Reduced exercise capacity occurs before intrinsic skeletal muscle dysfunction in experimental rat models of pulmonary hypertension

IF 2.2 4区医学 Q2 CARDIAC & CARDIOVASCULAR SYSTEMS

Pulmonary Circulation Pub Date : 2024-04-04 DOI:10.1002/pul2.12358

Peng Zhang, Denielli Da Silva Goncalves Bos, Alexander Vang, Julia Feord, Danielle J. McCullough, Alexsandra Zimmer, Natalie D'Silva, Richard T. Clements, Gaurav Choudhary

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Abstract

Reduced exercise capacity in pulmonary hypertension (PH) significantly impacts quality of life. However, the cause of reduced exercise capacity in PH remains unclear. The objective of this study was to investigate whether intrinsic skeletal muscle changes are causative in reduced exercise capacity in PH using preclinical PH rat models with different PH severity. PH was induced in adult Sprague–Dawley (SD) or Fischer (CDF) rats with one dose of SU5416 (20 mg/kg) injection, followed by 3 weeks of hypoxia and additional 0–4 weeks of normoxia exposure. Control s rats were injected with vehicle and housed in normoxia. Echocardiography was performed to assess cardiac function. Exercise capacity was assessed by VO₂ max. Skeletal muscle structural changes (atrophy, fiber type switching, and capillary density), mitochondrial function, isometric force, and fatigue profile were assessed. In SD rats, right ventricular systolic dysfunction is associated with reduced exercise capacity in PH rats at 7-week timepoint in comparison to control rats, while no changes were observed in skeletal muscle structure, mitochondrial function, isometric force, or fatigue profile. CDF rats at 4-week timepoint developed a more severe PH and, in addition to right ventricular dysfunction, the reduced exercise capacity in these rats is associated with skeletal muscle atrophy; however, mitochondrial function, isometric force, and fatigue profile in skeletal muscle remain unchanged. Our data suggest that cardiopulmonary impairments in PH are the primary cause of reduced exercise capacity, which occurs before intrinsic skeletal muscle dysfunction.

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在肺动脉高压实验大鼠模型中，运动能力下降发生在骨骼肌内在功能障碍之前

肺动脉高压（PH）患者运动能力下降会严重影响生活质量。然而，PH 运动能力下降的原因仍不清楚。本研究的目的是利用不同PH严重程度的临床前PH大鼠模型，研究骨骼肌的内在变化是否是导致PH运动能力下降的原因。在成年 Sprague-Dawley （SD）或 Fischer （CDF）大鼠体内注射一剂 SU5416（20 毫克/千克）诱导 PH，然后进行为期 3 周的缺氧和 0-4 周的常氧暴露。对照组大鼠注射了药物并在常氧条件下饲养。进行超声心动图检查以评估心脏功能。运动能力通过最大容氧量进行评估。对骨骼肌结构变化（萎缩、纤维类型转换和毛细血管密度）、线粒体功能、等长力和疲劳曲线进行了评估。在 SD 大鼠中，与对照组大鼠相比，PH 大鼠在 7 周时间点的右心室收缩功能障碍与运动能力下降有关，而骨骼肌结构、线粒体功能、等长力和疲劳曲线均未观察到变化。4 周时间点的 CDF 大鼠出现了更严重的 PH，除了右心室功能障碍外，这些大鼠运动能力的降低还与骨骼肌萎缩有关；但是，骨骼肌的线粒体功能、等长力和疲劳曲线保持不变。我们的数据表明，PH 中的心肺功能损伤是运动能力下降的主要原因，而运动能力下降发生在骨骼肌内在功能障碍之前。

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.