CPET – Page 3 – American ME and CFS Society

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

Reproducibility of Measurements Obtained During Cardiopulmonary Exercise Testing in Individuals With Fatiguing Health Conditions – A Case Series

Abstract:

Purpose: Measurements obtained during maximal cardiopulmonary exercise testing (CPET) demonstrate high test–retest reliability, which indicates low error variance. However, measurements obtained from people with myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS) may depart from typically observed high reproducibility, which could represent functionally relevant biological variability that is characteristic of the underlying pathophysiology. The purpose of this case series was to document individual experiences with test–retest variability in CPET measurements in individuals with ME/CFS compared with other fatiguing health conditions.

Methods: In this case series, 6 women matched for age and body mass index underwent 2 maximal CPETs spaced 24 hours apart. Clients comprised 1 sedentary individual without fatigue, 1 active individual without fatigue, 1 individual with multiple sclerosis (MS), 1 individual diagnosed with HIV, 1 individual with ME/CFS and low maximal volume of oxygen consumed (VO₂max), and 1 high-functioning individual with ME/CFS and high VO₂max. Percent change in CPET measurements between tests was calculated for each client.

Results: Nondisabled clients and clients with MS and HIV reproduced or improved in their volume of oxygen consumed (VO₂), workload (WL), heart rate (HR), and minute ventilation (VE) at ventilatory anaerobic threshold (VAT) and at peak exercise (except peak WL and VE for the individual with HIV). Neither individual with ME/CFS reproduced VO₂, WL, HR, or VE at VAT within literature estimates.

Conclusions: Measurements during CPET for individual patients may relate to potential condition-specific deficits in cardiac, pulmonary, and metabolic functioning.

Source: Larson, Benjamin PT, DPT¹; Davenport, Todd E. PT, DPT, MPH, OCS^2,3; Stevens, Staci R. MA³; Stevens, Jared BS³; Van Ness, J. Mark PhD^3,4; Snell, Christopher R. PhD³. Reproducibility of Measurements Obtained During Cardiopulmonary Exercise Testing in Individuals With Fatiguing Health Conditions: A Case Series. Cardiopulmonary Physical Therapy Journal: October 2019 – Volume 30 – Issue 4 – p 145-152 doi: 10.1097/CPT.0000000000000100 https://journals.lww.com/cptj/Abstract/2019/10000/Reproducibility_of_Measurements_Obtained_D%20uring.4.aspx

Validity of 2-Day Cardiopulmonary Exercise Testing in Male Patients with Myalgic Encephalomyelitis/Chronic Fatigue Syndrome

Abstract:

Introduction: Among the main characteristics of patients with myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS) are effort intolerance along with a prolonged recovery from exercise and post-exertional exacerbation of ME/CFS symptoms. The gold standard for measuring the severity of physical activity intolerance is cardiopulmonary exercise testing (CPET). Multiple studies have shown that peak oxygen consumption is reduced in the majority of ME/CFS patients. A consecutive day CPET protocol has shown a difference on day 2 in ME/CFS patients in contrast to sedentary controls. Because of the low number of male ME/CFS patients in the published literature, and because of a possible gender difference in the clinical phenotype, the aim of this study was to examine whether the response to a 2-day CPET protocol in a larger sample of male ME/CFS patients was similar to that observed in females.

Methods: From 77 male patients, 25 male ME/CFS patients fulfilled the criteria of a 2-day CPET protocol for analysis. Measures of oxygen consumption (VO₂), heart rate (HR), systolic and diastolic blood pressure, workload (Work), and respiratory exchange ratio (RER) were made at maximal (peak) and ventilatory threshold (VT) intensities. Data were analysed using a paired t-test.

Results: Baseline characteristics of the group were as follows. Mean age was 44 (12) years, mean BMI was 27.1 (4.4) kg/m². Median disease duration was 10 years (IQR 7 – 13). Heart rate, systolic and diastolic blood pressure at rest and the RER did not differ significantly between CPET 1 and CPET 2. All other CPET parameters at the ventilatory threshold and maximum exercise differed significantly (p-value between <0.005 and <0.0001). All patients experienced a deterioration of performance on CPET2 as measured by the predicted and actual VO₂ and workload at peak exercise and ventilatory threshold.

Conclusion: This study confirms that male ME/CFS patients have a reduction in exercise capacity in response to a consecutive day CPET. These results are similar to published results in female ME/CFS populations.

Source:

Correlation of respiratory muscle function and cardiopulmonary exercise testing in post-acute COVID-19 syndrome

To the editors,

We read the paper published by Hennigs et al. [1] with great interest and thank the authors for shifting the focus to studying respiratory muscle function in Post-COVID-19 patients. The authors report striking pathological findings of mouth occlusion pressure (MOP) measurements in previously hospitalized but also non-hospitalized patients presenting with post-acute COVID-19 syndrome (PACS). In their study, Hennigs and co-authors found a high proportion of patients, more frequently females, with decreased maximum inspiratory pressure (MIP, or PImax), suggesting impairment of respiratory muscle strength. Additionally, their data indicate that increased neuroventilatory or central ventilatory drive (P0.1) may have a role in perceived respiratory distress in patients suffering from Post-COVID-19 fatigue. With this letter, we would like to share complementary data from a case series correlating MIP and P0.1 with cardiopulmonary exercise testing (CPET) in patients with PACS. Furthermore, we aim to elaborate on the limitations of MOP measurements, particularly MIP.

Read the rest of this article HERE.

Source: Leo F, Bülau JE, Semper H, Grohé C. Correlation of respiratory muscle function and cardiopulmonary exercise testing in post-acute COVID-19 syndrome. Infection. 2022 Aug 16:1–4. doi: 10.1007/s15010-022-01899-4. Epub ahead of print. PMID: 35972679; PMCID: PMC9379900. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9379900/ (Full text)

Inflammation during early post-acute COVID-19 is associated with reduced exercise capacity and Long COVID symptoms after 1 year

Abstract:

Background: Mechanisms underlying persistent cardiopulmonary symptoms following SARS-CoV-2 infection (post-acute sequelae of COVID-19 “PASC” or “Long COVID”) remain unclear. The purpose of this study was to elucidate the pathophysiology of cardiopulmonary PASC using multimodality cardiovascular imaging including cardiopulmonary exercise testing (CPET), cardiac magnetic resonance imaging (CMR) and ambulatory rhythm monitoring.

Methods: We performed CMR, CPET, and ambulatory rhythm monitoring among adults > 1 year after PCR-confirmed SARS-CoV-2 infection in the UCSF Long-Term Impact of Infection with Novel Coronavirus cohort (LIINC; NCT04362150 ) and correlated findings with previously measured biomarkers. We used logistic regression to estimate associations with PASC symptoms (dyspnea, chest pain, palpitations, and fatigue) adjusted for confounders and linear regression to estimate differences between those with and without symptoms adjusted for confounders.

Results: Out of 120 participants in the cohort, 46 participants (unselected for symptom status) had at least one advanced cardiac test performed at median 17 months following initial SARS-CoV-2 infection. Median age was 52 (IQR 42-61), 18 (39%) were female, and 6 (13%) were hospitalized for severe acute infection. On CMR (n=39), higher extracellular volume was associated with symptoms, but no evidence of late-gadolinium enhancement or differences in T1 or T2 mapping were demonstrated. We did not find arrhythmias on ambulatory monitoring. In contrast, on CPET (n=39), 13/23 (57%) with cardiopulmonary symptoms or fatigue had reduced exercise capacity (peak VO ₂ <85% predicted) compared to 2/16 (13%) without symptoms (p=0.008). The adjusted difference in peak VO ₂ was 5.9 ml/kg/min lower (-9.6 to -2.3; p=0.002) or -21% predicted (-35 to -7; p=0.006) among those with symptoms. Chronotropic incompetence was the primary abnormality among 9/15 (60%) with reduced peak VO ₂ . Adjusted heart rate reserve <80% was associated with reduced exercise capacity (OR 15.6, 95%CI 1.30-187; p=0.03). Inflammatory markers (hsCRP, IL-6, TNF-α) and SARS-CoV-2 antibody levels measured early in PASC were negatively correlated with peak VO ₂ more than 1 year later.

Conclusions: Cardiopulmonary symptoms and elevated inflammatory markers present early in PASC are associated with objectively reduced exercise capacity measured on cardiopulmonary exercise testing more than 1 year following COVID-19. Chronotropic incompetence may explain reduced exercise capacity among some individuals with PASC.

Clinical perspective: What is New? Elevated inflammatory markers in early post-acute COVID-19 are associated with reduced exercise capacity more than 1 year later. Impaired chronotropic response to exercise is associated with reduced exercise capacity and cardiopulmonary symptoms more than 1 year after SARS-CoV-2 infection. Findings on ambulatory rhythm monitoring point to perturbed autonomic function, while cardiac MRI findings argue against myocardial dysfunction and myocarditis.

Clinical implications: Cardiopulmonary testing to identify etiologies of persistent symptoms in post-acute sequalae of COVID-19 or “Long COVID” should be performed in a manner that allows for assessment of heart rate response to exercise. Therapeutic trials of anti-inflammatory and exercise strategies in PASC are urgently needed and should include assessment of symptoms and objective testing with cardiopulmonary exercise testing.

Source: Durstenfeld MS, Peluso MJ, Kaveti P, Hill C, Li D, Sander E, Swaminathan S, Arechiga VM, Sun K, Ma Y, Zepeda V, Lu S, Goldberg SA, Hoh R, Chenna A, Yee BC, Winslow JW, Petropoulos CJ, Win S, Kelly JD, Glidden DV, Henrich TJ, Martin JN, Lee YJ, Aras MA, Long CS, Grandis DJ, Deeks SG, Hsue PY. Inflammation during early post-acute COVID-19 is associated with reduced exercise capacity and Long COVID symptoms after 1 year. medRxiv [Preprint]. 2022 Jun 1:2022.05.17.22275235. doi: 10.1101/2022.05.17.22275235. PMID: 35677073; PMCID: PMC9176659. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9176659/ (Full text)

Decreased Fatty Acid Oxidation and Altered Lactate Production during Exercise in Patients with Post-acute COVID-19 Syndrome

To the Editor:

After acute infection with the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), many individuals experience a range of symptoms including dyspnea, exercise intolerance, and chest pain commonly referred to as “post–COVID-19 syndrome” or as post-acute sequelae of SARS-CoV-2 infection (PASC) (1). Exertional dyspnea and physical activity intolerance in PASC can be debilitating despite mild acute coronavirus disease (COVID-19) and normal resting pulmonary physiology and cardiac function (2). There is an urgent need to understand the pathogenesis of PASC and find effective treatments. The cardiopulmonary exercise test (CPET) is commonly used to investigate unexplained exertional dyspnea; as such, it could provide insight into mechanisms of PASC. CPET data can be used to calculate rates of β-oxidation of fatty acids (FATox) and of lactate clearance, providing insight into mitochondrial function (3). Fit individuals have better mitochondrial function and a higher rate of FATox during exercise than less fit individuals (4). Our results suggest that patients with PASC have significant impairment in fat β-oxidation and increased blood lactate accumulation during exercise, regardless of previous comorbidities.

Read the rest of this article HERE.

Source: de Boer, E., Petrache, I., Goldstein, N. M., Olin, J. T., Keith, R. C., Modena, B., Mohning, M. P., Yunt, Z. X., San-Millán, I., & Swigris, J. J. (2022). Decreased Fatty Acid Oxidation and Altered Lactate Production during Exercise in Patients with Post-acute COVID-19 Syndrome. American journal of respiratory and critical care medicine, 205(1), 126–129. https://doi.org/10.1164/rccm.202108-1903LE I https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8865580/ (Full text)

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

Persistent Exertional Intolerance After COVID-19: Insights From Invasive Cardiopulmonary Exercise Testing

Abstract:

Background: Some patients with COVID-19 who have recovered from the acute infection after experiencing only mild symptoms continue to exhibit persistent exertional limitation that often is unexplained by conventional investigative studies.

Research question: What is the pathophysiologic mechanism of exercise intolerance that underlies the post-COVID-19 long-haul syndrome in patients without cardiopulmonary disease?

Study design and methods: This study examined the systemic and pulmonary hemodynamics, ventilation, and gas exchange in 10 patients who recovered from COVID-19 and were without cardiopulmonary disease during invasive cardiopulmonary exercise testing (iCPET) and compared the results with those from 10 age- and sex-matched control participants. These data then were used to define potential reasons for exertional limitation in the cohort of patients who had recovered from COVID-19.

Results: The patients who had recovered from COVID-19 exhibited markedly reduced peak exercise aerobic capacity (oxygen consumption [VO₂]) compared with control participants (70 ± 11% predicted vs 131 ± 45% predicted; P < .0001). This reduction in peak VO₂ was associated with impaired systemic oxygen extraction (ie, narrow arterial-mixed venous oxygen content difference to arterial oxygen content ratio) compared with control participants (0.49 ± 0.1 vs 0.78 ± 0.1; P < .0001), despite a preserved peak cardiac index (7.8 ± 3.1 L/min vs 8.4±2.3 L/min; P > .05). Additionally, patients who had recovered from COVID-19 demonstrated greater ventilatory inefficiency (ie, abnormal ventilatory efficiency [VE/VCO₂] slope: 35 ± 5 vs 27 ± 5; P = .01) compared with control participants without an increase in dead space ventilation.

Interpretation: Patients who have recovered from COVID-19 without cardiopulmonary disease demonstrate a marked reduction in peak VO₂ from a peripheral rather than a central cardiac limit, along with an exaggerated hyperventilatory response during exercise.

Source: Singh I, Joseph P, Heerdt PM, Cullinan M, Lutchmansingh DD, Gulati M, Possick JD, Systrom DM, Waxman AB. Persistent Exertional Intolerance After COVID-19: Insights From Invasive Cardiopulmonary Exercise Testing. Chest. 2022 Jan;161(1):54-63. doi: 10.1016/j.chest.2021.08.010. Epub 2021 Aug 11. PMID: 34389297; PMCID: PMC8354807. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8354807/ (Full text)

Impaired systemic oxygen extraction long after mild COVID-19: potential perioperative implications

Editor:

The extraordinary number of severe acute respiratory syndrome coronavirus-2 (SARS-CoV-2) infections world-wide has made it inevitable that patients who have recovered from COVID-19 will present for anaesthesia and surgery. Recent data indicate that in the United States alone, roughly one-third of the population had been infected by the end of 20201. With this in mind, we read with interest the recent correspondence by Silvapulle and colleagues2 underscoring the wide range of symptoms that often follow recovery from COVID-19 and the complexity of considering residual physiologic abnormalities when assessing perioperative risk. They note that patients suffering from “long COVID” have been reported to exhibit demonstrable abnormalities in several biomarkers as well as cardiac, neurologic, haematologic, renal, hepatic, and endocrine impairment. Based on current evidence, the authors suggest that patients previously experiencing mild COVID-19 but without clear evidence of these sequelae can be regarded as having minimal additional perioperative risk. In this context, the relatively young person who suffered mild COVID-19 a year earlier, complains of exertional fatigue but admits to being sedentary and unfit, and has no objective evidence of cardiopulmonary disease or other organ dysfunction will likely raise little concern.

While the morbidity and mortality associated with severe COVID-19 has appropriately received considerable attention, most SARS-CoV-2 infections result in relatively mild, self-limited symptoms not requiring hospitalization. Nonetheless, some of these patients subsequently experience persistent fatigue and reduced exercise capacity that is not attributable to cardiopulmonary impairment diagnosed by conventional means3. Several mechanisms have been proposed including anaemia, deconditioning, and red blood cell abnormalities4. However, many of the studies describing these mechanisms were conducted in patients following hospitalization and/or within a few months of recovery.

A central focus of perioperative management has always been maintenance of systemic oxygen delivery (DO2) and tissue perfusion. Toward this end, research has defined how the fundamental relationships between DO2, tissue oxygen consumption (VO2), and oxygen extraction (EO2) shift from the intraoperative setting where VO2 tends to be reduced, to the postoperative period when VO2 increases5. Although a range of postoperative complications has been linked to suboptimal tissue DO26, 7, the incidence of these complications appears relatively low in relation to the documented incidence of perioperative hypoxaemia8, 9, particularly when considered in light of potential coincidence with other common factors such as anaemia, hypovolaemia, and transient hypotension. A contributing factor may be that, as with most physiological systems, evolutionary pressure has yielded compensatory mechanisms for reduced DO2 to many organs. Under most circumstances, when DO2 is low, VO2 is maintained by augmented EO2 to prevent tissue hypoxia10. This compensatory EO2 reserve persists until limits that vary among tissue beds are reached and VO2 becomes DO2-dependent. Ultimately, in the perioperative setting where alterations in regional VO2/DO2 balance occur with regularity it is probable that this EO2 reserve is working continuously ‘behind the scenes’ for organ protection.

But what if this seemingly occult protective mechanism is impaired? Clinical experience imparts heightened suspicion of tissue vulnerability in patients with defined end-organ impairment or risk factors for reduced functional reserve such as aging, smoking, diabetes mellitus, or hypertension. But how does this affect that relatively young person who admits to being sedentary and unfit but has no objective evidence of cardiopulmonary disease, and whose only other notable medical history is mild COVID-19 a year earlier? A recent report proposed the existence of a specific “long COVID phenotype” with exertional intolerance and dyspnoea despite normal pulmonary function11, raising the question of whether there is more to this patient than meets the eye.

Read the rest of this article HERE.

Source: Paul M. Heerdt, Ben Shelley, Inderjit Singh. Impaired systemic oxygen extraction long after mild COVID-19: potential perioperative implications. Published: December 27, 2021. DOI:https://doi.org/10.1016/j.bja.2021.12.036

Use of Cardiopulmonary Stress Testing for Patients With Unexplained Dyspnea Post–Coronavirus Disease

Abstract:

Objectives: The authors used cardiopulmonary exercise testing (CPET) to define unexplained dyspnea in patients with post-acute sequelae of severe acute respiratory syndrome-coronavirus-2 (SARS-CoV-2) infection (PASC). We assessed participants for criteria to diagnose myalgic encephalomyelitis/chronic fatigue syndrome (ME/CFS).

Background: Approximately 20% of patients who recover from coronavirus disease (COVID) remain symptomatic. This syndrome is named PASC. Its etiology is unclear. Dyspnea is a frequent symptom.

Methods: The authors performed CPET and symptom assessment for ME/CFS in 41 patients with PASC 8.9 ± 3.3 months after COVID. All patients had normal pulmonary function tests, chest X-ray, and chest computed tomography scans. Peak oxygen consumption (peak VO₂), slope of minute ventilation to CO₂ production (VE/VCO₂ slope), and end tidal pressure of CO₂ (PetCO₂) were measured. Ventilatory patterns were reviewed with dysfunctional breathing defined as rapid erratic breathing.

Results: Eighteen men and 23 women (average age: 45 ± 13 years) were studied. Left ventricular ejection fraction was 59% ± 9%. Peak VO₂ averaged 20.3 ± 7 mL/kg/min (77% ± 21% predicted VO₂). VE/VCO₂ slope was 30 ± 7. PetCO₂ at rest was 33.5 ± 4.5 mm Hg. Twenty-four patients (58.5%) had a peak VO₂ <80% predicted. All patients with peak VO₂ <80% had a circulatory limitation to exercise. Fifteen of 17 patients with normal peak VO₂ had ventilatory abnormalities including peak respiratory rate >55 (n = 3) or dysfunctional breathing (n = 12). For the whole cohort, 88% of patients (n = 36) had ventilatory abnormalities with dysfunctional breathing (n = 26), increased VE/VCO₂ (n = 17), and/or hypocapnia PetCO₂ <35 (n = 25). Nineteen patients (46%) met criteria for ME/CFS.

Conclusions: Circulatory impairment, abnormal ventilatory pattern, and ME/CFS are common in patients with PASC. The dysfunctional breathing, resting hypocapnia, and ME/CFS may contribute to symptoms. CPET is a valuable tool to assess these patients.

Source: Mancini DM, Brunjes DL, Lala A, Trivieri MG, Contreras JP, Natelson BH. Use of Cardiopulmonary Stress Testing for Patients With Unexplained Dyspnea Post-Coronavirus Disease. JACC Heart Fail. 2021 Dec;9(12):927-937. doi: 10.1016/j.jchf.2021.10.002. PMID: 34857177; PMCID: PMC8629098. https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8629098/ (Full text)