4 resultados para Kenny
em Repositório Científico da Universidade de Évora - Portugal
Resumo:
Development of a sheep vertebroplasty model for bioceramic materials assessment Sheep has been widely used as an animal orthopaedic model. Although several studies report anatomic and biomechanical similarities as well as distinctions of ovine lumbar vertebrae when compared to human’s, only a few studies describe its actual use as a vertebroplasty model. Due to distinct anatomic features, sheep lumbar vertebrae pose a challenge when developing a minimally invasive procedure for vertebroplasty material testing, under conditions meant to be the most similar to clinical procedure. The present work describes the development of an appropriate surgical percutaneous vertebroplasty model in the lumbar spine of sheep, applicable in vivo, that minimizes the risk of post-surgical complications. This model was mechanically evaluated ex-vivo regarding its safety, and used to evaluate the injectability and radiopacity of two new bioceramic materials when compared to a commercial bioceramic bone substitute (Cerament™ SpineSupport). Microtomography techniques helped in the development of the model and results assessment. Under fluoroscopic guidance, a defect was created through a bilateral modified parapedicular access in the cranial hemivertebrae of 30 sheep lumbar vertebrae (L4, L5 and L6). The manually drilled defect had an average volume of 1209 ±226 mm3 and allowed the novel materials injection through a standardized injection cannula placed in one of the entrance points. Adequate defect filling was observed with all tested materials. No mechanical failure was observed under loads higher than the physiological.
Resumo:
O teste de novos biomateriais para vertebroplastia percutânea (VP), depende da escolha de um modelo animal adequado. O objectivo deste estudo foi o desenvolvimento ex vivo de um modelo animal reprodutível e fiável para VP, para posterior aplicação in vivo, tendo em consideração a necessidade de evitar o derrame de cimento para o canal vertebral e estruturas vasculares adjacentes. Foi seleccionado um modelo animal superior (ovino), pelas suas reconhecidas propriedades translacionais para a espécie humana. Foram realizadas VP’s em vértebras lombares sob controlo táctil e fluoroscópico, através de uma abordagem parapedicular bilateral. O volume médio de defeito obtido foi 1234±240 mm3, o que assegura defeitos viáveis para o teste de novos biomateriais injectáveis. Seis vértebras foram injectadas com um cimento comercial (Cerament®, Bone Support, Suécia) tendo-se observado preenchimento adequado dos defeitos em todas as vértebras. Todas as vértebras foram avaliadas por microtomografia axial computorizada (microTAC) antes e após a criação dos defeitos e após injecção dos cimentos. Realizaram-se testes mecânicos de compressão, tendo as vértebras sido sujeitas a cargas superiores às fisiológicas e inspeccionadas macroscopicamente. Em conclusão considera-se este modelo adequado para estudos in vivo pré-clínicos, mimetizando aplicações clínicas.
Resumo:
O teste de novos biomateriais para vertebroplastia percutânea (VP), depende da escolha de um modelo animal adequado. O objectivo deste estudo foi o desenvolvimento ex vivo de um modelo animal reprodutível e fiável para VP, para posterior aplicação in vivo, tendo em consideração a necessidade de evitar o derrame de cimento para o canal vertebral e estruturas vasculares adjacentes. Foi seleccionado um modelo animal superior (ovino), pelas suas reconhecidas propriedades translacionais para a espécie humana. Foram realizadas VP’s em vértebras lombares sob controlo táctil e fluoroscópico, através de uma abordagem parapedicular bilateral. O volume médio de defeito obtido foi 1234±240 mm3, o que assegura defeitos viáveis para o teste de novos biomateriais injectáveis. Seis vértebras foram injectadas com um cimento comercial (Cerament®, Bone Support, Suécia) tendo-se observado preenchimento adequado dos defeitos em todas as vértebras. Todas as vértebras foram avaliadas por microtomografia axial computorizada (microTAC) antes e após a criação dos defeitos e após injecção dos cimentos. Realizaram-se testes mecânicos de compressão, tendo as vértebras sido sujeitas a cargas superiores às fisiológicas e inspeccionadas macroscopicamente. Em conclusão considera-se este modelo adequado para estudos in vivo pré-clínicos, mimetizando aplicações clínicas.
Resumo:
Background Context Percutaneous vertebroplasty (PVP) is a minimally invasive surgical procedure and is frequently performed in humans who need surgical treatment of vertebral fractures. PVP involves cement injection into the vertebral body, thereby providing rapid and significant pain relief. Purpose The testing of novel biomaterials depends on suitable animal models. The aim of this study was to develop a reproducible and safe model of PVP in sheep. Study Design This study used ex vivo and in vivo large animal model study (Merino sheep). Methods Ex vivo vertebroplasty was performed through a bilateral modified parapedicular access in 24 ovine lumbar hemivertebrae, divided into four groups (n=6). Cerament (Bone Support, Lund, Sweden) was the control material. In the experimental group, a novel composite was tested—Spine-Ghost—which consisted of an alpha-calcium sulfate matrix enriched with micrometric particles of mesoporous bioactive glass. All vertebrae were assessed by micro-computed tomography (micro-CT) and underwent mechanical testing. For the in vivo study, 16 sheep were randomly allocated into control and experimental groups (n=8), and underwent PVP using the same bone cements. All vertebrae were assessed postmortem by micro-CT, histology, and reverse transcription-polymerase chain reaction (rt-PCR). This work has been supported by the European Commission under the 7th Framework Programme for collaborative projects (600,000–650,000 USD). Results In the ex vivo model, the average defect volume was 1,275.46±219.29 mm3. Adequate defect filling with cement was observed. No mechanical failure was observed under loads which were higher than physiological. In the in vivo study, cardiorespiratory distress was observed in two animals, and one sheep presented mild neurologic deficits in the hind limbs before recovering. Conclusions The model of PVP is considered suitable for preclinical in vivo studies, mimicking clinical application. All sheep recovered and completed a 6-month implantation period. There was no evidence of cement leakage into the vertebral foramen in the postmortem examination.