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Higher stroke rates seen among patients with COVID-19 compared with influenza
, according to a retrospective cohort study conducted at New York–Presbyterian Hospital and Weill Cornell Medicine, New York. “These findings suggest that clinicians should be vigilant for symptoms and signs of acute ischemic stroke in patients with COVID-19 so that time-sensitive interventions, such as thrombolysis and thrombectomy, can be instituted if possible to reduce the burden of long-term disability,” wrote Alexander E. Merkler and colleagues. Their report is in JAMA Neurology.
While several recent publications have “raised the possibility” of this link, none have had an appropriate control group, noted Dr. Merkler of the department of neurology, Weill Cornell Medicine. “Further elucidation of thrombotic mechanisms in patients with COVID-19 may yield better strategies to prevent disabling thrombotic complications like ischemic stroke,” he added.
An increased risk of stroke
The study included 1,916 adults with confirmed COVID-19 (median age 64 years) who were either hospitalized or visited an emergency department between March 4 and May 2, 2020. These cases were compared with a historical cohort of 1,486 patients (median age 62 years) who were hospitalized with laboratory-confirmed influenza A or B between January 1, 2016, and May 31, 2018.
Among the patients with COVID-19, a diagnosis of cerebrovascular disease during hospitalization, a brain computed tomography (CT), or brain magnetic resonance imaging (MRI) was an indication of possible ischemic stroke. These records were then independently reviewed by two board-certified attending neurologists (with a third resolving any disagreement) to adjudicate a final stroke diagnosis. In the influenza cohort, the Cornell Acute Stroke Academic Registry (CAESAR) was used to ascertain ischemic strokes.
The study identified 31 patients with stroke among the COVID-19 cohort (1.6%; 95% confidence interval, 1.1%-2.3%) and 3 in the influenza cohort (0.2%; 95% CI, 0.0%-0.6%). After adjustment for age, sex, and race, stroke risk was almost 8 times higher in the COVID-19 cohort (OR, 7.6; 95% CI, 2.3-25.2).
This association “persisted across multiple sensitivity analyses, with the magnitude of relative associations ranging from 4.0 to 9,” wrote the authors. “This included a sensitivity analysis that adjusted for the number of vascular risk factors and ICU admissions (OR, 4.6; 95% CI, 1.4-15.7).”
The median age of patients with COVID-19 and stroke was 69 years, and the median duration of COVID-19 symptom onset to stroke diagnosis was 16 days. Stroke symptoms were the presenting complaint in only 26% of the patients, while the remainder developing stroke while hospitalized, and more than a third (35%) of all strokes occurred in patients who were mechanically ventilated with severe COVID-19. Inpatient mortality was considerably higher among patients with COVID-19 with stroke versus without (32% vs. 14%; P = .003).
In patients with COVID-19 “most ischemic strokes occurred in older age groups, those with traditional stroke risk factors, and people of color,” wrote the authors. “We also noted that initial plasma D-dimer levels were nearly 3-fold higher in those who received a diagnosis of ischemic stroke than in those who did not” (1.930 mcg/mL vs. 0.682 mcg/mL).
The authors suggested several possible explanations for the elevated risk of stroke in COVID-19. Acute viral illnesses are known to trigger inflammation, and COVID-19 in particular is associated with “a vigorous inflammatory response accompanied by coagulopathy, with elevated D-dimer levels and the frequent presence of antiphospholipid antibodies,” they wrote. The infection is also associated with more severe respiratory syndrome compared with influenza, as well as a heightened risk for complications such as atrial arrhythmias, myocardial infarction, heart failure, myocarditis, and venous thromboses, all of which likely contribute to the risk of ischemic stroke.”
COVID or conventional risk factors?
Asked to comment on the study, Benedict Michael, MBChB (Hons), MRCP (Neurol), PhD, from the United Kingdom’s Coronerve Studies Group, a collaborative initiative to study the neurological features of COVID-19, said in an interview that “this study suggests many cases of stroke are occurring in older patients with multiple existing conventional and well recognized risks for stroke, and may simply represent decompensation during sepsis.”
Dr. Michael, a senior clinician scientist fellow at the University of Liverpool and an honorary consultant neurologist at the Walton Centre, was the senior author on a recently published UK-wide surveillance study on the neurological and neuropsychiatric complications of COVID-19 (Lancet Psychiatry. 2020 Jun 25. doi: 10.1016/S2215-0366[20]30287-X).
He said among patients in the New York study, “those with COVID and a stroke appeared to have many conventional risk factors for stroke (and often at higher percentages than COVID patients without a stroke), e.g. hypertension, overweight, diabetes, hyperlipidemia, existing vascular disease affecting the coronary arteries and atrial fibrillation. To establish evidence-based treatment pathways, clearly further studies are needed to determine the biological mechanisms underlying the seemingly higher rate of stroke with COVID-19 than influenza; but this must especially focus on those younger patients without conventional risk factors for stroke (which are largely not included in this study).”
SOURCE: Merkler AE et al. JAMA Neurol. doi: 10.1001/jamaneurol.2020.2730.
, according to a retrospective cohort study conducted at New York–Presbyterian Hospital and Weill Cornell Medicine, New York. “These findings suggest that clinicians should be vigilant for symptoms and signs of acute ischemic stroke in patients with COVID-19 so that time-sensitive interventions, such as thrombolysis and thrombectomy, can be instituted if possible to reduce the burden of long-term disability,” wrote Alexander E. Merkler and colleagues. Their report is in JAMA Neurology.
While several recent publications have “raised the possibility” of this link, none have had an appropriate control group, noted Dr. Merkler of the department of neurology, Weill Cornell Medicine. “Further elucidation of thrombotic mechanisms in patients with COVID-19 may yield better strategies to prevent disabling thrombotic complications like ischemic stroke,” he added.
An increased risk of stroke
The study included 1,916 adults with confirmed COVID-19 (median age 64 years) who were either hospitalized or visited an emergency department between March 4 and May 2, 2020. These cases were compared with a historical cohort of 1,486 patients (median age 62 years) who were hospitalized with laboratory-confirmed influenza A or B between January 1, 2016, and May 31, 2018.
Among the patients with COVID-19, a diagnosis of cerebrovascular disease during hospitalization, a brain computed tomography (CT), or brain magnetic resonance imaging (MRI) was an indication of possible ischemic stroke. These records were then independently reviewed by two board-certified attending neurologists (with a third resolving any disagreement) to adjudicate a final stroke diagnosis. In the influenza cohort, the Cornell Acute Stroke Academic Registry (CAESAR) was used to ascertain ischemic strokes.
The study identified 31 patients with stroke among the COVID-19 cohort (1.6%; 95% confidence interval, 1.1%-2.3%) and 3 in the influenza cohort (0.2%; 95% CI, 0.0%-0.6%). After adjustment for age, sex, and race, stroke risk was almost 8 times higher in the COVID-19 cohort (OR, 7.6; 95% CI, 2.3-25.2).
This association “persisted across multiple sensitivity analyses, with the magnitude of relative associations ranging from 4.0 to 9,” wrote the authors. “This included a sensitivity analysis that adjusted for the number of vascular risk factors and ICU admissions (OR, 4.6; 95% CI, 1.4-15.7).”
The median age of patients with COVID-19 and stroke was 69 years, and the median duration of COVID-19 symptom onset to stroke diagnosis was 16 days. Stroke symptoms were the presenting complaint in only 26% of the patients, while the remainder developing stroke while hospitalized, and more than a third (35%) of all strokes occurred in patients who were mechanically ventilated with severe COVID-19. Inpatient mortality was considerably higher among patients with COVID-19 with stroke versus without (32% vs. 14%; P = .003).
In patients with COVID-19 “most ischemic strokes occurred in older age groups, those with traditional stroke risk factors, and people of color,” wrote the authors. “We also noted that initial plasma D-dimer levels were nearly 3-fold higher in those who received a diagnosis of ischemic stroke than in those who did not” (1.930 mcg/mL vs. 0.682 mcg/mL).
The authors suggested several possible explanations for the elevated risk of stroke in COVID-19. Acute viral illnesses are known to trigger inflammation, and COVID-19 in particular is associated with “a vigorous inflammatory response accompanied by coagulopathy, with elevated D-dimer levels and the frequent presence of antiphospholipid antibodies,” they wrote. The infection is also associated with more severe respiratory syndrome compared with influenza, as well as a heightened risk for complications such as atrial arrhythmias, myocardial infarction, heart failure, myocarditis, and venous thromboses, all of which likely contribute to the risk of ischemic stroke.”
COVID or conventional risk factors?
Asked to comment on the study, Benedict Michael, MBChB (Hons), MRCP (Neurol), PhD, from the United Kingdom’s Coronerve Studies Group, a collaborative initiative to study the neurological features of COVID-19, said in an interview that “this study suggests many cases of stroke are occurring in older patients with multiple existing conventional and well recognized risks for stroke, and may simply represent decompensation during sepsis.”
Dr. Michael, a senior clinician scientist fellow at the University of Liverpool and an honorary consultant neurologist at the Walton Centre, was the senior author on a recently published UK-wide surveillance study on the neurological and neuropsychiatric complications of COVID-19 (Lancet Psychiatry. 2020 Jun 25. doi: 10.1016/S2215-0366[20]30287-X).
He said among patients in the New York study, “those with COVID and a stroke appeared to have many conventional risk factors for stroke (and often at higher percentages than COVID patients without a stroke), e.g. hypertension, overweight, diabetes, hyperlipidemia, existing vascular disease affecting the coronary arteries and atrial fibrillation. To establish evidence-based treatment pathways, clearly further studies are needed to determine the biological mechanisms underlying the seemingly higher rate of stroke with COVID-19 than influenza; but this must especially focus on those younger patients without conventional risk factors for stroke (which are largely not included in this study).”
SOURCE: Merkler AE et al. JAMA Neurol. doi: 10.1001/jamaneurol.2020.2730.
, according to a retrospective cohort study conducted at New York–Presbyterian Hospital and Weill Cornell Medicine, New York. “These findings suggest that clinicians should be vigilant for symptoms and signs of acute ischemic stroke in patients with COVID-19 so that time-sensitive interventions, such as thrombolysis and thrombectomy, can be instituted if possible to reduce the burden of long-term disability,” wrote Alexander E. Merkler and colleagues. Their report is in JAMA Neurology.
While several recent publications have “raised the possibility” of this link, none have had an appropriate control group, noted Dr. Merkler of the department of neurology, Weill Cornell Medicine. “Further elucidation of thrombotic mechanisms in patients with COVID-19 may yield better strategies to prevent disabling thrombotic complications like ischemic stroke,” he added.
An increased risk of stroke
The study included 1,916 adults with confirmed COVID-19 (median age 64 years) who were either hospitalized or visited an emergency department between March 4 and May 2, 2020. These cases were compared with a historical cohort of 1,486 patients (median age 62 years) who were hospitalized with laboratory-confirmed influenza A or B between January 1, 2016, and May 31, 2018.
Among the patients with COVID-19, a diagnosis of cerebrovascular disease during hospitalization, a brain computed tomography (CT), or brain magnetic resonance imaging (MRI) was an indication of possible ischemic stroke. These records were then independently reviewed by two board-certified attending neurologists (with a third resolving any disagreement) to adjudicate a final stroke diagnosis. In the influenza cohort, the Cornell Acute Stroke Academic Registry (CAESAR) was used to ascertain ischemic strokes.
The study identified 31 patients with stroke among the COVID-19 cohort (1.6%; 95% confidence interval, 1.1%-2.3%) and 3 in the influenza cohort (0.2%; 95% CI, 0.0%-0.6%). After adjustment for age, sex, and race, stroke risk was almost 8 times higher in the COVID-19 cohort (OR, 7.6; 95% CI, 2.3-25.2).
This association “persisted across multiple sensitivity analyses, with the magnitude of relative associations ranging from 4.0 to 9,” wrote the authors. “This included a sensitivity analysis that adjusted for the number of vascular risk factors and ICU admissions (OR, 4.6; 95% CI, 1.4-15.7).”
The median age of patients with COVID-19 and stroke was 69 years, and the median duration of COVID-19 symptom onset to stroke diagnosis was 16 days. Stroke symptoms were the presenting complaint in only 26% of the patients, while the remainder developing stroke while hospitalized, and more than a third (35%) of all strokes occurred in patients who were mechanically ventilated with severe COVID-19. Inpatient mortality was considerably higher among patients with COVID-19 with stroke versus without (32% vs. 14%; P = .003).
In patients with COVID-19 “most ischemic strokes occurred in older age groups, those with traditional stroke risk factors, and people of color,” wrote the authors. “We also noted that initial plasma D-dimer levels were nearly 3-fold higher in those who received a diagnosis of ischemic stroke than in those who did not” (1.930 mcg/mL vs. 0.682 mcg/mL).
The authors suggested several possible explanations for the elevated risk of stroke in COVID-19. Acute viral illnesses are known to trigger inflammation, and COVID-19 in particular is associated with “a vigorous inflammatory response accompanied by coagulopathy, with elevated D-dimer levels and the frequent presence of antiphospholipid antibodies,” they wrote. The infection is also associated with more severe respiratory syndrome compared with influenza, as well as a heightened risk for complications such as atrial arrhythmias, myocardial infarction, heart failure, myocarditis, and venous thromboses, all of which likely contribute to the risk of ischemic stroke.”
COVID or conventional risk factors?
Asked to comment on the study, Benedict Michael, MBChB (Hons), MRCP (Neurol), PhD, from the United Kingdom’s Coronerve Studies Group, a collaborative initiative to study the neurological features of COVID-19, said in an interview that “this study suggests many cases of stroke are occurring in older patients with multiple existing conventional and well recognized risks for stroke, and may simply represent decompensation during sepsis.”
Dr. Michael, a senior clinician scientist fellow at the University of Liverpool and an honorary consultant neurologist at the Walton Centre, was the senior author on a recently published UK-wide surveillance study on the neurological and neuropsychiatric complications of COVID-19 (Lancet Psychiatry. 2020 Jun 25. doi: 10.1016/S2215-0366[20]30287-X).
He said among patients in the New York study, “those with COVID and a stroke appeared to have many conventional risk factors for stroke (and often at higher percentages than COVID patients without a stroke), e.g. hypertension, overweight, diabetes, hyperlipidemia, existing vascular disease affecting the coronary arteries and atrial fibrillation. To establish evidence-based treatment pathways, clearly further studies are needed to determine the biological mechanisms underlying the seemingly higher rate of stroke with COVID-19 than influenza; but this must especially focus on those younger patients without conventional risk factors for stroke (which are largely not included in this study).”
SOURCE: Merkler AE et al. JAMA Neurol. doi: 10.1001/jamaneurol.2020.2730.
FROM JAMA NEUROLOGY
Three stages to COVID-19 brain damage, new review suggests
In stage 1, viral damage is limited to epithelial cells of the nose and mouth, and in stage 2 blood clots that form in the lungs may travel to the brain, leading to stroke. In stage 3, the virus crosses the blood-brain barrier and invades the brain.
“Our major take-home points are that patients with COVID-19 symptoms, such as shortness of breath, headache, or dizziness, may have neurological symptoms that, at the time of hospitalization, might not be noticed or prioritized, or whose neurological symptoms may become apparent only after they leave the hospital,” lead author Majid Fotuhi, MD, PhD, medical director of NeuroGrow Brain Fitness Center in McLean, Va., said.
“Hospitalized patients with COVID-19 should have a neurological evaluation and ideally a brain MRI before leaving the hospital; and, if there are abnormalities, they should follow up with a neurologist in 3-4 months,” said Dr. Fotuhi, who is also affiliate staff at Johns Hopkins Medicine, Baltimore.
The review was published online June 8 in the Journal of Alzheimer’s Disease.
Wreaks CNS havoc
It has become “increasingly evident” that SARS-CoV-2 can cause neurologic manifestations, including anosmia, seizures, stroke, confusion, encephalopathy, and total paralysis, the authors wrote.
They noted that SARS-CoV-2 binds to ACE2, which facilitates the conversion of angiotensin II to angiotensin. After ACE2 has bound to respiratory epithelial cells and then to epithelial cells in blood vessels, SARS-CoV-2 triggers the formation of a “cytokine storm.”
These cytokines, in turn, increase vascular permeability, edema, and widespread inflammation, as well as triggering “hypercoagulation cascades,” which cause small and large blood clots that affect multiple organs.
If SARS-CoV-2 crosses the blood-brain barrier, directly entering the brain, it can contribute to demyelination or neurodegeneration.
“We very thoroughly reviewed the literature published between Jan. 1 and May 1, 2020, about neurological issues [in COVID-19] and what I found interesting is that so many neurological things can happen due to a virus which is so small,” said Dr. Fotuhi.
“This virus’ DNA has such limited information, and yet it can wreak havoc on our nervous system because it kicks off such a potent defense system in our body that damages our nervous system,” he said.
Three-stage classification
- Stage 1: The extent of SARS-CoV-2 binding to the ACE2 receptors is limited to the nasal and gustatory epithelial cells, with the cytokine storm remaining “low and controlled.” During this stage, patients may experience smell or taste impairments, but often recover without any interventions.
- Stage 2: A “robust immune response” is activated by the virus, leading to inflammation in the blood vessels, increased hypercoagulability factors, and the formation of blood clots in cerebral arteries and veins. The patient may therefore experience either large or small strokes. Additional stage 2 symptoms include fatigue, hemiplegia, sensory loss, , tetraplegia, , or ataxia.
- Stage 3: The cytokine storm in the blood vessels is so severe that it causes an “explosive inflammatory response” and penetrates the blood-brain barrier, leading to the entry of cytokines, blood components, and viral particles into the brain parenchyma and causing neuronal cell death and encephalitis. This stage can be characterized by seizures, confusion, , coma, loss of consciousness, or death.
“Patients in stage 3 are more likely to have long-term consequences, because there is evidence that the virus particles have actually penetrated the brain, and we know that SARS-CoV-2 can remain dormant in neurons for many years,” said Dr. Fotuhi.
“Studies of coronaviruses have shown a link between the viruses and the risk of multiple sclerosis or Parkinson’s disease even decades later,” he added.
“Based on several reports in recent months, between 36% to 55% of patients with COVID-19 that are hospitalized have some neurological symptoms, but if you don’t look for them, you won’t see them,” Dr. Fotuhi noted.
As a result, patients should be monitored over time after discharge, as they may develop cognitive dysfunction down the road.
Additionally, “it is imperative for patients [hospitalized with COVID-19] to get a baseline MRI before leaving the hospital so that we have a starting point for future evaluation and treatment,” said Dr. Fotuhi.
“The good news is that neurological manifestations of COVID-19 are treatable,” and “can improve with intensive training,” including lifestyle changes – such as a heart-healthy diet, regular physical activity, stress reduction, improved sleep, biofeedback, and brain rehabilitation, Dr. Fotuhi added.
Routine MRI not necessary
Kenneth Tyler, MD, chair of the department of neurology at the University of Colorado at Denver, Aurora, disagreed that all hospitalized patients with COVID-19 should routinely receive an MRI.
“Whenever you are using a piece of equipment on patients who are COVID-19 infected, you risk introducing the infection to uninfected patients,” he said. Instead, “the indication is in patients who develop unexplained neurological manifestations – altered mental status or focal seizures, for example – because in those cases, you do need to understand whether there are underlying structural abnormalities,” said Dr. Tyler, who was not involved in the review.
Also commenting on the review, Vanja Douglas, MD, associate professor of clinical neurology, University of California, San Francisco, described the review as “thorough” and suggested it may “help us understand how to design observational studies to test whether the associations are due to severe respiratory illness or are specific to SARS-CoV-2 infection.”
Dr. Douglas, who was not involved in the review, added that it is “helpful in giving us a sense of which neurologic syndromes have been observed in COVID-19 patients, and therefore which patients neurologists may want to screen more carefully during the pandemic.”
The study had no specific funding. Dr. Fotuhi disclosed no relevant financial relationships. One coauthor reported receiving consulting fees as a member of the scientific advisory board for Brainreader and reports royalties for expert witness consultation in conjunction with Neurevolution. Dr. Tyler and Dr. Douglas disclosed no relevant financial relationships.
A version of this article originally appeared on Medscape.com.
In stage 1, viral damage is limited to epithelial cells of the nose and mouth, and in stage 2 blood clots that form in the lungs may travel to the brain, leading to stroke. In stage 3, the virus crosses the blood-brain barrier and invades the brain.
“Our major take-home points are that patients with COVID-19 symptoms, such as shortness of breath, headache, or dizziness, may have neurological symptoms that, at the time of hospitalization, might not be noticed or prioritized, or whose neurological symptoms may become apparent only after they leave the hospital,” lead author Majid Fotuhi, MD, PhD, medical director of NeuroGrow Brain Fitness Center in McLean, Va., said.
“Hospitalized patients with COVID-19 should have a neurological evaluation and ideally a brain MRI before leaving the hospital; and, if there are abnormalities, they should follow up with a neurologist in 3-4 months,” said Dr. Fotuhi, who is also affiliate staff at Johns Hopkins Medicine, Baltimore.
The review was published online June 8 in the Journal of Alzheimer’s Disease.
Wreaks CNS havoc
It has become “increasingly evident” that SARS-CoV-2 can cause neurologic manifestations, including anosmia, seizures, stroke, confusion, encephalopathy, and total paralysis, the authors wrote.
They noted that SARS-CoV-2 binds to ACE2, which facilitates the conversion of angiotensin II to angiotensin. After ACE2 has bound to respiratory epithelial cells and then to epithelial cells in blood vessels, SARS-CoV-2 triggers the formation of a “cytokine storm.”
These cytokines, in turn, increase vascular permeability, edema, and widespread inflammation, as well as triggering “hypercoagulation cascades,” which cause small and large blood clots that affect multiple organs.
If SARS-CoV-2 crosses the blood-brain barrier, directly entering the brain, it can contribute to demyelination or neurodegeneration.
“We very thoroughly reviewed the literature published between Jan. 1 and May 1, 2020, about neurological issues [in COVID-19] and what I found interesting is that so many neurological things can happen due to a virus which is so small,” said Dr. Fotuhi.
“This virus’ DNA has such limited information, and yet it can wreak havoc on our nervous system because it kicks off such a potent defense system in our body that damages our nervous system,” he said.
Three-stage classification
- Stage 1: The extent of SARS-CoV-2 binding to the ACE2 receptors is limited to the nasal and gustatory epithelial cells, with the cytokine storm remaining “low and controlled.” During this stage, patients may experience smell or taste impairments, but often recover without any interventions.
- Stage 2: A “robust immune response” is activated by the virus, leading to inflammation in the blood vessels, increased hypercoagulability factors, and the formation of blood clots in cerebral arteries and veins. The patient may therefore experience either large or small strokes. Additional stage 2 symptoms include fatigue, hemiplegia, sensory loss, , tetraplegia, , or ataxia.
- Stage 3: The cytokine storm in the blood vessels is so severe that it causes an “explosive inflammatory response” and penetrates the blood-brain barrier, leading to the entry of cytokines, blood components, and viral particles into the brain parenchyma and causing neuronal cell death and encephalitis. This stage can be characterized by seizures, confusion, , coma, loss of consciousness, or death.
“Patients in stage 3 are more likely to have long-term consequences, because there is evidence that the virus particles have actually penetrated the brain, and we know that SARS-CoV-2 can remain dormant in neurons for many years,” said Dr. Fotuhi.
“Studies of coronaviruses have shown a link between the viruses and the risk of multiple sclerosis or Parkinson’s disease even decades later,” he added.
“Based on several reports in recent months, between 36% to 55% of patients with COVID-19 that are hospitalized have some neurological symptoms, but if you don’t look for them, you won’t see them,” Dr. Fotuhi noted.
As a result, patients should be monitored over time after discharge, as they may develop cognitive dysfunction down the road.
Additionally, “it is imperative for patients [hospitalized with COVID-19] to get a baseline MRI before leaving the hospital so that we have a starting point for future evaluation and treatment,” said Dr. Fotuhi.
“The good news is that neurological manifestations of COVID-19 are treatable,” and “can improve with intensive training,” including lifestyle changes – such as a heart-healthy diet, regular physical activity, stress reduction, improved sleep, biofeedback, and brain rehabilitation, Dr. Fotuhi added.
Routine MRI not necessary
Kenneth Tyler, MD, chair of the department of neurology at the University of Colorado at Denver, Aurora, disagreed that all hospitalized patients with COVID-19 should routinely receive an MRI.
“Whenever you are using a piece of equipment on patients who are COVID-19 infected, you risk introducing the infection to uninfected patients,” he said. Instead, “the indication is in patients who develop unexplained neurological manifestations – altered mental status or focal seizures, for example – because in those cases, you do need to understand whether there are underlying structural abnormalities,” said Dr. Tyler, who was not involved in the review.
Also commenting on the review, Vanja Douglas, MD, associate professor of clinical neurology, University of California, San Francisco, described the review as “thorough” and suggested it may “help us understand how to design observational studies to test whether the associations are due to severe respiratory illness or are specific to SARS-CoV-2 infection.”
Dr. Douglas, who was not involved in the review, added that it is “helpful in giving us a sense of which neurologic syndromes have been observed in COVID-19 patients, and therefore which patients neurologists may want to screen more carefully during the pandemic.”
The study had no specific funding. Dr. Fotuhi disclosed no relevant financial relationships. One coauthor reported receiving consulting fees as a member of the scientific advisory board for Brainreader and reports royalties for expert witness consultation in conjunction with Neurevolution. Dr. Tyler and Dr. Douglas disclosed no relevant financial relationships.
A version of this article originally appeared on Medscape.com.
In stage 1, viral damage is limited to epithelial cells of the nose and mouth, and in stage 2 blood clots that form in the lungs may travel to the brain, leading to stroke. In stage 3, the virus crosses the blood-brain barrier and invades the brain.
“Our major take-home points are that patients with COVID-19 symptoms, such as shortness of breath, headache, or dizziness, may have neurological symptoms that, at the time of hospitalization, might not be noticed or prioritized, or whose neurological symptoms may become apparent only after they leave the hospital,” lead author Majid Fotuhi, MD, PhD, medical director of NeuroGrow Brain Fitness Center in McLean, Va., said.
“Hospitalized patients with COVID-19 should have a neurological evaluation and ideally a brain MRI before leaving the hospital; and, if there are abnormalities, they should follow up with a neurologist in 3-4 months,” said Dr. Fotuhi, who is also affiliate staff at Johns Hopkins Medicine, Baltimore.
The review was published online June 8 in the Journal of Alzheimer’s Disease.
Wreaks CNS havoc
It has become “increasingly evident” that SARS-CoV-2 can cause neurologic manifestations, including anosmia, seizures, stroke, confusion, encephalopathy, and total paralysis, the authors wrote.
They noted that SARS-CoV-2 binds to ACE2, which facilitates the conversion of angiotensin II to angiotensin. After ACE2 has bound to respiratory epithelial cells and then to epithelial cells in blood vessels, SARS-CoV-2 triggers the formation of a “cytokine storm.”
These cytokines, in turn, increase vascular permeability, edema, and widespread inflammation, as well as triggering “hypercoagulation cascades,” which cause small and large blood clots that affect multiple organs.
If SARS-CoV-2 crosses the blood-brain barrier, directly entering the brain, it can contribute to demyelination or neurodegeneration.
“We very thoroughly reviewed the literature published between Jan. 1 and May 1, 2020, about neurological issues [in COVID-19] and what I found interesting is that so many neurological things can happen due to a virus which is so small,” said Dr. Fotuhi.
“This virus’ DNA has such limited information, and yet it can wreak havoc on our nervous system because it kicks off such a potent defense system in our body that damages our nervous system,” he said.
Three-stage classification
- Stage 1: The extent of SARS-CoV-2 binding to the ACE2 receptors is limited to the nasal and gustatory epithelial cells, with the cytokine storm remaining “low and controlled.” During this stage, patients may experience smell or taste impairments, but often recover without any interventions.
- Stage 2: A “robust immune response” is activated by the virus, leading to inflammation in the blood vessels, increased hypercoagulability factors, and the formation of blood clots in cerebral arteries and veins. The patient may therefore experience either large or small strokes. Additional stage 2 symptoms include fatigue, hemiplegia, sensory loss, , tetraplegia, , or ataxia.
- Stage 3: The cytokine storm in the blood vessels is so severe that it causes an “explosive inflammatory response” and penetrates the blood-brain barrier, leading to the entry of cytokines, blood components, and viral particles into the brain parenchyma and causing neuronal cell death and encephalitis. This stage can be characterized by seizures, confusion, , coma, loss of consciousness, or death.
“Patients in stage 3 are more likely to have long-term consequences, because there is evidence that the virus particles have actually penetrated the brain, and we know that SARS-CoV-2 can remain dormant in neurons for many years,” said Dr. Fotuhi.
“Studies of coronaviruses have shown a link between the viruses and the risk of multiple sclerosis or Parkinson’s disease even decades later,” he added.
“Based on several reports in recent months, between 36% to 55% of patients with COVID-19 that are hospitalized have some neurological symptoms, but if you don’t look for them, you won’t see them,” Dr. Fotuhi noted.
As a result, patients should be monitored over time after discharge, as they may develop cognitive dysfunction down the road.
Additionally, “it is imperative for patients [hospitalized with COVID-19] to get a baseline MRI before leaving the hospital so that we have a starting point for future evaluation and treatment,” said Dr. Fotuhi.
“The good news is that neurological manifestations of COVID-19 are treatable,” and “can improve with intensive training,” including lifestyle changes – such as a heart-healthy diet, regular physical activity, stress reduction, improved sleep, biofeedback, and brain rehabilitation, Dr. Fotuhi added.
Routine MRI not necessary
Kenneth Tyler, MD, chair of the department of neurology at the University of Colorado at Denver, Aurora, disagreed that all hospitalized patients with COVID-19 should routinely receive an MRI.
“Whenever you are using a piece of equipment on patients who are COVID-19 infected, you risk introducing the infection to uninfected patients,” he said. Instead, “the indication is in patients who develop unexplained neurological manifestations – altered mental status or focal seizures, for example – because in those cases, you do need to understand whether there are underlying structural abnormalities,” said Dr. Tyler, who was not involved in the review.
Also commenting on the review, Vanja Douglas, MD, associate professor of clinical neurology, University of California, San Francisco, described the review as “thorough” and suggested it may “help us understand how to design observational studies to test whether the associations are due to severe respiratory illness or are specific to SARS-CoV-2 infection.”
Dr. Douglas, who was not involved in the review, added that it is “helpful in giving us a sense of which neurologic syndromes have been observed in COVID-19 patients, and therefore which patients neurologists may want to screen more carefully during the pandemic.”
The study had no specific funding. Dr. Fotuhi disclosed no relevant financial relationships. One coauthor reported receiving consulting fees as a member of the scientific advisory board for Brainreader and reports royalties for expert witness consultation in conjunction with Neurevolution. Dr. Tyler and Dr. Douglas disclosed no relevant financial relationships.
A version of this article originally appeared on Medscape.com.
Intervention for AVM still too high risk: The latest from ARUBA
Enrollment into the trial, which compared medical management alone with medical management with interventional therapy (neurosurgery, embolization, or stereotactic radiotherapy, alone or in combination), was stopped prematurely in 2013 after 33 months of follow-up because of a much higher rate of death and stroke in the intervention group.
Reaffirming the benefit of no intervention
Now the investigators are reporting extended follow-up to 50 months. The results were very similar to those at 33 months.
The current 50-month follow-up results show that 15 of 110 patients in the medical group had died or had a stroke (3.39 per 100 patient-years) versus 41 of 116 (12.32 per 100 patient-years) in the intervention group. The results reaffirm the strong benefit of not undergoing intervention (hazard ratio, 0.31; 95% confidence interval, 0.17-0.56).
These latest results were published in the July issue of the Lancet Neurology.
“With an AVM, the natural reflex is to try and fix it, but our trial shows that the tools we have to do that seem to be more damaging than just living with the AVM. If we try to take it out, the stroke risk is three to five times higher than just leaving it alone,” coauthor Christian Stapf, MD, a professor at the University of Montreal, said in an interview.
Dr. Stapf explained that an AVM is a congenital abnormality in the linking of the arteries to the veins. “There are an excess number of arteries and veins. They usually sit there silently, but they can trigger seizures, as they can tickle the neurons in the vicinity.”
It is estimated that one to two AVMs are found spontaneously in every 100,000 persons every year, but this is dependent on the availability of MRI, and many go undetected, he noted. In MRI studies in healthy volunteers, the rate was about one AVM in every 2,000 individuals.
Challenging standard practice
With AVMs, rupture and intracerebral hemorrhage occur at a rate of about 1%-2% per year. Until the ARUBA results were published, the standard practice was to intervene to embolize or excise the malformation, Dr. Stapf said.
“The standard treatment was intervention. The experiment was not to do it. We were challenging standard practice, and the trial was not popular with interventionalists,” he said.
The initial study, which was published in 2014, received much criticism from the interventionalist community. Among the criticisms were that the selection criteria for enrollment limited its generalizability, fewer patients than expected in the intervention arm were referred for microvascular surgery, and the follow-up was too short to allow a meaningful comparison.
“The study received criticism, but this was mainly from interventionalists, who were having their income threatened,” Dr. Stapf said. “This was very unhappy news for them, especially in the U.S., with the fee-for-service system.”
But he says these longer-term results, together with additional analyses and data from other cohorts, reinforce their initial conclusions.
The current report also shows a benefit in functional outcome in the medical group. “After 5 years, patients are twice as likely to have a neurological handicap, defined as a score of 2 or higher on the modified Rankin scale in the intervention group,” he noted. “We also found that more patients in the intervention group had deficits not related to stroke, such as an increase in seizures.”
Results of subgroup analysis were consistent in all patient groups.
The “study was designed for 400 patients, but we only recruited about half that number. But even so, the effect of intervention on stroke is so strong there is no subgroup where it looks favorable,” Dr. Stapf said. “This result was not heterogeneous. The same effect is seen regardless of age, gender, presence of symptoms, size of AVM, location, anatomy, drainage. No matter how you look, there is no benefit for intervention.”
He also referred to a Scottish population-based cohort study that showed a similar risk reduction from not intervening. “This was an unselected population of every unruptured AVM patient in Scotland, which found a 65% relative reduction in death/stroke over 12 years. We found a 69% reduction. The Scottish study did not select any particular types of patients but showed the same result as us,” he noted. “It is hard to argue against these findings.”
Regarding the claim of selection bias, Dr. Stapf acknowledged that the study excluded patients who were judged to be in need of intervention and those judged to be at very low risk and who would not be considered for an intervention.
“But when we compared our cohort to two other unselected cohorts, they look very similar, apart from the fact that very large AVMs were not entered in our study, as they were considered too difficult to treat,” he said. “If there is a selection bias at all, it actually trends towards the intervention group, as we excluded those at the highest treatment risk, but we still showed more benefit of not intervening.”
He also says the microvascular surgery rates were consistent with real-world practice, with about 25% of patients undergoing such surgery. “This is similar to the Scottish population study. Our trial also showed a similar result in patients treated with the various different interventions – they all showed a much higher risk than not intervening,” he added.
He says practice has changed since the trial was first reported. “There are far fewer interventions now for unruptured AVMs. Most interventionalists have accepted the results now, although there are some who continue to find reasons to criticize the trial and carry on with the procedures.”
He says his advice to patients who have an unruptured AVM is to forget about it. “There doesn’t seem to be a trigger for rupture,” he said. “It doesn’t seem to be dependent on blood pressure or physical activity, and we can’t tell if it’s just about to go by looking at it. They are very different from an aneurysm in that regard.
“When I explain to patients that they are at an increased stroke risk and tell them about the results of the ARUBA study, they say they would prefer to get that stroke later in life than earlier. These patents can live for 30 or 40 years without a stroke.
“But, yes, there remains a major unmet need. We need to find a way to protect these patients. In future, we might find a better way of intervening, but at this point in time, the treatment we have is more dangerous than doing nothing,” he said.
Longer follow-up needed
In an editorial that accompanies the current study, Peter M. Rothwell, MD, of the University of Oxford, England, also dismisses much of the criticism of the ARUBA study. On the issue of external validity, he said: “I do not think that this is really any greater an issue for ARUBA than for most other similar trials.”
But Dr. Rothwell does believe that follow-up for longer than 5 years is needed. “To really understand the benefit/risk balance, we would need a 20- or 30-year follow-up. These patients are often in their 20s, 30s, or 40s, so we really need to know their cumulative risk over decades,” he said in an interview.
Noting that the study was funded by the National Institute of Neurological Disorders and Stroke (NINDS), Dr. Rothwell said funding should have been provided for much longer follow-up. “Patients who generously agreed to be randomly assigned in ARUBA and future similar patients have been let down by NINDS.
“We probably now won’t ever know the very–long-term impact, although the Scottish population study is following patients longer term,” he added.
“After this trial was first published, the guidelines recommended not to intervene. These latest results will not change that,” he said.
The ARUBA trial was funded internationally by the National Institutes of Health/NINDS. Dr. Stapf and Dr. Rothwell have disclosed no relevant financial relationships.
A version of this article originally appeared on Medscape.com.
Enrollment into the trial, which compared medical management alone with medical management with interventional therapy (neurosurgery, embolization, or stereotactic radiotherapy, alone or in combination), was stopped prematurely in 2013 after 33 months of follow-up because of a much higher rate of death and stroke in the intervention group.
Reaffirming the benefit of no intervention
Now the investigators are reporting extended follow-up to 50 months. The results were very similar to those at 33 months.
The current 50-month follow-up results show that 15 of 110 patients in the medical group had died or had a stroke (3.39 per 100 patient-years) versus 41 of 116 (12.32 per 100 patient-years) in the intervention group. The results reaffirm the strong benefit of not undergoing intervention (hazard ratio, 0.31; 95% confidence interval, 0.17-0.56).
These latest results were published in the July issue of the Lancet Neurology.
“With an AVM, the natural reflex is to try and fix it, but our trial shows that the tools we have to do that seem to be more damaging than just living with the AVM. If we try to take it out, the stroke risk is three to five times higher than just leaving it alone,” coauthor Christian Stapf, MD, a professor at the University of Montreal, said in an interview.
Dr. Stapf explained that an AVM is a congenital abnormality in the linking of the arteries to the veins. “There are an excess number of arteries and veins. They usually sit there silently, but they can trigger seizures, as they can tickle the neurons in the vicinity.”
It is estimated that one to two AVMs are found spontaneously in every 100,000 persons every year, but this is dependent on the availability of MRI, and many go undetected, he noted. In MRI studies in healthy volunteers, the rate was about one AVM in every 2,000 individuals.
Challenging standard practice
With AVMs, rupture and intracerebral hemorrhage occur at a rate of about 1%-2% per year. Until the ARUBA results were published, the standard practice was to intervene to embolize or excise the malformation, Dr. Stapf said.
“The standard treatment was intervention. The experiment was not to do it. We were challenging standard practice, and the trial was not popular with interventionalists,” he said.
The initial study, which was published in 2014, received much criticism from the interventionalist community. Among the criticisms were that the selection criteria for enrollment limited its generalizability, fewer patients than expected in the intervention arm were referred for microvascular surgery, and the follow-up was too short to allow a meaningful comparison.
“The study received criticism, but this was mainly from interventionalists, who were having their income threatened,” Dr. Stapf said. “This was very unhappy news for them, especially in the U.S., with the fee-for-service system.”
But he says these longer-term results, together with additional analyses and data from other cohorts, reinforce their initial conclusions.
The current report also shows a benefit in functional outcome in the medical group. “After 5 years, patients are twice as likely to have a neurological handicap, defined as a score of 2 or higher on the modified Rankin scale in the intervention group,” he noted. “We also found that more patients in the intervention group had deficits not related to stroke, such as an increase in seizures.”
Results of subgroup analysis were consistent in all patient groups.
The “study was designed for 400 patients, but we only recruited about half that number. But even so, the effect of intervention on stroke is so strong there is no subgroup where it looks favorable,” Dr. Stapf said. “This result was not heterogeneous. The same effect is seen regardless of age, gender, presence of symptoms, size of AVM, location, anatomy, drainage. No matter how you look, there is no benefit for intervention.”
He also referred to a Scottish population-based cohort study that showed a similar risk reduction from not intervening. “This was an unselected population of every unruptured AVM patient in Scotland, which found a 65% relative reduction in death/stroke over 12 years. We found a 69% reduction. The Scottish study did not select any particular types of patients but showed the same result as us,” he noted. “It is hard to argue against these findings.”
Regarding the claim of selection bias, Dr. Stapf acknowledged that the study excluded patients who were judged to be in need of intervention and those judged to be at very low risk and who would not be considered for an intervention.
“But when we compared our cohort to two other unselected cohorts, they look very similar, apart from the fact that very large AVMs were not entered in our study, as they were considered too difficult to treat,” he said. “If there is a selection bias at all, it actually trends towards the intervention group, as we excluded those at the highest treatment risk, but we still showed more benefit of not intervening.”
He also says the microvascular surgery rates were consistent with real-world practice, with about 25% of patients undergoing such surgery. “This is similar to the Scottish population study. Our trial also showed a similar result in patients treated with the various different interventions – they all showed a much higher risk than not intervening,” he added.
He says practice has changed since the trial was first reported. “There are far fewer interventions now for unruptured AVMs. Most interventionalists have accepted the results now, although there are some who continue to find reasons to criticize the trial and carry on with the procedures.”
He says his advice to patients who have an unruptured AVM is to forget about it. “There doesn’t seem to be a trigger for rupture,” he said. “It doesn’t seem to be dependent on blood pressure or physical activity, and we can’t tell if it’s just about to go by looking at it. They are very different from an aneurysm in that regard.
“When I explain to patients that they are at an increased stroke risk and tell them about the results of the ARUBA study, they say they would prefer to get that stroke later in life than earlier. These patents can live for 30 or 40 years without a stroke.
“But, yes, there remains a major unmet need. We need to find a way to protect these patients. In future, we might find a better way of intervening, but at this point in time, the treatment we have is more dangerous than doing nothing,” he said.
Longer follow-up needed
In an editorial that accompanies the current study, Peter M. Rothwell, MD, of the University of Oxford, England, also dismisses much of the criticism of the ARUBA study. On the issue of external validity, he said: “I do not think that this is really any greater an issue for ARUBA than for most other similar trials.”
But Dr. Rothwell does believe that follow-up for longer than 5 years is needed. “To really understand the benefit/risk balance, we would need a 20- or 30-year follow-up. These patients are often in their 20s, 30s, or 40s, so we really need to know their cumulative risk over decades,” he said in an interview.
Noting that the study was funded by the National Institute of Neurological Disorders and Stroke (NINDS), Dr. Rothwell said funding should have been provided for much longer follow-up. “Patients who generously agreed to be randomly assigned in ARUBA and future similar patients have been let down by NINDS.
“We probably now won’t ever know the very–long-term impact, although the Scottish population study is following patients longer term,” he added.
“After this trial was first published, the guidelines recommended not to intervene. These latest results will not change that,” he said.
The ARUBA trial was funded internationally by the National Institutes of Health/NINDS. Dr. Stapf and Dr. Rothwell have disclosed no relevant financial relationships.
A version of this article originally appeared on Medscape.com.
Enrollment into the trial, which compared medical management alone with medical management with interventional therapy (neurosurgery, embolization, or stereotactic radiotherapy, alone or in combination), was stopped prematurely in 2013 after 33 months of follow-up because of a much higher rate of death and stroke in the intervention group.
Reaffirming the benefit of no intervention
Now the investigators are reporting extended follow-up to 50 months. The results were very similar to those at 33 months.
The current 50-month follow-up results show that 15 of 110 patients in the medical group had died or had a stroke (3.39 per 100 patient-years) versus 41 of 116 (12.32 per 100 patient-years) in the intervention group. The results reaffirm the strong benefit of not undergoing intervention (hazard ratio, 0.31; 95% confidence interval, 0.17-0.56).
These latest results were published in the July issue of the Lancet Neurology.
“With an AVM, the natural reflex is to try and fix it, but our trial shows that the tools we have to do that seem to be more damaging than just living with the AVM. If we try to take it out, the stroke risk is three to five times higher than just leaving it alone,” coauthor Christian Stapf, MD, a professor at the University of Montreal, said in an interview.
Dr. Stapf explained that an AVM is a congenital abnormality in the linking of the arteries to the veins. “There are an excess number of arteries and veins. They usually sit there silently, but they can trigger seizures, as they can tickle the neurons in the vicinity.”
It is estimated that one to two AVMs are found spontaneously in every 100,000 persons every year, but this is dependent on the availability of MRI, and many go undetected, he noted. In MRI studies in healthy volunteers, the rate was about one AVM in every 2,000 individuals.
Challenging standard practice
With AVMs, rupture and intracerebral hemorrhage occur at a rate of about 1%-2% per year. Until the ARUBA results were published, the standard practice was to intervene to embolize or excise the malformation, Dr. Stapf said.
“The standard treatment was intervention. The experiment was not to do it. We were challenging standard practice, and the trial was not popular with interventionalists,” he said.
The initial study, which was published in 2014, received much criticism from the interventionalist community. Among the criticisms were that the selection criteria for enrollment limited its generalizability, fewer patients than expected in the intervention arm were referred for microvascular surgery, and the follow-up was too short to allow a meaningful comparison.
“The study received criticism, but this was mainly from interventionalists, who were having their income threatened,” Dr. Stapf said. “This was very unhappy news for them, especially in the U.S., with the fee-for-service system.”
But he says these longer-term results, together with additional analyses and data from other cohorts, reinforce their initial conclusions.
The current report also shows a benefit in functional outcome in the medical group. “After 5 years, patients are twice as likely to have a neurological handicap, defined as a score of 2 or higher on the modified Rankin scale in the intervention group,” he noted. “We also found that more patients in the intervention group had deficits not related to stroke, such as an increase in seizures.”
Results of subgroup analysis were consistent in all patient groups.
The “study was designed for 400 patients, but we only recruited about half that number. But even so, the effect of intervention on stroke is so strong there is no subgroup where it looks favorable,” Dr. Stapf said. “This result was not heterogeneous. The same effect is seen regardless of age, gender, presence of symptoms, size of AVM, location, anatomy, drainage. No matter how you look, there is no benefit for intervention.”
He also referred to a Scottish population-based cohort study that showed a similar risk reduction from not intervening. “This was an unselected population of every unruptured AVM patient in Scotland, which found a 65% relative reduction in death/stroke over 12 years. We found a 69% reduction. The Scottish study did not select any particular types of patients but showed the same result as us,” he noted. “It is hard to argue against these findings.”
Regarding the claim of selection bias, Dr. Stapf acknowledged that the study excluded patients who were judged to be in need of intervention and those judged to be at very low risk and who would not be considered for an intervention.
“But when we compared our cohort to two other unselected cohorts, they look very similar, apart from the fact that very large AVMs were not entered in our study, as they were considered too difficult to treat,” he said. “If there is a selection bias at all, it actually trends towards the intervention group, as we excluded those at the highest treatment risk, but we still showed more benefit of not intervening.”
He also says the microvascular surgery rates were consistent with real-world practice, with about 25% of patients undergoing such surgery. “This is similar to the Scottish population study. Our trial also showed a similar result in patients treated with the various different interventions – they all showed a much higher risk than not intervening,” he added.
He says practice has changed since the trial was first reported. “There are far fewer interventions now for unruptured AVMs. Most interventionalists have accepted the results now, although there are some who continue to find reasons to criticize the trial and carry on with the procedures.”
He says his advice to patients who have an unruptured AVM is to forget about it. “There doesn’t seem to be a trigger for rupture,” he said. “It doesn’t seem to be dependent on blood pressure or physical activity, and we can’t tell if it’s just about to go by looking at it. They are very different from an aneurysm in that regard.
“When I explain to patients that they are at an increased stroke risk and tell them about the results of the ARUBA study, they say they would prefer to get that stroke later in life than earlier. These patents can live for 30 or 40 years without a stroke.
“But, yes, there remains a major unmet need. We need to find a way to protect these patients. In future, we might find a better way of intervening, but at this point in time, the treatment we have is more dangerous than doing nothing,” he said.
Longer follow-up needed
In an editorial that accompanies the current study, Peter M. Rothwell, MD, of the University of Oxford, England, also dismisses much of the criticism of the ARUBA study. On the issue of external validity, he said: “I do not think that this is really any greater an issue for ARUBA than for most other similar trials.”
But Dr. Rothwell does believe that follow-up for longer than 5 years is needed. “To really understand the benefit/risk balance, we would need a 20- or 30-year follow-up. These patients are often in their 20s, 30s, or 40s, so we really need to know their cumulative risk over decades,” he said in an interview.
Noting that the study was funded by the National Institute of Neurological Disorders and Stroke (NINDS), Dr. Rothwell said funding should have been provided for much longer follow-up. “Patients who generously agreed to be randomly assigned in ARUBA and future similar patients have been let down by NINDS.
“We probably now won’t ever know the very–long-term impact, although the Scottish population study is following patients longer term,” he added.
“After this trial was first published, the guidelines recommended not to intervene. These latest results will not change that,” he said.
The ARUBA trial was funded internationally by the National Institutes of Health/NINDS. Dr. Stapf and Dr. Rothwell have disclosed no relevant financial relationships.
A version of this article originally appeared on Medscape.com.
FROM LANCET NEUROLOGY
First reported U.S. case of COVID-19 linked to Guillain-Barré syndrome
further supporting a link between the virus and neurologic complications, including GBS.
Physicians in China reported the first case of COVID-19 that initially presented as acute GBS. The patient was a 61-year-old woman returning home from Wuhan during the pandemic.
Subsequently, physicians in Italy reported five cases of GBS in association with COVID-19.
The first U.S. case is described in the June issue of the Journal of Clinical Neuromuscular Disease.
Like cases from China and Italy, the U.S. patient’s symptoms of GBS reportedly occurred within days of being infected with SARS-CoV-2. “This onset is similar to a case report of acute Zika virus infection with concurrent GBS suggesting a parainfectious complication,” first author Sandeep Rana, MD, and colleagues noted.
The 54-year-old man was transferred to Allegheny General Hospital after developing ascending limb weakness and numbness that followed symptoms of a respiratory infection. Two weeks earlier, he initially developed rhinorrhea, odynophagia, fevers, chills, and night sweats. The man reported that his wife had tested positive for COVID-19 and that his symptoms started soon after her illness. The man also tested positive for COVID-19.
His deficits were characterized by quadriparesis and areflexia, burning dysesthesias, mild ophthalmoparesis, and dysautonomia. He did not have the loss of smell and taste documented in other COVID-19 patients. He briefly required mechanical ventilation and was successfully weaned after receiving a course of intravenous immunoglobulin.
Compared with other cases reported in the literature, the unique clinical features in the U.S. case are urinary retention secondary to dysautonomia and ocular symptoms of diplopia. These highlight the variability in the clinical presentation of GBS associated with COVID-19, the researchers noted.
They added that, with the Pittsburgh patient, electrophysiological findings were typical of demyelinating polyneuropathy seen in patients with GBS. The case series from Italy suggests that axonal variants could be as common in COVID-19–associated GBS.
“Although the number of documented cases internationally is notably small to date, it’s not completely surprising that a COVID-19 diagnosis may lead to a patient developing GBS. The increase of inflammation and inflammatory cells caused by the infection may trigger an irregular immune response that leads to the hallmark symptoms of this neurological disorder,” Dr. Rana said in a news release.
“Since GBS can significantly affect the respiratory system and other vital organs being pushed into overdrive during a COVID-19 immune response, it will be critically important to further investigate and understand this potential connection,” he added.
A version of this article originally appeared on Medscape.com.
further supporting a link between the virus and neurologic complications, including GBS.
Physicians in China reported the first case of COVID-19 that initially presented as acute GBS. The patient was a 61-year-old woman returning home from Wuhan during the pandemic.
Subsequently, physicians in Italy reported five cases of GBS in association with COVID-19.
The first U.S. case is described in the June issue of the Journal of Clinical Neuromuscular Disease.
Like cases from China and Italy, the U.S. patient’s symptoms of GBS reportedly occurred within days of being infected with SARS-CoV-2. “This onset is similar to a case report of acute Zika virus infection with concurrent GBS suggesting a parainfectious complication,” first author Sandeep Rana, MD, and colleagues noted.
The 54-year-old man was transferred to Allegheny General Hospital after developing ascending limb weakness and numbness that followed symptoms of a respiratory infection. Two weeks earlier, he initially developed rhinorrhea, odynophagia, fevers, chills, and night sweats. The man reported that his wife had tested positive for COVID-19 and that his symptoms started soon after her illness. The man also tested positive for COVID-19.
His deficits were characterized by quadriparesis and areflexia, burning dysesthesias, mild ophthalmoparesis, and dysautonomia. He did not have the loss of smell and taste documented in other COVID-19 patients. He briefly required mechanical ventilation and was successfully weaned after receiving a course of intravenous immunoglobulin.
Compared with other cases reported in the literature, the unique clinical features in the U.S. case are urinary retention secondary to dysautonomia and ocular symptoms of diplopia. These highlight the variability in the clinical presentation of GBS associated with COVID-19, the researchers noted.
They added that, with the Pittsburgh patient, electrophysiological findings were typical of demyelinating polyneuropathy seen in patients with GBS. The case series from Italy suggests that axonal variants could be as common in COVID-19–associated GBS.
“Although the number of documented cases internationally is notably small to date, it’s not completely surprising that a COVID-19 diagnosis may lead to a patient developing GBS. The increase of inflammation and inflammatory cells caused by the infection may trigger an irregular immune response that leads to the hallmark symptoms of this neurological disorder,” Dr. Rana said in a news release.
“Since GBS can significantly affect the respiratory system and other vital organs being pushed into overdrive during a COVID-19 immune response, it will be critically important to further investigate and understand this potential connection,” he added.
A version of this article originally appeared on Medscape.com.
further supporting a link between the virus and neurologic complications, including GBS.
Physicians in China reported the first case of COVID-19 that initially presented as acute GBS. The patient was a 61-year-old woman returning home from Wuhan during the pandemic.
Subsequently, physicians in Italy reported five cases of GBS in association with COVID-19.
The first U.S. case is described in the June issue of the Journal of Clinical Neuromuscular Disease.
Like cases from China and Italy, the U.S. patient’s symptoms of GBS reportedly occurred within days of being infected with SARS-CoV-2. “This onset is similar to a case report of acute Zika virus infection with concurrent GBS suggesting a parainfectious complication,” first author Sandeep Rana, MD, and colleagues noted.
The 54-year-old man was transferred to Allegheny General Hospital after developing ascending limb weakness and numbness that followed symptoms of a respiratory infection. Two weeks earlier, he initially developed rhinorrhea, odynophagia, fevers, chills, and night sweats. The man reported that his wife had tested positive for COVID-19 and that his symptoms started soon after her illness. The man also tested positive for COVID-19.
His deficits were characterized by quadriparesis and areflexia, burning dysesthesias, mild ophthalmoparesis, and dysautonomia. He did not have the loss of smell and taste documented in other COVID-19 patients. He briefly required mechanical ventilation and was successfully weaned after receiving a course of intravenous immunoglobulin.
Compared with other cases reported in the literature, the unique clinical features in the U.S. case are urinary retention secondary to dysautonomia and ocular symptoms of diplopia. These highlight the variability in the clinical presentation of GBS associated with COVID-19, the researchers noted.
They added that, with the Pittsburgh patient, electrophysiological findings were typical of demyelinating polyneuropathy seen in patients with GBS. The case series from Italy suggests that axonal variants could be as common in COVID-19–associated GBS.
“Although the number of documented cases internationally is notably small to date, it’s not completely surprising that a COVID-19 diagnosis may lead to a patient developing GBS. The increase of inflammation and inflammatory cells caused by the infection may trigger an irregular immune response that leads to the hallmark symptoms of this neurological disorder,” Dr. Rana said in a news release.
“Since GBS can significantly affect the respiratory system and other vital organs being pushed into overdrive during a COVID-19 immune response, it will be critically important to further investigate and understand this potential connection,” he added.
A version of this article originally appeared on Medscape.com.
Five healthy lifestyle choices tied to dramatic cut in dementia risk
“I hope this study will motivate people to engage in a healthy lifestyle by not smoking, being physically and cognitively active, and having a high-quality diet,” lead investigator Klodian Dhana, MD, PhD, department of internal medicine, Rush University Medical Center, Chicago, said in an interview.
The study was published online June 17 in Neurology.
Risk-modifying behaviors
To help quantify the impact of a healthy life on risk for Alzheimer’s dementia, Dr. Dhana and colleagues reviewed data from two longitudinal study populations: the Chicago Health and Aging Project (CHAP), with 1,845 participants, and the Memory and Aging Project (MAP), with 920 participants.
They defined a healthy lifestyle score on the basis of the following factors: not smoking; engaging in 150 min/wk or more of physical exercise of moderate to vigorous intensity; light to moderate alcohol consumption (between 1 and less than 15 g/day for women and between 1 and less than 30 g/day for men); consuming a high-quality Mediterranean-DASH Diet Intervention for Neurodegenerative Delay diet (upper 40%); and engaging in late-life cognitive activities (upper 40%). The overall score ranged from 0 to 5.
At baseline, the mean age of participants was 73.2 years in the CHAP study and 81.1 years in the MAP study; 62.4% of the CHAP participants and 75.2% of the MAP participants were women.
During a median follow-up of 5.8 years in CHAP and 6.0 years in MAP, a total of 379 and 229 participants, respectively, developed Alzheimer’s dementia. Rates of dementia decreased with an increasing number of healthy lifestyle behaviors.
In multivariable-adjusted models across the two cohorts, the risk for Alzheimer’s dementia was 27% lower with each additional healthy lifestyle factor (pooled hazard ratio, 0.73; 95% confidence interval, 0.66-0.80).
Compared with individuals with a healthy lifestyle score of 0-1, the risk was 37% lower (pooled HR, 0.63; 95% CI, 0.47-0.84) for those with two or three healthy lifestyle factors and 60% lower (pooled HR, 0.40; 95% CI, 0.28-0.56) for those with four or five healthy lifestyle factors.
“From these findings and the fact that the lifestyle factors we studied are modifiable and in direct control of the individual, it is imperative to promote them concurrently among older adults as a strategy to delay or prevent Alzheimer’s dementia,” Dr. Dhana and colleagues concluded.
In a statement, Dallas Anderson, PhD, program director, division of neuroscience, National Institute on Aging, said the findings help “paint the picture of how multiple factors are likely playing parts in Alzheimer’s disease risk.”
“It’s not a clear cause-and-effect result, but a strong finding because of the dual data sets and combination of modifiable lifestyle factors that appear to lead to risk reduction,” Dr. Anderson added.
Essential questions remain
Commenting on the new study, Luca Giliberto, MD, PhD, neurologist with the Litwin-Zucker Research Center for Alzheimer’s Disease and Memory Disorders at the Feinstein Institutes for Medical Research in Manhasset, N.Y., said this analysis is “further demonstration that a healthy lifestyle is essential to overcome or curb” the risk for Alzheimer’s disease.
“What needs to be determined is how early should we start ‘behaving.’ We should all aim to score four to five factors across our entire lifespan, but this is not always feasible. So, when is the time to behave? Also, what is the relative weight of each of these factors?” said Dr. Giliberto.
Of note, he added, although addressing vascular risk factors such as hypertension, hyperlipidemia, and diabetes “may require an extensive mindful and logistic effort, a healthy diet is effortlessly achieved in some countries, where both the DASH and MIND diets do not need to be ‘prescribed’ but are rather culturally engraved in the population.
“This is, in part, related to the wide availability of high-quality food in these countries, which is not the same in the U.S. This work is one more demonstration of the need to revisit our take on quality of food in the U.S.,” said Dr. Giliberto.
Numerous clinical trials testing lifestyle interventions for dementia prevention are currently underway. The MIND Diet Intervention to Prevent Alzheimer’s Disease, for example, is an interventional clinical trial comparing parallel groups with two different diets. MIND has enrolled more than 600 participants and is ongoing. The anticipated completion date is 2021. Another is the U.S. Study to Protect Brain Health Through Lifestyle Intervention to Reduce Risk (U.S. POINTER), a multisite randomized clinical trial evaluating whether lifestyle interventions – including exercise, cognitively stimulating activities, and the MIND diet – may protect cognitive function in older adults who are at increased risk for cognitive decline.
Funding for the current study was provided by the National Institutes of Health and the National Institute on Aging. Dr. Dhana and Dr. Giliberto have disclosed no relevant financial relationships.
A version of this article originally appeared on Medscape.com.
“I hope this study will motivate people to engage in a healthy lifestyle by not smoking, being physically and cognitively active, and having a high-quality diet,” lead investigator Klodian Dhana, MD, PhD, department of internal medicine, Rush University Medical Center, Chicago, said in an interview.
The study was published online June 17 in Neurology.
Risk-modifying behaviors
To help quantify the impact of a healthy life on risk for Alzheimer’s dementia, Dr. Dhana and colleagues reviewed data from two longitudinal study populations: the Chicago Health and Aging Project (CHAP), with 1,845 participants, and the Memory and Aging Project (MAP), with 920 participants.
They defined a healthy lifestyle score on the basis of the following factors: not smoking; engaging in 150 min/wk or more of physical exercise of moderate to vigorous intensity; light to moderate alcohol consumption (between 1 and less than 15 g/day for women and between 1 and less than 30 g/day for men); consuming a high-quality Mediterranean-DASH Diet Intervention for Neurodegenerative Delay diet (upper 40%); and engaging in late-life cognitive activities (upper 40%). The overall score ranged from 0 to 5.
At baseline, the mean age of participants was 73.2 years in the CHAP study and 81.1 years in the MAP study; 62.4% of the CHAP participants and 75.2% of the MAP participants were women.
During a median follow-up of 5.8 years in CHAP and 6.0 years in MAP, a total of 379 and 229 participants, respectively, developed Alzheimer’s dementia. Rates of dementia decreased with an increasing number of healthy lifestyle behaviors.
In multivariable-adjusted models across the two cohorts, the risk for Alzheimer’s dementia was 27% lower with each additional healthy lifestyle factor (pooled hazard ratio, 0.73; 95% confidence interval, 0.66-0.80).
Compared with individuals with a healthy lifestyle score of 0-1, the risk was 37% lower (pooled HR, 0.63; 95% CI, 0.47-0.84) for those with two or three healthy lifestyle factors and 60% lower (pooled HR, 0.40; 95% CI, 0.28-0.56) for those with four or five healthy lifestyle factors.
“From these findings and the fact that the lifestyle factors we studied are modifiable and in direct control of the individual, it is imperative to promote them concurrently among older adults as a strategy to delay or prevent Alzheimer’s dementia,” Dr. Dhana and colleagues concluded.
In a statement, Dallas Anderson, PhD, program director, division of neuroscience, National Institute on Aging, said the findings help “paint the picture of how multiple factors are likely playing parts in Alzheimer’s disease risk.”
“It’s not a clear cause-and-effect result, but a strong finding because of the dual data sets and combination of modifiable lifestyle factors that appear to lead to risk reduction,” Dr. Anderson added.
Essential questions remain
Commenting on the new study, Luca Giliberto, MD, PhD, neurologist with the Litwin-Zucker Research Center for Alzheimer’s Disease and Memory Disorders at the Feinstein Institutes for Medical Research in Manhasset, N.Y., said this analysis is “further demonstration that a healthy lifestyle is essential to overcome or curb” the risk for Alzheimer’s disease.
“What needs to be determined is how early should we start ‘behaving.’ We should all aim to score four to five factors across our entire lifespan, but this is not always feasible. So, when is the time to behave? Also, what is the relative weight of each of these factors?” said Dr. Giliberto.
Of note, he added, although addressing vascular risk factors such as hypertension, hyperlipidemia, and diabetes “may require an extensive mindful and logistic effort, a healthy diet is effortlessly achieved in some countries, where both the DASH and MIND diets do not need to be ‘prescribed’ but are rather culturally engraved in the population.
“This is, in part, related to the wide availability of high-quality food in these countries, which is not the same in the U.S. This work is one more demonstration of the need to revisit our take on quality of food in the U.S.,” said Dr. Giliberto.
Numerous clinical trials testing lifestyle interventions for dementia prevention are currently underway. The MIND Diet Intervention to Prevent Alzheimer’s Disease, for example, is an interventional clinical trial comparing parallel groups with two different diets. MIND has enrolled more than 600 participants and is ongoing. The anticipated completion date is 2021. Another is the U.S. Study to Protect Brain Health Through Lifestyle Intervention to Reduce Risk (U.S. POINTER), a multisite randomized clinical trial evaluating whether lifestyle interventions – including exercise, cognitively stimulating activities, and the MIND diet – may protect cognitive function in older adults who are at increased risk for cognitive decline.
Funding for the current study was provided by the National Institutes of Health and the National Institute on Aging. Dr. Dhana and Dr. Giliberto have disclosed no relevant financial relationships.
A version of this article originally appeared on Medscape.com.
“I hope this study will motivate people to engage in a healthy lifestyle by not smoking, being physically and cognitively active, and having a high-quality diet,” lead investigator Klodian Dhana, MD, PhD, department of internal medicine, Rush University Medical Center, Chicago, said in an interview.
The study was published online June 17 in Neurology.
Risk-modifying behaviors
To help quantify the impact of a healthy life on risk for Alzheimer’s dementia, Dr. Dhana and colleagues reviewed data from two longitudinal study populations: the Chicago Health and Aging Project (CHAP), with 1,845 participants, and the Memory and Aging Project (MAP), with 920 participants.
They defined a healthy lifestyle score on the basis of the following factors: not smoking; engaging in 150 min/wk or more of physical exercise of moderate to vigorous intensity; light to moderate alcohol consumption (between 1 and less than 15 g/day for women and between 1 and less than 30 g/day for men); consuming a high-quality Mediterranean-DASH Diet Intervention for Neurodegenerative Delay diet (upper 40%); and engaging in late-life cognitive activities (upper 40%). The overall score ranged from 0 to 5.
At baseline, the mean age of participants was 73.2 years in the CHAP study and 81.1 years in the MAP study; 62.4% of the CHAP participants and 75.2% of the MAP participants were women.
During a median follow-up of 5.8 years in CHAP and 6.0 years in MAP, a total of 379 and 229 participants, respectively, developed Alzheimer’s dementia. Rates of dementia decreased with an increasing number of healthy lifestyle behaviors.
In multivariable-adjusted models across the two cohorts, the risk for Alzheimer’s dementia was 27% lower with each additional healthy lifestyle factor (pooled hazard ratio, 0.73; 95% confidence interval, 0.66-0.80).
Compared with individuals with a healthy lifestyle score of 0-1, the risk was 37% lower (pooled HR, 0.63; 95% CI, 0.47-0.84) for those with two or three healthy lifestyle factors and 60% lower (pooled HR, 0.40; 95% CI, 0.28-0.56) for those with four or five healthy lifestyle factors.
“From these findings and the fact that the lifestyle factors we studied are modifiable and in direct control of the individual, it is imperative to promote them concurrently among older adults as a strategy to delay or prevent Alzheimer’s dementia,” Dr. Dhana and colleagues concluded.
In a statement, Dallas Anderson, PhD, program director, division of neuroscience, National Institute on Aging, said the findings help “paint the picture of how multiple factors are likely playing parts in Alzheimer’s disease risk.”
“It’s not a clear cause-and-effect result, but a strong finding because of the dual data sets and combination of modifiable lifestyle factors that appear to lead to risk reduction,” Dr. Anderson added.
Essential questions remain
Commenting on the new study, Luca Giliberto, MD, PhD, neurologist with the Litwin-Zucker Research Center for Alzheimer’s Disease and Memory Disorders at the Feinstein Institutes for Medical Research in Manhasset, N.Y., said this analysis is “further demonstration that a healthy lifestyle is essential to overcome or curb” the risk for Alzheimer’s disease.
“What needs to be determined is how early should we start ‘behaving.’ We should all aim to score four to five factors across our entire lifespan, but this is not always feasible. So, when is the time to behave? Also, what is the relative weight of each of these factors?” said Dr. Giliberto.
Of note, he added, although addressing vascular risk factors such as hypertension, hyperlipidemia, and diabetes “may require an extensive mindful and logistic effort, a healthy diet is effortlessly achieved in some countries, where both the DASH and MIND diets do not need to be ‘prescribed’ but are rather culturally engraved in the population.
“This is, in part, related to the wide availability of high-quality food in these countries, which is not the same in the U.S. This work is one more demonstration of the need to revisit our take on quality of food in the U.S.,” said Dr. Giliberto.
Numerous clinical trials testing lifestyle interventions for dementia prevention are currently underway. The MIND Diet Intervention to Prevent Alzheimer’s Disease, for example, is an interventional clinical trial comparing parallel groups with two different diets. MIND has enrolled more than 600 participants and is ongoing. The anticipated completion date is 2021. Another is the U.S. Study to Protect Brain Health Through Lifestyle Intervention to Reduce Risk (U.S. POINTER), a multisite randomized clinical trial evaluating whether lifestyle interventions – including exercise, cognitively stimulating activities, and the MIND diet – may protect cognitive function in older adults who are at increased risk for cognitive decline.
Funding for the current study was provided by the National Institutes of Health and the National Institute on Aging. Dr. Dhana and Dr. Giliberto have disclosed no relevant financial relationships.
A version of this article originally appeared on Medscape.com.
FROM NEUROLOGY
Circadian rhythm changes linked to future Parkinson’s disease risk
a new study suggests. “We found that men with abnormal circadian rhythms had three times the risk of developing Parkinson’s disease over an 11-year follow-up period,” lead author, Yue Leng, MD, University of California, San Francisco, said in an interview.
“If confirmed to be a risk factor for Parkinson’s disease, then circadian rhythmicity could be a promising intervention target and will open new opportunities for the prevention and management of Parkinson’s disease,” the researchers concluded.
The study was published online in JAMA Neurology on June 15.
Circadian disruption is very common in neurodegenerative diseases such as Parkinson’s disease, but there isn’t much information on how it may predict the disease, Dr. Leng explained. “We wanted to see whether circadian abnormalities may predict Parkinson’s disease,” she said. “Parkinson’s disease has a long prodromal phase where brain changes have started to occur but no clinical symptoms have become evident. It would be useful to be able to identify these patients, and maybe changes in circadian rhythms may help us to do that,” she added.
For the study, the researchers analyzed data from 2,930 community-dwelling men aged 65 years or older (mean age, 76 years) who participated in the Osteoporotic Fractures in Men Study, in which they underwent comprehensive sleep and rest-activity rhythms assessment. “Patterns of rest and activity were measured with an actigraph device, which is worn on the wrist like a watch and captures movements which are translated into a rest-activity rhythm model – one of the most commonly used and evidence-based measures of circadian rhythm,” Dr. Leng said. Men were asked to wear the actigraphs continuously for a minimum of three 24-hour periods.
Results showed that 78 men (2.7%) developed Parkinson’s disease during the 11-year follow-up. After accounting for all covariates, the risk of Parkinson’s disease increased with decreasing circadian amplitude (strength of the rhythm) with an odds ratio of 1.77 per each decrease by one standard deviation; mesor (mean level of activity) with an odds ratio of 1.64; or robustness (how closely activity follows a 24-hour pattern) with an odds ratio of 1.54.
Those in the lowest quartile of amplitude, mesor, or robustness had approximately three times the risk of developing Parkinson’s disease compared with those in the highest quartile of amplitude. The association remained after further adjustment for nighttime sleep disturbances.
“It has previously been shown that daytime napping has been linked to risk of developing Parkinson’s disease. Now we have shown that abnormalities in the overall 24-hour circadian rest activity rhythm are also present in the prodromal phase of Parkinson’s disease, and this association was independent of several confounders, including nighttime sleep disturbances,” Dr. Leng said.
“This raises awareness of the importance of circadian rhythm in older individuals and changes in their 24-hour pattern of behavior could be an early signal of Parkinson’s disease,” she said.
“This study does not tell us whether these circadian changes are causal for Parkinson’s or not,” Dr. Leng noted.
Future studies are needed to explore underlying mechanisms and to determine whether circadian disruption itself might contribute to the development of Parkinson’s disease, the researchers said.
“If there is a causal link, then using techniques to improve circadian rhythm could help to prevent or slow the onset of Parkinson’s disease,” Dr. Leng suggested. There are many established therapies that act on circadian rhythm including bright light therapy, melatonin, and chronotherapy, she added.
Support for this study was provided by the National Institute on Aging (NIA); the National Institute of Arthritis and Musculoskeletal and Skin Diseases; the National Center for Advancing Translational Sciences; the National Heart, Lung, and Blood Institute; and the Weill Pilot Award. Dr. Leng reported grants from the NIA and the University of California, San Francisco, Weill Institute for Neurosciences during the conduct of the study; and grants from Global Brain Health Institute, the Alzheimer’s Association, and the Alzheimer’s Society outside the submitted work.
A version of this article originally appeared on Medscape.com.
a new study suggests. “We found that men with abnormal circadian rhythms had three times the risk of developing Parkinson’s disease over an 11-year follow-up period,” lead author, Yue Leng, MD, University of California, San Francisco, said in an interview.
“If confirmed to be a risk factor for Parkinson’s disease, then circadian rhythmicity could be a promising intervention target and will open new opportunities for the prevention and management of Parkinson’s disease,” the researchers concluded.
The study was published online in JAMA Neurology on June 15.
Circadian disruption is very common in neurodegenerative diseases such as Parkinson’s disease, but there isn’t much information on how it may predict the disease, Dr. Leng explained. “We wanted to see whether circadian abnormalities may predict Parkinson’s disease,” she said. “Parkinson’s disease has a long prodromal phase where brain changes have started to occur but no clinical symptoms have become evident. It would be useful to be able to identify these patients, and maybe changes in circadian rhythms may help us to do that,” she added.
For the study, the researchers analyzed data from 2,930 community-dwelling men aged 65 years or older (mean age, 76 years) who participated in the Osteoporotic Fractures in Men Study, in which they underwent comprehensive sleep and rest-activity rhythms assessment. “Patterns of rest and activity were measured with an actigraph device, which is worn on the wrist like a watch and captures movements which are translated into a rest-activity rhythm model – one of the most commonly used and evidence-based measures of circadian rhythm,” Dr. Leng said. Men were asked to wear the actigraphs continuously for a minimum of three 24-hour periods.
Results showed that 78 men (2.7%) developed Parkinson’s disease during the 11-year follow-up. After accounting for all covariates, the risk of Parkinson’s disease increased with decreasing circadian amplitude (strength of the rhythm) with an odds ratio of 1.77 per each decrease by one standard deviation; mesor (mean level of activity) with an odds ratio of 1.64; or robustness (how closely activity follows a 24-hour pattern) with an odds ratio of 1.54.
Those in the lowest quartile of amplitude, mesor, or robustness had approximately three times the risk of developing Parkinson’s disease compared with those in the highest quartile of amplitude. The association remained after further adjustment for nighttime sleep disturbances.
“It has previously been shown that daytime napping has been linked to risk of developing Parkinson’s disease. Now we have shown that abnormalities in the overall 24-hour circadian rest activity rhythm are also present in the prodromal phase of Parkinson’s disease, and this association was independent of several confounders, including nighttime sleep disturbances,” Dr. Leng said.
“This raises awareness of the importance of circadian rhythm in older individuals and changes in their 24-hour pattern of behavior could be an early signal of Parkinson’s disease,” she said.
“This study does not tell us whether these circadian changes are causal for Parkinson’s or not,” Dr. Leng noted.
Future studies are needed to explore underlying mechanisms and to determine whether circadian disruption itself might contribute to the development of Parkinson’s disease, the researchers said.
“If there is a causal link, then using techniques to improve circadian rhythm could help to prevent or slow the onset of Parkinson’s disease,” Dr. Leng suggested. There are many established therapies that act on circadian rhythm including bright light therapy, melatonin, and chronotherapy, she added.
Support for this study was provided by the National Institute on Aging (NIA); the National Institute of Arthritis and Musculoskeletal and Skin Diseases; the National Center for Advancing Translational Sciences; the National Heart, Lung, and Blood Institute; and the Weill Pilot Award. Dr. Leng reported grants from the NIA and the University of California, San Francisco, Weill Institute for Neurosciences during the conduct of the study; and grants from Global Brain Health Institute, the Alzheimer’s Association, and the Alzheimer’s Society outside the submitted work.
A version of this article originally appeared on Medscape.com.
a new study suggests. “We found that men with abnormal circadian rhythms had three times the risk of developing Parkinson’s disease over an 11-year follow-up period,” lead author, Yue Leng, MD, University of California, San Francisco, said in an interview.
“If confirmed to be a risk factor for Parkinson’s disease, then circadian rhythmicity could be a promising intervention target and will open new opportunities for the prevention and management of Parkinson’s disease,” the researchers concluded.
The study was published online in JAMA Neurology on June 15.
Circadian disruption is very common in neurodegenerative diseases such as Parkinson’s disease, but there isn’t much information on how it may predict the disease, Dr. Leng explained. “We wanted to see whether circadian abnormalities may predict Parkinson’s disease,” she said. “Parkinson’s disease has a long prodromal phase where brain changes have started to occur but no clinical symptoms have become evident. It would be useful to be able to identify these patients, and maybe changes in circadian rhythms may help us to do that,” she added.
For the study, the researchers analyzed data from 2,930 community-dwelling men aged 65 years or older (mean age, 76 years) who participated in the Osteoporotic Fractures in Men Study, in which they underwent comprehensive sleep and rest-activity rhythms assessment. “Patterns of rest and activity were measured with an actigraph device, which is worn on the wrist like a watch and captures movements which are translated into a rest-activity rhythm model – one of the most commonly used and evidence-based measures of circadian rhythm,” Dr. Leng said. Men were asked to wear the actigraphs continuously for a minimum of three 24-hour periods.
Results showed that 78 men (2.7%) developed Parkinson’s disease during the 11-year follow-up. After accounting for all covariates, the risk of Parkinson’s disease increased with decreasing circadian amplitude (strength of the rhythm) with an odds ratio of 1.77 per each decrease by one standard deviation; mesor (mean level of activity) with an odds ratio of 1.64; or robustness (how closely activity follows a 24-hour pattern) with an odds ratio of 1.54.
Those in the lowest quartile of amplitude, mesor, or robustness had approximately three times the risk of developing Parkinson’s disease compared with those in the highest quartile of amplitude. The association remained after further adjustment for nighttime sleep disturbances.
“It has previously been shown that daytime napping has been linked to risk of developing Parkinson’s disease. Now we have shown that abnormalities in the overall 24-hour circadian rest activity rhythm are also present in the prodromal phase of Parkinson’s disease, and this association was independent of several confounders, including nighttime sleep disturbances,” Dr. Leng said.
“This raises awareness of the importance of circadian rhythm in older individuals and changes in their 24-hour pattern of behavior could be an early signal of Parkinson’s disease,” she said.
“This study does not tell us whether these circadian changes are causal for Parkinson’s or not,” Dr. Leng noted.
Future studies are needed to explore underlying mechanisms and to determine whether circadian disruption itself might contribute to the development of Parkinson’s disease, the researchers said.
“If there is a causal link, then using techniques to improve circadian rhythm could help to prevent or slow the onset of Parkinson’s disease,” Dr. Leng suggested. There are many established therapies that act on circadian rhythm including bright light therapy, melatonin, and chronotherapy, she added.
Support for this study was provided by the National Institute on Aging (NIA); the National Institute of Arthritis and Musculoskeletal and Skin Diseases; the National Center for Advancing Translational Sciences; the National Heart, Lung, and Blood Institute; and the Weill Pilot Award. Dr. Leng reported grants from the NIA and the University of California, San Francisco, Weill Institute for Neurosciences during the conduct of the study; and grants from Global Brain Health Institute, the Alzheimer’s Association, and the Alzheimer’s Society outside the submitted work.
A version of this article originally appeared on Medscape.com.
FROM JAMA NEUROLOGY
Relapsing, progressive MS classifications should be abandoned
Most disability accumulation in relapsing multiple sclerosis (MS) is not associated with overt relapses, challenging the current clinical distinction of relapsing and progressive forms of the disease, a new analysis shows. “We have to abandon the distinction between relapsing and progressive MS being different populations,” said lead author Ludwig Kappos, MD, University of Basel (Switzerland). “The disease appears to be more of a continuum of disability progression, which is sometimes also accompanied by relapses.”
The analysis was published online June 8 in JAMA Neurology.
Assessing disability progression
Noting that there are mounting data to suggest patients with relapsing MS frequently experience worsening disability over time – even when relapse activity appears well controlled – the researchers aimed to investigate the relative contributions of progression independent of relapse activity and relapse-associated worsening to overall accumulating disability in patients with relapsing multiple sclerosis. To do this, they analyzed data from two identical randomized clinical trials (OPERA I and OPERA II) conducted between 2011 and 2015, which compared treatment with the new B-cell–depleting therapy ocrelizumab with interferon beta-1a in 1,656 patients with relapsing MS.
Confirmed disability accumulation was defined by an increase in 1 or more of 3 measures (Expanded Disability Status Scale, timed 25-ft walk, or 9-hole peg test), confirmed after 3 or 6 months, and was classified as being related to a clinical relapse or occurring in the absence of a relapse.
Results showed that after 96 weeks (1.8 years) of treatment, 12-week composite confirmed disability accumulation had occurred in 29.6% of patients receiving interferon beta-1a and 21.1% of those given ocrelizumab; 24-week composite confirmed disability accumulation occurred in 22.7% of interferon beta-1a patients and 16.2% of the ocrelizumab group.
In both treatment groups, the vast majority of events contributing to disability accumulation occurred independently of relapse activity. In the interferon group, 78% of events contributing to 12-week confirmed disability accumulation and 80.6% of events contributing to 24-week confirmed disability accumulation occurred in the absence of clinical relapses, with the corresponding figures in the ocrelizumab group being 88.0% (12 weeks) and 89.1% (24 weeks).
Only a minority of patients (about 17% in both groups) had confirmed disability accumulation accompanied by clinical relapses. Very few patients with confirmed disability accumulation (4% to 5%) experienced disability worsening both associated and independent of relapses. Ocrelizumab was associated with a reduced risk of both relapse-associated and relapse-independent confirmed disability accumulation, compared with interferon beta-1a.
“We found that there was progression of disability in both groups, and the really astonishing finding was that although all patients were classified as having relapsing remitting MS, actually most of the disability progression occurred without preceding relapses,” Dr. Kappos commented. He noted that there have been two previous observational studies that have shown a high rate of disability progressions without temporal association to relapses in relapsing remitting patients, but this is the first time that this progression of disability independent of relapses has been shown in the controlled setting of two prospective, randomized clinical trials over a 2-year period.
“While we expected to see some disability progression independent of relapses, we were surprised to see that the disability progression occurring in both studies was almost exclusively happening without temporal relation to relapses. That was certainly an unexpected finding,” Dr. Kappos said. “These observations make it difficult to keep the current definitions of ‘relapsing remitting’ and ‘secondary progressive’ MS, [ones] that suggest a clear-cut distinction marked by the presence or absence of relapses. This can no longer be justified,” he stressed.
“We are not saying that relapses do not contribute to disability progression. There are a lot of data to support the fact that they do. But I think what we might be seeing is that the drug therapy is quite effective in reducing disability due to relapses but only partially effective in reducing progression independent of relapses,” Dr. Kappos explained.
Although there have been many advances in reducing relapses with drug therapy, focus now needs to shift to the other more continuous process of disability progression independent of relapses, Dr. Kappos said. “There is still a lot of room for improvement here.”
“If continuous progression independent of relapses is already present in the early phases of MS, it is reasonable to study the effects of intervention on steady progression already in this early phase,” he noted. “This might help to capture patients at earlier stages who better respond to treatment aimed at halting progression.”
Dr. Kappos also called for more subtle measurements of disability than the EDSS alone, including measures such as the 9-hole peg test and the 25-ft walk as they did in this analysis. But other measures could also be added that would characterize continuous disease activity and progression, such as laboratory values (e.g., neurofilament light chain) and advanced, more tissue-specific quantitative MRI techniques and digital biomarkers to detect subtle changes in neurologic function.
An artificial distinction?
Commenting on the study, Jeffrey Cohen, MD, director of the experimental therapeutics program at the Mellen Center for Multiple Sclerosis Treatment and Research, Cleveland Clinic, said he too sees very little distinction between relapsing remitting and progressive forms of the disease.
“This study confirms what has been suspected for quite a few years –that if one looks sufficiently and carefully, there is gradual worsening of some aspects of the disease in many patients from the earliest stages,” Dr. Cohen said. “Conversely, some patients with progressive MS have superimposed relapses or MRI lesion activity.
“Thus, the distinction between relapsing-remitting and progressive MS subtypes appears artificial,” he concluded.
This study was sponsored by F. Hoffmann–La Roche. Dr. Kappos has received research support from the company.
This article first appeared on Medscape.com.
Most disability accumulation in relapsing multiple sclerosis (MS) is not associated with overt relapses, challenging the current clinical distinction of relapsing and progressive forms of the disease, a new analysis shows. “We have to abandon the distinction between relapsing and progressive MS being different populations,” said lead author Ludwig Kappos, MD, University of Basel (Switzerland). “The disease appears to be more of a continuum of disability progression, which is sometimes also accompanied by relapses.”
The analysis was published online June 8 in JAMA Neurology.
Assessing disability progression
Noting that there are mounting data to suggest patients with relapsing MS frequently experience worsening disability over time – even when relapse activity appears well controlled – the researchers aimed to investigate the relative contributions of progression independent of relapse activity and relapse-associated worsening to overall accumulating disability in patients with relapsing multiple sclerosis. To do this, they analyzed data from two identical randomized clinical trials (OPERA I and OPERA II) conducted between 2011 and 2015, which compared treatment with the new B-cell–depleting therapy ocrelizumab with interferon beta-1a in 1,656 patients with relapsing MS.
Confirmed disability accumulation was defined by an increase in 1 or more of 3 measures (Expanded Disability Status Scale, timed 25-ft walk, or 9-hole peg test), confirmed after 3 or 6 months, and was classified as being related to a clinical relapse or occurring in the absence of a relapse.
Results showed that after 96 weeks (1.8 years) of treatment, 12-week composite confirmed disability accumulation had occurred in 29.6% of patients receiving interferon beta-1a and 21.1% of those given ocrelizumab; 24-week composite confirmed disability accumulation occurred in 22.7% of interferon beta-1a patients and 16.2% of the ocrelizumab group.
In both treatment groups, the vast majority of events contributing to disability accumulation occurred independently of relapse activity. In the interferon group, 78% of events contributing to 12-week confirmed disability accumulation and 80.6% of events contributing to 24-week confirmed disability accumulation occurred in the absence of clinical relapses, with the corresponding figures in the ocrelizumab group being 88.0% (12 weeks) and 89.1% (24 weeks).
Only a minority of patients (about 17% in both groups) had confirmed disability accumulation accompanied by clinical relapses. Very few patients with confirmed disability accumulation (4% to 5%) experienced disability worsening both associated and independent of relapses. Ocrelizumab was associated with a reduced risk of both relapse-associated and relapse-independent confirmed disability accumulation, compared with interferon beta-1a.
“We found that there was progression of disability in both groups, and the really astonishing finding was that although all patients were classified as having relapsing remitting MS, actually most of the disability progression occurred without preceding relapses,” Dr. Kappos commented. He noted that there have been two previous observational studies that have shown a high rate of disability progressions without temporal association to relapses in relapsing remitting patients, but this is the first time that this progression of disability independent of relapses has been shown in the controlled setting of two prospective, randomized clinical trials over a 2-year period.
“While we expected to see some disability progression independent of relapses, we were surprised to see that the disability progression occurring in both studies was almost exclusively happening without temporal relation to relapses. That was certainly an unexpected finding,” Dr. Kappos said. “These observations make it difficult to keep the current definitions of ‘relapsing remitting’ and ‘secondary progressive’ MS, [ones] that suggest a clear-cut distinction marked by the presence or absence of relapses. This can no longer be justified,” he stressed.
“We are not saying that relapses do not contribute to disability progression. There are a lot of data to support the fact that they do. But I think what we might be seeing is that the drug therapy is quite effective in reducing disability due to relapses but only partially effective in reducing progression independent of relapses,” Dr. Kappos explained.
Although there have been many advances in reducing relapses with drug therapy, focus now needs to shift to the other more continuous process of disability progression independent of relapses, Dr. Kappos said. “There is still a lot of room for improvement here.”
“If continuous progression independent of relapses is already present in the early phases of MS, it is reasonable to study the effects of intervention on steady progression already in this early phase,” he noted. “This might help to capture patients at earlier stages who better respond to treatment aimed at halting progression.”
Dr. Kappos also called for more subtle measurements of disability than the EDSS alone, including measures such as the 9-hole peg test and the 25-ft walk as they did in this analysis. But other measures could also be added that would characterize continuous disease activity and progression, such as laboratory values (e.g., neurofilament light chain) and advanced, more tissue-specific quantitative MRI techniques and digital biomarkers to detect subtle changes in neurologic function.
An artificial distinction?
Commenting on the study, Jeffrey Cohen, MD, director of the experimental therapeutics program at the Mellen Center for Multiple Sclerosis Treatment and Research, Cleveland Clinic, said he too sees very little distinction between relapsing remitting and progressive forms of the disease.
“This study confirms what has been suspected for quite a few years –that if one looks sufficiently and carefully, there is gradual worsening of some aspects of the disease in many patients from the earliest stages,” Dr. Cohen said. “Conversely, some patients with progressive MS have superimposed relapses or MRI lesion activity.
“Thus, the distinction between relapsing-remitting and progressive MS subtypes appears artificial,” he concluded.
This study was sponsored by F. Hoffmann–La Roche. Dr. Kappos has received research support from the company.
This article first appeared on Medscape.com.
Most disability accumulation in relapsing multiple sclerosis (MS) is not associated with overt relapses, challenging the current clinical distinction of relapsing and progressive forms of the disease, a new analysis shows. “We have to abandon the distinction between relapsing and progressive MS being different populations,” said lead author Ludwig Kappos, MD, University of Basel (Switzerland). “The disease appears to be more of a continuum of disability progression, which is sometimes also accompanied by relapses.”
The analysis was published online June 8 in JAMA Neurology.
Assessing disability progression
Noting that there are mounting data to suggest patients with relapsing MS frequently experience worsening disability over time – even when relapse activity appears well controlled – the researchers aimed to investigate the relative contributions of progression independent of relapse activity and relapse-associated worsening to overall accumulating disability in patients with relapsing multiple sclerosis. To do this, they analyzed data from two identical randomized clinical trials (OPERA I and OPERA II) conducted between 2011 and 2015, which compared treatment with the new B-cell–depleting therapy ocrelizumab with interferon beta-1a in 1,656 patients with relapsing MS.
Confirmed disability accumulation was defined by an increase in 1 or more of 3 measures (Expanded Disability Status Scale, timed 25-ft walk, or 9-hole peg test), confirmed after 3 or 6 months, and was classified as being related to a clinical relapse or occurring in the absence of a relapse.
Results showed that after 96 weeks (1.8 years) of treatment, 12-week composite confirmed disability accumulation had occurred in 29.6% of patients receiving interferon beta-1a and 21.1% of those given ocrelizumab; 24-week composite confirmed disability accumulation occurred in 22.7% of interferon beta-1a patients and 16.2% of the ocrelizumab group.
In both treatment groups, the vast majority of events contributing to disability accumulation occurred independently of relapse activity. In the interferon group, 78% of events contributing to 12-week confirmed disability accumulation and 80.6% of events contributing to 24-week confirmed disability accumulation occurred in the absence of clinical relapses, with the corresponding figures in the ocrelizumab group being 88.0% (12 weeks) and 89.1% (24 weeks).
Only a minority of patients (about 17% in both groups) had confirmed disability accumulation accompanied by clinical relapses. Very few patients with confirmed disability accumulation (4% to 5%) experienced disability worsening both associated and independent of relapses. Ocrelizumab was associated with a reduced risk of both relapse-associated and relapse-independent confirmed disability accumulation, compared with interferon beta-1a.
“We found that there was progression of disability in both groups, and the really astonishing finding was that although all patients were classified as having relapsing remitting MS, actually most of the disability progression occurred without preceding relapses,” Dr. Kappos commented. He noted that there have been two previous observational studies that have shown a high rate of disability progressions without temporal association to relapses in relapsing remitting patients, but this is the first time that this progression of disability independent of relapses has been shown in the controlled setting of two prospective, randomized clinical trials over a 2-year period.
“While we expected to see some disability progression independent of relapses, we were surprised to see that the disability progression occurring in both studies was almost exclusively happening without temporal relation to relapses. That was certainly an unexpected finding,” Dr. Kappos said. “These observations make it difficult to keep the current definitions of ‘relapsing remitting’ and ‘secondary progressive’ MS, [ones] that suggest a clear-cut distinction marked by the presence or absence of relapses. This can no longer be justified,” he stressed.
“We are not saying that relapses do not contribute to disability progression. There are a lot of data to support the fact that they do. But I think what we might be seeing is that the drug therapy is quite effective in reducing disability due to relapses but only partially effective in reducing progression independent of relapses,” Dr. Kappos explained.
Although there have been many advances in reducing relapses with drug therapy, focus now needs to shift to the other more continuous process of disability progression independent of relapses, Dr. Kappos said. “There is still a lot of room for improvement here.”
“If continuous progression independent of relapses is already present in the early phases of MS, it is reasonable to study the effects of intervention on steady progression already in this early phase,” he noted. “This might help to capture patients at earlier stages who better respond to treatment aimed at halting progression.”
Dr. Kappos also called for more subtle measurements of disability than the EDSS alone, including measures such as the 9-hole peg test and the 25-ft walk as they did in this analysis. But other measures could also be added that would characterize continuous disease activity and progression, such as laboratory values (e.g., neurofilament light chain) and advanced, more tissue-specific quantitative MRI techniques and digital biomarkers to detect subtle changes in neurologic function.
An artificial distinction?
Commenting on the study, Jeffrey Cohen, MD, director of the experimental therapeutics program at the Mellen Center for Multiple Sclerosis Treatment and Research, Cleveland Clinic, said he too sees very little distinction between relapsing remitting and progressive forms of the disease.
“This study confirms what has been suspected for quite a few years –that if one looks sufficiently and carefully, there is gradual worsening of some aspects of the disease in many patients from the earliest stages,” Dr. Cohen said. “Conversely, some patients with progressive MS have superimposed relapses or MRI lesion activity.
“Thus, the distinction between relapsing-remitting and progressive MS subtypes appears artificial,” he concluded.
This study was sponsored by F. Hoffmann–La Roche. Dr. Kappos has received research support from the company.
This article first appeared on Medscape.com.
Huntington’s disease biomarkers appear 24 years before clinical symptoms
, according to a study published in the June Lancet Neurology. The data come from the Huntington’s disease Young Adult Study (HD-YAS) conducted in the United Kingdom.
The genetic cause of Huntington’s disease provides a potential target for biomarker treatment, wrote joint first authors Rachael I. Scahill, PhD, and Paul Zeun, BMBS, of University College London and colleagues.
“A detailed characterization of the premanifest period in Huntington’s disease is crucial for disease staging, informing the optimum time to initiate treatments, and identifying biomarkers for future trials in people with premanifest Huntington’s disease (preHD),” they said.
Identifying biomarkers of pre-Huntington’s disease
For their study, the researchers recruited 64 young adults with presymptomatic Huntington’s disease (preHD) and 67 controls, with an average age of 29 years. Brain imaging was conducted between Aug. 2, 2017, and April 25, 2019. Individuals with preexisting measurable cognitive and psychiatric disorders were excluded.
The researchers found no significant evidence of cognitive or psychiatric impairment in the preHD group at 23.6 years from the predicted onset of symptoms. The preHD group showed smaller putamen volumes, compared with controls, but this difference had no apparent relation to the timing of symptom onset, the researchers said.
Brain imaging revealed elevations in the CSF mutant huntingtin, neurofilament light protein (NfL), YKL-40, and plasma NfL among individuals with preHD, compared with controls. Of these, CSF NfL showed the highest effect size of measures in the study and showed a significant increasing association with estimated years to the onset of clinical symptoms of HD carriers. Overall, 53% of individuals with preHD had CSF NfL values in the normal range, and 47% had elevated values, compared with controls.
“NfL is therefore a potential candidate to provide a measure of disease progression in early preHD and might eventually be used as a marker of response to treatment in future preventive trials,” the researchers said.
The study findings were limited by several factors including potential underpowering to detect associations with age and CAG gene segment repeats, the researchers noted.
However, “By identifying a cohort of individuals with preHD and no detectable functional impairment but who begin to exhibit subtle elevations in select biological measures of neurodegeneration, we have highlighted a crucial point early in the disease process,” they concluded.
“Intervening at this stage might offer the prospect of delaying or preventing further neurodegeneration while function is intact, giving gene carriers many more years of life without impairment,” they added.
What is the best window for treatment?
The study is “particularly important since the absence of any subclinical symptoms in preHD individuals far from onset shows that the abnormal developmental aspect of Huntington’s disease has no substantial effect on adults’ clinical pattern,” wrote Anne-Catherine Bachoud-Lévi, MD, of Université Paris Est, Créteil, France, in an accompanying comment.
“The most robust findings of [the study] are the sensitiveness of NfL, compared with mutant huntingtin in CSF of individuals with preHD, and that degenerative rather than developmental disorders are clinically relevant,” she said. However, potential limitations to the study include the exclusion absence of language and calculation as part of the cognitive assessments, she noted. “Ideally, more sensitive cognitive tasks including these domains should be designed for preHD participants.”
In addition, the risks versus benefits of any long-term treatment must be considered, Dr. Bachoud-Lévi noted.
“The best window for treatment should instead target the time when a detectable subclinical slope of cognitive performance allows for predicting disease onset within a few years,” she said. “Turning to machine learning methodology, such as that in oncology, might also permit combining the best window and the best disease-modifying therapy for individuals with preHD,” she added.
The study was supported by the Wellcome Trust, CHDI Foundation. The researchers had no financial conflicts to disclose. Dr. Bachoud-Lévi disclosed grants and personal fees from Roche, and grants from the French Ministry of Health and Direction de la Recherche Clinique.
SOURCES: Scahill RI et al. Lancet Neurol. 2020 June;19:502-12; Bachoud-Lévi A-C. Lancet Neurol. 2020 June;19:473-5.
, according to a study published in the June Lancet Neurology. The data come from the Huntington’s disease Young Adult Study (HD-YAS) conducted in the United Kingdom.
The genetic cause of Huntington’s disease provides a potential target for biomarker treatment, wrote joint first authors Rachael I. Scahill, PhD, and Paul Zeun, BMBS, of University College London and colleagues.
“A detailed characterization of the premanifest period in Huntington’s disease is crucial for disease staging, informing the optimum time to initiate treatments, and identifying biomarkers for future trials in people with premanifest Huntington’s disease (preHD),” they said.
Identifying biomarkers of pre-Huntington’s disease
For their study, the researchers recruited 64 young adults with presymptomatic Huntington’s disease (preHD) and 67 controls, with an average age of 29 years. Brain imaging was conducted between Aug. 2, 2017, and April 25, 2019. Individuals with preexisting measurable cognitive and psychiatric disorders were excluded.
The researchers found no significant evidence of cognitive or psychiatric impairment in the preHD group at 23.6 years from the predicted onset of symptoms. The preHD group showed smaller putamen volumes, compared with controls, but this difference had no apparent relation to the timing of symptom onset, the researchers said.
Brain imaging revealed elevations in the CSF mutant huntingtin, neurofilament light protein (NfL), YKL-40, and plasma NfL among individuals with preHD, compared with controls. Of these, CSF NfL showed the highest effect size of measures in the study and showed a significant increasing association with estimated years to the onset of clinical symptoms of HD carriers. Overall, 53% of individuals with preHD had CSF NfL values in the normal range, and 47% had elevated values, compared with controls.
“NfL is therefore a potential candidate to provide a measure of disease progression in early preHD and might eventually be used as a marker of response to treatment in future preventive trials,” the researchers said.
The study findings were limited by several factors including potential underpowering to detect associations with age and CAG gene segment repeats, the researchers noted.
However, “By identifying a cohort of individuals with preHD and no detectable functional impairment but who begin to exhibit subtle elevations in select biological measures of neurodegeneration, we have highlighted a crucial point early in the disease process,” they concluded.
“Intervening at this stage might offer the prospect of delaying or preventing further neurodegeneration while function is intact, giving gene carriers many more years of life without impairment,” they added.
What is the best window for treatment?
The study is “particularly important since the absence of any subclinical symptoms in preHD individuals far from onset shows that the abnormal developmental aspect of Huntington’s disease has no substantial effect on adults’ clinical pattern,” wrote Anne-Catherine Bachoud-Lévi, MD, of Université Paris Est, Créteil, France, in an accompanying comment.
“The most robust findings of [the study] are the sensitiveness of NfL, compared with mutant huntingtin in CSF of individuals with preHD, and that degenerative rather than developmental disorders are clinically relevant,” she said. However, potential limitations to the study include the exclusion absence of language and calculation as part of the cognitive assessments, she noted. “Ideally, more sensitive cognitive tasks including these domains should be designed for preHD participants.”
In addition, the risks versus benefits of any long-term treatment must be considered, Dr. Bachoud-Lévi noted.
“The best window for treatment should instead target the time when a detectable subclinical slope of cognitive performance allows for predicting disease onset within a few years,” she said. “Turning to machine learning methodology, such as that in oncology, might also permit combining the best window and the best disease-modifying therapy for individuals with preHD,” she added.
The study was supported by the Wellcome Trust, CHDI Foundation. The researchers had no financial conflicts to disclose. Dr. Bachoud-Lévi disclosed grants and personal fees from Roche, and grants from the French Ministry of Health and Direction de la Recherche Clinique.
SOURCES: Scahill RI et al. Lancet Neurol. 2020 June;19:502-12; Bachoud-Lévi A-C. Lancet Neurol. 2020 June;19:473-5.
, according to a study published in the June Lancet Neurology. The data come from the Huntington’s disease Young Adult Study (HD-YAS) conducted in the United Kingdom.
The genetic cause of Huntington’s disease provides a potential target for biomarker treatment, wrote joint first authors Rachael I. Scahill, PhD, and Paul Zeun, BMBS, of University College London and colleagues.
“A detailed characterization of the premanifest period in Huntington’s disease is crucial for disease staging, informing the optimum time to initiate treatments, and identifying biomarkers for future trials in people with premanifest Huntington’s disease (preHD),” they said.
Identifying biomarkers of pre-Huntington’s disease
For their study, the researchers recruited 64 young adults with presymptomatic Huntington’s disease (preHD) and 67 controls, with an average age of 29 years. Brain imaging was conducted between Aug. 2, 2017, and April 25, 2019. Individuals with preexisting measurable cognitive and psychiatric disorders were excluded.
The researchers found no significant evidence of cognitive or psychiatric impairment in the preHD group at 23.6 years from the predicted onset of symptoms. The preHD group showed smaller putamen volumes, compared with controls, but this difference had no apparent relation to the timing of symptom onset, the researchers said.
Brain imaging revealed elevations in the CSF mutant huntingtin, neurofilament light protein (NfL), YKL-40, and plasma NfL among individuals with preHD, compared with controls. Of these, CSF NfL showed the highest effect size of measures in the study and showed a significant increasing association with estimated years to the onset of clinical symptoms of HD carriers. Overall, 53% of individuals with preHD had CSF NfL values in the normal range, and 47% had elevated values, compared with controls.
“NfL is therefore a potential candidate to provide a measure of disease progression in early preHD and might eventually be used as a marker of response to treatment in future preventive trials,” the researchers said.
The study findings were limited by several factors including potential underpowering to detect associations with age and CAG gene segment repeats, the researchers noted.
However, “By identifying a cohort of individuals with preHD and no detectable functional impairment but who begin to exhibit subtle elevations in select biological measures of neurodegeneration, we have highlighted a crucial point early in the disease process,” they concluded.
“Intervening at this stage might offer the prospect of delaying or preventing further neurodegeneration while function is intact, giving gene carriers many more years of life without impairment,” they added.
What is the best window for treatment?
The study is “particularly important since the absence of any subclinical symptoms in preHD individuals far from onset shows that the abnormal developmental aspect of Huntington’s disease has no substantial effect on adults’ clinical pattern,” wrote Anne-Catherine Bachoud-Lévi, MD, of Université Paris Est, Créteil, France, in an accompanying comment.
“The most robust findings of [the study] are the sensitiveness of NfL, compared with mutant huntingtin in CSF of individuals with preHD, and that degenerative rather than developmental disorders are clinically relevant,” she said. However, potential limitations to the study include the exclusion absence of language and calculation as part of the cognitive assessments, she noted. “Ideally, more sensitive cognitive tasks including these domains should be designed for preHD participants.”
In addition, the risks versus benefits of any long-term treatment must be considered, Dr. Bachoud-Lévi noted.
“The best window for treatment should instead target the time when a detectable subclinical slope of cognitive performance allows for predicting disease onset within a few years,” she said. “Turning to machine learning methodology, such as that in oncology, might also permit combining the best window and the best disease-modifying therapy for individuals with preHD,” she added.
The study was supported by the Wellcome Trust, CHDI Foundation. The researchers had no financial conflicts to disclose. Dr. Bachoud-Lévi disclosed grants and personal fees from Roche, and grants from the French Ministry of Health and Direction de la Recherche Clinique.
SOURCES: Scahill RI et al. Lancet Neurol. 2020 June;19:502-12; Bachoud-Lévi A-C. Lancet Neurol. 2020 June;19:473-5.
FROM LANCET NEUROLOGY
COVID-19 neurologic effects: Does the virus directly attack the brain?
A new review article summarizes what is known so far, and what clinicians need to look out for.
“We frequently see neurological conditions in people with COVID-19, but we understand very little about these effects. Is it the virus entering the brain/nerves or are they a result of a general inflammation or immune response – a bystander effect of people being severely ill. It is probably a combination of both,” said senior author Serena Spudich, MD, Gilbert H. Glaser Professor of Neurology; division chief of neurological infections & global neurology; and codirector of the Center for Neuroepidemiology and Clinical Neurological Research at Yale University, New Haven, Conn.
“Our message is that there are fairly frequent neurological sequelae of COVID-19 and we need to be alert to these, and to try to understand the potential long-term consequences,” she said.
The review was published online May 29 in JAMA Neurology.
Brain changes linked to loss of smell
In a separate article also published online in JAMA Neurology the same day, an Italian group describes a COVID-19 patient with anosmia (loss of sense of smell) who showed brain abnormalities on MRI in the areas associated with smell – the right gyrus rectus and the olfactory bulbs. These changes were resolved on later scan and the patient recovered her sense of smell.
“Based on the MRI findings, we can speculate that SARS-CoV-2 might invade the brain through the olfactory pathway,” conclude the researchers, led by first author Letterio S. Politi, MD, of the department of neuroradiology at IRCCS Istituto Clinico Humanitas and Humanitas University, Milan, Italy.
Can coronaviruses enter the CNS?
Dr. Spudich described this case report as “compelling evidence suggesting that loss of smell is a neurologic effect.”
“Loss of smell and/or taste is a common symptom in COVID-19, so this may suggest that an awful lot of people have some neurological involvement,” Dr. Spudich commented. “While a transient loss of smell or taste is not serious, if the virus has infected brain tissue the question is could this then spread to other parts of the brain and cause other more serious neurological effects,” she added.
In their review article, Dr. Spudich and colleagues present evidence showing that coronaviruses can enter the CNS.
“We know that SARS-1 and MERS have been shown to enter the nervous system and several coronaviruses have been shown to cause direct brain effects,” she said. “There is also some evidence that SARS-CoV-2 can do this too. As well as these latest MRI findings linked to loss of smell, there is a report of the virus being found in endothelial cells in the brain and a French autopsy study has also detected virus in the brain.”
Complications of other systemic effects?
Dr. Spudich is a neurologist specializing in neurologic consequences of infectious disease. “We don’t normally have such vast numbers of patients but in the last 3 months there has been an avalanche,” she says. From her personal experience, she believes the majority of neurologic symptoms in COVID-19 patients are most probably complications of other systemic effects, such as kidney, heart, or liver problems. But there is likely also a direct viral effect on the CNS in some patients.
“Reports from China suggested that serious neurologic effects were present in about one-third of hospitalized COVID-19 patients. I would say in our experience the figure would be less than that – maybe around 10%,” she noted.
Some COVID-19 patients are presenting with primary neurologic symptoms. For example, an elderly person may first develop confusion rather than a cough or shortness of breath; others have had severe headache as an initial COVID-19 symptom, Dr. Spudich reported. “Medical staff need to be aware of this – a severe headache in a patient who doesn’t normally get headaches could be a sign of the virus.”
Some of the neurologic symptoms could be caused by autoimmunity. Dr. Spudich explained that, in acute HIV infection a small proportion of patients can first present with autoimmune neurologic effects such as Guillain-Barré syndrome, an autoimmune condition of the nerves which causes a tingling sensation in the hands and feet. “This is well described in HIV, but we are also now seeing this in COVID-19 patients too,” she said. “A panoply of conditions can be caused by autoimmunity.”
On the increase in strokes that has been reported in COVID-19 patients, Dr. Spudich said, “this could be due to direct effects of the virus (e.g., causing an increase in coagulation or infecting the endothelial cells in the brain) or it could just be the final trigger for patients who were at risk of stroke anyway.”
There have been some very high-profile reports of younger patients with major strokes, she said, “but we haven’t seen that in our hospital. For the most part in my experience, strokes are happening in older COVID-19 patients with stroke risk factors such as AF [atrial fibrillation], hypertension, and diabetes. We haven’t seen a preponderance of strokes in young, otherwise healthy people.”
Even in patients who have neurologic effects as the first sign of COVID-19 infection, it is not known whether these symptoms are caused directly by the virus.
“We know that flu can cause people to have headaches, but that is because of an increase in inflammatory cytokines. On the other hand, patients with acute HIV infection often have headaches as a result of the virus getting into the brain. We don’t know where in this [cluster] COVID-19 virus falls,” Dr. Spudich said.
Much is still unknown
“The information we have is very sparse at this point. We need far more systematic information on this from CSF samples and imaging.” Dr. Spudich urged clinicians to try to collect such information in patients with neurologic symptoms.
Acknowledging that fewer such tests are being done at present because of concerns over infection risk, Dr. Spudich suggested that some changes in procedure may help. “In our hospital we have a portable MRI scanner which can be brought to the patient. This means the patient does not have to move across the hospital for a scan. This helps us to decide whether the patient has had a stroke, which can be missed when patients are on a ventilator.”
It is also unclear whether the neurologic effects seen during COVID-19 infection will last long term.
Dr. Spudich noted that there have been reports of COVID-19 patients discharged from intensive care having difficulty with higher cognitive function for some time thereafter. “This can happen after being in ICU but is it more pronounced in COVID-19 patients? An ongoing study is underway to look at this,” she said.
This article first appeared on Medscape.com.
A new review article summarizes what is known so far, and what clinicians need to look out for.
“We frequently see neurological conditions in people with COVID-19, but we understand very little about these effects. Is it the virus entering the brain/nerves or are they a result of a general inflammation or immune response – a bystander effect of people being severely ill. It is probably a combination of both,” said senior author Serena Spudich, MD, Gilbert H. Glaser Professor of Neurology; division chief of neurological infections & global neurology; and codirector of the Center for Neuroepidemiology and Clinical Neurological Research at Yale University, New Haven, Conn.
“Our message is that there are fairly frequent neurological sequelae of COVID-19 and we need to be alert to these, and to try to understand the potential long-term consequences,” she said.
The review was published online May 29 in JAMA Neurology.
Brain changes linked to loss of smell
In a separate article also published online in JAMA Neurology the same day, an Italian group describes a COVID-19 patient with anosmia (loss of sense of smell) who showed brain abnormalities on MRI in the areas associated with smell – the right gyrus rectus and the olfactory bulbs. These changes were resolved on later scan and the patient recovered her sense of smell.
“Based on the MRI findings, we can speculate that SARS-CoV-2 might invade the brain through the olfactory pathway,” conclude the researchers, led by first author Letterio S. Politi, MD, of the department of neuroradiology at IRCCS Istituto Clinico Humanitas and Humanitas University, Milan, Italy.
Can coronaviruses enter the CNS?
Dr. Spudich described this case report as “compelling evidence suggesting that loss of smell is a neurologic effect.”
“Loss of smell and/or taste is a common symptom in COVID-19, so this may suggest that an awful lot of people have some neurological involvement,” Dr. Spudich commented. “While a transient loss of smell or taste is not serious, if the virus has infected brain tissue the question is could this then spread to other parts of the brain and cause other more serious neurological effects,” she added.
In their review article, Dr. Spudich and colleagues present evidence showing that coronaviruses can enter the CNS.
“We know that SARS-1 and MERS have been shown to enter the nervous system and several coronaviruses have been shown to cause direct brain effects,” she said. “There is also some evidence that SARS-CoV-2 can do this too. As well as these latest MRI findings linked to loss of smell, there is a report of the virus being found in endothelial cells in the brain and a French autopsy study has also detected virus in the brain.”
Complications of other systemic effects?
Dr. Spudich is a neurologist specializing in neurologic consequences of infectious disease. “We don’t normally have such vast numbers of patients but in the last 3 months there has been an avalanche,” she says. From her personal experience, she believes the majority of neurologic symptoms in COVID-19 patients are most probably complications of other systemic effects, such as kidney, heart, or liver problems. But there is likely also a direct viral effect on the CNS in some patients.
“Reports from China suggested that serious neurologic effects were present in about one-third of hospitalized COVID-19 patients. I would say in our experience the figure would be less than that – maybe around 10%,” she noted.
Some COVID-19 patients are presenting with primary neurologic symptoms. For example, an elderly person may first develop confusion rather than a cough or shortness of breath; others have had severe headache as an initial COVID-19 symptom, Dr. Spudich reported. “Medical staff need to be aware of this – a severe headache in a patient who doesn’t normally get headaches could be a sign of the virus.”
Some of the neurologic symptoms could be caused by autoimmunity. Dr. Spudich explained that, in acute HIV infection a small proportion of patients can first present with autoimmune neurologic effects such as Guillain-Barré syndrome, an autoimmune condition of the nerves which causes a tingling sensation in the hands and feet. “This is well described in HIV, but we are also now seeing this in COVID-19 patients too,” she said. “A panoply of conditions can be caused by autoimmunity.”
On the increase in strokes that has been reported in COVID-19 patients, Dr. Spudich said, “this could be due to direct effects of the virus (e.g., causing an increase in coagulation or infecting the endothelial cells in the brain) or it could just be the final trigger for patients who were at risk of stroke anyway.”
There have been some very high-profile reports of younger patients with major strokes, she said, “but we haven’t seen that in our hospital. For the most part in my experience, strokes are happening in older COVID-19 patients with stroke risk factors such as AF [atrial fibrillation], hypertension, and diabetes. We haven’t seen a preponderance of strokes in young, otherwise healthy people.”
Even in patients who have neurologic effects as the first sign of COVID-19 infection, it is not known whether these symptoms are caused directly by the virus.
“We know that flu can cause people to have headaches, but that is because of an increase in inflammatory cytokines. On the other hand, patients with acute HIV infection often have headaches as a result of the virus getting into the brain. We don’t know where in this [cluster] COVID-19 virus falls,” Dr. Spudich said.
Much is still unknown
“The information we have is very sparse at this point. We need far more systematic information on this from CSF samples and imaging.” Dr. Spudich urged clinicians to try to collect such information in patients with neurologic symptoms.
Acknowledging that fewer such tests are being done at present because of concerns over infection risk, Dr. Spudich suggested that some changes in procedure may help. “In our hospital we have a portable MRI scanner which can be brought to the patient. This means the patient does not have to move across the hospital for a scan. This helps us to decide whether the patient has had a stroke, which can be missed when patients are on a ventilator.”
It is also unclear whether the neurologic effects seen during COVID-19 infection will last long term.
Dr. Spudich noted that there have been reports of COVID-19 patients discharged from intensive care having difficulty with higher cognitive function for some time thereafter. “This can happen after being in ICU but is it more pronounced in COVID-19 patients? An ongoing study is underway to look at this,” she said.
This article first appeared on Medscape.com.
A new review article summarizes what is known so far, and what clinicians need to look out for.
“We frequently see neurological conditions in people with COVID-19, but we understand very little about these effects. Is it the virus entering the brain/nerves or are they a result of a general inflammation or immune response – a bystander effect of people being severely ill. It is probably a combination of both,” said senior author Serena Spudich, MD, Gilbert H. Glaser Professor of Neurology; division chief of neurological infections & global neurology; and codirector of the Center for Neuroepidemiology and Clinical Neurological Research at Yale University, New Haven, Conn.
“Our message is that there are fairly frequent neurological sequelae of COVID-19 and we need to be alert to these, and to try to understand the potential long-term consequences,” she said.
The review was published online May 29 in JAMA Neurology.
Brain changes linked to loss of smell
In a separate article also published online in JAMA Neurology the same day, an Italian group describes a COVID-19 patient with anosmia (loss of sense of smell) who showed brain abnormalities on MRI in the areas associated with smell – the right gyrus rectus and the olfactory bulbs. These changes were resolved on later scan and the patient recovered her sense of smell.
“Based on the MRI findings, we can speculate that SARS-CoV-2 might invade the brain through the olfactory pathway,” conclude the researchers, led by first author Letterio S. Politi, MD, of the department of neuroradiology at IRCCS Istituto Clinico Humanitas and Humanitas University, Milan, Italy.
Can coronaviruses enter the CNS?
Dr. Spudich described this case report as “compelling evidence suggesting that loss of smell is a neurologic effect.”
“Loss of smell and/or taste is a common symptom in COVID-19, so this may suggest that an awful lot of people have some neurological involvement,” Dr. Spudich commented. “While a transient loss of smell or taste is not serious, if the virus has infected brain tissue the question is could this then spread to other parts of the brain and cause other more serious neurological effects,” she added.
In their review article, Dr. Spudich and colleagues present evidence showing that coronaviruses can enter the CNS.
“We know that SARS-1 and MERS have been shown to enter the nervous system and several coronaviruses have been shown to cause direct brain effects,” she said. “There is also some evidence that SARS-CoV-2 can do this too. As well as these latest MRI findings linked to loss of smell, there is a report of the virus being found in endothelial cells in the brain and a French autopsy study has also detected virus in the brain.”
Complications of other systemic effects?
Dr. Spudich is a neurologist specializing in neurologic consequences of infectious disease. “We don’t normally have such vast numbers of patients but in the last 3 months there has been an avalanche,” she says. From her personal experience, she believes the majority of neurologic symptoms in COVID-19 patients are most probably complications of other systemic effects, such as kidney, heart, or liver problems. But there is likely also a direct viral effect on the CNS in some patients.
“Reports from China suggested that serious neurologic effects were present in about one-third of hospitalized COVID-19 patients. I would say in our experience the figure would be less than that – maybe around 10%,” she noted.
Some COVID-19 patients are presenting with primary neurologic symptoms. For example, an elderly person may first develop confusion rather than a cough or shortness of breath; others have had severe headache as an initial COVID-19 symptom, Dr. Spudich reported. “Medical staff need to be aware of this – a severe headache in a patient who doesn’t normally get headaches could be a sign of the virus.”
Some of the neurologic symptoms could be caused by autoimmunity. Dr. Spudich explained that, in acute HIV infection a small proportion of patients can first present with autoimmune neurologic effects such as Guillain-Barré syndrome, an autoimmune condition of the nerves which causes a tingling sensation in the hands and feet. “This is well described in HIV, but we are also now seeing this in COVID-19 patients too,” she said. “A panoply of conditions can be caused by autoimmunity.”
On the increase in strokes that has been reported in COVID-19 patients, Dr. Spudich said, “this could be due to direct effects of the virus (e.g., causing an increase in coagulation or infecting the endothelial cells in the brain) or it could just be the final trigger for patients who were at risk of stroke anyway.”
There have been some very high-profile reports of younger patients with major strokes, she said, “but we haven’t seen that in our hospital. For the most part in my experience, strokes are happening in older COVID-19 patients with stroke risk factors such as AF [atrial fibrillation], hypertension, and diabetes. We haven’t seen a preponderance of strokes in young, otherwise healthy people.”
Even in patients who have neurologic effects as the first sign of COVID-19 infection, it is not known whether these symptoms are caused directly by the virus.
“We know that flu can cause people to have headaches, but that is because of an increase in inflammatory cytokines. On the other hand, patients with acute HIV infection often have headaches as a result of the virus getting into the brain. We don’t know where in this [cluster] COVID-19 virus falls,” Dr. Spudich said.
Much is still unknown
“The information we have is very sparse at this point. We need far more systematic information on this from CSF samples and imaging.” Dr. Spudich urged clinicians to try to collect such information in patients with neurologic symptoms.
Acknowledging that fewer such tests are being done at present because of concerns over infection risk, Dr. Spudich suggested that some changes in procedure may help. “In our hospital we have a portable MRI scanner which can be brought to the patient. This means the patient does not have to move across the hospital for a scan. This helps us to decide whether the patient has had a stroke, which can be missed when patients are on a ventilator.”
It is also unclear whether the neurologic effects seen during COVID-19 infection will last long term.
Dr. Spudich noted that there have been reports of COVID-19 patients discharged from intensive care having difficulty with higher cognitive function for some time thereafter. “This can happen after being in ICU but is it more pronounced in COVID-19 patients? An ongoing study is underway to look at this,” she said.
This article first appeared on Medscape.com.
Immunotherapy, steroids had positive outcomes in COVID-19–associated multisystem inflammatory syndrome
According to study of a cluster of patients in France and Switzerland, children may experience an acute cardiac decompensation from the severe inflammatory state following SARS-CoV-2 infection, termed multisystem inflammatory syndrome in children (MIS-C). Treatment with immunoglobulin appears to be associated with recovery of left ventricular systolic function.
“The pediatric and cardiology communities should be acutely aware of this new disease probably related to SARS-CoV-2 infection (MIS-C), that shares similarities with Kawasaki disease but has specificities in its presentation,” researchers led by Zahra Belhadjer, MD, of Necker-Enfants Malades Hospital in Paris, wrote in a cases series report published online in Circulation “Early diagnosis and management appear to lead to favorable outcome using classical therapies. Elucidating the immune mechanisms of this disease will afford further insights for treatment and potential global prevention of severe forms.”
Over a 2-month period that coincided with the SARS-CoV-2 pandemic in France and Switzerland, the researchers retrospectively collected clinical, biological, therapeutic, and early-outcomes data in 35 children who were admitted to pediatric ICUs in 14 centers for cardiogenic shock, left ventricular dysfunction, and severe inflammatory state. Their median age was 10 years, all presented with a fever, 80% had gastrointestinal symptoms of abdominal pain, vomiting, or diarrhea, and 28% had comorbidities that included body mass index of greater than 25 kg/m2 (17%), asthma (9%), and lupus (3%), and overweight. Only 17% presented with chest pain. The researchers observed that left ventricular ejection fraction was less than 30% in 28% of patients, and 80% required inotropic support with 28% treated with extracorporeal membrane oxygenation (ECMO). All patients presented with a severe inflammatory state evidenced by elevated C-reactive protein and d-dimer. Interleukin 6 was elevated to a median of 135 pg/mL in 13 of the patients. Elevation of troponin I was constant but mild to moderate, and NT-proBNP or BNP elevation was present in all children.
Nearly all patients 35 (88%) patients tested positive for SARS-CoV-2 infection by polymerase chain reaction of nasopharyngeal swab or serology. Most patients (80%) received IV inotropic support, 71% received first-line IV immunoglobulin, 65% received anticoagulation with heparin, 34% received IV steroids having been considered high-risk patients with symptoms similar to an incomplete form of Kawasaki disease, and 8% received treatment with an interleukin-1 receptor antagonist because of a persistent severe inflammatory state. Left ventricular function was restored in 71% of those discharged from the intensive care unit. No patient died, and all patients treated with ECMO were successfully weaned after a median of 4.5 days.
“Some aspects of this emerging pediatric disease (MIS-C) are similar to those of Kawasaki disease: prolonged fever, multisystem inflammation with skin rash, lymphadenopathy, diarrhea, meningism, and high levels of inflammatory biomarkers,” the researchers wrote. “But differences are important and raise the question as to whether this syndrome is Kawasaki disease with SARS-CoV-2 as the triggering agent, or represents a different syndrome (MIS-C). Kawasaki disease predominantly affects young children younger than 5 years, whereas the median age in our series is 10 years. Incomplete forms of Kawasaki disease occur in infants who may have fever as the sole clinical finding, whereas older patients are more prone to exhibit the complete form.”
They went on to note that the overlapping features between MIS-C and Kawasaki disease “may be due to similar pathophysiology. The etiologic agent of Kawasaki disease is unknown but likely to be ubiquitous, causing asymptomatic childhood infection but triggering the immunologic cascade of Kawasaki disease in genetically susceptible individuals. Please note that infection with a novel RNA virus that enters through the upper respiratory tract has been proposed to be the cause of the disease (see PLoS One. 2008 Feb 13;3:e1582 and J Infect Dis. 2011 Apr 1;203:1021-30).”
Based on the work of authors, it appears that a high index of suspicion for MIS-C is important for children who develop Kawasaki-like symptoms, David J. Goldberg, MD, said in an interview. “Although children have largely been spared from the acute respiratory presentation of the SARS-CoV-2 pandemic, the recognition and understanding of what appears to be a postviral inflammatory response is a critical first step in developing treatment algorithms for this disease process,” said Dr. Goldberg, a board-certified attending cardiologist in the cardiac center and fetal heart program at Children’s Hospital of Philadelphia. “If inflammatory markers are elevated, particularly if there are accompanying gastrointestinal symptoms, the possibility of cardiac involvement suggests the utility of screening echocardiography. Given the potential need for inotropic or mechanical circulatory support, the presence of myocardial dysfunction dictates care in an intensive care unit capable of providing advanced therapies. While the evidence from Dr. Belhadjer’s cohort suggests that full recovery is probable, there is still much to be learned about this unique inflammatory syndrome and the alarm has rightly been sounded.”
The researchers and Dr. Goldberg reported having no disclosures.
SOURCE: Belhadjer Z et al. Circulation 2020 May 17; doi: 10.1161/circulationaha.120.048360.
According to study of a cluster of patients in France and Switzerland, children may experience an acute cardiac decompensation from the severe inflammatory state following SARS-CoV-2 infection, termed multisystem inflammatory syndrome in children (MIS-C). Treatment with immunoglobulin appears to be associated with recovery of left ventricular systolic function.
“The pediatric and cardiology communities should be acutely aware of this new disease probably related to SARS-CoV-2 infection (MIS-C), that shares similarities with Kawasaki disease but has specificities in its presentation,” researchers led by Zahra Belhadjer, MD, of Necker-Enfants Malades Hospital in Paris, wrote in a cases series report published online in Circulation “Early diagnosis and management appear to lead to favorable outcome using classical therapies. Elucidating the immune mechanisms of this disease will afford further insights for treatment and potential global prevention of severe forms.”
Over a 2-month period that coincided with the SARS-CoV-2 pandemic in France and Switzerland, the researchers retrospectively collected clinical, biological, therapeutic, and early-outcomes data in 35 children who were admitted to pediatric ICUs in 14 centers for cardiogenic shock, left ventricular dysfunction, and severe inflammatory state. Their median age was 10 years, all presented with a fever, 80% had gastrointestinal symptoms of abdominal pain, vomiting, or diarrhea, and 28% had comorbidities that included body mass index of greater than 25 kg/m2 (17%), asthma (9%), and lupus (3%), and overweight. Only 17% presented with chest pain. The researchers observed that left ventricular ejection fraction was less than 30% in 28% of patients, and 80% required inotropic support with 28% treated with extracorporeal membrane oxygenation (ECMO). All patients presented with a severe inflammatory state evidenced by elevated C-reactive protein and d-dimer. Interleukin 6 was elevated to a median of 135 pg/mL in 13 of the patients. Elevation of troponin I was constant but mild to moderate, and NT-proBNP or BNP elevation was present in all children.
Nearly all patients 35 (88%) patients tested positive for SARS-CoV-2 infection by polymerase chain reaction of nasopharyngeal swab or serology. Most patients (80%) received IV inotropic support, 71% received first-line IV immunoglobulin, 65% received anticoagulation with heparin, 34% received IV steroids having been considered high-risk patients with symptoms similar to an incomplete form of Kawasaki disease, and 8% received treatment with an interleukin-1 receptor antagonist because of a persistent severe inflammatory state. Left ventricular function was restored in 71% of those discharged from the intensive care unit. No patient died, and all patients treated with ECMO were successfully weaned after a median of 4.5 days.
“Some aspects of this emerging pediatric disease (MIS-C) are similar to those of Kawasaki disease: prolonged fever, multisystem inflammation with skin rash, lymphadenopathy, diarrhea, meningism, and high levels of inflammatory biomarkers,” the researchers wrote. “But differences are important and raise the question as to whether this syndrome is Kawasaki disease with SARS-CoV-2 as the triggering agent, or represents a different syndrome (MIS-C). Kawasaki disease predominantly affects young children younger than 5 years, whereas the median age in our series is 10 years. Incomplete forms of Kawasaki disease occur in infants who may have fever as the sole clinical finding, whereas older patients are more prone to exhibit the complete form.”
They went on to note that the overlapping features between MIS-C and Kawasaki disease “may be due to similar pathophysiology. The etiologic agent of Kawasaki disease is unknown but likely to be ubiquitous, causing asymptomatic childhood infection but triggering the immunologic cascade of Kawasaki disease in genetically susceptible individuals. Please note that infection with a novel RNA virus that enters through the upper respiratory tract has been proposed to be the cause of the disease (see PLoS One. 2008 Feb 13;3:e1582 and J Infect Dis. 2011 Apr 1;203:1021-30).”
Based on the work of authors, it appears that a high index of suspicion for MIS-C is important for children who develop Kawasaki-like symptoms, David J. Goldberg, MD, said in an interview. “Although children have largely been spared from the acute respiratory presentation of the SARS-CoV-2 pandemic, the recognition and understanding of what appears to be a postviral inflammatory response is a critical first step in developing treatment algorithms for this disease process,” said Dr. Goldberg, a board-certified attending cardiologist in the cardiac center and fetal heart program at Children’s Hospital of Philadelphia. “If inflammatory markers are elevated, particularly if there are accompanying gastrointestinal symptoms, the possibility of cardiac involvement suggests the utility of screening echocardiography. Given the potential need for inotropic or mechanical circulatory support, the presence of myocardial dysfunction dictates care in an intensive care unit capable of providing advanced therapies. While the evidence from Dr. Belhadjer’s cohort suggests that full recovery is probable, there is still much to be learned about this unique inflammatory syndrome and the alarm has rightly been sounded.”
The researchers and Dr. Goldberg reported having no disclosures.
SOURCE: Belhadjer Z et al. Circulation 2020 May 17; doi: 10.1161/circulationaha.120.048360.
According to study of a cluster of patients in France and Switzerland, children may experience an acute cardiac decompensation from the severe inflammatory state following SARS-CoV-2 infection, termed multisystem inflammatory syndrome in children (MIS-C). Treatment with immunoglobulin appears to be associated with recovery of left ventricular systolic function.
“The pediatric and cardiology communities should be acutely aware of this new disease probably related to SARS-CoV-2 infection (MIS-C), that shares similarities with Kawasaki disease but has specificities in its presentation,” researchers led by Zahra Belhadjer, MD, of Necker-Enfants Malades Hospital in Paris, wrote in a cases series report published online in Circulation “Early diagnosis and management appear to lead to favorable outcome using classical therapies. Elucidating the immune mechanisms of this disease will afford further insights for treatment and potential global prevention of severe forms.”
Over a 2-month period that coincided with the SARS-CoV-2 pandemic in France and Switzerland, the researchers retrospectively collected clinical, biological, therapeutic, and early-outcomes data in 35 children who were admitted to pediatric ICUs in 14 centers for cardiogenic shock, left ventricular dysfunction, and severe inflammatory state. Their median age was 10 years, all presented with a fever, 80% had gastrointestinal symptoms of abdominal pain, vomiting, or diarrhea, and 28% had comorbidities that included body mass index of greater than 25 kg/m2 (17%), asthma (9%), and lupus (3%), and overweight. Only 17% presented with chest pain. The researchers observed that left ventricular ejection fraction was less than 30% in 28% of patients, and 80% required inotropic support with 28% treated with extracorporeal membrane oxygenation (ECMO). All patients presented with a severe inflammatory state evidenced by elevated C-reactive protein and d-dimer. Interleukin 6 was elevated to a median of 135 pg/mL in 13 of the patients. Elevation of troponin I was constant but mild to moderate, and NT-proBNP or BNP elevation was present in all children.
Nearly all patients 35 (88%) patients tested positive for SARS-CoV-2 infection by polymerase chain reaction of nasopharyngeal swab or serology. Most patients (80%) received IV inotropic support, 71% received first-line IV immunoglobulin, 65% received anticoagulation with heparin, 34% received IV steroids having been considered high-risk patients with symptoms similar to an incomplete form of Kawasaki disease, and 8% received treatment with an interleukin-1 receptor antagonist because of a persistent severe inflammatory state. Left ventricular function was restored in 71% of those discharged from the intensive care unit. No patient died, and all patients treated with ECMO were successfully weaned after a median of 4.5 days.
“Some aspects of this emerging pediatric disease (MIS-C) are similar to those of Kawasaki disease: prolonged fever, multisystem inflammation with skin rash, lymphadenopathy, diarrhea, meningism, and high levels of inflammatory biomarkers,” the researchers wrote. “But differences are important and raise the question as to whether this syndrome is Kawasaki disease with SARS-CoV-2 as the triggering agent, or represents a different syndrome (MIS-C). Kawasaki disease predominantly affects young children younger than 5 years, whereas the median age in our series is 10 years. Incomplete forms of Kawasaki disease occur in infants who may have fever as the sole clinical finding, whereas older patients are more prone to exhibit the complete form.”
They went on to note that the overlapping features between MIS-C and Kawasaki disease “may be due to similar pathophysiology. The etiologic agent of Kawasaki disease is unknown but likely to be ubiquitous, causing asymptomatic childhood infection but triggering the immunologic cascade of Kawasaki disease in genetically susceptible individuals. Please note that infection with a novel RNA virus that enters through the upper respiratory tract has been proposed to be the cause of the disease (see PLoS One. 2008 Feb 13;3:e1582 and J Infect Dis. 2011 Apr 1;203:1021-30).”
Based on the work of authors, it appears that a high index of suspicion for MIS-C is important for children who develop Kawasaki-like symptoms, David J. Goldberg, MD, said in an interview. “Although children have largely been spared from the acute respiratory presentation of the SARS-CoV-2 pandemic, the recognition and understanding of what appears to be a postviral inflammatory response is a critical first step in developing treatment algorithms for this disease process,” said Dr. Goldberg, a board-certified attending cardiologist in the cardiac center and fetal heart program at Children’s Hospital of Philadelphia. “If inflammatory markers are elevated, particularly if there are accompanying gastrointestinal symptoms, the possibility of cardiac involvement suggests the utility of screening echocardiography. Given the potential need for inotropic or mechanical circulatory support, the presence of myocardial dysfunction dictates care in an intensive care unit capable of providing advanced therapies. While the evidence from Dr. Belhadjer’s cohort suggests that full recovery is probable, there is still much to be learned about this unique inflammatory syndrome and the alarm has rightly been sounded.”
The researchers and Dr. Goldberg reported having no disclosures.
SOURCE: Belhadjer Z et al. Circulation 2020 May 17; doi: 10.1161/circulationaha.120.048360.
FROM CIRCULATION