Osteoporotic hip fracture is the most severe kind of fracture with high morbidity and mortality. Patients' ambulation and quality of life are significantly affected by the fracture because only 50% regain their prefracture functional status, even if they undergo surgeries. There are many issues associated with the current preventive methods e.g., cost, side effects, patient compliance, and time for onset of action. Femoroplasty, the injection of bone cement into the proximal femur to augment femoral strength and to prevent fracture, has been an option with great potential. However, until now femoroplasty has remained at the stage of biomechanical testing. No in vivo study has evaluated its safety and effectiveness; there is not even an animal model for such investigations. The objective of this study was to develop a proximal femur fracture goat model that consistently fractures at the proximal femur when subject to vertical load, simulating osteoporotic hip fractures in human. Six pairs of fresh frozen mature Chinese goats' femora were obtained and randomly assigned into two groups. For the experimental group, a cylindrical bone defect was created at the proximal femur, while the control was left untreated. In addition, a configuration to mimic the mechanical axis of the goat femur was developed. When subjected to load along the mechanical axis, all the specimens from the bone defect group experienced femoral neck fractures, while fractures occurred at the femoral neck or other sites of the proximal femur in the control group. The biomechanical property (failure load) of the bone defect specimens was significantly lower than that of the control specimens (p<0.05). Osteoporotic hip fractures of humans were simulated by a goat fracture model, which may serve as a reference for future femoroplasty studies in vivo. The newly developed configuration simulating a femoral mechanical axis for biomechanical tests was practicable during the study.published_or_final_versio

Frankie Leung

Qiang Luo

Tak-Wing Lau

William W. Lu

BioResearch Open Access

PubMed

Lau, TW

Luo, Q

Lu, WW

Leung, FKL

HKU Scholars Hub

TitleDevelopment of an animal fracture model for evaluation ofcement augmentation femoroplasty: an in vitro biomechanicalstudyAuthor(s) Luo, Q; Lu, WW; Lau, TW; Leung, FKLCitation BioResearch Open Access, 2014, v. 3 n. 2, p. 70-74Issued Date 2014URL http://hdl.handle.net/10722/198055RightsThis is a copy of an article published in the BioResearch OpenAccess © 2014 copyright Mary Ann Liebert, Inc.; BioResearchOpen Access is available online at: http://www.liebertonline.com.Development of an Animal Fracture Modelfor Evaluation of Cement Augmentation Femoroplasty:An In Vitro Biomechanical StudyQiang Luo,1 William W. Lu,1 Tak-Wing Lau,1 and Frankie Leung1,2AbstractOsteoporotic hip fracture is the most severe kind of fracture with high morbidity and mortality. Patients’ ambu-lation and quality of life are significantly affected by the fracture because only 50% regain their prefracture func-tional status, even if they undergo surgeries. There are many issues associated with the current preventivemethods e.g., cost, side effects, patient compliance, and time for onset of action. Femoroplasty, the injectionof bone cement into the proximal femur to augment femoral strength and to prevent fracture, has been an optionwith great potential. However, until now femoroplasty has remained at the stage of biomechanical testing. Noin vivo study has evaluated its safety and effectiveness; there is not even an animal model for such investigations.The objective of this study was to develop a proximal femur fracture goat model that consistently fractures at theproximal femur when subject to vertical load, simulating osteoporotic hip fractures in human. Six pairs of freshfrozen mature Chinese goats’ femora were obtained and randomly assigned into two groups. For the experimen-tal group, a cylindrical bone defect was created at the proximal femur, while the control was left untreated. Inaddition, a configuration to mimic the mechanical axis of the goat femur was developed. When subjected toload along the mechanical axis, all the specimens from the bone defect group experienced femoral neck fractures,while fractures occurred at the femoral neck or other sites of the proximal femur in the control group. The bio-mechanical property (failure load) of the bone defect specimens was significantly lower than that of the controlspecimens ( p< 0.05). Osteoporotic hip fractures of humans were simulated by a goat fracture model, which mayserve as a reference for future femoroplasty studies in vivo. The newly developed configuration simulating a fem-oral mechanical axis for biomechanical tests was practicable during the study.Key words: aging; femur fracture; hip fracture; osteoporosisIntroductionOsteoporotic hip fracture is the most severe kind offracture caused by osteoporosis. Hip fracture patientshave a high mortality rate of up to 30% during the firstyear after fracture.1 In addition, their ambulation and qualityof life are significantly affected by the fracture, and only 50%regain their prefracture functional status.2 This constitutes asignificant health problem and a major burden to society.Hence in the past few decades, there have been numerous at-tempts to improve the management of these fractures, boththrough surgical treatment and preventive measures.The currently available methods of prevention includenoninvasive physical protection and various pharmacologi-cal agents. Padded hip protectors and energy-absorbing mat-tresses have been shown to have limited effectiveness inreducing hip fractures.3–5 An array of drugs, including cal-cium, vitamin D, bisphosphonates, and strontium ranelate,have been used to improve bone mineral density, thus de-crease the risk of fractures. However, there are many issuesassociated with the use of these methods (e.g., cost, side ef-fects, patient compliance, and time for onset of action) thatcan inhibit efficacy.6–8 A logical solution is the develop-ment of a prophylactic surgical intervention to increase thestrength of the proximal femur and to decrease the risk offracture. This technique should be quick, easy, and minimallyinvasive and carry minimal risk to the patients. Femoroplasty,the injection of bone cement into the proximal femur to aug-ment the femur and to prevent fracture, has been an optionwith great potential.1Department of Orthopaedics and Traumatology, University of Hong Kong, Hong Kong, China.2Shenzhen Key Laboratory for Innovative Technology in Orthopaedic Trauma, The University of Hong Kong Shenzhen Hospital,Shenzhen, China.BioResearch Open AccessVolume 3, Number 2, April 2014ª Mary Ann Liebert, Inc.DOI: 10.1089/biores.2013.003670Prophylactic bone cement augmentation of proximal fe-mur remains at the stage of biomechanical testing. Therehave only been some in vitro studies in cadaveric bone,which showed beneficial effect of femoroplasty in rein-forcing bone strength.9–13 However, there has not beenenough evidence to support its clinical feasibility andbenefits. Moreover, its acceptance in clinical applicationis still hampered by possible adverse effects, which in-clude exothermic reaction during bone cement harden-ing, the effect on blood supply of bone and adjacent softtissues, the increase in intramedullary pressure, and therisk of fat embolism.10–12 Therefore, before femoroplastycan become a viable clinical option, these potential adverseeffects must be investigated with appropriate in vivo studiesto evaluate the safety issues and therapeutic potential offemoroplasty.The purpose of this study was to develop an animal modelfor femoroplasty in vivo study. The model can consistentlyfracture at the proximal femur when subject to load, simulat-ing osteoporotic hip fractures in human. We hypothesize thatwith a bone defect in the proximal femur, this femur fracturemodel will serve this purpose well.Methods and MaterialsSix pairs of fresh frozen Chinese mountain goat femurswere utilized in this study. Any focal bone pathology wasprecluded by using radiographs in two planes. The speci-mens were divided into two groups. The left femur fromeach pair served as the bone defect group, and the rightfemur was left untreated and served as the control.For the bone defect group, a cylindrical bone defect wascreated through the lateral wall of the proximal femur tothe femoral head. Afterward all specimens were subjectedto biomechanical tests using the Material Testing System(MTS 858 Mini Bionix, Minneapolis, MN) with a newlycreated configuration. Based on the concept of the humanmechanical axis of the lower extremity, the goat femoralmechanical axis was defined as the line from the center offemoral head to the center of knee. The vertical load wasapplied through the femoral mechanical axis until fracturesoccurred.Creating a bone defectFirst each femur from bone defect group was fixed on the ex-periment table, simulating the position of human surgery. Theentry point was defined by the line passing through the greatertrochanter along the long axis of the bone at the level of lessertrochanter. A hole was made at this point with a 5-mm-diameterbone drill. A 4-cm-long cylindrical cancellous bone defect at anangle of 45 to the longitudinal axis of the femur was then madewith a 5-mm-diameter burr, reaching the dense cancellous bonein the femoral head (Fig. 1).Biomechanical testingAll femora were stored in sealed plastic bags at 20Cafter the development of bone defect until 1 day before bio-mechanical testing, at which time they were removed fromthe freezer and allowed to thaw overnight to room tempera-ture in the same sealed plastic bags.Biomechanical tests were performed in a configuration thatsimulated the mechanical axis of the goat femur (Fig. 2). Thedistal femur of the specimen was embedded into a cylindricaltray with Huntsman glue mixture (Araldite AW2104+Hardener HW2934, Huntsman, Switzerland). The femoralshaft was oriented so that the center of femoral head and thecenter of the knee joint were located in the same verticalline, which represented the biomechanical axis for load testing.The specimens were left wrapped in gauze soaked in saline so-lution for 24 h to ensure glue fixation of the distal end of femur.The whole construct was placed in a servo hydraulic grip con-trol testing machine (MTS 858 Mini Bionix) under a custom-made stainless steel spherical pressing shell. The femoral headwas preloaded to 40 N through the pressing shell attached tothe actuator of MTS. The actuator was displaced downwardat a rate of 1 mm/s until failure occurred (Fig. 3). The fractureposition and fracture load were recorded.Statistical analysisSignificant differences, defined by p < 0.05, in the vari-ables of interest (fracture load, yield load) between thebone defect group and the control group using paired t-tests. All statistical calculations were performed with SPSSversion 15 software (SPSS Inc., Chicago, IL).FIG. 1. (A) The entry pointwas defined by the line pass-ing through the greater tro-chanter along the long axis ofthe bone at the level of lessertrochanter. A cylindricalcancellous bone defect,4.0 cm long at an angle of 45to the longitudinal axis of thefemur, was then made with a5-mm-diameter burr, reach-ing the dense cancellous bonein the femoral head. (B) Thebone defect under X-ray.CEMENT AUGMENTATION FEMOROPLASTY EVALUATION 71ResultsAll six specimens from the bone defect group fractured atthe femoral neck (Fig. 3), while fractures occurred at thefemoral neck or other sites of proximal femur in the controlgroup.For biomechanical properties, the average failure load inthe control group was 3635– 820 N while 2348– 944 N inthe bone defect group. The difference regarding yield andfailure load between the two groups was significant ( p =0.030 and p = 0.02, respectively; Fig. 4).DiscussionOsteoporotic hip fracture is a great challenge to most or-thopedic surgeons, and the complication rates after surgeryare high. The most effective methods may be preventive pro-cedures. However, the currently available preventive meth-ods, including noninvasive physical protection and variouspharmacological agents, are far from ideal and hindered byadverse effects, patients’ compliance, or onset time of action.Hence in the past few decades, doctors have attempted to de-velop a prophylactic surgical procedure to protect the osteo-porotic hip.In 2004, Heini et al.12 first reported that femoroplasty,bone cement (polymethylmethacrylate [PMMA]) augmenta-tion of the proximal femur, could reinforce the proximalfemur and potentially decrease the risk of hip fracture. Sub-sequent biomechanical studies further proved that femoro-plasty using different bone cements (including PMMA andother bioactive cements) and different augmentation pat-terns could improve femoral biomechanical properties,decreasing the risk of osteoporotic hip fracture. The sideeffects related to this surgical procedure were presentedand roughly addressed using cadaveric osteoporotic bone.However, until now the safety and feasibility issues hadnot been addressed in vivo; a specific animal model for fem-oroplasty in vivo study did not even exist. To our knowledge,the goat is a well-established animal model to study femoralFIG. 2. (A) Mechanicalaxis under X-ray. (B) Setupfor mechanical testing: thecenter of the femoral headand the midpoint betweenfemoral entepicondyle andthe lateral epicondyle werelocated in the same verticalline.FIG. 3. After biomechanicaltesting, the fractures occurred (A) atthe femoral neck in bone defectgroup and (B) at the femoral head inthe control group.72 LUO ET AL.head osteonecrosis.14,15 So we developed the proximal femurfracture goat model to simulate human osteoporotic hip frac-ture for future in vitro and in vivo studies of femoroplasty.Through creating a cylindrical bone defect in the goatproximal femur, we simulated a fracture. Due to this weakpoint between the femoral neck and calcar, the bone defectspecimens experienced femoral neck fracture. This resultwas consistent with our original hypothesis. In addition,the fracture load and yield load in the control group were1.5 and 2.2 times higher, respectively, than in the bone defectgroup (Fig. 5).In this study, we aimed to develop an animal model tomimic human hip fracture. The results showed that thegoat model consistently fractured at femoral necks when sub-jected to vertical load, and the fracture line was similar to os-teoporotic femoral neck fracture that occurs in humans. Inaddition, the mechanical axis of the goat femur was testedbiomechanically, and the newly developed configurationwas practicable during this study.There are some limitations in this study. First, human os-teoporotic hip fracture can hardly be duplicated on a largefour-legged animal. Most osteoporotic hip fractures happenwhen individuals sustain low-energy trauma falling fromstanding height. Goats have little chance of falling on thegreat trochanter. Second, most human hip fractures are inter-trochanteric fractures. Possibly because the goat femur ismuch shorter than the human femur, this model’s fracture lo-cation was at the femoral neck rather than the intertrochan-teric region. Third, the configuration of falling on thegreater trochanter is widely accepted as a test of the biome-chanical properties of the femur; however, when it is appliedto a goat femur, we found that fracture location was different.So, the configuration of one leg stance was selected. In addi-tion, because osteoporotic goat bone can hardly be obtained,the goat femora used in this study were healthy.In conclusion, the aim of establishing this goat femoralfracture model was to evaluate the safety and feasibility offemoroplasty. The limitations of this model will not mattertoo much for further in vivo study of femoroplasty.AcknowledgmentThis study was financially supported by the seeding fundof The University of Hong Kong in 2012.Author Disclosure StatementNo competing financial interests exist.References1. Keene GS, Parker MJ, Pryor GA. Mortality and morbidityafter hip fractures. BMJ. 1993;307:1248–1250.2. Sernbo I, Johnell O. Consequences of a hip fracture: a pro-spective study over 1 year. Osteoporos Int. 1993;3:148–153.3. Kannus P, Parkkari J, Niemi S, et al. Prevention of hip frac-ture in elderly people with use of a hip protector. N Engl JMed. 2000;343:1506–1513.4. Zacker C, Shea D. An economic evaluation of energy-ab-sorbing flooring to prevent hip fractures. Int J TechnolAssess Health Care. 1998;14:446–457.5. Sawka AM, Boulos P, Beattie K, et al. Do hip protectors de-crease the risk of hip fracture in institutional and community-dwelling elderly? A systematic review and meta-analysis ofrandomized controlled trials. Osteoporos Int. 2005;16:1461–1474.6. Courtney AC, Wachtel EF, Myers ER, Hayes WC. Effectsof loading rate on strength of the proximal femur. CalcifTissue Int. 1994;55:53–58.7. Oden ZM, Selvitelli DM, Bouxsein ML. Effect of local den-sity changes on the failure load of the proximal femur. JOrthop Res 1999;17:661–667.8. Recker RR, Barger-Lux J. Risedronate for prevention andtreatment of osteoporosis in postmenopausal women. ExpertOpin Pharmacother. 2005;6:465–477.9. Beckmann J, Springorum R, Vettorazzi E, et al. Fractureprevention by femoroplasty—cement augmentation of theproximal femur. J Orthop Res. 2011;29:1753–1758.10. Sutter EG, Mears SC, Belkoff SM. A biomechanical evalu-ation of femoroplasty under simulated fall conditions. JOrthop Trauma. 2010;24:95–99.11. Beckmann J, Ferguson SJ, Gebauer M, Luering C, Gasser B,Heini P. Femoroplasty—augmentation of the proximalfemur with a composite bone cement—feasibility, biome-chanical properties and osteosynthesis potential. Med EngPhys. 2007;29:755–764.FIG. 4. The failure load in bone defect group was muchlower than in the control group. *p< 0.05.FIG. 5. The representative cures of load versus displace-ment. Data shown are fracture loads for the control speci-mens (a) and for the femoroplasty specimens (b).CEMENT AUGMENTATION FEMOROPLASTY EVALUATION 7312. Heini PF, Franz T, Fankhauser C, Gasser B, Ganz R. Fem-oroplasty-augmentation of mechanical properties in the os-teoporotic proximal femur: a biomechanical investigation ofPMMA reinforcement in cadaver bones. Clin Biomech(Bristol, Avon). 2004;19:506–512.13. Fliri L, Sermon A, Wa¨hnert D, Schmoelz W, Blauth M,Windolf M. Limited V-shaped cement augmentation ofthe proximal femur to prevent secondary hip fractures. JBiomater Appl. 2013;28:136–143.14. Yang S, Wu X, Mei R, et al. Biomaterial-loaded allograftthreaded cage for the treatment of femoral head osteonecro-sis in a goat model. Biotechnol Bioeng. 2008;100:560–566.15. Tang TT, Lu B, Yue B, et al. Treatment of osteonecrosis of thefemoral head with hBMP-2-gene-modified tissue-engineeredbone in goats. J Bone Joint Surg Br. 2007;89:127–129.Address correspondence to:Frankie Leung, MBBS, FRCS, FHKCOS, FHKAM5F, Professorial Block, Queen Mary Hospital102, Pokfulam RoadHong KongChinaE-mail: klleunga@hku.hkAbbreviations UsedMTS¼Material Testing SystemPMMA¼ polymethylmethacrylate74 LUO ET AL.

Development of an animal fracture model for evaluation of cement augmentation femoroplasty: an in vitro biomechanical study

http://dx.doi.org/10.1089/biores.2013.0036

Development of an animal fracture model for evaluation of cement augmentation femoroplasty: an in vitro biomechanical study

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