Tag: astrocyte dysfunction

Brain fog in long COVID: A glutamatergic hypothesis with astrocyte dysfunction accounting for brain PET glucose hypometabolism

Abstract:

Brain [18F]FDG-PET scans have revealed a glucose hypometabolic pattern in patients with long COVID. This hypometabolism might reflect primary astrocyte dysfunction. Astrocytes play a key role in regulating energy metabolism to support neuronal and synaptic activity, especially activity involving glutamate as the main neurotransmitter.

Neuroinflammation is one of the purported mechanisms to explain brain damage caused by infection with SARS-CoV-2. Microglial activation can trigger reactive astrogliosis, contributing to neuroinflammatory changes. These changes can disturb glutamatergic homeostasis, ultimately leading to cognitive fatigue, which has been described in other clinical situations.

We hypothesize that glutamatergic dysregulation related to astrocyte dysfunction could be the substrate of brain PET hypometabolism in long COVID patients with brain fog. Based on these elements, we propose that therapeutics targeting astrocytic glutamate regulation could help mitigate long COVID neurological manifestations.

Source: Tatiana Horowitz, Luc Pellerin, Eduardo R. Zimmer, Eric Guedj. Brain fog in long COVID: A glutamatergic hypothesis with astrocyte dysfunction accounting for brain PET glucose hypometabolism. Medical Hypotheses, Volume 180, 2023, 111186, ISSN 0306-9877, https://doi.org/10.1016/j.mehy.2023.111186. https://www.sciencedirect.com/science/article/pii/S0306987723001822 (Full text)

Hypothesis: Astrocyte dysregulation of sympathetic nervous system causes metabolic dysfunction in subset of Long COVID and ME/CFS patients

Abstract:

An overactive sympathetic nervous system (SNS) may cause one subtype of Long COVID. People who are genetically at risk for noradrenergic nerve problems may develop an overactive SNS after an infection. Alternatively, genetic or virus-induced dysregulation of astrocytes could lead to overactivation of the SNS. An overactive SNS could disrupt regulation of immune cells, energy metabolism, sleep homeostasis, respiratory rate, gastrointestinal function, and systemic and cerebral blood pressure, causing fatigue and cognitive dysfunction.

Hypothesis: Long COVID refers to symptoms that continue for more than four weeks after onset of acute COVID-19 illness. This umbrella term includes a wide variety of symptoms and presentations. Long COVID patients may have different types of biological dysfunction, meaning that there may be distinct subtypes of Long COVID. One possible subtype is sympathetic nervous system (SNS) over-activation. This subtype may exist in both Long COVID and myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS)1.

Underlying mechanisms of the SNS overactivation subtype: Theoretically, patients with this subtype already have a genetic dysregulation of neuronal norepinephrine (NE) release/clearance or noradrenergic receptor sensitivity2. This latent genetic dysfunction of NE signaling may not cause significant problems unless there is a trigger that causes excess NE release.

As NE affects immune cell signaling, this could result in an over-activation or prolonged activation of the immune system in response to infection with SARS-CoV-2, the virus that causes COVID-193 . This subtype could explain why ME/CFS is often triggered by a virus or brain injury, as these occurrences can trigger noradrenergic signaling3.

Possible mechanisms for the SNS overactivation subtype include viral reservoirs, antibody reaction, and dysregulation of noradrenergic receptor expression. In Long COVID patients, viral antigens and reservoirs that remain in the body long after the initial infection may keep the overactive immune system in an inflammatory state4,5. A healthy person may not react to these SARS-CoV-2 reservoirs, as their functional immune cells should develop immune tolerance. Another possibility is that the immune system is reacting to SARS-CoV-2 antibodies.

Finally, it is possible that excess extracellular NE could keep the SNS and noradrenergic systems in the brain stuck in an overactive state. A prolonged period of increased levels of extracellular NE could lead to dysregulation of noradrenergic receptor expression. The excess extracellular NE may be due to a prolonged release of excess NE during the initial infection, or a failure of the negative feedback mechanisms that should reduce NE release.

Symptoms of an overactive SNS: An overactive SNS explains many of the symptoms found in Long COVID patients, such as IBS/gastrointestinal symptoms6, heart palpitations7, and sleep disturbance8. Additionally, in orthostatic intolerance, which is common in Long COVID and ME/CFS, the release of NE causes pronounced tachycardia. This rapid heart rate may cause palpitations, breathlessness, and chest pain.

Dysfunctional energy metabolism causes fatigue and cognitive dysfunction: An important piece of the puzzle is to explain how a dysregulated SNS could lead to chronic fatigue and brain fog (cognitive dysfunction). The most likely explanation is a dysregulation of metabolic function. There are many ways excess NE could affect metabolism, including enhancing aerobic glycolysis and depleting glycogen stores.

Source: Carnac, T. (2023). Hypothesis: Astrocyte dysregulation of sympathetic nervous system causes metabolic dysfunction in subset of Long COVID and ME/CFS patients. Patient-Generated Hypotheses Journal for Long COVID & Associated Conditions, Vol. 1, 36-43 https://patientresearchcovid19.com/hypothesis-astrocyte-dysregulation-of-sympathetic-nervous-system-causes-metabolic-dysfunction-in-subset-of-long-covid-and-me-cfs-patients-pghj-issue1-may2023/ (Full text)

Inflammation From Peripheral Organs to the Brain: How Does Systemic Inflammation Cause Neuroinflammation?

Abstract:

As inflammation in the brain contributes to several neurological and psychiatric diseases, the cause of neuroinflammation is being widely studied. The causes of neuroinflammation can be roughly divided into the following domains: viral infection, autoimmune disease, inflammation from peripheral organs, mental stress, metabolic disorders, and lifestyle. In particular, the effects of neuroinflammation caused by inflammation of peripheral organs have yet unclear mechanisms.

Many diseases, such as gastrointestinal inflammation, chronic obstructive pulmonary disease, rheumatoid arthritis, dermatitis, chronic fatigue syndrome, or myalgic encephalomyelitis (CFS/ME), trigger neuroinflammation through several pathways. The mechanisms of action for peripheral inflammation-induced neuroinflammation include disruption of the blood-brain barrier, activation of glial cells associated with systemic immune activation, and effects on autonomic nerves via the organ-brain axis. In this review, we consider previous studies on the relationship between systemic inflammation and neuroinflammation, focusing on the brain regions susceptible to inflammation.

Source: Sun Y, Koyama Y, Shimada S. Inflammation From Peripheral Organs to the Brain: How Does Systemic Inflammation Cause Neuroinflammation? Front Aging Neurosci. 2022 Jun 16;14:903455. doi: 10.3389/fnagi.2022.903455. PMID: 35783147; PMCID: PMC9244793. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9244793/ (Full text)

The Pathobiology of Myalgic Encephalomyelitis/Chronic Fatigue Syndrome: The Case for Neuroglial Failure

Abstract:

Although myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS) has a specific and distinctive profile of clinical features, the disease remains an enigma because causal explanation of the pathobiological matrix is lacking. Several potential disease mechanisms have been identified, including immune abnormalities, inflammatory activation, mitochondrial alterations, endothelial and muscular disturbances, cardiovascular anomalies, and dysfunction of the peripheral and central nervous systems. Yet, it remains unclear whether and how these pathways may be related and orchestrated.

Here we explore the hypothesis that a common denominator of the pathobiological processes in ME/CFS may be central nervous system dysfunction due to impaired or pathologically reactive neuroglia (astrocytes, microglia and oligodendrocytes). We will test this hypothesis by reviewing, in reference to the current literature, the two most salient and widely accepted features of ME/CFS, and by investigating how these might be linked to dysfunctional neuroglia.

From this review we conclude that the multifaceted pathobiology of ME/CFS may be attributable in a unifying manner to neuroglial dysfunction. Because the two key features – post exertional malaise and decreased cerebral blood flow – are also recognized in a subset of patients with post-acute sequelae COVID, we suggest that our findings may also be pertinent to this entity.

Source: Renz-Polster H, Tremblay ME, Bienzle D, Fischer JE. The Pathobiology of Myalgic Encephalomyelitis/Chronic Fatigue Syndrome: The Case for Neuroglial Failure. Front Cell Neurosci. 2022 May 9;16:888232. doi: 10.3389/fncel.2022.888232. PMID: 35614970; PMCID: PMC9124899. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9124899/ (Full text)

A brain MRI study of chronic fatigue syndrome: evidence of brainstem dysfunction and altered homeostasis

Abstract:

To explore brain involvement in chronic fatigue syndrome (CFS), the statistical parametric mapping of brain MR images has been extended to voxel-based regressions against clinical scores.

Using SPM5 we performed voxel-based morphometry (VBM) and analysed T(1) – and T(2) -weighted spin-echo MR signal levels in 25 CFS subjects and 25 normal controls (NC). Clinical scores included CFS fatigue duration, a score based on the 10 most common CFS symptoms, the Bell score, the hospital anxiety and depression scale (HADS) anxiety and depression, and hemodynamic parameters from 24-h blood pressure monitoring. We also performed group × hemodynamic score interaction regressions to detect locations where MR regressions were opposite for CFS and NC, thereby indicating abnormality in the CFS group.

In the midbrain, white matter volume was observed to decrease with increasing fatigue duration. For T(1) -weighted MR and white matter volume, group × hemodynamic score interactions were detected in the brainstem [strongest in midbrain grey matter (GM)], deep prefrontal white matter (WM), the caudal basal pons and hypothalamus. A strong correlation in CFS between brainstem GM volume and pulse pressure suggested impaired cerebrovascular autoregulation.

It can be argued that at least some of these changes could arise from astrocyte dysfunction. These results are consistent with an insult to the midbrain at fatigue onset that affects multiple feedback control loops to suppress cerebral motor and cognitive activity and disrupt local CNS homeostasis, including resetting of some elements of the autonomic nervous system (ANS).

Copyright © 2011 John Wiley & Sons, Ltd.

 

Source: Barnden LR, Crouch B, Kwiatek R, Burnet R, Mernone A, Chryssidis S, Scroop G, Del Fante P. A brain MRI study of chronic fatigue syndrome: evidence of brainstem dysfunction and altered homeostasis. NMR Biomed. 2011 Dec;24(10):1302-12. doi: 10.1002/nbm.1692. Epub 2011 May 11. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC4369126/ (Full article)