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Background: Nervous system post-acute sequelae of COVID-19 (NS-PASC) include cognitive and mental health symptoms. To further define these, we applied a Research Domain Criteria (RDoC) approach to examine motor, positive valence (PV) and negative valence (NV) systems, and social processing data in The COVID Mind Study of NS-PASC. Method(s): NS-PASC participants (>3 months after COVID-19) referred from a NeuroCOVID Clinic and non-COVID controls from New Haven, CT and Baltimore, MD completed an RDoC test battery for cognition (language, declarative and working memory, cognitive control, perception), motor, PV, NV, and social processes. To date, 3T MRI with diffusion tensor imaging was performed in 11 NS-PASC to assess white matter integrity (global white matter fractional anisotropy [FA]) as a contributor to alterations identified on the RDoC tests. Analysis of Covariance examined group differences after adjusting for sex, race, ethnicity, age, and years of education. Result(s): 25 NS-PASC participants (age 43.4+/-11.3 yrs, 76% female, 402 days after COVID-19 symptom onset) and 29 controls (age 46.2.6+/-13.1 yrs, 66% female) completed the battery. Controls were more racially diverse and less educated than NS-PASC (43% vs. 12% Black, p=0.005;14.5 vs. 16.1 yrs of education, p< 0.05). Means and statistics for RDoC between NS-PASC and controls are shown in Table. NS-PASC performed worse in language, verbal working and declarative memory, and perception and reported greater cognitive control difficulties (e.g., behavioral inhibition, set shifting) without issues on performance-based metrics (Stroop, Trail Making Test-Part B), and had slower motor function. NS-PASC reported more NV issues including greater symptoms of depression, rumination in response to depressive mood, apathy, childhood trauma, anxiety, and perceived stress. There were no differences in PV and social processing. In a subset of NS-PASC participants who underwent MRI, there was a dynamic range of FA values with a mean of 0.509 (IQR 0.481 - 0.536). Conclusion(s): Our findings extend previous PASC studies characterizing cognitive and mental health alterations, indicating that additional RDoC assessments warrant focus, including alterations in motor and the negative valence system. In future analyses, we will examine white matter integrity as a pathophysiologic contributor to these RDoC systems.
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Background: It is unknown whether individuals with neurological post-acute sequelae of COVID-19 (NeuroPASC) display altered levels of neuroimmune activity or neuronal injury. Method(s): Participants with new or worsened neurologic symptoms at least 3 months after laboratory-confirmed COVID-19 were enrolled in The COVID Mind Study at Yale. Never COVID controls (no history of COVID-19;nucleocapsid (N) antibody negative) were pre-pandemic or prospectively enrolled volunteers. CSF and plasma were assessed for neopterin and for IL-1beta, IL-1RA, IL-2, IL-4, IL-5, IL-6, IL-8, IL-10, IL-12p40, IL-12p70, IL-13, MCP-1, TNFalpha by bead-based multiplex assay;and for anti-SARS-CoV-2 N antibodies by Luminex-based multiplex assay in technical replicate, normalized against bovine serum albumin conjugated beads. Plasma concentrations of D-dimer, C-reactive protein, neurofilament light chain (NFL), and glial fibrillary acid protein (GFAP) were measured using high-sensitivity immunoassays. Group comparisons used non-parametric tests. Result(s): NeuroPASC participants (n=38) were studied 329 (median) days (range 81-742) after first positive test for acute COVID-19. Cognitive impairment (84%) and fatigue (82%) were the most frequent post-COVID symptoms. NeuroPASC and controls (n=22) were median 49 vs 52 yrs old (p=0.9), 74% vs 32% female (p< 0.001), 76% vs 23% white race (p< 0.001), and 6% vs 57% smokers (p< 0.001). CSF white blood cells/mL, CSF protein, and serum:CSF albumin ratio were normal in both groups. CSF TNFalpha (0.66 vs 0.55 pg/ul) and plasma IL12p40 were higher (103.3 vs 42.7);and MCP-1 (503 vs 697 pg/ul) and IL-6 (1.32 vs 1.84 pg/ul;p < 0.05 for IL-6) were lower in NeuroPASC vs controls (p< 0.05);but none of these differences were significant after adjusting for multiple comparisons. Plasma GFAP was elevated in NeuroPASC vs controls (54.4 vs 42.3 pg/ml;adjusted p< 0.03). There were no differences in the other biomarkers tested. 10/31 and 7/31 NeuroPASC had anti-N antibodies in CSF and plasma, respectively. Conclusion(s): When comparing NeuroPASC to never COVID controls, we found no evidence of neuroinflammation (normal CSF cell count, inflammatory cytokines) or blood-brain barrier dysfunction (normal albumin ratio), and no support for ongoing neuronal damage (normal plasma NFL). Future studies should include better gender and race matched controls and should explore the significance of a persistent CNS humoral immune response to SARS-CoV-2 and elevated plasma GFAP after COVID-19. (Figure Presented).
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Objective: To report a case series documenting biopsy-proven small fiber neuropathy (SFN) after COVID-19. Background: Patients recovering from COVID-19 who present with sensory as well as autonomic symptoms, including positional orthostatic tachycardia syndrome (POTS), frequently have negative electrodiagnostic testing. Skin biopsy may be required to reveal SFN. Design/Methods: This is a retrospective case series of patients seen in the Yale Neurology COVID-19 Clinic with positive SARS-CoV-2 PCR or antibody or a clinically consistent illness. After laboratory testing and a negative nerve conduction study, all patients underwent skin biopsy to test for intraepidermal SFN. Case 1: A 40F with pre-diabetes (HbA1c 6.2%) developed burning, numbness, and tingling in the hands and legs and POTS 6 weeks after acute COVID-19. Skin biopsy demonstrated non-length dependent SFN. Complete remission of neuropathy symptoms occurred within days of intravenous immunoglobulin (IVIG) therapy, which has been continued longitudinally. Case 2: A 65F with non-insulin dependent diabetes (HbA1c 8.0%) developed excruciating burning pain in her feet and orthostasis within weeks of acute COVID-19. Skin biopsy demonstrated non-length dependent SFN. She experienced partial relief of symptoms after IVIG and gabapentin. Case 3: A 43F with pre-diabetes (HbA1c 6.0%) developed orthostasis, numbness, paresthesias, and a “sunburned” feeling in her face, back, hands, and feet 2 weeks after acute COVID-19. Skin biopsy demonstrated length-dependent SFN. Symptoms improved over several months of pregabalin treatment, but have not resolved. The patient deferred immunotherapy. Case 4: A 40M developed POTS, numbness, and paresthesias in his face and left leg up to the knee within weeks of a clinical COVID-19 illness. Skin biopsy demonstrated non-length dependent SFN. IVIG therapy has resulted in significant improvement in symptoms. Conclusions: Sensory symptoms and POTS occur post-COVID, and SFN should be considered in the differential. Given the time of onset and response to immunotherapy, post-COVID SFN may have an underlying autoimmune etiology.
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Background: The pathogenesis of neuropsychiatric symptoms persisting months after acute SARS-CoV-2 infection is poorly understood. We examined clinical and laboratory parameters in participants with post-acute COVID-19 neuropsychiatric symptom to assess for systemic and nervous system immune perturbations. Methods: Participants with a history of laboratory confirmed COVID-19 and ongoing neurologic symptoms were enrolled in an observational study that collected medical history;detailed post-COVID symptom survey;and paired cerebrospinal fluid (CSF) and blood. In addition to standard clinical labs, neopterin and anti-SARS-CoV-2 antibodies (anti-spike, RBD, and nucleocapsid) were measured by ELISA. Non-parametric tests were used to compare CSF and blood findings between the post-COVID participants and pre-COVID-19 era healthy controls. Results: Post-COVID participants (n=27) and controls (n=21) were similar in age (median 51 and 46 years), but there was a greater proportion of females (67% vs 24%;p=0.004) and white participants in the post-COVID cohort (63% vs 24%;p=0.04). The post-COVID study visit was a median of 264 days (IQR 59-332) after acute COVID-19 symptom onset. 35% were hospitalized during their acute illness;12% required intensive care. 33% had previously been treated with medications for mental health conditions. The most frequent neuropsychiatric symptoms were cognitive impairment (67%), mood symptoms (67%), headache (56%), and neuropathy (41%). Blood c-reactive protein, T cell count, and T cell subset frequency (CD4% and CD8%) were similar between groups, while D-dimer was higher in the post-COVID cohort (median 0.48 vs 0.27 mg/L;p = 0.019) (Figure). CSF WBC, protein, neopterin, and CSF/blood albumin ratio were similar between the groups;the frequency of CSF lymphocytes was lower in the post-COVID cohort (p = 0.05) (Figure 1). Antibodies against at least one SARS-CoV-2 antigen were detected in 7/10 CSF and 8/9 blood samples in the post-COVID CSF (antibody reactivity range 1.5 to 55-fold greater than to control antigens). Conclusion: In this small cohort of post-COVID participants with neurologic symptoms, we found limited differences in CSF and blood markers when compared to pre-pandemic healthy controls. Deeper immunophenotyping in a larger number of participants may provide greater insight into subtle differences. The presence of anti-SARS-CoV-2 antibodies in CSF months after acute infection warrants further investigation.
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Objective: Early reports suggest an increased risk of ischemic stroke during COVID-19 infection. We aimed to identify patients with COVID-19 and ischemic stroke and explore markers of endotheliopathy, inflammation, and hypercoagulability. Background: Novel coronavirus-19 disease (COVID-19) is associated with a diverse array of neurologic complications, including ischemic stroke. Suspected mechanisms include hypercoagulability and endothelial injury, although evidence is sparse in stroke patients. Design/Methods: This was a retrospective, observational cohort study of patients with acute ischemic stroke and COVID-19 (n=21) compared to non-COVID-19 acute ischemic stroke patients (n=11). Timing of stroke onset during COVID-19 course, acute phase reactant levels, cytokine levels, endothelial activation, and hypercoagulability were evaluated with respect to stroke onset and etiology. Results: Twenty-one ischemic stroke patients were diagnosed with COVID-19 during the study period. Both groups had a similar age and burden of vascular risk factors. COVID-19 patients had significantly higher levels of endothelial activation around the time of stroke when compared to controls. The mean Factor VIII level was 332% of normal in the COVID-19 group and 49% in the control group, while von Willebrand Factor antigen and activity were 330% and 285% in the COVID-19 group and 213% and 152% in the control group, respectively. Cytokine storming and a strong inflammatory responses are defining features of severe COVID-19. We demonstrated a temporal correlation between stroke onset and the peak of acute phase reactants. Elevated cytokine levels, IL-6 and soluble IL-2 receptor levels in particular, were significantly associated with embolic stroke of undetermined source (ESUS) in COVID-19 patients when compared with other etiologies. Conclusions: We provide emerging evidence that endotheliopathy and the systemic inflammatory response in patients with vascular risk factors and COVID-19 is associated with ischemic stroke. Further research is needed. Understanding the mechanism of stroke in COVID- 19 patients will be critical in providing primary stroke prevention and treatment.
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Background: One third of COVID-19 patients develop significant neurological symptoms, yet SARS-CoV-2 is rarely detected in central nervous system (CNS) tissue, suggesting a potential role for parainfectious processes, including neuroimmune responses. Methods: We examined immune parameters in CSF and blood samples from a cohort of hospitalized patients with COVID-19 and significant neurological complications (n=6), compared to SARS-CoV-2 uninfected controls (Fig1A). Immune cells were characterized by single cell RNA and repertoire sequencing. Intrathecal antibodies were assessed for anti-viral and auto-reactivity by ELISA, mouse brain immunostaining, phage display, and IP-MS. Results: Through single cell and parallel cytokine analyses of CSF and paired plasma, we found divergent T cell responses in the CNS compartment, including increased levels of IL-1B and IL-12-associated innate and adaptive immune cell activation (Fig1B). We found evidence of clonal expansion of B cells in the CSF, with B cell receptor sequences that were unique from those observed in peripheral blood B cells (Fig1C), suggesting a divergent intrathecal humoral response to SARS-CoV-2. Indeed, all COVID-19 cases examined had anti-SARS-antibodies. Next, we directly examined whether CSF resident antibodies targeted self-antigens and found a significant burden of CNS autoimmunity, with the CSF from most patients recognizing neural self-antigens. COVID-19 CSF produced immunoreactive staining of specific anatomic regions of the brain including cortical neurons, olfactory bulb, thalamus, and cerebral vasculature. Finally, we produced a panel of monoclonal antibodies from patients' CSF and peripheral blood, and show that these target both anti-viral and anti-neural antigens-including one CSF-derived mAb specific for the spike protein that also recognizes neural tissue (Fig1D). Conclusion: This immune survey reveals evidence of a compartmentalized and self-reactive immune response in the CNS in COVID-19 patients with neurologic symptoms. We identified both innate and adaptive anti-viral immune responses, as well as humoral autoimmunity that appears to be unique to the CNS during SARS-CoV-2 infection. These data suggest a potential role for autoimmunity in contributing to neurological symptoms, and merit further investigation to the potential role of autoantibodies in post-acute COVID-19 neurological symptoms.