Understanding the neurological implications of acute and long COVID using brain organoids

Abstract:

As early as in the acute phase of the coronavirus disease 2019 (COVID-19) pandemic, the research community voiced concerns about the long-term implications of infection. Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), like many other viruses, can trigger chronic disorders that last months or even years.

Long COVID, the chronic and persistent disorder lasting more than 12 weeks after the primary infection with SARS-CoV-2, involves a variable number of neurological manifestations, ranging from mild to severe and even fatal. In vitro and in vivo modeling suggest that SARS-CoV-2 infection drives changes within neurons, glia and the brain vasculature.

In this Review, we summarize the current understanding of the neuropathology of acute and long COVID, with particular emphasis on the knowledge derived from brain organoid models. We highlight the advantages and main limitations of brain organoids, leveraging their human-derived origin, their similarity in cellular and tissue architecture to human tissues, and their potential to decipher the pathophysiology of long COVID.

Source: García-González L, Martí-Sarrias A, Puertas MC, Bayón-Gil Á, Resa-Infante P, Martinez-Picado J, Navarro A, Acosta S. Understanding the neurological implications of acute and long COVID using brain organoids. Dis Model Mech. 2023 Jul 1;16(7):dmm050049. doi: 10.1242/dmm.050049. Epub 2023 Jul 17. PMID: 37458167. https://journals.biologists.com/dmm/article/16/7/dmm050049/323961/Understanding-the-neurological-implications-of  (Full text)

Treatment and outcomes of 95 post-Covid patients with an antidepressant and neurobiological explanations

Abstract:

After Covid-19 infection, 12.5% develop a post-Covid-syndrome. Symptoms affect numerous organ systems, but after one year they are mainly neurological and neuropsychiatric in nature. There is evidence that treatment with selective serotonin reuptake inhibitors (SSRIs) during Covid-19 infection decreases the likelihood of a post-Covid condition, but there is no known research on treating post-Covid syndrome itself with SSRIs.

This study used an exploratory questionnaire and found that 63,4% of 95 post-Covid syndrome patients reported a reasonably good to strong response to an SSRI. Outcomes were measured with three different measures that correlated strongly with each other. Brainfog and sensory overload decreased the most. Patients experienced improved well-being. The response to SSRIs in post-Covid conditions was explained by seven possible neurobiological mechanisms as reported in the recent literature. The promising results of this study should be followed by a randomized controlled trial.

Source: Rus CC, de Vries B, Vries IE, Nutma I, Kooij JJS. Treatment and outcomes of 95 post-Covid patients with an antidepressant and neurobiological explanations. Research Square; 2023. DOI: 10.21203/rs.3.rs-3153645/v1. https://assets.researchsquare.com/files/rs-3153645/v1/ffdd7433-9013-41d5-9f16-154074f3a204.pdf (Full text)

Cognitive impairment after Long COVID-19: Current Evidence and Perspectives

Abstract:

COVID-19 is a respiratory infectious disease caused by the SARS-CoV-2 virus. Most patients recover after treatment, but COVID-19 treatment may lead to cognitive impairment. Recent studies have found that some recoverers experience cognitive impairments such as decreased memory and attention, and sleep disorder, indicating that COVID-19 may have longerterm effects on cognitive function.

Studies have found that COVID-19 may cause cognitive decline by damaging key brain regions such as the hippocampus and anterior cingulate cortex. Studies have also found that COVID-19 patients have active neuroinflammation, mitochondrial dysfunction, and microglial activation, suggesting that neuroinflammation, mitochondrial stress, and neurodegenerative changes may be potential mechanisms leading to cognitive impairment.

In summary, the possibility of cognitive impairment after COVID-19 treatment deserves close attention. Large-scale follow-up studies will help further explore the impact of COVID-19 on cognitive function and provide evidence to support clinical treatment and rehabilitation practices. Neuropathological and biological studies can explore precise mechanisms in-depth and provide a theoretical basis for prevention, treatment, and intervention research.

Given the risks of long-term COVID-19 and reinfection, it is necessary to integrate basic and clinical research data to maximize the maintenance of patient’s cognitive function and life quality. This also provides important experience in responding to similar public health events. This article integrates clinical and basic evidence of cognitive impairment after COVID-19 and discusses potential mechanisms and future research directions.

Source: Zhi-Tao Li, ZHANG ZHEN, Zhuoya Zhang, Zhi-Yong Wang, Hao Li. Cognitive impairment after Long COVID-19: Current Evidence and Perspectives. Front. Neurol. Sec. Neuroinfectious Diseases. Volume 14 – 2023 | doi: 10.3389/fneur.2023.1239182 https://www.frontiersin.org/articles/10.3389/fneur.2023.1239182/abstract

Evaluation of Outpatients in the Post-COVID-19 Period in Terms of Autonomic Dysfunction and Silent Ischemia

Abstract:

Introduction and objective: In this context, the objective of this study is to evaluate the 24-hour ambulatory electrocardiography (ECG) recordings, autonomous function with heart rate variability (HRV), and silent ischemia (SI) attacks with ST depression burden (SDB) and ST depression time (SDT) of post-COVID-19 patients. Materials and methods: The 24-hour ambulatory ECG recordings obtained >12 weeks after the diagnosis of COVID-19 were compared between 55 consecutive asymptomatic and 73 symptomatic post-COVID-19 patients who applied to the cardiology outpatient clinic with complaints of palpitation and chest pain in comparison with asymptomatic post-COVID-19 patients in Kars Harakani state hospital. SDB, SDT, and HRV parameters were analyzed. Patients who had been on medication that might affect HRV, had comorbidities that might have caused coronary ischemia, and were hospitalized with severe COVID-19 were excluded from the study.

Results: There was no significant difference between symptomatic and asymptomatic post-COVID-19 patients in autonomic function. On the other hand, SDB and SDT parameters were significantly higher in symptomatic post-COVID-19 patients than in asymptomatic post-COVID-19 patients. Multivariate analysis indicated that creatine kinase-myoglobin binding (CK-MB) (OR:1.382, 95% CI:1.043-1.831; p=0.024) and HRV index (OR: 1.033, 95% CI:1.005-1.061; p=0.019) were found as independent predictors of palpitation and chest pain symptoms in post-COVID-19 patients.

Conclusion: The findings of this study revealed that parasympathetic overtone and increased HRV were significantly higher in symptomatic patients with a history of COVID-19 compared to asymptomatic patients with a history of COVID-19 in the post-COVID-19 period. Additionally, 24-hour ambulatory ECG recordings and ST depression analysis data indicated that patients who experienced chest pain in the post-COVID-19 period experienced silent ischemia (SI) attacks.

Source: Karakayalı M, Artac I, Ilis D, Omar T, Rencuzogullari I, Karabag Y, Altunova M, Arslan A, Guzel E. Evaluation of Outpatients in the Post-COVID-19 Period in Terms of Autonomic Dysfunction and Silent Ischemia. Cureus. 2023 Jun 11;15(6):e40256. doi: 10.7759/cureus.40256. PMID: 37440812; PMCID: PMC10335598. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10335598/ (Full text)

A Cross-Sectional Study of Symptom Prevalence, Frequency, Severity, and Impact of Long-COVID in Scotland: Part II

Abstract:

Background: There has been some effort to map the prevalence, frequency, and severity of symptoms of long-COVID at local and national levels. However, what is frequently absent from such accounts is details of the impact the disease and its symptoms have had on those living with the condition. In this manuscript, we present details of impact to work, caring, and mental health gathered using a cross-sectional survey.

Methods: Data were collected using an online survey which was available from 21st April 2022 to 5th August 2022. Included participants had either self-diagnosed or confirmed long-COVID, were living in Scotland, and were ≥18 years old. Hospitalisation during initial COVID-19 infection was an exclusion criterion. Participants were asked to report on the impact of their illness on everyday activities such as working, studying, or caring. They also completed an assessment of their current mood.

Results: People with long-COVID were often severely impacted in their ability to work and study. Severe impact on work and study were predicted by more severe and more frequent fatigue, more severe pain, and more severe cognitive impairment. Respondents’ ability to care for child dependants was also associated with more severe and more frequent fatigue, as well as more severe cognitive impairments. More severe pain associated with greater impact on adult care. Negative mood correlated most strongly with frequency and severity of neurological symptoms, including lack of attention, loss of smell, impaired sense of smell, loss of taste, impaired sense of taste, and loss of appetite.

Conclusions: Long-COVID has a significant impact on ability to work, study, and care for dependants. The severity of this impact is associated with specific symptom burden, including fatigue, pain, and cognitive impairment.

Source: Mclaughlin M, Cerexhe L, Macdonald E, Ingram J, Sanal-Hayes NEM, Hayes LD, Meach R, Carless D, Sculthorpe N. A Cross-Sectional Study of Symptom Prevalence, Frequency, Severity, and Impact of Long-COVID in Scotland: Part II. Am J Med. 2023 Jul 19:S0002-9343(23)00461-8. doi: 10.1016/j.amjmed.2023.07.009. Epub ahead of print. PMID: 37478960. https://www.amjmed.com/article/S0002-9343(23)00461-8/fulltext (Full text)

Cortical thickness alterations and systemic inflammation define long-COVID patients with cognitive impairment

Abstract:

As the heterogeneity of symptoms is increasingly recognized among long-COVID patients, it appears highly relevant to study potential pathophysiological differences along the different subtypes. Preliminary evidence suggests distinct alterations in brain structure and systemic inflammatory patterns in specific groups of long-COVID patients.

To this end, we analyzed differences in cortical thickness and peripheral immune signature between clinical subgroups based on 3T-MRI scans and signature inflammatory markers in n=120 participants comprising healthy never-infected controls, healthy COVID-19 survivors, and subgroups of long-COVID patients with and without cognitive impairment according to screening with Montreal Cognitive Assessment.

Whole-brain comparison of cortical thickness between the 4 groups was conducted by surface-based morphometry. We identified distinct cortical areas showing a progressive increase in cortical thickness across different groups, starting from healthy individuals who had never been infected with COVID-19, followed by healthy COVID-19 survivors, long-COVID patients without cognitive deficits (MoCA ≥ 26), and finally, long-COVID patients exhibiting significant cognitive deficits (MoCA < 26). These findings highlight the continuum of cortical thickness alterations associated with COVID-19, with more pronounced changes observed in individuals experiencing cognitive impairment (p<0.05, FWE-corrected).

Affected cortical regions covered prefrontal and temporal gyri, insula, posterior cingulate, parahippocampal gyrus, and parietal areas. Additionally, we discovered a distinct immunophenotype, with elevated levels of IL-10, IFNg, and sTREM2 in long-COVID patients, especially in the group suffering from cognitive impairment.

We demonstrate lingering cortical and immunological alterations in healthy and impaired subgroups of COVID-19 survivors. This implies a complex underlying pathomechanism in long-COVID and emphasizes the necessity to investigate the whole spectrum of post-COVID biology to determine targeted treatment strategies targeting specific sub-groups.

Source: Bianca BesteherTonia RocktaeschelAlejandra Patricia GarzaMarlene MachnikJohanna BallezDario Lucas HelbingKatrhin FinkePhilipp ReukenDaniel GuellmarChristian GaserMartin WalterNils OpelIldiko Rita Dunay. Cortical thickness alterations and systemic inflammation define long-COVID patients with cognitive impairment. (Full text available as PDF file)

Carotid body dysregulation contributes to the enigma of long COVID

Abstract:

The symptoms of long COVID, which include fatigue, breathlessness, dysregulated breathing, and exercise intolerance, have unknown mechanisms. These symptoms are also observed in heart failure and are partially driven by increased sensitivity of the carotid chemoreflex. As the carotid body has an abundance of ACE2 (the cell entry mechanism for SARS-CoV-2), we investigated whether carotid chemoreflex sensitivity was elevated in participants with long COVID. During cardiopulmonary exercise testing, the VE/VCO2 slope (a measure of breathing efficiency) was higher in the long COVID group than in the controls, indicating excessive hyperventilation.

The hypoxic ventilatory response, which measures carotid chemoreflex sensitivity, was increased in long COVID participants and correlated with the VE/VCO2 slope, suggesting that excessive hyperventilation may be related to carotid body hypersensitivity. Therefore, the carotid chemoreflex is sensitized in long COVID and may explain dysregulated breathing and exercise intolerance in these participants. Tempering carotid body excitability may be a viable treatment option for long COVID patients.

Source: Ahmed El-MedanyZoe H AdamsHazel C BlytheKatrina A HopeAdrian H KendrickAna Paula Abdala SheikhJulian FR PatonAngus K NightingaleEmma C Hart. Carotid body dysregulation contributes to the enigma of long COVID. https://www.medrxiv.org/content/10.1101/2023.05.25.23290513v1.full-text (Full text)

Long COVID, the Brain, Nerves, and Cognitive Function

Abstract:

SARS-CoV-2, a single-stranded RNA coronavirus, causes an illness known as coronavirus disease 2019 (COVID-19). Long-term complications are an increasing issue in patients who have been infected with COVID-19 and may be a result of viral-associated systemic and central nervous system inflammation or may arise from a virus-induced hypercoagulable state. COVID-19 may incite changes in brain function with a wide range of lingering symptoms.
Patients often experience fatigue and may note brain fog, sensorimotor symptoms, and sleep disturbances. Prolonged neurological and neuropsychiatric symptoms are prevalent and can interfere substantially in everyday life, leading to a massive public health concern. The mechanistic pathways by which SARS-CoV-2 infection causes neurological sequelae are an important subject of ongoing research. Inflammation- induced blood-brain barrier permeability or viral neuro-invasion and direct nerve damage may be involved. Though the mechanisms are uncertain, the resulting symptoms have been documented from numerous patient reports and studies.
This review examines the constellation and spectrum of nervous system symptoms seen in long COVID and incorporates information on the prevalence of these symptoms, contributing factors, and typical course. Although treatment options are generally lacking, potential therapeutic approaches for alleviating symptoms and improving quality of life are explored.
Source: Reiss AB, Greene C, Dayaramani C, Rauchman SH, Stecker MM, De Leon J, Pinkhasov A. Long COVID, the Brain, Nerves, and Cognitive Function. Neurology International. 2023; 15(3):821-841. https://doi.org/10.3390/neurolint15030052 https://www.mdpi.com/2035-8377/15/3/52 (Full text)

Altered brain connectivity in Long Covid during cognitive exertion: a pilot study

Abstract:

Introduction: Debilitating Long-Covid symptoms occur frequently after SARS-COVID-19 infection.

Methods: Functional MRI was acquired in 10 Long Covid (LCov) and 13 healthy controls (HC) with a 7 Tesla scanner during a cognitive (Stroop color-word) task. BOLD time series were computed for 7 salience and 4 default-mode network hubs, 2 hippocampus and 7 brainstem regions (ROIs). Connectivity was characterized by the correlation coefficient between each pair of ROI BOLD time series. We tested for HC versus LCov differences in connectivity between each pair of the 20 regions (ROI-to-ROI) and between each ROI and the rest of the brain (ROI-to-voxel). For LCov, we also performed regressions of ROI-to-ROI connectivity with clinical scores.

Results: Two ROI-to-ROI connectivities differed between HC and LCov. Both involved the brainstem rostral medulla, one connection to the midbrain, another to a DM network hub. Both were stronger in LCov than HC. ROI-to-voxel analysis detected multiple other regions where LCov connectivity differed from HC located in all major lobes. Most, but not all connections, were weaker in LCov than HC. LCov, but not HC connectivity, was correlated with clinical scores for disability and autonomic function and involved brainstem ROI.

Discussion: Multiple connectivity differences and clinical correlations involved brainstem ROIs. Stronger connectivity in LCov between the medulla and midbrain may reflect a compensatory response. This brainstem circuit regulates cortical arousal, autonomic function and the sleep-wake cycle. In contrast, this circuit exhibited weaker connectivity in ME/CFS. LCov connectivity regressions with disability and autonomic scores were consistent with altered brainstem connectivity in LCov.

Source: Barnden L, Thapaliya K, Eaton-Fitch N, Barth M, Marshall-Gradisnik S. Altered brain connectivity in Long Covid during cognitive exertion: a pilot study. Front Neurosci. 2023 Jun 22;17:1182607. doi: 10.3389/fnins.2023.1182607. PMID: 37425014; PMCID: PMC10323677. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC10323677/ (Full text)

Scientific Rationale for the Treatment of Cognitive Deficits from Long COVID

Abstract:

Sustained cognitive deficits are a common and debilitating feature of “long COVID”, but currently there are no FDA-approved treatments. The cognitive functions of the dorsolateral prefrontal cortex (dlPFC) are the most consistently afflicted by long COVID, including deficits in working memory, motivation, and executive functioning. COVID-19 infection greatly increases kynurenic acid (KYNA) and glutamate carboxypeptidase II (GCPII) in brain, both of which can be particularly deleterious to PFC function.
KYNA blocks both NMDA and nicotinic-alpha-7 receptors, the two receptors required for dlPFC neurotransmission, and GCPII reduces mGluR3 regulation of cAMP-calcium-potassium channel signaling, which weakens dlPFC network connectivity and reduces dlPFC neuronal firing. Two agents approved for other indications may be helpful in restoring dlPFC physiology: the antioxidant N-acetyl cysteine inhibits the production of KYNA, and the α2A-adrenoceptor agonist guanfacine regulates cAMP-calcium-potassium channel signaling in dlPFC and is also anti-inflammatory. Thus, these agents may be helpful in treating the cognitive symptoms of long COVID.
Source: Fesharaki Zadeh A, Arnsten AFT, Wang M. Scientific Rationale for the Treatment of Cognitive Deficits from Long COVID. Neurology International. 2023; 15(2):725-742. https://doi.org/10.3390/neurolint15020045 https://www.mdpi.com/2035-8377/15/2/45 (Full text)