Delaying post-exercise carbohydrate intake impairs next-day exercise capacity but not muscle glycogen or molecular responses

IF 5.6 2区医学 Q1 PHYSIOLOGY Acta Physiologica Pub Date : 2024-09-12 DOI:10.1111/apha.14215

Javier Díaz-Lara, Elizabeth Reisman, Javier Botella, Bianka Probert, Louise M. Burke, David J. Bishop, Matthew J. Lee

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Abstract

Aim

To investigate how delayed post-exercise carbohydrate intake affects muscle glycogen, metabolic- and mitochondrial-related molecular responses, and subsequent high-intensity interval exercise (HIIE) capacity.

Methods

In a double-blind cross-over design, nine recreationally active men performed HIIE (10 × 2-min cycling, ~94% W˙_peak) in the fed state, on two occasions. During 0–3 h post-HIIE, participants drank either carbohydrates (“Immediate Carbohydrate” [IC], providing 2.4 g/kg) or water (“Delayed Carbohydrate” [DC]); total carbohydrate intake over 24 h post-HIIE was matched (~7 g/kg/d). Skeletal muscle (sampled pre-HIIE, post-HIIE, +3 h, +8 h, +24 h) was analyzed for whole-muscle glycogen and mRNA content, plus signaling proteins in cytoplasmic- and nuclear-enriched fractions. After 24 h, participants repeated the HIIE protocol until failure, to test subsequent HIIE capacity; blood lactate, heart rate, and ratings of perceived effort (RPE) were measured throughout.

Results

Muscle glycogen concentrations, and relative changes, were similar between conditions throughout (p > 0.05). Muscle glycogen was reduced from baseline (mean ± SD mmol/kg dm; IC: 409 ± 166; DC: 352 ± 76) at post-HIIE (IC: 253 ± 96; DC: 214 ± 82), +3 h (IC: 276 ± 62; DC: 269 ± 116) and + 8 h (IC: 321 ± 56; DC: 269 ± 116), returning to near-baseline by +24 h. Several genes (PGC-1ɑ, p53) and proteins (p-ACC^Ser79, p-P38 MAPK^{Thr180/Tyr182}) elicited typical exercise-induced changes irrespective of condition. Delaying carbohydrate intake reduced next-day HIIE capacity (5 ± 3 intervals) and increased RPE (~2 ratings), despite similar physiological responses between conditions.

Conclusion

Molecular responses to HIIE (performed in the fed state) were not enhanced by delayed post-exercise carbohydrate intake. Our findings support immediate post-exercise refueling if the goal is to maximize next-day HIIE capacity and recovery time is ≤24 h.

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运动后延迟摄入碳水化合物会影响第二天的运动能力，但不会影响肌糖原或分子反应

目的研究运动后延迟摄入碳水化合物如何影响肌糖原、代谢和线粒体相关分子反应以及随后的高强度间歇运动（HIIE）能力。方法在双盲交叉设计中，9 名休闲运动男性在进食状态下进行了两次 HIIE（10 × 2 分钟自行车运动，约 94% W˙峰值）。在 HIIE 后的 0-3 小时内，参与者饮用碳水化合物（"即时碳水化合物"[IC]，提供 2.4 克/千克）或水（"延迟碳水化合物"[DC]）；HIIE 后 24 小时内的碳水化合物总摄入量相匹配（约 7 克/千克/天）。对骨骼肌（HIIE 前、HIIE 后、+3 小时、+8 小时、+24 小时采样）的全肌糖原和 mRNA 含量，以及细胞质和细胞核富集部分的信号蛋白进行分析。24 小时后，参与者重复 HIIE 方案直至失败，以测试随后的 HIIE 能力；在整个过程中测量血乳酸、心率和感知努力值（RPE）。肌糖原在HIIE后（IC：253±96；DC：214±82）、+3 h（IC：276±62；DC：269±116）和+8 h（IC：321±56；DC：269±116）从基线降低（平均值±标度mmol/kg dm；IC：409±166；DC：352±76），到+24 h恢复到接近基线。一些基因（PGC-1ɑ、p53）和蛋白质（p-ACCSer79、p-P38 MAPKThr180/Tyr182）在任何条件下都会引起典型的运动诱导变化。尽管不同条件下的生理反应相似，但延迟摄入碳水化合物会降低第二天的 HIIE 能力（5 ± 3 个间隔）并增加 RPE（~2 个评级）。如果目标是最大限度地提高第二天的 HIIE 能力，且恢复时间不超过 24 小时，我们的研究结果支持运动后立即补充能量。

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

Acta Physiologica 医学-生理学

CiteScore

11.80

自引率

15.90%

发文量

182

审稿时长

4-8 weeks

期刊介绍： Acta Physiologica is an important forum for the publication of high quality original research in physiology and related areas by authors from all over the world. Acta Physiologica is a leading journal in human/translational physiology while promoting all aspects of the science of physiology. The journal publishes full length original articles on important new observations as well as reviews and commentaries.