Hinda and Arthur Marcus Institute of Aging Research, Hebrew SeniorLife, Department of Medicine, Beth Israel Deaconess Medical Center, Harvard Medical School, Boston, Massachusetts, USA.
Biostatistics and Epidemiology Data Analytics Center, Boston University School of Public Health, Boston, Massachusetts, USA.
J Gerontol A Biol Sci Med Sci. 2023 Jul 8;78(7):1189-1197. doi: 10.1093/gerona/glad097.
Dysfunction in blood vessel dynamics may contribute to changes in muscle measures. Therefore, we examined associations of vascular health measures with grip strength and gait speed in adults from the Framingham Heart Study.
The cross-sectional study (1998-2001) included participants with 1 measure of grip strength (kg, dynamometer) or gait speed (4-m walk, m/s) and at least 1 measure of aortic stiffness (carotid-femoral pulse wave velocity, brachial pulse pressure, and brachial flow pulsatility index) or brachial artery structure and function (resting flow velocity, resting brachial artery diameter, flow-mediated dilation %, hyperemic brachial blood flow velocity, and mean arterial pressure [MAP]) assessed by tonometry and brachial artery ultrasound. The longitudinal study included participants with ≥1 follow-up measurement of gait speed or grip strength. Multivariable linear regression estimated the association of 1 standard deviation (SD) higher level of each vascular measure with annualized percent change in grip strength and gait speed, adjusting for covariates.
In cross-sectional analyses (n = 2 498, age 61 ± 10 years; 56% women), higher resting brachial artery diameter (β ± standard error [SE] per 1 SD: 0.59 ± 0.24, p = .01) and MAP (β ± SE: 0.39 ± 0.17, p = .02) were associated with higher grip strength. Higher brachial pulse pressure (β ± SE: -0.02 ± 0.01, p = .07) was marginally associated with slower gait speed. In longitudinal analyses (n = 2 157), higher brachial pulse pressure (β ± SE: -0.19 ± 0.07, p = .005), was associated with slowing of gait speed but not with grip strength.
Higher brachial artery pulse pressure (measure of aortic stiffness) was associated with loss of physical function over ~11 years, although we found no evidence that microvascular function contributed to the relation.
血管动力学功能障碍可能导致肌肉指标的变化。因此,我们研究了弗雷明汉心脏研究中成年人的血管健康指标与握力和步速之间的关联。
这项横断面研究(1998-2001 年)纳入了至少有 1 次握力(kg,测力计)或步速(4 米步行,m/s)测量值以及至少 1 次主动脉僵硬度(颈动脉-股动脉脉搏波速度、肱动脉脉压和肱动脉血流脉动指数)或肱动脉结构和功能(通过张力测定法和肱动脉超声评估的静息血流速度、静息肱动脉直径、血流介导的扩张%、充血性肱动脉血流速度和平均动脉压[MAP])测量值的参与者。纵向研究纳入了至少有 1 次随访测量的步速或握力的参与者。多变量线性回归估计了每个血管指标每升高 1 个标准差(SD)与握力和步速年化变化率的关系,调整了协变量。
在横断面分析中(n=2498 人,年龄 61±10 岁;56%为女性),较高的静息肱动脉直径(每 SD 增加 0.59±0.24,p=0.01)和 MAP(每 SD 增加 0.39±0.17,p=0.02)与握力较高有关。较高的肱动脉脉压(每 SD 降低 0.02±0.01,p=0.07)与步速较慢相关,但与握力无关。在纵向分析中(n=2157),较高的肱动脉脉压(每 SD 降低 0.19±0.07,p=0.005)与步速减慢有关,但与握力无关。
较高的肱动脉脉压(主动脉僵硬度的测量指标)与大约 11 年内身体功能的丧失有关,尽管我们没有证据表明微血管功能对这种关系有贡献。
