severe. Exchange transfusion can also be done especially for those with high parasitemia or severe symptoms.
Powassan virus is seen in the northeastern United States and the Minnesota/Wisconsin region. It has a fatality rate of 10%. About 50% of patients have long-term neurologic sequelae. Heartland virus has symptoms similar to other tick-borne illnesses, but can be associated with nausea, headache, diarrhea, myalgias, arthralgias, and renal failure. Bourbon virus also behaves like most tick-borne illnesses, but patients can develop a rapid sepsis picture.
Key takeaways for HM
- Lyme disease can be seen in inpatient settings with cardiac, neurologic, and musculoskeletal manifestations.
- Several emerging tick-borne infections (tularemia, STARI [southern tick-associated rash illness]), relapsing fever (B. hermsii), B. miyamotoi, and B. mayonii should also be on clinicians’ radar.
- Ticks can also spread viruses that can have particularly deadly consequences such as Powassan, Heartland, and Bourbon.
- Climate change is good for ticks, but bad for humans.
Dr. Kim is assistant professor of medicine in the division of hospital medicine at Emory University, Atlanta.
Sound and light levels are similarly disruptive in ICU and non-ICU wards
Clinical question: While it is generally thought that ICU wards are not conducive for sleep because of light and noise disruptions, are general wards any better?
Background: Hospitalized patients frequently report poor sleep, partly because of the inpatient environment. Sound level changes (SLCs), rather than the total volumes, are important in disrupting sleep. The World Health Organization recommends that nighttime baseline noise levels do not exceed 30 decibels (dB) and that nighttime noise peaks (i.e., loud noises) do not exceed 40 dB. The circadian rhythm system depends on ambient light to regulate the internal clock. Insufficient and inappropriately timed light exposure can desynchronize the biological clock, thereby negatively affecting sleep quality.
Setting: Tertiary care hospital in La Jolla, Calif.
Synopsis: For approximately 24-72 hours, recordings of sound and light were performed. ICU rooms were louder (hourly averages ranged from 56.1 dB to 60.3 dB) than were non-ICU wards (44.6-55.1 dB). However, SLCs of 17.5 dB or greater were not statistically different (ICU, 203.9 ± 28.8 times; non-ICU, 270.9 ± 39.5; P = .11). In both ICU and non-ICU wards, average daytime light levels were less than 250 lux and generally were brightest in the afternoon. This corresponds to low, office-level lighting, which may not be conducive for maintaining circadian rhythm.
Bottom line: While ICU wards are generally louder than non-ICU wards, sound level changes are equivalent and probably more important concerning sleep disruption. While no significant differences were seen in light levels, the amount and timing of lighting may not be optimal for keeping circadian rhythm.
Citation: Jaiswal SJ et al. Sound and light levels are similarly disruptive in ICU and non-ICU wards. J Hosp Med. 2017 Oct;12(10):798-804.
Dr. Kim is assistant professor of medicine in the division of hospital medicine, Emory University, Atlanta.
Clinical question: While it is generally thought that ICU wards are not conducive for sleep because of light and noise disruptions, are general wards any better?
Background: Hospitalized patients frequently report poor sleep, partly because of the inpatient environment. Sound level changes (SLCs), rather than the total volumes, are important in disrupting sleep. The World Health Organization recommends that nighttime baseline noise levels do not exceed 30 decibels (dB) and that nighttime noise peaks (i.e., loud noises) do not exceed 40 dB. The circadian rhythm system depends on ambient light to regulate the internal clock. Insufficient and inappropriately timed light exposure can desynchronize the biological clock, thereby negatively affecting sleep quality.
Setting: Tertiary care hospital in La Jolla, Calif.
Synopsis: For approximately 24-72 hours, recordings of sound and light were performed. ICU rooms were louder (hourly averages ranged from 56.1 dB to 60.3 dB) than were non-ICU wards (44.6-55.1 dB). However, SLCs of 17.5 dB or greater were not statistically different (ICU, 203.9 ± 28.8 times; non-ICU, 270.9 ± 39.5; P = .11). In both ICU and non-ICU wards, average daytime light levels were less than 250 lux and generally were brightest in the afternoon. This corresponds to low, office-level lighting, which may not be conducive for maintaining circadian rhythm.
Bottom line: While ICU wards are generally louder than non-ICU wards, sound level changes are equivalent and probably more important concerning sleep disruption. While no significant differences were seen in light levels, the amount and timing of lighting may not be optimal for keeping circadian rhythm.
Citation: Jaiswal SJ et al. Sound and light levels are similarly disruptive in ICU and non-ICU wards. J Hosp Med. 2017 Oct;12(10):798-804.
Dr. Kim is assistant professor of medicine in the division of hospital medicine, Emory University, Atlanta.
Clinical question: While it is generally thought that ICU wards are not conducive for sleep because of light and noise disruptions, are general wards any better?
Background: Hospitalized patients frequently report poor sleep, partly because of the inpatient environment. Sound level changes (SLCs), rather than the total volumes, are important in disrupting sleep. The World Health Organization recommends that nighttime baseline noise levels do not exceed 30 decibels (dB) and that nighttime noise peaks (i.e., loud noises) do not exceed 40 dB. The circadian rhythm system depends on ambient light to regulate the internal clock. Insufficient and inappropriately timed light exposure can desynchronize the biological clock, thereby negatively affecting sleep quality.
Setting: Tertiary care hospital in La Jolla, Calif.
Synopsis: For approximately 24-72 hours, recordings of sound and light were performed. ICU rooms were louder (hourly averages ranged from 56.1 dB to 60.3 dB) than were non-ICU wards (44.6-55.1 dB). However, SLCs of 17.5 dB or greater were not statistically different (ICU, 203.9 ± 28.8 times; non-ICU, 270.9 ± 39.5; P = .11). In both ICU and non-ICU wards, average daytime light levels were less than 250 lux and generally were brightest in the afternoon. This corresponds to low, office-level lighting, which may not be conducive for maintaining circadian rhythm.
Bottom line: While ICU wards are generally louder than non-ICU wards, sound level changes are equivalent and probably more important concerning sleep disruption. While no significant differences were seen in light levels, the amount and timing of lighting may not be optimal for keeping circadian rhythm.
Citation: Jaiswal SJ et al. Sound and light levels are similarly disruptive in ICU and non-ICU wards. J Hosp Med. 2017 Oct;12(10):798-804.
Dr. Kim is assistant professor of medicine in the division of hospital medicine, Emory University, Atlanta.