Department of Internal Medicine, University of Buffalo, Buffalo, New York, USA.
Department of Orthopedics and Rehabilitation, University of Iowa Hospitals and Clinics, Iowa City, Iowa, USA.
Iowa Orthop J. 2022 Jun;42(1):249-254.
As overall cancer survival continues to improve, the incidence of metastatic lesions to the bone continues to increase. The subsequent skeletal related events that can occur with osseous metastasis can be debilitating. Complete and impending pathologic femur fractures are common with patients often requiring operative fixation. However, the efficacy of an intramedullary nail construct, on providing stability, continue to be debated. Therefore, the purpose of this study was to utilize a synthetic femur model to determine 1) how proximal femur defect size and cortical breach impact femur load to failure (strength) and stiffness, and 2) and how the utilization of an IMN, in a prophylactic fashion, subsequently alters the overall strength and stiffness of the proximal femur.
A total of 21 synthetic femur models were divided into four groups: 1) intact (no defect), 2) 2 cm defect, 3) 2.5 cm defect, and 4) 4 cm defect. An IMN was inserted in half of the femur specimens that had a defect present. This procedure was performed using standard antegrade technique. Specimens were mechanically tested in offset torsion. Force-displacement curves were utilized to determine each constructs load to failure and overall torsional stiffness. The ultimate load to failure and construct stiffness of the synthetic femurs with defects were compared to the intact synthetic femur, while the femurs with the placement of the IMN were directly compared to the synthetic femurs with matching defect size.
The size of the defect invertedly correlated with the load the failure and overall stiffness. There was no difference in load to failure or overall stiffness when comparing intact models with no defect and the 2 cm defect group (p=0.98, p=0.43). The 2.5 cm, and 4.5 cm defect groups demonstrated significant difference in both load to failure and overall stiffness when compared to intact models with results demonstrating 1313 N (95% CI: 874-1752 N; p<0.001) and 104 N/mm (95% CI: 98-110 N/mm; p=0.03) in the 2.5 cm defect models, and 512 N (95% CI: 390-634 N, p<0.001) and 21 N/mm (95% CI: 9-33 N/mm, p<0.001) in the models with a 4 cm defect. Compared to the groups with defects, the placement an IMN increased overall stiffness in the 2.5 cm defect group (125 N/mm; 95% CI:114-136 N/mm; p=0.003), but not load to failure (p=0.91). In the 4 cm defect group, there was a significant increase in load to failure (1067 N; 95% CI: 835-1300 N; p=0.002) and overall stiffness (57 N/mm; 95% CI:46-69 N/mm; p=0.001).
Prophylactic IMN fixation significantly improved failure load and overall stiffness in the group with the largest cortical defects, but still demonstrated a failure loads less than 50% of the intact model. This investigation suggests that a cortical breach causes a loss of strength that is not completely restored by intramedullary fixation. .
随着整体癌症存活率的持续提高,转移性骨病变的发生率继续增加。随后可能发生的与骨转移相关的骨骼相关事件可能会使人衰弱。由于患者经常需要手术固定,因此经常发生完全性和即将发生的病理性股骨骨折。但是,髓内钉结构在提供稳定性方面的功效仍存在争议。因此,本研究的目的是利用合成股骨模型来确定 1)股骨近端缺陷的大小和皮质破裂如何影响股骨失效时的负荷(强度)和刚度,以及 2)如何以预防性方式使用 IMN 随后改变股骨近端的整体强度和刚度。
总共对 21 个合成股骨模型进行了分组:1)完整(无缺陷),2)2cm 缺陷,3)2.5cm 缺陷和 4)4cm 缺陷。将 IMN 插入存在缺陷的一半股骨标本中。使用标准的顺行技术进行此操作。将标本在偏置扭转中进行机械测试。利用力-位移曲线确定每个结构的失效时的负荷和整体扭转刚度。将具有缺陷的合成股骨的最终失效负荷和结构刚度与完整的合成股骨进行比较,而将带有 IMN 放置的股骨直接与具有匹配缺陷尺寸的合成股骨进行比较。
缺陷的大小与失效时的负荷和整体刚度呈反相关。在比较无缺陷和 2cm 缺陷组的完整模型时,失效时的负荷或整体刚度没有差异(p=0.98,p=0.43)。2.5cm 和 4.5cm 缺陷组在失效时的负荷和整体刚度方面均与完整模型存在显著差异,结果显示 2.5cm 缺陷模型中的 1313N(95%CI:874-1752N;p<0.001)和 104N/mm(95%CI:98-110N/mm;p=0.03)以及 4cm 缺陷模型中的 512N(95%CI:390-634N,p<0.001)和 21N/mm(95%CI:9-33N/mm,p<0.001)。与存在缺陷的组相比,在 2.5cm 缺陷组中,放置 IMN 增加了整体刚度(125N/mm;95%CI:114-136N/mm;p=0.003),但并未增加失效时的负荷(p=0.91)。在 4cm 缺陷组中,失效时的负荷(1067N;95%CI:835-1300N;p=0.002)和整体刚度(57N/mm;95%CI:46-69N/mm;p=0.001)均有显著增加。
预防性 IMN 固定可显着提高皮质缺损最大组的失效负荷和整体刚度,但失效负荷仍低于完整模型的 50%。这项研究表明,皮质破裂会导致强度丧失,而这种强度的丧失不能完全通过髓内固定来恢复。