J Beckmann1, S J Ferguson, M Gebauer, C Luering, B Gasser, P Heini. 1. Orthopaedic Clinic and Policlinic of the University of Regensburg, Asklepios Klinik Bad Abbach, Kaiser-Karl-V-Allee 3, 93077 Bad Abbach, Germany. j.beckmann@asklepios.com
Abstract
BACKGROUND: Analogous to vertebroplasty, cement-augmentation of the proximal femur ("femoroplasty") could reinforce osteoporotic bones. This study was to evaluate (i) the feasibility of femoroplasty with a composite cement (Cortoss), (ii) its influence on femoral strength by mechanical testing and (iii) the feasibility of stable osteosynthesis of the augmented fractured bones. METHODS: Nine human cadaveric femora were augmented with a composite bone cement, the surface heat generation monitored, and then tested biomechanically against their native contralateral control to determine fracture strength. Subsequently, thirteen reinforced and fractured femora were osteosynthetized by different implants and tested against their osteosynthetisized, non-augmented contralateral control. FINDINGS: Cement could be injected easily, with a moderate temperature rise. A positive correlation between BMD and fracture load and a significant increase in fracture load (+43%) of the augmented femora compared to their native controls (6324 N and 4430 N, respectively) as well as a significant increase in energy-to-failure (+187%, 86 N m and 30 N m, respectively) was found. Osteosynthesis was possible in cement-augmented femora. Osteosynthetisized femora showed equivalent strength to the intact controls. INTERPRETATION: Augmentation of the proximal femur with composite bone cement could be of use in prophylaxis of fractures in osteoporotic femurs. Osteosynthesis of the fractured augmented bones is a challenging procedure but has a good chance to restore strength.
BACKGROUND: Analogous to vertebroplasty, cement-augmentation of the proximal femur ("femoroplasty") could reinforce osteoporotic bones. This study was to evaluate (i) the feasibility of femoroplasty with a composite cement (Cortoss), (ii) its influence on femoral strength by mechanical testing and (iii) the feasibility of stable osteosynthesis of the augmented fractured bones. METHODS: Nine human cadaveric femora were augmented with a composite bone cement, the surface heat generation monitored, and then tested biomechanically against their native contralateral control to determine fracture strength. Subsequently, thirteen reinforced and fractured femora were osteosynthetized by different implants and tested against their osteosynthetisized, non-augmented contralateral control. FINDINGS: Cement could be injected easily, with a moderate temperature rise. A positive correlation between BMD and fracture load and a significant increase in fracture load (+43%) of the augmented femora compared to their native controls (6324 N and 4430 N, respectively) as well as a significant increase in energy-to-failure (+187%, 86 N m and 30 N m, respectively) was found. Osteosynthesis was possible in cement-augmented femora. Osteosynthetisized femora showed equivalent strength to the intact controls. INTERPRETATION: Augmentation of the proximal femur with composite bone cement could be of use in prophylaxis of fractures in osteoporotic femurs. Osteosynthesis of the fractured augmented bones is a challenging procedure but has a good chance to restore strength.
Authors: S Kolta; S Paratte; T Amphoux; S Persohn; S Campana; W Skalli; S Paternotte; J-N Argenson; J-M Bouler; O Gagey; C Roux Journal: Osteoporos Int Date: 2011-06-09 Impact factor: 4.507
Authors: Ehsan Basafa; Ryan J Murphy; Yoshito Otake; Michael D Kutzer; Stephen M Belkoff; Simon C Mears; Mehran Armand Journal: J Biomech Date: 2014-11-12 Impact factor: 2.712
Authors: Ehsan Basafa; Robert S Armiger; Michael D Kutzer; Stephen M Belkoff; Simon C Mears; Mehran Armand Journal: Med Eng Phys Date: 2013-02-01 Impact factor: 2.242