MRC-ARUK Centre for Musculoskeletal Ageing Research, Clinical, Metabolic and Molecular Physiology, University of Nottingham, Royal Derby Hospital Centre, Derby, UK.
MRC-ARUK Centre for Musculoskeletal Ageing Research, Clinical, Metabolic and Molecular Physiology, University of Nottingham, Royal Derby Hospital Centre, Derby, UK; Nottingham NIHR BRC, UK.
Clin Nutr. 2019 Oct;38(5):2071-2078. doi: 10.1016/j.clnu.2018.09.025. Epub 2018 Sep 27.
Age-related sarcopenia and dynapenia are associated with frailty and metabolic diseases. Resistance exercise training (RET) adjuvant to evidence-based nutritional intervention(s) have been shown as mitigating strategies. Given that β-hydroxy-β-methyl-butyrate (HMB) supplementation during RET improves lean body mass in younger humans, and that we have shown that HMB acutely stimulates muscle protein synthesis (MPS) and inhibits breakdown; we hypothesized that chronic supplementation of HMB free acid (HMB-FA) would enhance MPS and muscle mass/function in response to RET in older people. We recruited 16 healthy older men (Placebo (PLA): 68.5 ± 1.0 y, HMB-FA: 67.8 ± 1.15 y) for a randomised double-blind-placebo controlled trial (HMB-FA 3 × 1 g/day vs. PLA) involving a 6-week unilateral progressive RET regime (6 × 8 repetitions, 75% 1-RM, 3 · wk). Deuterium oxide (DO) dosing was performed over the first two weeks (0-2 wk) and last two weeks (4-6 wk) with bilateral vastus lateralis (VL) biopsies at 0-2 and 4-6 wk (each time 75 ± 2 min after a single bout of resistance exercise (RE)) for quantification of early and later MPS responses and post-RE myogenic gene expression. Thigh lean mass (TLM) was measured by DXA, VL thickness and architecture (fibre length and pennation angle) by ultrasound at 0/3/6 wk, and strength by knee extensor 1-RM testing and MVC by isokinetic dynamometry (approx. every 10 days). RET induced strength increases (1-RM) in the exercised leg of both groups (398 ± 22N to 499 ± 30N HMB-FA vs. 396 ± 29N to 510 ± 43N PLA (both P < 0.05)). In addition, maximal voluntary contraction (MVC) also increased (179 ± 12 Nm to 203 ± 12 Nm HMB-FA vs. 185 ± 10 Nm to 217 ± 11 Nm PLA (both P < 0.05); with no group differences. VL muscle thickness increased significantly in the exercised leg in both groups, with no group differences. TLM (by DXA) rose to significance only in the HMB-FA group (by 5.8%-5734 ± 245 g p = 0.015 vs. 3.0% to 5644 ± 323 g P = 0.06 in PLA). MPS remained unchanged in the untrained legs (UT) 0-2 weeks being 1.06 ± 0.08%.d (HMB-FA) and 1.14 ± 0.09%.d (PLA), the trained legs (T) exhibited increased MPS in the HMB-FA group only at 0-2-weeks (1.39 ± 0.10%.d, P < 0.05) compared with UT: but was not different at 4-6-weeks: 1.26 ± 0.05%.d. However, there were no significant differences in MPS between the HMB-FA and PLA groups at any given time point and no significant treatment interaction observed. We also observed significant inductions of c-Myc gene expression following each acute RE bout, with no group differences. Further, there were no changes in any other muscle atrophy/hypertrophy or myogenic transcription factor genes we measured. RET with adjuvant HMB-FA supplements in free-living healthy older men did not enhance muscle strength or mass greater than that of RET alone (PLA). That said, only HMB-FA increased TLM, supported by early increases in chronic MPS. As such, chronic HMB-FA supplementation may result in long term benefits in older males, however longer and larger studies may be needed to fully determine the potential effects of HMB-FA supplementation; translating to any functional benefit.
年龄相关性肌肉减少症和动力不足与虚弱和代谢疾病有关。阻力运动训练 (RET) 辅助基于证据的营养干预措施已被证明是一种缓解策略。鉴于β-羟基-β-甲基丁酸 (HMB) 在 RET 期间补充可增加年轻人类的瘦体重,并且我们已经表明 HMB 可急性刺激肌肉蛋白质合成 (MPS) 并抑制分解;我们假设慢性补充 HMB 游离酸 (HMB-FA) 将增强 RET 对老年人的 MPS 和肌肉质量/功能。我们招募了 16 名健康的老年人(安慰剂 (PLA):68.5 ± 1.0 岁,HMB-FA:67.8 ± 1.15 岁)进行随机双盲安慰剂对照试验(HMB-FA 3 × 1 g/天与 PLA),涉及 6 周单侧渐进性 RET 方案(6 × 8 次重复,75% 1-RM,3 周)。氘水 (DO) 给药在第一和第二周(0-2 周)和最后两周(4-6 周)进行,双侧股外侧肌 (VL) 活检在 0-2 周和 4-6 周(每次在单次抗阻运动 (RE) 后 75 ± 2 分钟)进行,以量化早期和晚期 MPS 反应和 RE 后肌源性基因表达。大腿瘦体重 (TLM) 通过 DXA 测量,VL 厚度和结构(纤维长度和肌纤维角)通过超声在 0/3/6 周测量,力量通过膝关节伸肌 1-RM 测试和等速测力计(大约每 10 天)测量。RET 增加了两组运动腿的力量(HMB-FA 从 398 ± 22N 增加到 499 ± 30N,PLA 从 396 ± 29N 增加到 510 ± 43N(均 P < 0.05))。此外,最大自主收缩 (MVC) 也增加了(HMB-FA 从 179 ± 12 Nm 增加到 203 ± 12 Nm,PLA 从 185 ± 10 Nm 增加到 217 ± 11 Nm(均 P < 0.05);两组之间没有差异)。VL 肌肉厚度在两组运动腿中均显著增加,两组之间无差异。TLM(通过 DXA)仅在 HMB-FA 组中显著增加(增加 5.8%-5734 ± 245g,P = 0.015 与 PLA 中的 3.0%-5644 ± 323g,P = 0.06)。在未训练的腿部(UT)0-2 周内,MPS 保持不变,HMB-FA 为 1.06 ± 0.08%.d,PLA 为 1.14 ± 0.09%.d,训练的腿部(T)仅在 HMB-FA 组中在 0-2 周时增加 MPS(1.39 ± 0.10%.d,P < 0.05)与 UT 相比:但在 4-6 周时没有差异:1.26 ± 0.05%.d。然而,在任何给定时间点,HMB-FA 和 PLA 组之间的 MPS 均无显着差异,也没有观察到治疗的显着相互作用。我们还观察到急性 RE 发作后 c-Myc 基因表达的显着诱导,两组之间没有差异。此外,我们测量的任何其他肌肉萎缩/肥大或肌源性转录因子基因均无变化。在自由生活的健康老年人中,RET 联合辅助 HMB-FA 补充剂并未增强肌肉力量或质量,超过 RET 单独(PLA)。也就是说,只有 HMB-FA 增加了 TLM,这得益于慢性 MPS 的早期增加。因此,慢性 HMB-FA 补充剂可能会给老年男性带来长期益处,但是可能需要更长和更大的研究来充分确定 HMB-FA 补充剂的潜在影响;转化为任何功能益处。
