Multi-Directional Mechanical Testing of Bone using CT-Compatible Loading Mechanisms

使用 CT 兼容的加载机制对骨骼进行多方向机械测试

• 批准号: RGPIN-2019-06632
• 负责人: Ferreira, Louis
• 金额: $ 2.33万
• 依托单位: University of Western Ontario
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2021
• 资助国家: 加拿大
• 起止时间: 2021-01-01 至 2022-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=739014
• 关键词: Multi; Directional; Mechanical; Testing; Bone

Arthritis is becoming more prevalent with the aging population, and recent reports from the Arthritis Alliance of Canada indicate that arthritis is a $33 Billion burden on Canadians, which includes healthcare expenses and lost productivity. Within 30 years, 1 in 4 Canadians is expected to have osteoarthritis. When a patient's osteoarthritis becomes symptomatic and associated with functional loss, then patients can benefit from surgical intervention in the form of a joint replacement surgery, in which the joint is replaced with implants. Typically with osteoarthritis, the joint undergoes adaptive changes as the cartilage degrades. However, treatment is hampered because differences between normal and osteoarthritic patients are poorly understood, and our current inability to model patient-specific bone quality prevents us from being able to predict the success of a joint replacement surgery. Also, surgeons are currently not able to consider the patient's bone quality to select an optimal implant type that minimizes mechanical stresses in the patient's bone. High internal bone stresses may lead to small fractures that progress to cause loosening of implants and eventual failure. This then necessitates a revision surgery, which places the patient at increased risk and requires prolonged hospital stay. Revision surgeries also cost 3 to 5 times more than the original joint replacement surgery, which further increases the cost burden on our healthcare system. The purpose of this research is to develop and validate bone predictive models by experimentally applying forces to bone samples while viewing their internal structure in a high resolution micro-CT scanner. The internal structure of bone is a complex Bone samples are acquired from patients who undergo shoulder replacement surgery. In this research, we utilize these patient bone fragments that would otherwise be discarded, and we test them with applied forces in the laboratory. Mechanical testing of patient bone is essential to improve our understanding of compromised bone quality in patients requiring joint replacements, or who are at risk of fracture. While this research will initially be conducted in shoulder bone, the resulting work will be transferrable to other joints like hips and knees. Ultimately, this work will provide new methods to assess mechanical performance of newly developed biomaterials and implantable devices, including joint implants used in the treatment of osteoarthritis. Additionally, these new bone patient-specific analysis methods will lead to the development of new diagnostic and predictive tools that surgeons can use to better understand the case of the individual patient. These advancements have to potential to improve surgical outcomes for patients.

随着人口老龄化，关节炎变得越来越普遍，加拿大关节炎联盟最近的报告表明，关节炎给加拿大人带来了330亿美元的负担，其中包括医疗费用和生产力损失。在30年内，预计每4个加拿大人中就有1人患有骨关节炎。当患者的骨关节炎出现症状并伴有功能丧失时，患者可以从关节置换手术形式的手术干预中受益，其中关节被植入物置换。典型的骨关节炎，随着软骨退化，关节经历适应性变化。然而，治疗受到阻碍，因为正常和骨关节炎患者之间的差异知之甚少，我们目前无法模拟患者特定的骨质量，使我们无法预测关节置换手术的成功。此外，外科医生目前无法考虑患者的骨质来选择最佳的植入物类型，从而使患者骨骼中的机械应力最小化。高内部骨应力可能导致小骨折，进而导致植入物松动和最终失效。这就需要进行翻修手术，这会增加患者的风险，并需要延长住院时间。翻修手术的费用也是原始关节置换手术的3至5倍，这进一步增加了我们医疗保健系统的成本负担。 本研究的目的是开发和验证骨预测模型，通过实验施加力的骨样本，同时查看其内部结构的高分辨率micro-CT扫描仪。骨的内部结构是复杂的，骨样本是从接受肩关节置换手术的患者中获得的。在这项研究中，我们利用这些患者的骨碎片，否则将被丢弃，我们在实验室中测试他们与施加的力量。患者骨的力学测试对于提高我们对需要关节置换或有骨折风险的患者的骨质量受损的理解至关重要。 虽然这项研究最初将在肩胛骨中进行，但由此产生的工作将转移到其他关节，如髋关节和膝关节。最终，这项工作将提供新的方法来评估新开发的生物材料和可植入设备的机械性能，包括用于治疗骨关节炎的关节植入物。此外，这些新的骨患者特异性分析方法将导致新的诊断和预测工具的开发，外科医生可以使用这些工具来更好地了解个体患者的情况。这些进步有可能改善患者的手术结局。