Tag: oxidative stress

Intracellular Nutritional Biomarker Differences in Myalgic Encephalomyelitis/Chronic Fatigue Syndrome Subjects and Healthy Controls

Abstract:

Objectives

A comparison of the nutritional biomarkers between ME/CFS subjects and healthy controls (HC) was undertaken on secondary data collected from an IRB approved cross-sectional study in ME/CFS patients.

Methods

ME/CFS participants were recruited per the 2018 revised Canadian Clinical Case Definition for ME/CFS along with age matched HCs. Self-reported information on demographics and supplement use was collected, and body mass index calculated. HEI was calculated from Willet FFQ and multiple day 24-hour recall data, and severity of fatigue measured by Multidimensional Fatigue Inventory (MFI). Lymphocyte transformation assay by SpectraCell Lab (Houston, TX) was employed for intracellular micronutrient status. A series of two-tailed Mann-Whitney U tests (ɑ = 0.05) were performed for the non-parametric data expressed as mean ± standard error of the mean. All statistical analyses were conducted in IBM SPSS Statistics version 25 (Armonk, NY).

Results

Out of the 21 participants (11 ME/CFS and 10 HC), 82% of ME/CFS and 50% of HC were female. Higher fatigue scores were observed in ME/CFS (16.64 ± 1.36) than HC (10.78 ± 2.14). ME/CFS had better HEI scores (63.36 ± 13.44) than the HC (38.55 ± 12.29). However, despite better diet quality and supplementation, ME/CFS group showed lower intracellular Vitamin B3 and manganese (Mn) (86.3 ± 2.42 and 53.6 ± 2.81 respectively) but higher calcium (Ca) (57.5 ± 3.55) as compared to HC (97.2 ± 2.31, 64.5 ± 1.87 and 46.5 ± 0.96 respectively).

Conclusions

The results align with the current literature on indications of mitochondrial dysfunction in ME/CFS. Reduced intracellular vit B3 provides suboptimal production of the NAD(P)(H)-cofactor family, thus affecting mitochondrial function and consequently energy production. The aberration in energy metabolism is compounded by other factors, such as reduced Mn but higher Ca intracellular levels seen in this study indicating disruptions in oxidative stress pathways, resulting in debilitating fatigue experienced by individuals with ME/CFS.

Source: Priya Krishnakumar, Camila Jaramillo, Shawn Kurian, Wendy Levy, Cara Milman, Nadine Mikati, Fatma Huffman, Maria Abreu, Amanpreet Cheema, Intracellular Nutritional Biomarker Differences in Myalgic Encephalomyelitis/Chronic Fatigue Syndrome Subjects and Healthy Controls, Current Developments in Nutrition, Volume 6, Issue Supplement_1, June 2022, Page 745, https://doi.org/10.1093/cdn/nzac062.014

Long COVID and the Autonomic Nervous System: The Journey from Dysautonomia to Therapeutic Neuro-Modulation through the Retrospective Analysis of 152 Patients

Abstract:

Introduction. The severity and prevalence of Post-Acute COVID-19 Sequela (PACS) or long-COVID syndrome (long COVID) should not be a surprise. Long-COVID symptoms may be explained by oxidative stress and parasympathetic and sympathetic (P&S) dysfunction. This is a retrospective, hypothesis generating, outcomes study.
Methods. From two suburban practices in northeastern United States, 152 long COVID patients were exposed to the following practices: (1) first, they were P&S tested (P&S Monitor 4.0; Physio PS, Inc., Atlanta, GA, USA) prior to being infected with COVID-19 due to other causes of autonomic dysfunction; (2) received a pre-COVID-19 follow-up P&S test after autonomic therapy; (3) then, they were infected with COVID-19; (4) P&S tested within three months of surviving the COVID-19 infection with long-COVID symptoms; and, finally, (5) post-COVID-19, follow-up P&S tested, again, after autonomic therapy. All the patients completed autonomic questionnaires with each test. This cohort included 88 females (57.8%), with an average age of 47.0 years (ranging from 14 to 79 years), and an average BMI of 26.9 #/in2. Results. More pre-COVID-19 patients presented with sympathetic withdrawal than parasympathetic excess. Post-COVID-19, these patients presented with this ratio reversed and, on average, 49.9% more autonomic symptoms than they did pre-COVID-19.
Discussion. Both parasympathetic excess and sympathetic withdrawal are separate and treatable autonomic dysfunctions and autonomic treatment significantly reduces the prevalence of autonomic symptoms.
Conclusion. SARS-CoV-2, via its oxidative stress, can lead to P&S dysfunction, which, in turn, affects the control and coordination of all systems throughout the whole body and may explain all of the symptoms of long-COVID syndrome. Autonomic therapy leads to positive outcomes and patient quality of life may be restored.
Source: Colombo J, Weintraub MI, Munoz R, Verma A, Ahmad G, Kaczmarski K, Santos L, DePace NL. Long COVID and the Autonomic Nervous System: The Journey from Dysautonomia to Therapeutic Neuro-Modulation through the Retrospective Analysis of 152 Patients. NeuroSci. 2022; 3(2):300-310. https://doi.org/10.3390/neurosci3020021 https://www.mdpi.com/2673-4087/3/2/21/htm (Full text)

Aberrations in the Cross-Talks Among Redox, Nuclear Factor-κB, and Wnt/β-Catenin Pathway Signaling Underpin Myalgic Encephalomyelitis and Chronic Fatigue Syndrome

Abstract:

There is evidence that chronic fatigue spectrum disorders (CFAS-D) including Myalgic Encephalomyelitis (ME), chronic fatigue syndrome (CFS) and chronic fatigue with physiosomatic symptoms including when due to comorbid medical disease are characterized by neuroimmune and neuro-oxidative biomarkers.

The present study was performed to delineate the protein-protein interaction (PPI) network of CFAS-D and to discover the pathways, molecular patterns and domains enriched in their PPI network.

We performed network, enrichment and annotation analysis using differentially expressed proteins and metabolics, which were established in CFAS-D patients.

PPI network analysis revealed that the backbone of the highly connective CFAS-D network comprises NFKB1, CTNNB1, ALB, peroxides, NOS2, TNF, and IL6, and that the network comprises interconnected immune-oxidative-nitrosative and Wnt/catenin subnetworks.

MultiOmics enrichment analysis shows that the CFAS-D network is highly significantly associated with cellular (antioxidant) detoxification, hydrogen peroxide metabolic process, peroxidase and oxidoreductase activity, IL10 anti-inflammatory signaling, and neurodegenerative, canonical Wnt, the catenin complex, cadherin domains, cell-cell junctions and TLR2/4 pathways; and the transcription factors NF-κB and RELA.

The top-10 DOID annotations of the CFAS-D network include four intestinal, three immune system disorders, cancer and infectious disease.

Custom GO term annotation analysis revealed that the CFAS-D network is associated with a response to a toxic substance, lipopolysaccharides, bacterium or virus.

In conclusion, CFAS-D may be triggered by a variety of stimuli and their effects are mediated by aberrations in the cross-talks between redox, NF-κB, and Wnt/catenin signaling pathways leading to dysfunctions in multicellular organismal homeostatic processes.

Source: Michael Maes, Marta Kubera and Magdalena Kotańska. Aberrations in the Cross-Talks Among Redox, Nuclear Factor-κB, and Wnt/β-Catenin Pathway Signaling Underpin Myalgic Encephalomyelitis and Chronic Fatigue Syndrome. Frontiers in Psychiatry 13: 822382. https://www.frontiersin.org/articles/10.3389/fpsyt.2022.822382/full  (Full text)

Long-COVID post-viral chronic fatigue syndrome and affective symptoms are associated with oxidative damage, lowered antioxidant defenses and inflammation: a proof of concept and mechanism study

Abstract:

The immune-inflammatory response during the acute phase of COVID-19, as assessed using peak body temperature (PBT) and peripheral oxygen saturation (SpO2), predicts the severity of chronic fatigue, depression and anxiety (“physio-affective”) symptoms three to four months later. The present study was performed to characterize whether the effects of SpO2 and PBT on the physio-affective phenome of Long COVID are mediated by immune, oxidative and nitrosative stress (IO&NS) pathways.

This study assayed SpO2 and PBT during acute COVID-19, and C-reactive protein (CRP), malondialdehyde (MDA), protein carbonyls (PCs), myeloperoxidase (MPO), nitric oxide (NO), zinc, and glutathione peroxidase (Gpx) in 120 Long COVID individuals and 36 controls. Cluster analysis showed that 31.7% of the Long COVID patients had severe abnormalities in SpO2, body temperature, increased oxidative toxicity (OSTOX) and lowered antioxidant defenses (ANTIOX), and increased total Hamilton Depression (HAMD) and Anxiety (HAMA) and Fibromylagia-Fatigue (FF) scores.

Around 60% of the variance in the physio-affective phenome of Long COVID (a factor extracted from HAMD, HAMA and FF scores) was explained by OSTOX/ANTIOX ratio, PBT and SpO2. Increased PBT predicted increased CRP and lowered ANTIOX and zinc levels, while lowered SpO2 predicted lowered Gpx and increased NO production. Both PBT and SpO2 strongly predict OSTOX/ATIOX during Long COVID.

In conclusion, the impact of acute COVID-19 on the physio-affective symptoms of Long COVID is partly mediated by OSTOX/ANTIOX, especially lowered Gpx and zinc, increased MPO and NO production and lipid peroxidation-associated aldehyde formation. Post-viral physio-affective symptoms have an inflammatory origin and are partly mediated by neuro-oxidative toxicity.

Source: Hussein Kadhem Al-HakeimHaneen Tahseen Al-RubayeDhurgham Shihab Al-HadrawiAbbas F. AlmullaMichael Maes. Long-COVID post-viral chronic fatigue syndrome and affective symptoms are associated with oxidative damage, lowered antioxidant defenses and inflammation: a proof of concept and mechanism study. medRxiv 2022.04.25.22274251; doi: https://doi.org/10.1101/2022.04.25.22274251 https://www.medrxiv.org/content/10.1101/2022.04.25.22274251v1.full-text  (Full text)

Elevated ATG13 in serum of patients with ME/CFS stimulates oxidative stress response in microglial cells via activation of receptor for advanced glycation end products (RAGE)

Abstract:

Myalgic Encephalomyelitis, also known as Chronic Fatigue Syndrome (ME/CFS), is a multisystem illness characterized by extreme muscle fatigue associated with pain, neurocognitive impairment, and chronic inflammation. Despite intense investigation, the molecular mechanism of this disease is still unknown. Here we demonstrate that autophagy-related protein ATG13 is strongly upregulated in the serum of ME/CFS patients, indicative of impairment in the metabolic events of autophagy.

A Thioflavin T-based protein aggregation assay, array screening for autophagy-related factors, densitometric analyses, and confirmation with ELISA revealed that the level of ATG13 was strongly elevated in serum samples of ME/CFS patients compared to age-matched controls. Moreover, our microglia-based oxidative stress response experiments indicated that serum samples of ME/CFS patients evoke the production of reactive oxygen species (ROS) and nitric oxide in human HMC3 microglial cells, whereas neutralization of ATG13 strongly diminishes the production of ROS and NO, suggesting that ATG13 plays a role in the observed stress response in microglial cells. Finally, an in vitro ligand binding assay provided evidence that ATG13 employs the Receptor for Advanced Glycation End-products (RAGE) to stimulate ROS in microglial cells.

Collectively, our results suggest that an impairment of autophagy following the release of ATG13 into serum could be a pathological signal in ME/CFS.

Source: Gottschalk G, Peterson D, Knox K, Maynard M, Whelan RJ, Roy A. Elevated ATG13 in serum of patients with ME/CFS stimulates oxidative stress response in microglial cells via activation of receptor for advanced glycation end products (RAGE). Mol Cell Neurosci. 2022 Apr 26:103731. doi: 10.1016/j.mcn.2022.103731. Epub ahead of print. PMID: 35487443. https://www.sciencedirect.com/science/article/abs/pii/S1044743122000379?via%3Dihub (Full text)

“LONG COVID”-A hypothesis for understanding the biological basis and pharmacological treatment strategy

Abstract:

Infection of humans with SARS-CoV-2 virus causes a disease known colloquially as “COVID-19” with symptoms ranging from asymptomatic to severe pneumonia. Initial pathology is due to the virus binding to the ACE-2 protein on endothelial cells lining blood vessels and entering these cells in order to replicate. Viral replication causes oxidative stress due to elevated levels of reactive oxygen species. Many (~60%) of the infected people appear to have eliminated the virus from their body after 28 days and resume normal activity. However, a significant proportion (~40%) experience a variety of symptoms (loss of smell and/or taste, fatigue, cough, aching pain, “brain fog,” insomnia, shortness of breath, and tachycardia) after 12 weeks and are diagnosed with a syndrome named “LONG COVID.”

Longitudinal clinical studies in a group of subjects who were infected with SARS-CoV-2 have been compared to a non-infected matched group of subjects. A cohort of infected subjects can be identified by a battery of cytokine markers to have persistent, low level grade of inflammation and often self-report two or more troubling symptoms. There is no drug that will relieve their symptoms effectively.

It is hypothesized that drugs that activate the intracellular transcription factor, nuclear factor erythroid-derived 2-like 2 (NRF2) may increase the expression of enzymes to synthesize the intracellular antioxidant, glutathione that will quench free radicals causing oxidative stress. The hormone melatonin has been identified as an activator of NRF2 and a relatively safe chemical for most people to ingest chronically. Thus, it is an option for consideration of re-purposing studies in “LONG COVID” subjects experiencing insomnia, depression, fatigue, and “brain fog” but not tachycardia. Appropriately designed clinical trials are required to evaluate melatonin.

Source: Jarrott B, Head R, Pringle KG, Lumbers ER, Martin JH. “LONG COVID”-A hypothesis for understanding the biological basis and pharmacological treatment strategy. Pharmacol Res Perspect. 2022 Feb;10(1):e00911. doi: 10.1002/prp2.911. PMID: 35029046. https://bpspubs.onlinelibrary.wiley.com/doi/10.1002/prp2.911 (Full text)

Relationship Between Exercise-induced Oxidative Stress Changes and Parasympathetic Activity in Chronic Fatigue Syndrome: An Observational Study in Patients and Healthy Subjects

Abstract:

Purpose: Oxidative stress has been proposed as a contributor to pain in patients with myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS). During incremental exercise in patients with ME/CFS, oxidative stress enhances sooner and antioxidant response is delayed. We explored whether oxidative stress is associated with pain symptoms or pain changes following exercise, and the possible relationships between oxidative stress and parasympathetic vagal nerve activity in patients with ME/CFS versus healthy, inactive controls.

Methods: The present study reports secondary outcomes from a previous work. Data from 36 participants were studied (women with ME/CFS and healthy controls). Subjects performed a submaximal exercise test with continuous cardiorespiratory monitoring. Levels of thiobarbituric acid–reactive substances (TBARSs) were used as a measure of oxidative stress, and heart rate variability was used to assess vagal activity. Before and after the exercise, subjects were asked to rate their pain using a visual analogic scale.

Findings: Significant between-group differences in pain at both baseline and following exercise were found (both, P < 0.007). In healthy controls, pain was significantly improved following exercise (P = 0.002). No change in oxidative stress level after exercise was found. Significant correlation between TBARS levels and pain was found at baseline (r = 0.540; P = 0.021) and after exercise (r = 0.524; P = 0.024) in patients only. No significant correlation between TBARS and heart rate variability at baseline or following exercise was found in either group. However, a significant correlation was found between exercise-induced changes in HRV and TBARS in healthy controls (r = −0.720; P = 0.001).

Implications: Oxidative stress showed an association with pain symptoms in people with ME/CFS, but no exercise-induced changes in oxidative stress were found. In addition, the change in parasympathetic activity following exercise partially accounted for the change in oxidative stress in healthy controls. More research is required to further explore this link.

Source: Andrea Polli, MSc, Jessica Van Oosterwijck, PhD, Jo Nijs, PhD, Greta Moorkens, PhD, Luc Lambrecht, MD, Kelly Ickmans, PhD. Relationship Between Exercise-induced Oxidative Stress Changes and Parasympathetic Activity in Chronic Fatigue Syndrome: An Observational Study in Patients and Healthy Subjects. Clinical Therapeutics. ORIGINAL RESEARCH| VOLUME 41, ISSUE 4, P641-655, APRIL 01, 2019. Published online: January 18, 2019. Accepted: December 14, 2018. DOI: https://doi.org/10.1016/j.clinthera.2018.12.012 https://www.clinicaltherapeutics.com/article/S0149-2918(18)30611-8/fulltext#secsectitle0010 (Full article)

Neurochemical abnormalities in chronic fatigue syndrome: a pilot magnetic resonance spectroscopy study at 7 Tesla

Abstract:

Rationale: Chronic fatigue syndrome (CFS) is a common and burdensome illness with a poorly understood pathophysiology, though many of the characteristic symptoms are likely to be of brain origin. The use of high-field proton magnetic resonance spectroscopy (MRS) enables the detection of a range of brain neurochemicals relevant to aetiological processes that have been linked to CFS, for example, oxidative stress and mitochondrial dysfunction.

Methods: We studied 22 CFS patients and 13 healthy controls who underwent MRS scanning at 7 T with a voxel placed in the anterior cingulate cortex. Neurometabolite concentrations were calculated using the unsuppressed water signal as a reference.

Results: Compared to controls, CFS patients had lowered levels of glutathione, total creatine and myo-inositol in anterior cingulate cortex. However, when using N-acetylaspartate as a reference metabolite, only myo-inositol levels continued to be significantly lower in CFS participants.

Conclusions: The changes in glutathione and creatine are consistent with the presence of oxidative and energetic stress in CFS patients and are potentially remediable by nutritional intervention. A reduction in myo-inositol would be consistent with glial dysfunction. However, the relationship of the neurochemical abnormalities to the causation of CFS remains to be established, and the current findings require prospective replication in a larger sample.

Source: Godlewska BR, Williams S, Emir UE, Chen C, Sharpley AL, Goncalves AJ, Andersson MI, Clarke W, Angus B, Cowen PJ. Neurochemical abnormalities in chronic fatigue syndrome: a pilot magnetic resonance spectroscopy study at 7 Tesla. Psychopharmacology (Berl). 2021 Oct 5. doi: 10.1007/s00213-021-05986-6. Epub ahead of print. PMID: 34609538. https://pubmed.ncbi.nlm.nih.gov/34609538/

Redox Imbalance: A Core Feature of ME/CFS and Acute COVID-19

By Dr. Anthony Komaroff

ME/CFS is defined exclusively by symptoms—subjective experiences that are hard to verify by objective testing. For that reason, since interest in ME/CFS began to grow in the 1980s, scientists have been looking for evidence of underlying objective abnormalities that might explain the symptoms.

A recent review, published August 24, 2021, in the Proceedings of the National Academy of Sciences USA, summarizes in detail the evidence demonstrating one of the several objective abnormalities in people with ME/CFS and acute COVID-19: redox imbalance.1 It speculates that redox imbalance may also be present in post-acute COVID-19 syndrome, or “long COVID-19”, although this remains to be studied.

Redox imbalance occurs when the molecules that are oxidants (particularly “free radicals” or reactive oxygen species) exceed the number of molecules that are antioxidants. Essentially, redox imbalance is the same as the more familiar term of “oxidative stress”.

Read the rest of this article HERE.

The reification of the clinical diagnosis of myalgic encephalomyelitis / chronic fatigue syndrome (ME/CFS) as an immune and oxidative stress disorder: construction of a data-driven nomothethic network and exposure of ME/CFS subgroups

Abstract:

The approach towards myalgic encephalomyelitis / chronic fatigue syndrome (ME/CFS) remains in a permanent state of crisis with fierce competition between the psychosocial school, which attributes ME/CFS to the perception of effort, and the medical approach (Maes and Twisk, BMC Med, 2010,8,35). The aim of this paper is to review how to construct a nomothetic model of ME/CFS using Partial Least Squares (PLS) path analysis and ensembling causome (bacterial translocation as assessed with IgM/IgA responses to LPS), protectome (lowered coenzyme Q10), adverse outcome pathways (AOP) including increased lysozyme, CD38+ T cell activation, cell-mediated immune activation (CMI), and IgM responses to oxidative specific epitopes and NO-adducts (IgM OSENO).

Using PLS, we trained, tested and validated this knowledge- and data-driven causal ME/CFS model, which showed adequate convergence, construct and replicability validity. This bottom-up explicit data model of ME/CFS objectivates the descriptive narratives of the ME/CFS phenome, using causome-protectome-AOP data, whereby the abstract concept ME/CFS is translated into pathways, thereby securing the reification of the ME/CFS phenome.

We found that 31.6% of the variance in the physiosomatic symptom dimension of ME/CFS was explained by the cumulative effects of CMI and CD38+ activation, IgM OSENO, IgA LPS, lysozyme (all positive) and coenzyme Q10 (inversely). Cluster analysis performed on the PLS-generated latent vector scores of all feature sets exposed three distinct immune groups of ME/CFS, namely one with increased lysozyme, one with increased CMI + CD38 activation + depressive symptoms, and another with increased bacterial translocation + autoimmune responses to OSENO

Source: Maes M, Kubera M, Stoyanova K, Leunis JC. The reification of the clinical diagnosis of myalgic encephalomyelitis / chronic fatigue syndrome (ME/CFS) as an immune and oxidative stress disorder: construction of a data-driven nomothethic network and exposure of ME/CFS subgroups. Curr Top Med Chem. 2021 Jul 27. doi: 10.2174/1568026621666210727170147. Epub ahead of print. PMID: 34315375. https://pubmed.ncbi.nlm.nih.gov/34315375/