Tag: PEM

Single-cell transcriptomics of the immune system in ME/CFS at baseline and following symptom provocation

Summary:

ME/CFS is a serious and poorly understood disease. To understand immune dysregulation in ME/CFS, we used single-cell RNA-seq (scRNA-seq) to examine immune cells in cohorts of patients and controls. Post-exertional malaise (PEM), an exacerbation of symptoms following strenuous exercise, is a characteristic symptom of ME/CFS. Thus, to detect changes coincident with PEM, we also performed scRNA-seq on the same cohorts following exercise. At baseline, ME/CFS patients displayed dysregulation of classical monocytes suggestive of inappropriate differentiation and migration to tissue. We were able to identify both diseased and more normal monocytes within patients, and the fraction of diseased cells correlated with metrics of disease severity. Comparing the transcriptome at baseline and post-exercise challenge, we discovered patterns indicative of improper platelet activation in patients, with minimal changes elsewhere in the immune system. Taken together, these data identify immunological defects present at baseline in patients and an additional layer of dysregulation following exercise.

Highlights ME/CFS is a debilitating disease with unknown causes. Here, we provide, for the first time, an extensive single cell resolution dataset detailing the gene expression programs of circulating immune cells of ME/CFS cases at baseline and after symptom provocation. We were able to detect robust dysregulation in certain immune cells from patients, with dysregulation of classical monocytes manifesting the strongest signal. Indeed, the fraction of aberrant monocytes in ME/CFS patients correlated with the degree of disease severity. Surprisingly, platelet transcriptomes were also altered in ME/CFS, and they were the only component of the immune system that showed large-scale changes following symptom provocation.

Source: Faraz AhmedLuyen Tien VuHongya ZhuDavid Shing Huk IuElizabeth A. FogartyYeonui KwakWeizhong ChenCarl J. FranconiPaul R. MunnSusan M. LevineJared StevensXiangling MaoDikoma C. ShunguGeoffrey E. MooreBetsy A. KellerMaureen R. HansonJennifer K. GrenierAndrew Grimson. Single-cell transcriptomics of the immune system in ME/CFS at baseline and following symptom provocation. bioRxiv 2022.10.13.512091; doi: https://doi.org/10.1101/2022.10.13.512091 https://www.cell.com/cell-reports-medicine/fulltext/S2666-3791(23)00602-X (Full text)

Diminished Cardiopulmonary Capacity During Post-Exertional Malaise

Abstract:

Reduced functional capacity and post-exertional malaise following physical activity are hallmark symptoms of Chronic Fatigue Syndrome (CFS). That these symptoms are often delayed may explain the equivocal results for clinical cardiopulmonary exercise testing with CFS patients. The reproducibility of VO2 max in healthy subjects is well documented. This may not be the case with CFS due to delayed recovery symptoms.

Purpose: To compare results from repeated exercise tests as indicators of post-exertional malaise in CFS.

Methods: Peak oxygen consumption (VO2 peak), percentage of predicted peak heart rate (HR%), and VO2 at anaerobic threshold (AT), were compared between six CFS patients and six control subjects for two maximal exercise tests separated by 24 hours.

Results: Multivariate analysis showed no significant differences between control and CFS, respectively, for test 1: VO2 peak (28.4 ± 7.2 ml/ kg/min; 26.2 ± 4.9 ml/kg/min), AT (17.5 ± 4.8 ml/kg/min; 15.0 ± 4.9 ml/ kg/min) or HR% (87.0 ± 25.4%; 94.8 ± 8.8%). However, for test 2 the CFS patients achieved significantly lower values for both VO2 peak (28.9 ± 8.0 ml/kg/min; 20.5 ± 1.8 ml/kg/min, p = 0.031) and AT (18.0 ± 5.2 ml/kg/min; 11.0 ± 3.4 ml/kg/min, p = 0.021). HR% was not significantly different (97.6 ± 27.2%; 87.8 ± 9.3%, p = 0.07). A follow-up classification analysis differentiated between CFS patients and controls with an overall accuracy of 92%.

Conclusion: In the absence of a second exercise test, the lack of any significant differences for the first test would appear to suggest no functional impairment in CFS patients. However, the results from the second test indicate the presence of a CFS related post-exertional malaise. It might be concluded then that a single exercise test is insufficient to demonstrate functional impairment in CFS patients. A second test may be necessary to document the atypical recovery response and protracted malaise unique to CFS.

Source: J. Mark Vanness, Christopher R. Snell & Staci R. Stevens (2007) Diminished Cardiopulmonary Capacity During Post-Exertional Malaise, Journal of Chronic Fatigue Syndrome, 14:2, 77-85, DOI: 10.1300/J092v14n02_07

Post-COVID syndrome with fatigue and exercise intolerance: myalgic encephalomyelitis/chronic fatigue syndrome

Abstract:

in English, German

Background: A sizable part of post-COVID syndrome meets the diagnostic criteria for myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS). A doubling of cases of ME/CFS within the next years is therefore projected.

Objectives: Presentation of the current state of knowledge on ME/CFS.

Materials and methods: Unsystematic review of the literature and of own contributions in research and patient care.

Results and conclusions: ME/CFS is a neuroimmunological disease, mostly infection-induced, usually persisting throughout life. Clinically it is characterized by fatigue lasting at least 6 months and the defining core feature of exercise intolerance (post-exertional malaise, PEM). Exercise intolerance is defined as a worsening of symptoms after (even mild) everyday exertion, which usually begins after several hours or on the following day, is still noticeable at least 14 h after exertion, and often lasts for several days (up to weeks or longer). Furthermore, ME/CFS is characterized by pain, disturbances of sleep, thinking and memory, and dysregulation of the circulatory, endocrine, and immune systems.

As a separate clinical entity, ME/CFS should be distinguished from chronic fatigue, which occurs as a symptom of a range of very different diseases. The diagnosis of ME/CFS is made clinically using established international diagnostic criteria and requires careful stepwise diagnosis to exclude other diagnoses. A causal therapy for ME/CFS has not been established; the focus is on symptoms relief, treatment of the often accompanying orthostatic intolerance, and assistance with anticipatory energy management (pacing).

Source: Renz-Polster H, Scheibenbogen C. Post-COVID-Syndrom mit Fatigue und Belastungsintoleranz: Myalgische Enzephalomyelitis bzw. Chronisches Fatigue-Syndrom [Post-COVID syndrome with fatigue and exercise intolerance: myalgic encephalomyelitis/chronic fatigue syndrome]. Inn Med (Heidelb). 2022 Aug;63(8):830-839. German. doi: 10.1007/s00108-022-01369-x. Epub 2022 Jul 13. PMID: 35925074. https://pubmed.ncbi.nlm.nih.gov/35925074/  https://link.springer.com/article/10.1007/s00108-022-01369-x (Full text in German)

Neurovascular Dysregulation and Acute Exercise Intolerance in ME/CFS: A Randomized, Placebo-Controlled Trial of Pyridostigmine

Abstract:

Background: Myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS) is characterized by intractable fatigue, post-exertional malaise, and orthostatic intolerance, but its pathophysiology is poorly understood. Pharmacologic cholinergic stimulation was used to test the hypothesis that neurovascular dysregulation underlies exercise intolerance in ME/CFS.

Research Question: Does neurovascular dysregulation contribute to exercise intolerance in ME/CFS and can its treatment improve exercise capacity?

Methods: Forty-five subjects with ME/CFS were enrolled in a single-center, randomized, double-blind, placebo-controlled trial. Subjects were assigned in a 1:1 ratio to receive a 60 mg dose of oral pyridostigmine or placebo after an invasive cardiopulmonary exercise test (iCPET). A second iCPET was performed 50 minutes later. The primary end point was the difference in peak exercise oxygen uptake (VO2). Secondary end points included exercise pulmonary and systemic hemodynamics and gas exchange.

Results: Twenty-three subjects were assigned to pyridostigmine and 22 to placebo. The peak VO2 increased after pyridostigmine but decreased after placebo (13.3 ± 13.4 mL/min vs. -40.2 ± 21.3 mL/min, P<0.05). The treatment effect of pyridostigmine was 53.6 mL/min (95% CI, -105.2 to -2.0). Peak versus rest VO2 (25.9 ± 15.3 mL/min vs. -60.8 ± 25.6 mL/min, P<0.01), cardiac output (-0.2 ± 0.6 L/min vs. -1.9 ± 0.6 L/min, P<0.05), and RAP (1.0 ± 0.5 mm Hg vs. -0.6 ± 0.5 mm Hg, P<0.05) were greater in the pyridostigmine group compared to placebo.

Interpretation: Pyridostigmine improves peak VO2 in ME/CFS by increasing cardiac output and right ventricular filling pressures. Worsening peak exercise VO2, Qc, and RAP after placebo may signal the onset of post-exertional malaise. We suggest treatable neurovascular dysregulation underlies acute exercise intolerance in ME/CFS.

Abbreviations List: Ca-vO2 (arterial-venous oxygen content difference), iCPET (Invasive cardiopulmonary exercise test), MAP (Mean arterial pressure), mPAP (Mean pulmonary artery pressure), ME/CFS (Myalgic encephalomyelitis/chronic fatigue syndrome), PASC (Post-acute sequelae of SARS-CoV-2 infection), PAWP (Pulmonary arterial wedge pressure), POTS (Postural orthostatic tachycardia syndrome), Qc (Cardiac output), RAP (Right atrial pressure), SE (Standard error), SFN (Small fiber neuropathy), VE/VCO2 (Ventilatory efficiency), VO2 (Oxygen uptake)

Source: Phillip Joseph, MD, Rosa Pari, MD, Sarah Miller, BS, Arabella Warren, BS, Mary Catherine Stovall, BS, Johanna Squires, MSc, Chia-Jung Chang, PhD, Wenzhong Xiao, PhD, Aaron B. Waxman, MD, PhD, David M. Systrom, MD. Neurovascular Dysregulation and Acute Exercise Intolerance in ME/CFS: A Randomized, Placebo-Controlled Trial of Pyridostigmine. Chest, Published: May 05, 2022. DOI: https://doi.org/10.1016/j.chest.2022.04.146

Acute effect of pyridostigmine in exertional intolerance in Myalgic Encephalomyelitis/Chronic Fatigue Syndrome (ME/CFS): A randomized placebo-controlled clinical trial

Rationale: One third of patients with myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS) have evidence of small fiber neuropathy (SFN). Neurovascular dysregulation during upright exercise may be associated with impaired venoconstriction resulting in low biventricular filling pressures and impaired arteriolar constriction resulting in a mismatch between perfusion and skeletal muscle metabolism. We hypothesize that pyridostigmine, a reversible acetylcholinesterase inhibitor, may improve vascular regulation and exercise tolerance in ME/CFS by increasing sympathetic outflow.

Methods: 45 subjects (39 women, 6 men) with ME/CFS were assessed. A baseline invasive cardiopulmonary exercise test (iCPET) was performed to confirm presence of low peak exercise RAP (<6.5mmHg). Eligible subjects were blindly administered placebo (n=22) or 60mg pyridostigmine (n=23) at a 1:1 ratio. A second iCPET was performed following a 50 minute combined rest and dosing period. Serial iCPET results were compared to assess changes in oxygen uptake at peak exercise (VO2 max). Secondary outcomes included subject ventilatory efficiency (VE/VCO2), peak hemodynamic response (RAP, PCWP, SV, Qt), systemic gas exchange (Ca-vO2/Hgb), and subjective reporting of dyspnea and fatigue. Results: 39 subjects (all women) were considered in data analysis. There was a significant increase in VO2 max between iCPET 1 and iCPET 2 in the treatment group when compared with the placebo group (p = 0.043).

There was a significant decrease in the placebo group and a significant increase in the treatment group in VO2 (p = 0.008), Qt (p = 0.039), and RAP (p = 0.045) when comparing iCPET 1 peak – rest and iCPET 2 peak – rest between groups. There were no significant differences in peak arteriovenous oxygen content difference (Ca-vO2/Hgb). 38% of subjects had objective evidence of SFN with no statistically significant difference between groups.

Conclusion: Using pyridostigmine as an investigative tool, this study suggests that neurovascular dysregulation underlies acute exercise intolerance in ME/CFS. Additionally, we have new evidence that worsening vascular dysregulation results from prior exercise, which sheds insight into the post exertional malaise that is a hallmark of this syndrome.

Source: M. Stovall, P. Joseph, R. Pari, A. Warren, S. Miller, J. Squires, W. Xiao, A.B. Waxman, D.M. Systrom. Acute effect of pyridostigmine in exertional intolerance in Myalgic Encephalomyelitis/Chronic Fatigue Syndrome (ME/CFS): A randomized placebo-controlled clinical trial. American Journal of Respiratory and Clinical Care Medicine, Vol 205, p A2063, May 2022. https://www.atsjournals.org/doi/pdf/10.1164/ajrccm-conference.2022.205.1_MeetingAbstracts.A2063

Plasma metabolomics reveals disrupted response and recovery following maximal exercise in Myalgic Encephalomyelitis/Chronic Fatigue Syndrome

Abstract:

Post-exertional malaise (PEM) is a hallmark symptom of Myalgic Encephalomyelitis/Chronic Fatigue Syndrome (ME/CFS). We monitored the evolution of 1,157 plasma metabolites in 60 ME/CFS cases (45 females, 15 males) and in 45 matched healthy control subjects (30 females, 15 males) before and after two maximal Cardiopulmonary Exercise Test (CPET) challenges separated by 24 hours, with the intent of provoking PEM in patients. Four timepoints allowed exploration of the metabolic response to maximal energy-producing capacity and the recovery pattern of ME/CFS cases compared to the healthy control group.

Baseline comparison identified several significantly different metabolites, along with an enriched percentage of yet-to-be identified compounds. Additionally, temporal measures demonstrated an increased metabolic disparity between cohorts, including unknown metabolites. The effects of exertion in the ME/CFS cohort predominantly highlighted lipid- as well as energy-related pathways and chemical structure clusters, which were disparately affected by the first and second exercise sessions.

The 24-hour recovery period was distinct in the ME/CFS cohort, with over a quarter of the identified pathways statistically different. The pathways that are uniquely different 24 hours after an exercise challenge provide clues to metabolic disruptions that lead to PEM. Numerous altered pathways were observed to depend on glutamate metabolism, a crucial component to the homeostasis of many organs in the body, including the brain.

Source: Germain A, Giloteaux L, Moore GE, Levine SM, Chia JK, Keller BA, Stevens J, Franconi CJ, Mao X, Shungu DC, Grimson A, Hanson MR. Plasma metabolomics reveals disrupted response and recovery following maximal exercise in Myalgic Encephalomyelitis/Chronic Fatigue Syndrome. JCI Insight. 2022 Mar 31:e157621. doi: 10.1172/jci.insight.157621. Epub ahead of print. PMID: 35358096. https://pubmed.ncbi.nlm.nih.gov/35358096/

Lessons from Myalgic Encephalomyelitis/Chronic Fatigue Syndrome for Long COVID Part 4: Heart Rate Monitoring to Manage Postexertional Symptom Exacerbation

The physiology underlying postexertional symptom exacerbation (PESE) is abnormal in myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS) and likely long COVID. Activity pacing approaches appear warranted to accommodate the unusual physiological deficits of PESE.

The Rationale for Heart Rate Monitoring

Similar to people living with ME/CFS,7 people living with long COVID have reported finding activity pacing to be helpful. This idea is reflected in current safe rehabilitation guidelines for this condition.8 PESE is challenging to self-manage because of the variability in onset, duration, and nature from person to person.2,6 Social stigma associated with PESE may lead people to overexert to meet the demands of their daily tasks. This stigma may be exacerbated by people telling patients that “it’s all in their head” or they “just need to exercise.” Variability and stigma, in turn, make it difficult to identify important activity triggers in the early stages of learning to manage PESE.

PESE is characterized by aerobic system dysfunction. Pacing based on heart rate can help the patient avoid the dysfunctional aerobic system by keeping their activity intensity at a level anaerobic metabolism will dominate. Heart rate monitoring (HRM) provides an element of predictive potential for the patient to understand when their activities exceed physiological limits and eventually may result in PESE. In this post, we will discuss activity pacing to manage PESE that is based on HRM.

Source: Todd E. Davenport, Staci R. Stevens, Jared Stevens, Christopher R. Snell, J. Mark Van Ness. Lessons from Myalgic Encephalomyelitis/Chronic Fatigue Syndrome for Long COVID Part 4: Heart Rate Monitoring to Manage Postexertional Symptom Exacerbation. Published online on February 23, 2022. https://doi.org/10.2519/jospt.blog.20220223 (Full text)

Lessons from Myalgic Encephalomyelitis/Chronic Fatigue Syndrome for Long COVID Part 2: Physiological Characteristics During Acute Exercise Are Abnormal in People With Postexertional Symptom Exacerbation

In a previous post on the JOSPT Blog, we outlined the connection between postacute sequalae to novel coronavirus (long COVID) and myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS) through their common clinical presentation: postexertional symptom exacerbation (PESE). PESE suggests the presence of abnormal physiological responses to exercise/activity. These physiological responses may be measured using cardiopulmonary exercise testing (CPET), which allows for careful characterization of cardiac, pulmonary, and metabolic functioning during exercise. We will review the characteristic findings on CPET in people with PESE.

The Physiology of PESE

One well-established protocol involves consecutive-day CPETs.8 In deconditioned people and people with a whole host of health conditions, CPET measurements demonstrate low error variance. Yet, CPET measurements are known to vary between tests in people with PESE.2 The observed variation in people with PESE reflects the biological variance associated with PESE.2 Clues about biological variance can provide important information about the underlying pathoetiology, severity, and functional limitations present.2,8 CPET data from peak exertion and ventilatory anaerobic threshold (VAT) provide important snapshots of physiological functioning. Data from peak exertion tells us about the physiology of a person’s “top-end” performance, and data from VAT elucidates the physiology of more “everyday” levels of exertion.

Read the rest of this article HERE.

Source: Todd E. Davenport, Staci R. Stevens, Jared Stevens, Christopher R. Snell, J. Mark Van Ness. Lessons from Myalgic Encephalomyelitis/Chronic Fatigue Syndrome for Long COVID Part 2: Physiological Characteristics During Acute Exercise Are Abnormal in People With Postexertional Symptom Exacerbation. JOSPT blog, Published online on February 9, 2022. https://doi.org/10.2519/jospt.blog.20220209 (Full text)

Lessons from Myalgic Encephalomyelitis/Chronic Fatigue Syndrome for Long COVID: Postexertional Symptom Exacerbation is an Abnormal Response to Exercise/Activity

Prolonged symptoms after infection with the novel coronavirus 2019 (SARS-COV-2) are an emerging challenge to individual patients, society, and clinicians. In a previous post on the JOSPT Blog, we identified several lessons from research and clinical practice in myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS) that are important lessons for long COVID. The purpose of this post is to discuss the phenomenon of postexertional symptom exacerbation (PESE) and its clinical identification to recognize the potential onset of long COVID.

Data from a large international web-based patient survey indicate substantial symptom overlap between postacute SARS-COV-2 infection (long COVID) and ME/CFS at 6 months following the onset of first symptoms. Three quarters of respondents noted disabling fatigue and over half noted cognitive dysfunction.4 A unique finding of this survey was that 75% of respondents noted PESE, which is a worsening of symptoms after activity/exercise.4 PESE is foundational to the diagnosis of ME/CFS and it is common with long COVID.4,5 This observation suggests we can further extend lessons from ME/CFS to develop our understanding of long COVID.

Read the rest of this article HERE.

Source: Todd E. Davenport Staci R. Stevens Jared Stevens Christopher R. Snell J. Mark Van Ness. Lessons from Myalgic Encephalomyelitis/Chronic Fatigue Syndrome for Long COVID: Postexertional Symptom Exacerbation is an Abnormal Response to Exercise/Activity. Published online on February 2, 2022 https://doi.org/10.2519/jospt.blog.20220202

Myalgic encephalomyelitis/chronic fatigue syndrome post coronavirus disease 2019

Coronavirus disease 2019 (COVID-19), an infectious disease caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), has been the most impactful infectious disease in the 21st century. The SARS-CoV-2 pandemic significantly increased the number of patients and deaths worldwide. Long-course diseases related to COVID-19, which present with persistent reparatory distress or fatigue (so-called long COVID) have been reported in adult and pediatric patients since the latter half of 2020. Long-COVID is observed as a persistent symptom after the acute phase of the disease.1 Recent research suggested that it can present with myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS).2 We report a case of long COVID to contribute to the body of knowledge regarding this disease, which has not been well investigated in children.

A 14-year-old boy with well controlled asthma, controlled by a long-acting muscarinic antagonist, long-acting beta-agonist, and corticosteroid inhaler, was admitted to our hospital for severe fatigue and appetite loss. He suffered from COVID-19 diagnosed using reverse transcription polymerase chain reaction 90 days prior to hospitalization. He presented with a low-grade fever, mild cough, dysgeusia, and dysosmia. He was placed under quarantine in a hotel room for 6 days. His low-grade fever and mild cough resolved after 10 days, while the dysgeusia and dysosmia disappeared within a month. He presented with gradually progressive upper limb muscle weakness, severe fatigue, and difficulty concentrating (so-called “brain fog”) 20 days before hospitalization (70 days after the onset of COVID-19). He was unable to commute to attend junior high school. Three days before hospitalization, the patient did not eat due to appetite loss. He received oral prednisolone (20 mg/day) and Kanpō medicine (Rikkun-shito and Hotyu-ekkito). However, his symptoms were not relieved, and the patient was hospitalized. At the time of hospitalization, he did not present with fever, dyspnea, or desaturation. Physical examination revealed an upper limb strength of grade 4 on manual muscle testing, but the tendon reflexes or sensory/motor nerve abnormalities were not noted in the extremities. Blood tests revealed normal white blood cell and C-reactive protein levels. Epstein–Barr virus and human immunodeficiency virus antibodies and antinuclear antibodies were not detected. The 10 min standing test revealed an increase of 52 heartbeats after standing at an upright position (from 81 to 133 beats/min). The patient was diagnosed with postural orthostatic tachycardia syndrome (POTS). After the test, the patient complained of worsening fatigue, suggesting post-exertional malaise (PEM), a specific characteristic of ME/CFS. Based on the clinical course and physical examination, the patient was diagnosed with ME/CFS due to long-COVID. Oral prednisolone was discontinued, while the Kanpō medicine was continued. The patient then developed alopecia. Meanwhile, his muscle weakness and fatigue were alleviated by activity restriction due to hospitalization. On the 14th day of admission, he was discharged because his appetite improved, and he was referred to a hospital that specifically tended to chronic fatigue syndrome patients. Neither brain imaging nor electroencephalography were performed throughout the patient’s hospitalization.

The National Institute for Health Research in England classified long-COVID into four categories, namely, post-ICU syndrome, long-term organ damage, post-viral syndrome, and an entirely novel syndrome.3 Myalgic encephalomyelitis/chronic fatigue syndrome is typical of post-viral syndromes in adults, and similar cases have also been reported in children.4 Females are more likely to suffer from the disease, but males could also be affected. The exacerbation of symptoms upon exertion is known as PEM; avoiding extensive work is the essential aspect of ME/CFS management.5 In this case, the patient’s muscle fatigue and weakness dramatically improved with activity restriction due to hospitalization. This strategy may be useful for treating the severe exacerbation of ME/CFS. Chronic fatigue syndrome is diagnosed based on the persistence of symptoms for more than 6 months.2 This implies that patients have to wait for 6 months to be diagnosed with ME/CFS. Thus, new diagnostic criteria, specifically for ME/CFS due to COVID, are required to allow early intervention. Petracek et al. reported that POTS might be an early sign of COVID-induced ME/CFS,4 POTS is considered to be a viable diagnostic criterion. To prepare for a surge of pediatric ME/CFS, the diagnostic and treatment algorithm for the disease should be standardized, and physicians need to know about or recognize the disease.

Read more HERE.

Source: Kusama Y, Fukui S, Maruyama M, Kamimura K, Maihara T. Myalgic encephalomyelitis/chronic fatigue syndrome post coronavirus disease 2019. Pediatr Int. 2022 Jan;64(1):e14976. doi: 10.1111/ped.14976. PMID: 35143110. https://onlinelibrary.wiley.com/doi/10.1111/ped.14976 (Full text)