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IMR & Renishaw Streamline the Additive Manufacturing of Spinal Implants
技术
- 分析与建模 - Generative AI
- 功能应用 - 制造执行系统 (MES)
- 功能应用 - 产品生命周期管理系统 (PLM)
适用行业
- 医疗保健和医院
适用功能
- 产品研发
- 质量保证
用例
- 添加剂制造
- 预测性维护
服务
- 软件设计与工程服务
- 系统集成
挑战
The engineers of the Irish Manufacturing Research (IMR) and Renishaw aimed to develop an additively manufactured Anterior Cervical Interbody Device (ACID) using nTopology. The goal was to create a device that could help restore intervertebral height in patients suffering from conditions such as degenerative intervertebral disc disease, vertebral fusion, spondylolisthesis, herniated disc, osteoporosis, and spinal stenosis. The challenge was to design a spinal implant with a porous lattice that promotes osseointegration and vascularization while matching the mechanical properties of bone. This required precise control over design variables and efficient design cycles to ensure the implant's effectiveness and safety.
关于客户
Irish Manufacturing Research (IMR) is a leading research organization in Ireland focused on advancing manufacturing technologies. They collaborate with various industry partners to develop innovative solutions that enhance manufacturing processes and product development. Renishaw, a global engineering and scientific technology company, specializes in precision measurement and healthcare solutions. Together, IMR and Renishaw leveraged their expertise to develop advanced spinal implants using additive manufacturing techniques. Their collaboration aimed to address the needs of patients with spinal conditions by creating implants that promote osseointegration and match the mechanical properties of bone.
解决方案
IMR and Renishaw utilized nTopology's design optimization capabilities to develop the Anterior Cervical Interbody Device (ACID). nTopology enabled the engineers to control all design aspects of the ACID throughout the development process. They varied design parameters in a spatially precise manner and used physical fields, such as pressure and strain across the implant volume, to optimize the design. This allowed them to arrive at an optimum osseointegration lattice pore size. IMR developed seven concepts that went through the complete design cycle, with multiple iterations in each cycle. nTopology's software facilitated quick and effective design parameter adjustments, expediting the design cycles. The engineers also sliced their designs in nTopology and exported the data directly to Renishaw’s build preparation software, streamlining the manufacturing process and reducing the risk of errors and inconsistencies.
运营影响
数量效益
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