vendex and Femoral-Neoplasms

We report on a patient after knee reconstruction for osteosarcoma in the distal femur using a hingeless prosthesis K-MAX KNEE system K-5 who walked without ipsilateral knee extension in the latter half of the stance phase (flexed knee gait). We evaluated the patient using three-dimensional gait analysis and isokinetic knee strength measurement, and compared the patient with five healthy subjects. The Musculoskeletal Tumor Society (MSTS) score was also used for evaluation. The patient kept his operated knee flexed during mid stance. The maximal ankle plantarflexion internal moment was lower on the ipsilateral side than on the contralateral side, and lower than in the healthy subjects. The negative ankle power during the stance phase was generally stronger on the ipsilateral side than on the contralateral side, and also in the healthy subjects. Unusual contralateral hip flexion occurred after the initial contact, indicating increased joint load on the ipsilateral ankle and the contralateral hip. The ratios of the peak knee extension/flexion torque were 0.7 on the ipsilateral side, 1.9 on the contralateral side, and 1.7 in the healthy subjects. The MSTS score of the patient was 23/30 (76.6%). Flexed knee gait might account for the reduction of ipsilateral hip flexion and ankle plantarflexion moment during the late stance phase. These results suggest the importance of focusing more on the ipsilateral ankle joint and the contralateral hip joint to maintain the function of the entire limb joints of the patients with flexed knee gait.

Topics: Arthroplasty, Replacement, Knee; Femoral Neoplasms; Gait; Humans; Knee Joint; Knee Prosthesis; Limb Salvage; Male; Osteosarcoma; Outcome Assessment, Health Care; Prosthesis Design; Range of Motion, Articular; Torque; Walking; Young Adult

The femur is the most common long bone affected by cancerous metastasis. Femoral tumor defects are known to induce pain and functional impairment in patients. Although prior studies exist evaluating the clinical and biomechanical effect of tumor defect size, no biomechanical studies have experimentally examined the risk of pathological fracture with respect to the anterior, posterior, medial, and lateral surfaces on which a proximal tumor defect is located on the femur.. Circular tumor-like defects of 40-mm diameter were created proximally in the subtrochanteric region on the Anterior (n = 5), Posterior (n = 5), Medial (n = 5), and Lateral (n = 5) sides of 20 synthetic femurs. Intact femurs served as a control group (n = 4). Femurs were tested for lateral, "offset" torsional, and axial stiffness, as well as axial strength.. Lateral stiffnesses (range, 121-162 N/mm) yielded no differences between groups (P = 0.069). "Offset" torsional stiffnesses (range, 135-188 N/mm) demonstrated that the Medial group was less stiff than the Intact, Anterior, and Lateral groups (P ≤ 0.012). Axial stiffnesses (range, 1057-1993 N/mm) showed that the Medial group was less stiff than the Intact group (P = 0.006). Axial strengths (range, 3250-6590 N) for the Medial group were lower than Anterior (P = 0.001) and Posterior (P = 0.001) specimens, whereas the Lateral group had a lower strength than Anterior specimens (P = 0.019). No other statistical differences were noted. Axial failure of Medial and Lateral specimens involved the tumor-like defect in 100% of cases, whereas 100% of Intact femurs and 80% of Anterior and Posterior femur groups failed only through the neck.. In 2 of 3 test modes, the Medial tumor-like defect group resulted in statistically lower stiffness values compared with Intact femurs and had lower strength than Anterior and Posterior groups in axial failure.

Topics: Biomimetic Materials; Bone Substitutes; Compressive Strength; Computer Simulation; Elastic Modulus; Femoral Fractures; Femoral Neoplasms; Femur; Fractures, Spontaneous; Humans; Models, Biological; Tensile Strength; Torque

Modular oncology implants using uncemented fixation represent a popular reconstruction technique for limb salvage patients. Initial stability is critical to facilitate bony ingrowth of host bone into the stem of a press-fit oncologic modular rotating-hinge total knee arthroplasty (TKA). The impact of stem design on initial stability has not been defined. The goal of this study was to evaluate the initial stability of 3 different stem designs as defined by torsional load to failure. An analysis of imaging was also performed. The pilot study consisted of 5 femora in each of 3 groups based on stem design. The specimen was mounted on a multi-axis biomechanical test frame equipped with a Vicon 3D motion analysis 4-camera system (Vicon Motion Systems, Lake Forest, California) to track the relative motion between the implant and the femur. Torsional force was applied until failure. The straight-fluted stem design had the highest average torsional stiffness (18.3±8.2 Nm/deg) and average torque at 150 μm of implant micromotion (23.2±10.6 Nm) of the 3 stem types tested.The results of this study will help to guide surgical decision making in limb salvage cases. Further investigation is warranted.

Topics: Aged; Cementation; Equipment Failure Analysis; Female; Femoral Neoplasms; Hip Prosthesis; Humans; In Vitro Techniques; Male; Middle Aged; Pilot Projects; Prosthesis Design; Torque; Treatment Outcome

Pathologic fractures from a reduction in bone mass and strength are a debilitating complication affecting the quality of life of individuals with metastatic lesions. There are a number of existing animal models for studying the effects of bone metastases experimentally, but these models are unsuitable for measuring structural changes in metastatic bone. Our goal was to present an in vivo model for directly investigating the densitometric and structural consequences of tumor-induced osteolysis in long bones. One femur from female Sprague Dawley rats was implanted with Walker Carcinosarcoma 256 malignant breast cancer cells or with a Sham implant. After 28 days, the animals were killed, and both femora of each animal evaluated using histomorphometry, densitometry, and mechanical testing. Compared to Sham-operated controls, we found an 11% decrease in bone mineral content, a 9% decrease in bone mineral density using dual energy X-ray absorptiometry, and a 16% decrease in bone density using peripheral quantitative computed tomography in the group with tumor cell implants. In addition, failure torque was decreased by 35% compared to the contralateral controls and by 41% compared to the Sham-operated controls. Torsional stiffness in the tumor cell-implanted femora was decreased by 35% compared to contralateral controls and by 39% compared to Sham-operated controls. Bone density was only weakly to moderately associated with bone strength in our model. By creating reproducible localized tumor-induced osteolytic lesions in a long bone, this model provides the most direct evaluation of the structural consequences of bone metastases. In the future, this model may provide a method for determining the effects of new therapeutic approaches on the preservation of bone mass and bone strength in the presence of metastatic bone disease.

Topics: Absorptiometry, Photon; Animals; Biomechanical Phenomena; Bone Density; Breast Neoplasms; Disease Models, Animal; Elasticity; Female; Femoral Neoplasms; Osteolysis; Rats; Rats, Sprague-Dawley; Tensile Strength; Tomography, X-Ray Computed; Torque