The medial femoral wall can play a more important role in unstable intertrochanteric fractures compared with lateral femoral wall: a biomechanical study

Six pairs of freshly frozen human cadaveric femora (n = 12, six males) with a mean age of 77.17 ± 4.36 years (range 70–82 years) were used in this study. All specimens were obtained from the Medical Tissue Bank of Shanxi Province in China. After dissection of the body, all specimens were stored at − 20 °C in doubly sealed plastic bags. X-rays were performed to ensure that the specimens did not have anatomical deformities or evidence of prior pathology, fracture, arthritis, or surgery. The geometry of the proximal femur region (head diameter, neck length, neck-shaft angle, and anteversion angle) was measured. Dual-energy X-ray absorptiometry (Hologic QDR-2000; Hologic, Bedford, MA, USA) was used to measure the bone mineral density (BMD) in each femur. The specimens were chosen to have a BMD of less than 0.8 g/cm² because a patient is at risk of osteoporosis if the BMD is more than 1 with standard deviation (SD) below the mean gender peaks for young men (0.98 ± 0.12 g/cm²) and women (0.92 ± 0.10 g/cm²) [7, 8]. Among the six paired specimens, each bone of the pair was randomly assigned to two groups, which were either in the medial wall group (n _med = 6) or lateral wall group (n _lat = 6), ensuring an equal number of left and right specimens in each group. Because only bone pairs were used, major differences in the bone quality among the groups were excluded [9, 10]. During the preparation, instrumentation, and biomechanical testing, the specimens were intermittently sprayed with normal saline to maintain hydration.

This study was approved by the Ethics Committee of Dayi Hospital of Shanxi Medical University, and participants’ next of kin provided informed consent before commencing the present study.

Before the testing, all specimens were thawed at room temperature. Surrounding soft tissues were removed from each femur. Thereafter, an oscillating saw was used to create a medial wall defect model in the femoral intertrochanteric region simulated from Arbeitsgemeinschaft für Osteosynthesefragen/Orthopedic Trauma Association (AO/OTA) classification type 31A2 [8, 11] for the medial wall group. Similarly, a lateral wall defect model was created for the lateral wall group simulated from AO/OTA classification type 31A3.1 [12, 13]. For the medial wall defect model, the first osteotomy line was made at an angle of 20° with respect to the axis of the femur. It started from the bottom of the lesser trochanter, passed superolaterally through the intertrochanteric ridge, and terminated at the middle of the diaphysis. The other line was created from the top of the lesser trochanter to the middle of the diaphysis and terminated at the intersection of the first osteotomy line. The wedge of the medial wall was removed (Fig. 1a). With regard to the lateral wall defect model, the first osteotomy line was made at an angle of 57° with respect to the axis of the femur. It started at the bottom level of the lesser trochanter superomedially run and terminated at the middle of the diaphysis. The other line was created from the top of the lateral wall [4] and terminated at the intersection of the first osteotomy line. The wedge of the lateral wall was removed (Fig. 1b).

After the distal part of the femur was cut off at a 30-cm distance from the tip of the greater trochanter, the femora were placed in steel cylinders and embedded in ethoxyline resin (E-44, Tervan, Feicheng, China) at a height of 10 cm. To imitate a physiological inclination during a single-leg stance, the proximal femora were tilted at 15° of adduction, 0° of flexion, and 0° of internal rotation using a standardized positioning device [14, 15].

Five uniaxial strain gauges (TST120-5AA, Test Electron, Jinjiang, China) were bonded to the femoral intertrochanteric region to measure the strain. For each femur pair, the position of gauge 1 was medially applied below the bottom of the lesser trochanter. Gauge 2 was anteriorly bonded below the intersection of the osteotomy line. Gauges 3 and 4 were laterally and posteriorly installed, corresponding to the levels of gauges 1 and 2, respectively. Gauge 5 was proximally bonded beside gauge 2 (Fig. 2). The detached part of each femur was provided with a separate strain gauge, which served as a resistance for temperature compensation of the room temperature.

Before the gauges were installed, the bone surface was smoothened using a sandpaper, degreased with acetone, and dried in an O₂ stream. In addition to gauge 5 being bonded perpendicular to the diaphyseal axis of the femur, the other four gauges were installed in parallel. After exact localization, cyanoacrylate adhesive was used to cement the uniaxial strain gauges. The leads of the gauges were soldered to wires connected to a strain tester (TST3826F-L, Test Electron, Jinjiang, China). The electrical continuity, insulation, and internal resistance (120 Ω) were carefully checked for all connections, as recommended by the manufacturer. The accuracy (1%) of the strain gauges relied on the manufacturer calibration.

Vertical loads were applied to the femora using a servohydraulic testing machine (RGT-20A, 20 KN nominal force, Reger Instrument, Shenzhen, China). The specimens, together with the steel cylinders, were mounted in the testing machine using a customized steel bolt. A custom-made spherical cap, which simulated the shape of the acetabulum, was fastened to the load cell and used to achieve equal load distribution on the femoral head (Fig. 3).

For the axial loading test, the preload was circulated three times under the same velocity (10 mm/min) and the same maximum load (100 N) before the official test to stabilize the construct. Prior to the official testing, the position of the load cell after preloading was manually adjusted to ensure that the spherical cap was in contact with the femoral head, and the compression load of the load cell was less than 1 N. This position of the load cell was set as the baseline to record the femoral axial displacement. Meanwhile, the strain gauges were adjusted to zero. The specimen was then loaded in a compression state at a loading rate of 5 mm/min from the baseline position. The testing was stopped when the specimen failed. Failure was defined as the appearance of a new fracture in the femur or when an acute change in the load-displacement curve occurred [13].

After the specimen failed, a PFNA with a helical blade (Double Medical, Xiamen, China) was then implanted following the surgical technique recommended by the manufacturer. To ensure consistency, all preparations and implantation procedures were performed by the same experienced orthopedic surgeons. An archiater supervised the “surgeries” and inspected the bone-implant constructs to ensure that the implants were properly installed.

The second axial loading test for the implant-femur constructs was performed using the same protocol as that of the first loading after the instrumentation. Failure was defined as a fracture in the femoral neck or shaft, and/or cutout/cut-through, and/or implant failure, and/or sudden drop in the load resistance observed in the load-displacement curve [9], or an axial displacement of the actuator of more than 20 mm [8].

For the axial testing, a load-displacement curve was plotted for each specimen, and the stiffness was calculated as the slope of the linear portion of the curve. The strains in each specimen were recorded at load levels of 350, 700, and 1800 N and the failure load.

After testing for normality (Shapiro-Wilk test), paired t test or Wilcoxon signed-rank test was performed to assess the differences between the groups in terms of the investigated variables (demographics, axial stiffness, axial displacement, and strain). The data were evaluated using the SPSS version 21 statistics software. The results are presented as mean and SD. p < 0.05 was used as the cutoff for significance.