McGinley Joseph C, Hopgood Brendon C, Gaughan John P, Sadeghipour Keyanoush, Kozin Scott H
School of Medicine, Temple University, 3400 North Broad Street, Philadelphia, PA 19140, USA.
J Bone Joint Surg Am. 2003 Dec;85(12):2403-9.
The purpose of this study was to develop an axial loading forearm fracture model and to determine the influence of forearm rotation on the fracture pattern.
Twenty-six cadaveric arms were thawed in saline solution. Pressure-sensitive film was sealed and was placed through a lateral arthrotomy into the radiocapitellar joint. The arm was potted at the proximal part of the humerus with the elbow in extension. Rotational range of motion was measured with use of a goniometer starting from a supinated position (0 degrees ). Specimens were placed in a vertical position at various angles of forearm rotation, and a 27-kg mass was raised to 90 cm and was dropped onto the distal part of the radius. The pressure film was removed and was analyzed to determine the radiocapitellar joint contact area following impact. Each arm was dissected, and the injury pattern was assessed.
Both-bone forearm fractures (proximal radial fractures with concomitant distal ulnar fractures) occurred at 5 degrees +/- 2.6 degrees of rotation, isolated radial head fractures occurred at 44.4 degrees +/- 5.2 degrees of rotation, and Essex-Lopresti fractures (radial head fractures with tearing of the interosseous membrane) occurred at 70 degrees +/- 25.2 degrees of rotation. The distribution of Essex-Lopresti and radial head fractures was significantly different at a cutpoint of 54 degrees of forearm rotation (p = 0.009), and the distribution of radial head fractures and both-bone forearm fractures was significantly different at a cutpoint of 10 degrees of forearm rotation (p = 0.001). The percent contact area of the radial head varied with the injury pattern (p = 0.029). Marginal radial head fractures occurred at 46.7 degrees +/- 6.6 degrees of rotation with a contact area of 30.9% +/- 8.6%, while comminuted radial head fractures occurred at 74.4 degrees +/- 27.2 degrees of rotation with a contact area of 53.9% +/- 8.3%.
The amount of forearm rotation at the time of axial load impact directly influenced the injury pattern. Furthermore, the radial head contact area and the fracture severity increased in pronation compared with supination.
本研究的目的是建立一种轴向负荷前臂骨折模型,并确定前臂旋转对骨折类型的影响。
26条尸体手臂在盐溶液中解冻。将压敏膜密封,通过外侧关节切开术放入桡骨头关节。手臂在肱骨近端固定,肘部伸直。使用角度计从旋后位(0度)开始测量旋转运动范围。将标本置于前臂不同旋转角度的垂直位置,将一个27千克的重物提升至90厘米并使其落在桡骨远端。取出压敏膜并进行分析,以确定撞击后桡骨头关节接触面积。对每条手臂进行解剖,并评估损伤类型。
双骨前臂骨折(近端桡骨骨折伴远端尺骨骨折)发生在前臂旋转5度±2.6度时,孤立性桡骨头骨折发生在前臂旋转44.4度±5.2度时,埃克塞尔-洛普雷斯蒂骨折(桡骨头骨折伴骨间膜撕裂)发生在前臂旋转70度±25.2度时。在前臂旋转54度的切点处,埃克塞尔-洛普雷斯蒂骨折和桡骨头骨折的分布有显著差异(p = 0.009),在前臂旋转10度的切点处,桡骨头骨折和双骨前臂骨折的分布有显著差异(p = 0.001)。桡骨头的接触面积百分比随损伤类型而变化(p = 0.029)。边缘性桡骨头骨折发生在前臂旋转46.7度±6.6度时,接触面积为30.9%±8.6%,而粉碎性桡骨头骨折发生在前臂旋转74.4度±27.2度时,接触面积为53.9%±8.3%。
轴向负荷撞击时前臂旋转的程度直接影响损伤类型。此外,与旋后相比,旋前时桡骨头接触面积和骨折严重程度增加。
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