DiAngelo Denis J, Hillyard Daniel C
Department of Orthopaedic Surgery and Biomedical Engineering, The University of Tennessee Health Science Center, USA.
J Rehabil Assist Technol Eng. 2016 Oct 10;3:2055668316670534. doi: 10.1177/2055668316670534. eCollection 2016 Jan-Dec.
Lumbar spinal orthoses are often used as non-surgical treatment and serve to support the spine and alleviate low back pain. More recently, dynamic orthoses claiming to decompress the spine have been introduced. A previously developed prototype of dynamic mobility orthosis (DMO1) was designed that provided a distractive load across the lumbar spine but required higher sagittal bending moments and was unable to maintain spinal off-loading throughout extended ranges of movement. The objective was to design a new orthosis (DMO2) that reduced bending moment buildup and sustained spinal off-loading throughout daily living ranges of flexion and extension movement.
A mechanical analog upper torso model and programmable robotic testing platform were used to design features of DMO2: a mobility-enabling component and a distractive force component. Test conditions for DMO2 were 300 of applied vertical torso load over a range of 25° flexion to 10° extension. Loads carried by the brace were determined throughout flexion and extension ranges. Applied moments to the upper torso model and transferred moments to the spine were measured. The difference in applied and transferred moments represented brace moment effects.
The DMO2 prototype improved spinal off-loading capacity from 172 to 290 at end-range flexion and from 247 to 293 at end range extension compared to the original DMO1 prototype. End-range applied moments (flexion-DMO1: 32.4 Nm/DMO2: 21.7 Nm; extension-DMO1: 15.0 Nm/DMO2: 10.9 Nm) and brace moments (flexion-DMO1: 18.6 Nm/DMO2: 6.6 Nm; extension-DMO1: 15.0 Nm/DMO2: 4.4 Nm) were also reduced.
A novel dynamic spinal orthosis was designed that maintained spinal off-loading throughout extended ranges of flexion and extension movement without buildup of adverse bending moments.
腰椎矫形器常被用作非手术治疗手段,用于支撑脊柱并缓解腰痛。最近,出现了声称能对脊柱进行减压的动态矫形器。之前研发的动态活动矫形器原型(DMO1)设计为能在腰椎上施加牵引负荷,但需要更高的矢状面弯矩,且在整个较大活动范围内无法维持脊柱卸载。目标是设计一种新的矫形器(DMO2),在日常屈伸活动范围内减少弯矩积累并持续保持脊柱卸载。
使用机械模拟上半身模型和可编程机器人测试平台来设计DMO2的特性:一个促进活动的部件和一个牵张力部件。DMO2的测试条件是在25°屈曲至10°伸展范围内施加300 的垂直躯干负荷。在整个屈伸范围内测定矫形器所承载的负荷。测量施加在上半身模型上的力矩以及传递到脊柱的力矩。施加力矩与传递力矩的差值代表矫形器的力矩效应。
与原始的DMO1原型相比,DMO2原型在终末屈曲时将脊柱卸载能力从172 提高到290 ,在终末伸展时从247 提高到293 。终末施加力矩(屈曲 - DMO1:32.4 Nm / DMO2:21.7 Nm;伸展 - DMO1:15.0 Nm / DMO2:10.9 Nm)和矫形器力矩(屈曲 - DMO1:18.6 Nm / DMO2:6.6 Nm;伸展 - DMO1:15.0 Nm / DMO2:4.4 Nm)也有所降低。
设计了一种新型动态脊柱矫形器,在整个较大的屈伸活动范围内维持脊柱卸载,且不会积累不利的弯矩。