-丙氨酸在高强度运动中的补充。

Medicine and sport science Pub Date : 2012-01-01 Epub Date: 2012-10-15 DOI:10.1159/000342372
Roger C Harris, Craig Sale
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引用次数: 35

摘要

糖酵解涉及代谢的每个糖基(或葡萄糖基)单位上的两个中性羟基的氧化,产生两个羧基。在低强度的运动中,这些与碳骨架的剩余部分一起进一步氧化成CO(2)和水。但在高强度运动中,大部分(血流量受损的地方)以乳酸阴离子和H(+)的形式积累。H(+)的积累对肌肉功能有有害影响,最终损害力量产生并导致疲劳。随着时间的推移,细胞内pH值的调节是通过向肌肉输出H(+)来实现的,尽管肌肉中的物理化学缓冲液提供了防止H(+)积累的第一道防线。为了在高强度运动中有效,缓冲液需要在肌肉中高浓度存在,并使pK(a)s在细胞内运动pH传递范围内。肌肽(β-丙烯酰- l-组氨酸)是理想的,因为它在骨骼肌中以毫摩尔浓度存在,并且pK(a)为6.83。肌肽是一种细胞质二肽,由组氨酸和β-丙氨酸在肌肽合成酶催化的反应中结合而成,尽管β-丙氨酸可以从肝脏合成中获得少量,但可能从饮食中获得大量的β-丙氨酸,限制了合成。通过增加饮食中β-丙氨酸的摄入来增加肌肉肌肽将增加细胞内缓冲能力,这反过来可能会增加高强度运动能力和pH值有限的表现。在本研究中,我们回顾了肌肽作为H(+)缓冲剂的作用,β-丙氨酸对肌肉肌肽的调节,以及补充β-丙氨酸对肌肉肌肽合成的影响及其对高强度运动能力和表现的影响的现有证据。
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Beta-alanine supplementation in high-intensity exercise.

Glycolysis involves the oxidation of two neutral hydroxyl groups on each glycosyl (or glucosyl) unit metabolised, yielding two carboxylic acid groups. During low-intensity exercise these, along with the remainder of the carbon skeleton, are further oxidised to CO(2) and water. But during high-intensity exercise a major portion (and where blood flow is impaired, then most) is accumulated as lactate anions and H(+). The accumulation of H(+) has deleterious effects on muscle function, ultimately impairing force production and contributing to fatigue. Regulation of intracellular pH is achieved over time by export of H(+) out of the muscle, although physicochemical buffers in the muscle provide the first line of defence against H(+) accumulation. In order to be effective during high-intensity exercise, buffers need to be present in high concentrations in muscle and have pK(a)s within the intracellular exercise pH transit range. Carnosine (β-alanyl-L-histidine) is ideal for this role given that it occurs in millimolar concentrations within the skeletal muscle and has a pK(a) of 6.83. Carnosine is a cytoplasmic dipeptide formed by bonding histidine and β-alanine in a reaction catalysed by carnosine synthase, although it is the availability of β-alanine, obtained in small amounts from hepatic synthesis and potentially in greater amounts from the diet that is limiting to synthesis. Increasing muscle carnosine through increased dietary intake of β-alanine will increase the intracellular buffering capacity, which in turn might be expected to increase high-intensity exercise capacity and performance where this is pH limited. In this study we review the role of muscle carnosine as an H(+) buffer, the regulation of muscle carnosine by β-alanine, and the available evidence relating to the effects of β-alanine supplementation on muscle carnosine synthesis and the subsequent effects of this on high-intensity exercise capacity and performance.

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