The Impact of Coronal Configuration of the Proximal Femur on Its Mechanical Properties and the Validation of a New Theoretical Model: Finite Element Analysis and Biomechanical Examination

Overview

Journal Orthop Surg

Specialty Orthopedics

Date 2022 Oct 17

PMID 36250538

Authors

Lijia Zhang

Baozhang Zhu

Liwan Chen

Wenqing Wang

Xiaoyong Zhang

Jianguo Zhang

Affiliations

Soon will be listed here.

Abstract

Objective: This study aims to establish the coronal configuration of the proximal femur as an independent factor for its mechanical properties and provide validation for the theoretical model "fulcrum-balance-reconstruction."

Methods: The digital 3D femur model constructed with the lower extremity high-resolution computed tomography of a senior subject was applied with the axial compression of 2100N under 5 different α angles of 10°, 5°, 0°, -5°, -10°. The equivalent stress distribution of the femoral geometric model under each angle were calculated. Under the same five α angles, fatigue test was performed on 15 composite artificial left femurs (three specimens in each angle group) to obtain the failure cycle and fracture site. The statistical analysis was accomplished using One-Way ANOVA.

Results: The maximum stress of the entire femur in physiological angle (α = 10°) occurred below femoral neck with a value of 63.91 MPa. When the proximal femur is in extreme abducted angle (α = -10°), the maximum stress shift to the lower medial cortex of femoral shaft with a value of 105.2 MPa. As the α angle changed from 10° to -10°, the greater trochanteric region had the largest increment in maximum stress (2.78 times for cortex and 1.67 times for cancellous bone) locally at the proximal femur. The failure cycles of the artificial femurs with a variety of abduction angle were averagely 9126 ± 2453.87 (α = -10°), 58,112.33 ± 1293.84 (α = -5°), 92,879.67 ± 2398.54 (α = 0°), 172,045.3 ± 11011.11 (α = 5°), and 264,949.3 ± 35,067.26 (α = 10°), and the statistical analysis revealed that the α angle of the group of concern is proportional to the P value of the corresponding group compared to the 10° group(α = 5° & α = 10°, P = 0.01; α = 0 & α = 10°, P = 0.001; α = -5°, -10° & α = 10°, P < 0.001). In fatigue test, the fracture appeared on femoral neck for the α angles of 10° (three subcapital), 5° (two basal; one transcervical), and 0° (one transcervical). Fracture sites located at trochanteric region were observed with the more abducted angles including 0° (two subtrochanteric) and -5° (two intertrochanteric; one subtrochanteric). The fracture line was only found on femoral shaft in the -10° group.

Conclusion: With increasing hip abduction, the proximal femur shows declining mechanical properties, which suggests higher risk of hip fracture and increasement in the fraction of trochanteric fracture subtype. Furthermore, the hypothesis of "fulcrum-balance-reconstruction" was validated by our study to a certain extent.

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References

Yang X, Sang H, Bai B, Ma X, Xu C, Lei W . Ex Vivo Evaluation of Hip Fracture Risk by Proximal Femur Geometry and Bone Mineral Density in Elderly Chinese Women. Med Sci Monit. 2018; 24:7438-7443. PMC: 6392087. DOI: 10.12659/MSM.910876. View

Pottecher P, Engelke K, Duchemin L, Museyko O, Moser T, Mitton D . Prediction of Hip Failure Load: In Vitro Study of 80 Femurs Using Three Imaging Methods and Finite Element Models-The European Fracture Study (EFFECT). Radiology. 2016; 280(3):837-47. DOI: 10.1148/radiol.2016142796. View

Deep K, Picard F, Baines J . Dynamic knee behaviour: does the knee deformity change as it is flexed-an assessment and classification with computer navigation. Knee Surg Sports Traumatol Arthrosc. 2016; 24(11):3575-3583. DOI: 10.1007/s00167-016-4338-0. View

Damm P, Kutzner I, Bergmann G, Rohlmann A, Schmidt H . Comparison of in vivo measured loads in knee, hip and spinal implants during level walking. J Biomech. 2016; 51:128-132. DOI: 10.1016/j.jbiomech.2016.11.060. View

Smith M, Cody D, Goldstein S, Cooperman A, Matthews L, Flynn M . Proximal femoral bone density and its correlation to fracture load and hip-screw penetration load. Clin Orthop Relat Res. 1992; (283):244-51. View

Gebauer M, Stark O, Vettorazzi E, Grifka J, Puschel K, Amling M . DXA and pQCT predict pertrochanteric and not femoral neck fracture load in a human side-impact fracture model. J Orthop Res. 2013; 32(1):31-8. DOI: 10.1002/jor.22478. View

Levadnyi I, Awrejcewicz J, Zhang Y, Gu Y . Comparison of femur strain under different loading scenarios: Experimental testing. Proc Inst Mech Eng H. 2020; 235(1):17-27. DOI: 10.1177/0954411920951033. View

Peng H, Ou A, Huang X, Wang C, Wang L, Yu T . Osteotomy Around the Knee: The Surgical Treatment of Osteoarthritis. Orthop Surg. 2021; 13(5):1465-1473. PMC: 8313165. DOI: 10.1111/os.13021. View

Bousson V, Le Bras A, Roqueplan F, Kang Y, Mitton D, Kolta S . Volumetric quantitative computed tomography of the proximal femur: relationships linking geometric and densitometric variables to bone strength. Role for compact bone. Osteoporos Int. 2006; 17(6):855-64. DOI: 10.1007/s00198-006-0074-5. View

10.

DallAra E, Luisier B, Schmidt R, Pretterklieber M, Kainberger F, Zysset P . DXA predictions of human femoral mechanical properties depend on the load configuration. Med Eng Phys. 2013; 35(11):1564-72. DOI: 10.1016/j.medengphy.2013.04.008. View

11.

Cooper C, Campion G, Melton 3rd L . Hip fractures in the elderly: a world-wide projection. Osteoporos Int. 1992; 2(6):285-9. DOI: 10.1007/BF01623184. View

12.

Tsai A, Ashworth T, Marcus R, Akkus O . Femoral Iatrogenic Subtrochanteric Fatigue Fracture Risk is not Increased by Placing Drill Holes Below the Level of the Lesser Trochanter. Iowa Orthop J. 2017; 37:23-28. PMC: 5508277. View

13.

Wirth T . [Spondyloepiphyseal and metaphyseal dysplasia]. Orthopade. 2008; 37(1):8-16. DOI: 10.1007/s00132-007-1179-z. View

14.

Bergmann G, Graichen F, Rohlmann A . Hip joint loading during walking and running, measured in two patients. J Biomech. 1993; 26(8):969-90. DOI: 10.1016/0021-9290(93)90058-m. View

15.

Zhao J, Shi H, Jiang D, Wang L, Chen S, Jia W . Analysis of Combined Indicators for Risk of Osteoporotic Hip Fracture in Elderly Women. Orthop Surg. 2021; 13(4):1205-1212. PMC: 8274211. DOI: 10.1111/os.12974. View

16.

Augat P, Reeb H, Claes L . Prediction of fracture load at different skeletal sites by geometric properties of the cortical shell. J Bone Miner Res. 1996; 11(9):1356-63. DOI: 10.1002/jbmr.5650110921. View

17.

Hoshaw S, Cody D, Saad A, Fyhrie D . Decrease in canine proximal femoral ultimate strength and stiffness due to fatigue damage. J Biomech. 1997; 30(4):323-9. DOI: 10.1016/s0021-9290(96)00159-5. View

18.

Hu J, Peng Y, Li J, Li M, Xiong Y, Xiao J . Spatial Bridge Locking Fixator versus Traditional Locking Plates in Treating AO/OTA 32-A3.2 Fracture: Finite Element Analysis and Biomechanical Evaluation. Orthop Surg. 2022; 14(8):1638-1648. PMC: 9363740. DOI: 10.1111/os.13308. View

19.

Beck T, Ruff C, Warden K, Scott Jr W, Rao G . Predicting femoral neck strength from bone mineral data. A structural approach. Invest Radiol. 1990; 25(1):6-18. DOI: 10.1097/00004424-199001000-00004. View

20.

Felson D, Zhang Y, Hannan M, Naimark A, Weissman B, Aliabadi P . The incidence and natural history of knee osteoarthritis in the elderly. The Framingham Osteoarthritis Study. Arthritis Rheum. 1995; 38(10):1500-5. DOI: 10.1002/art.1780381017. View