Toronto Rehabilitation Institute-UHN, Toronto, Ontario, Canada; University of Toronto IBBME, Toronto, Ontario, Canada.
PM R. 2012 Dec;4(12):963-75. doi: 10.1016/j.pmrj.2012.08.012. Epub 2012 Oct 24.
To date, few pharmacologic or rehabilitation interventions for sublesional osteoporosis (SLOP) or low bone mass of the hip and knee regions after spinal cord injury (SCI) have produced significant or sustained increases in lower extremity bone mineral density. Whole body vibration (WBV) is a potential intervention for the prevention and/or treatment of SLOP.
To identify the optimal WBV conditions (ie, plate, frequency, amplitude, and subject posture) among men with chronic SCI during passive standing and facilitate the implementation and future evaluation of the efficacy of WBV and passive standing for prevention and treatment of SLOP in men with SCI.
This phase 0 device development study assessed the lower extremity propagation characteristics of WBV in men with and without SCI by using a variety of a priori specified plates, frequencies, amplitudes, and postures that facilitate lower extremity vibration absorption while minimizing vibration propagation to the head.
A tertiary SCI rehabilitation center in Toronto, Canada.
Healthy men with chronic paraplegia (n = 5) and those without SCI (n = 7), ages 20-50 years, weight 68-113 kg, and height 168-188 cm.
An EasyStand standing frame (Altimate Medical Inc, Morton, MN) was fitted onto 2 commercially available vibration platforms: WAVE (WAVE Manufacturing Inc, Windsor, Ontario, Canada) and Juvent (Juvent Medical Inc, Somerset, NJ). Accelerometers were attached to the participants' forehead, hip, knee, and ankle to measure vibration propagation. Vibration parameters evaluated were posture (knee angles of 140°, 160°, and 180° [180° for Juvent only]), vibration frequency (25 Hz, 35 Hz, and 45 Hz), and vibration amplitude (0.6 mm and 1.2 mm [WAVE only]). The subjects were exposed to all combinations of posture, frequencies, and amplitudes during the experiments (total parameter combinations: 12 WAVE and 9 Juvent).
Peak-to-peak vibration and transmissibility of vibration were recorded and computed for each accelerometer at the tested locations.
Variations in frequency generated the most noticeable changes in propagation characteristics, followed by variations in knee angle and amplitude.
WBV therapy delivered with use of the WAVE platform with a knee angle of 140°, plate frequency of 45 Hz, and amplitude of 1.2 mm met our a priori criteria for the "optimal WBV condition." Future studies should evaluate the therapeutic efficacy of the WAVE platform by using these parameters to maintain or augment bone mass among persons with SCI and SLOP.
迄今为止,针对脊髓损伤(SCI)后亚部位骨质疏松症(SLOP)或髋膝区低骨量,仅有少数药物或康复干预措施能显著或持续增加下肢骨密度。全身振动(WBV)是预防和/或治疗 SLOP 的一种潜在干预措施。
确定慢性 SCI 男性在被动站立时最适合的 WBV 条件(即平板、频率、振幅和受试者姿势),并为 WBV 和被动站立在预防和治疗 SCI 男性 SLOP 中的疗效评估提供便利。
这项 0 期设备开发研究通过使用各种预先指定的平板、频率、振幅和姿势来评估有和无 SCI 的男性下肢的 WBV 传播特性,这些方法有利于下肢振动吸收,同时最大限度地减少振动向头部传播。
加拿大多伦多的一家三级 SCI 康复中心。
慢性截瘫(n=5)和无 SCI 的健康男性(n=7),年龄 20-50 岁,体重 68-113kg,身高 168-188cm。
将 EasyStand 站立架(Altimate Medical Inc,Morton,MN)安装在 2 个商业上可获得的振动平台上:WAVE(WAVE Manufacturing Inc,安大略省温莎市)和 Juvent(Juvent Medical Inc,新泽西州萨默塞特)。将加速度计贴在参与者的额头、臀部、膝盖和脚踝上,以测量振动传播。评估的振动参数包括姿势(140°、160°和 180°的膝关节角度[ Juvent 仅为 180°])、振动频率(25Hz、35Hz 和 45Hz)和振动幅度(0.6mm 和 1.2mm[仅 WAVE])。在实验中,受试者接受了所有组合的姿势、频率和振幅(总参数组合:12 个 WAVE 和 9 个 Juvent)。
在测试位置记录和计算每个加速度计的峰值到峰值振动和振动传递率。
频率的变化引起了传播特性最明显的变化,其次是膝关节角度和振幅的变化。
使用 WAVE 平台,在 140°的膝关节角度、45Hz 的平板频率和 1.2mm 的振幅下进行的 WBV 治疗符合我们对“最佳 WBV 条件”的预先设定标准。未来的研究应使用这些参数评估 WAVE 平台的治疗效果,以维持或增加 SCI 和 SLOP 患者的骨量。
