David S M, Harrow M E, Peindl R D, Frick S L, Kellam J F
Department of Orthopaedic Surgery, Carolinas Medical Center, Charlotte, North Carolina 28232-1758, USA.
J Orthop Trauma. 1997 Jul;11(5):344-50. doi: 10.1097/00005131-199707000-00008.
To compare the initial stability of the genucephalic (GSH) intramedullary nail and the 95-degree condylar compression screw and side plate (DCS) for distal femur fractures.
Human cadaveric biomechanical study.
Twelve matched pairs of fresh frozen human cadaveric femurs.
Genucephalic intramedullary nail device (Smith and Nephew Richards, Memphis, TN, U.S.A.) and the 95-degree DCS device (Synthes USA, Paoli, PA, U.S.A.) were compared. Grouped or dispersed screw constructs were tested for each fracture fixation system with progressively more severe simulated fracture patterns.
Axial and torsional stiffness values.
The DCS plate with the dispersed screw configuration had the greatest torsional stiffness (p < 0.0011). The GSH nail with the grouped screw configuration absorbed more energy (work) during axial loading compared with the plate constructs (p < 0.0007). There were no significant differences in axial or torsional stiffness within treatment groups for fracture patterns of increasing severity.
Based on the authors' results, the selection of a GSH nail or a DCS plate should not be determined by the severity of the fracture. If a DCS plate construct is selected, the authors recommend a dispersed screw configuration, including the most proximal hole in the plate, to provide superior stiffness in torsional loading and equal stiffness in axial loading when compared with the GSH nail constructs. If a GSH nail is selected, the authors recommend a grouped screw configuration, which absorbed more energy during axial loading compared with the DCS plate constructs and the nail with the dispersed screw configuration.
比较股骨髁上交锁髓内钉(GSH)与95°髁支持钢板(DCS)治疗股骨远端骨折的初始稳定性。
人体尸体生物力学研究。
12对新鲜冷冻的人体尸体股骨。
比较股骨髁上交锁髓内钉装置(美国田纳西州孟菲斯市史赛克公司)和95°DCS装置(美国宾夕法尼亚州波利市辛迪斯公司)。对每种骨折固定系统,采用分组或分散螺钉结构,模拟逐渐严重的骨折模式进行测试。
轴向和扭转刚度值。
采用分散螺钉结构的DCS钢板具有最大的扭转刚度(p < 0.0011)。与钢板结构相比,采用分组螺钉结构的GSH髓内钉在轴向加载过程中吸收更多能量(功)(p < 0.0007)。对于严重程度增加的骨折模式,各治疗组内轴向或扭转刚度无显著差异。
根据作者的研究结果,GSH髓内钉或DCS钢板的选择不应取决于骨折的严重程度。如果选择DCS钢板结构,作者建议采用分散螺钉结构,包括钢板最近端的孔,与GSH髓内钉结构相比,在扭转加载时提供更高的刚度,在轴向加载时提供同等的刚度。如果选择GSH髓内钉,作者建议采用分组螺钉结构,与DCS钢板结构和采用分散螺钉结构的髓内钉相比,其在轴向加载过程中吸收更多能量。