The metabolic and physiologic impairments underlying long COVID associated exercise intolerance.

IF 2.2 4区医学 Q2 CARDIAC & CARDIOVASCULAR SYSTEMS Pulmonary Circulation Pub Date : 2024-11-13 eCollection Date: 2024-10-01 DOI:10.1002/pul2.70009

Brooks P Leitner, Phillip Joseph, Andres Figueroa Quast, Maria Alejandra Ramirez, Paul M Heerdt, Jose G Villalobos, Inderjit Singh

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Abstract

Data from invasive CPET (iCPET) revealed long COVID patients have impaired systemic oxygen extraction (EO₂), suggesting impaired mitochondrial ATP production. However, it remains uncertain whether the initial severity of SARS-CoV-2 infection has implications on EO₂ and exercise capacity (VO₂) nor has there been assessment of anerobic ATP generation in long COVID patients. iCPET was performed on 47 long COVID patients (i.e., full cohort; n = 8 with severe SARS-CoV-2 infection). In a subset of patients (i.e., metabolomic cohort; n = 26) metabolomics on venous and arterial blood samples during iCPET was performed. In the full cohort, long COVID patients exhibited reduced peak EO₂ with reduced peak VO₂ (90 ± 17% predicted) relative to cardiac output (118 ± 23% predicted). Peak VO₂ [88% predicted (IQR 81% - 108%) vs. 70% predicted (IQR 64% - 89%); p = 0.02] and EO₂ [0.59(IQR 0.53-0.62) vs. 0.53(IQR 0.50-0.48); p = 0.01) were lower in severe versus mild infection. In the metabolomic cohort, 12 metabolites were significantly consumed, and 41 metabolites were significantly released (p-values < 0.05). Quantitative metabolomics demonstrated significant increases in inosine and succinate arteriovenous gradients during exercise. Peak VO₂ was significantly correlated with peak venous succinate (r = 0.68; p = 0.0008) and peak venous lactate (r = 0.49; p = 0.0004). Peak EO₂ and consequently peak VO₂ impact long COVID patients in a severity dependent manner. Exercise intolerance associated with long COVID is defined by impaired aerobic and anaerobic energy production. Peak venous succinate may serve as a potential biomarker in long COVID.

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长期 COVID 相关运动不耐受的代谢和生理缺陷。

有创 CPET（iCPET）数据显示，长期慢性阻塞性肺病患者的全身氧萃取（EO2）受损，表明线粒体 ATP 生成受损。然而，目前仍不确定 SARS-CoV-2 感染的最初严重程度是否会对 EO2 和运动能力（VO2）产生影响，也没有对长程 COVID 患者的无氧 ATP 生成情况进行过评估。在一部分患者（即代谢组群；n = 26）中，对 iCPET 期间的静脉和动脉血样本进行了代谢组学研究。在整个队列中，长COVID患者的峰值EO2降低，峰值VO2（90 ± 17%预测值）相对于心输出量（118 ± 23%预测值）降低。与轻度感染相比，重度感染患者的峰值 VO2 [预测值 88% (IQR 81% - 108%) vs. 预测值 70% (IQR 64% - 89%); p = 0.02]和 EO2 [0.59(IQR 0.53-0.62) vs. 0.53(IQR 0.50-0.48); p = 0.01]更低。在代谢组群中，12 种代谢物显著消耗，41 种代谢物显著释放（p 值 2 与静脉琥珀酸盐峰值（r = 0.68；p = 0.0008）和静脉乳酸盐峰值（r = 0.49；p = 0.0004）显著相关。长 COVID 患者的 EO2 峰值和 VO2 峰值会受到严重程度的影响。与长时 COVID 相关的运动不耐受定义为有氧和无氧能量生成受损。静脉琥珀酸盐峰值可作为长时COVID的潜在生物标志物。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Pulmonary Circulation Medicine-Pulmonary and Respiratory Medicine

CiteScore

4.20

自引率

11.50%

发文量

153

审稿时长

15 weeks

期刊介绍： Pulmonary Circulation''s main goal is to encourage basic, translational, and clinical research by investigators, physician-scientists, and clinicans, in the hope of increasing survival rates for pulmonary hypertension and other pulmonary vascular diseases worldwide, and developing new therapeutic approaches for the diseases. Freely available online, Pulmonary Circulation allows diverse knowledge of research, techniques, and case studies to reach a wide readership of specialists in order to improve patient care and treatment outcomes.