Exercise Physiology Research Group, Department of Movement Sciences, KU Leuven, Leuven, Belgium.
Department of Movement Sciences, KU Leuven, Leuven, Belgium.
J Physiol. 2023 Jun;601(12):2345-2358. doi: 10.1113/JP284346. Epub 2023 Apr 27.
De novo capillarization is a primary muscular adaptation to endurance exercise training and is crucial to improving performance. Excess training load, however, impedes such beneficial adaptations, yet we recently demonstrated that such downregulation may be counteracted by ketone ester ingestion (KE) post-exercise. Therefore, we investigated whether KE could increase pro-angiogenic factors and thereby stimulate muscular angiogenesis during a 3-week endurance training-overload period involving 10 training sessions/week in healthy, male volunteers. Subjects received either 25 g of a ketone ester (KE, n = 9) or a control drink (CON, n = 9) immediately after each training session and before sleep. In KE, but not in CON, the training intervention increased the number of capillary contacts and the capillary-to-fibre perimeter exchange index by 44% and 42%, respectively. Furthermore, KE also substantially increased vascular endothelial growth factor (VEGF) and endothelial nitric oxide synthase (eNOS) expression both at the protein and at the mRNA level. Serum erythropoietin concentration was concomitantly increased by 26%. Conversely, in CON the training intervention increased only the protein content of eNOS. These data indicate that intermittent exogenous ketosis during endurance overload training stimulates muscular angiogenesis. This likely resulted from a direct stimulation of muscle angiogenesis, which may be at least partly due to stimulation of erythropoietin secretion and elevated VEGF activity, and/or an inhibition of the suppressive effect of overload training on the normal angiogenic response to training. This study provides novel evidence to support the potential of exogenous ketosis to benefit endurance training-induced muscular adaptation. KEY POINTS: Increased capillarization is a primary muscular adaptation to endurance exercise training. However, excess training load may impede such response. We previously observed that intermittent exogenous ketosis by post-exercise and pre-sleep ketone ester ingestion (KE) counteracted physiological dysregulations induced by endurance overload training. Therefore, we investigated whether KE could increase pro-angiogenic factors thereby stimulating muscular angiogenesis during a 3-week endurance training overload period. We show that the overload training period in the presence, but not in the absence, of KE markedly increased muscle capillarization (+40%). This increase was accompanied by higher circulating erythropoietin concentration and stimulation of the pro-angiogenic factors vascular endothelial growth factor and endothelial nitric oxide synthase in skeletal muscle. Collectively, our data indicate that intermittent exogenous ketosis may evolve as a potent nutritional strategy to facilitate recovery from strenuous endurance exercise, thereby stimulating beneficial muscular adaptations.
新生毛细血管化是耐力运动训练的主要肌肉适应,对提高运动表现至关重要。然而,过度的训练负荷会阻碍这种有益的适应,但是我们最近的研究表明,这种下调可能会被运动后摄入酮酯(KE)所抵消。因此,我们研究了在涉及每周 10 次训练的 3 周耐力训练过载期间,KE 是否可以增加促血管生成因子,从而刺激肌肉血管生成。在健康的男性志愿者中。受试者在每次训练后和睡前立即接受 25 克酮酯(KE,n=9)或对照饮料(CON,n=9)。在 KE 中,但不在 CON 中,训练干预使毛细血管接触数增加了 44%,毛细血管与纤维周径交换指数增加了 42%。此外,KE 还显著增加了血管内皮生长因子(VEGF)和内皮型一氧化氮合酶(eNOS)的蛋白和 mRNA 水平的表达。血清促红细胞生成素浓度也相应增加了 26%。相反,在 CON 中,训练干预仅增加了 eNOS 的蛋白含量。这些数据表明,耐力过载训练期间间歇性外源性酮症会刺激肌肉血管生成。这可能是由于对肌肉血管生成的直接刺激,这至少部分可能是由于促红细胞生成素分泌和 VEGF 活性升高的刺激,和/或对正常血管生成反应的过度训练抑制的抑制。这项研究提供了新的证据,支持外源性酮症有益于耐力训练引起的肌肉适应。关键点:毛细血管化增加是耐力运动训练的主要肌肉适应。然而,过度的训练负荷可能会阻碍这种反应。我们之前观察到,运动后和睡前摄入酮酯(KE)的间歇性外源性酮症可以抵消耐力过载训练引起的生理失调。因此,我们研究了在 3 周耐力训练过载期间,KE 是否可以增加促血管生成因子从而刺激肌肉血管生成。我们发现,在存在 KE 的情况下,而不是在不存在 KE 的情况下,过载训练期会显著增加肌肉毛细血管化(增加 40%)。这种增加伴随着循环促红细胞生成素浓度的升高和骨骼肌中促血管生成因子血管内皮生长因子和内皮型一氧化氮合酶的刺激。总的来说,我们的数据表明,间歇性外源性酮症可能是一种有效的营养策略,可以促进剧烈耐力运动后的恢复,从而刺激有益的肌肉适应。
