Amanda Winstead, Freelance Writer04.19.24
Orthopedic devices play an important part in enhancing the quality of life for billions of people worldwide. The orthopedic devices market was valued at approximately $72.9 billion as of 2023, and it is expected to increase. The aging population, increased number of injury-causing accidents, and degenerative bone diseases all necessitate mass manufacturing, dissemination, and disposal of these devices.
Orthopedic devices like splints and braces have a unique lifecycle in the world of medical devices. Learn how each stage impacts the environment and how innovations can revolutionize sustainable solutions.
Testing includes environmental impact, mechanical stress assessments, wear simulations, and compatibility trials. Iterative refinements during this stage ideally lead to more robust, sustainable, and reliable orthopedic solutions.
Continuous feedback from patients, healthcare providers, and clinical studies informs design enhancements after-market. Real-world use of the devices extends beyond lab testing and helps identify trends in purchasing, use, adverse events, and patient experiences. The company can take these insights and address issues, enhance safety, and optimize performance by updating specific aspects of the orthopedic devices. This can help maintain regulatory compliance and drive the devices toward a more sustainable, helpful future.
Amanda Winstead is a writer from the Portland area with a background in communications and a passion for telling stories. Along with writing she enjoys traveling, reading, working out, and going to concerts. If you want to follow her writing journey, or even just say hi you can find her on Twitter.
Orthopedic devices like splints and braces have a unique lifecycle in the world of medical devices. Learn how each stage impacts the environment and how innovations can revolutionize sustainable solutions.
The Stages of the Orthopedic Device Lifecycle
The medical device lifecycle generally includes six key phases: concept, planning, design, validation, product launch, and post-market activities. While orthopedic devices broadly follow that same trajectory, some key qualities separate them from the pack. Let’s dive deeper into each stage to see how orthopedic devices are conceptualized, implemented, and disposed of in various ways.Concept Development and Design
In the concept development and design phase, engineers and medical professionals collaborate closely. They refine initial ideas into detailed specifications, considering factors of the proposed orthopedic devices like functionality, biomechanics, and patient safety. Market research and feasibility tests are also done to predict the viability of and demand for the design.Prototyping and Testing
Prototyping is the initial mockup phase where product samples are produced for testing. These small quantities of prototypes provide tangible representations of the initial idea, allowing designers and engineers to evaluate feasibility outside of software renditions. Orthopedic device prototypes undergo rigorous evaluation to ensure they meet safety, functionality, and performance standards.Testing includes environmental impact, mechanical stress assessments, wear simulations, and compatibility trials. Iterative refinements during this stage ideally lead to more robust, sustainable, and reliable orthopedic solutions.
Manufacturing, Production, and Launch
In the manufacturing and production phase of orthopedic devices, specialized facilities transform the initial detailed designs into ready-for-market products. Rigorous quality control ensures adherence to specifications. Processes like sterilization, surface finishing, and assembly need to be meticulously executed, resulting in reliable orthopedic devices ready for clinical use.Post-Market
After orthopedic devices have made it to market, they continue their journey beyond initial clinical use. Consumers and healthcare facilities engage in various disposal methods if the devices are faulty, broken, or no longer needed. Some devices can be recycled or repurposed for research or educational purposes.Continuous feedback from patients, healthcare providers, and clinical studies informs design enhancements after-market. Real-world use of the devices extends beyond lab testing and helps identify trends in purchasing, use, adverse events, and patient experiences. The company can take these insights and address issues, enhance safety, and optimize performance by updating specific aspects of the orthopedic devices. This can help maintain regulatory compliance and drive the devices toward a more sustainable, helpful future.
Environmental Impacts
The production, use, and disposal of orthopedic devices can all leave a negative mark on the planet. Here are some key environmental issues orthopedic implants may cause during their lifecycle:- The use of raw materials: Orthopedic implants, grafts, and sutures often rely on metals, plastics, and ceramics. Mining these materials depletes natural resources and disrupts ecosystems.
- Excessive energy consumption: Manufacturing orthopedic devices demands significant energy. From smelting metals to molding plastics, each step contributes to greenhouse gas emissions.
- Waste generation: During production, excess materials and rejected components accumulate as waste. Proper disposal of devices at the end-of-life stage is also critical to prevent pollution.
- Implant longevity: The lifespan of an orthopedic implant directly impacts its environmental footprint. Longer-lasting devices reduce the need for replacements and subsequent waste.
Innovative Strategies To Make Orthopedic Devices More Eco-Friendly
Orthopedic devices can leave less of a negative footprint on the environment. Designers, manufacturers, healthcare facilities, and patients just have to be creative. The following are some of the most innovative ways to enhance the environmental-friendliness of orthopedic devices throughout their lifecycles:- Manufacturing processes can be optimized with pre-production meetings, reviewing designs and requirements to maximize efficiency and minimize energy waste;
- Orthopedic devices can become part of the circular economy by designing for reuse, recycling, and reliability;
- Orthopedic implant metals from graves can be recycled;
- 3D printing companies can develop new materials to manufacture precise, customized orthopedic devices;
- Implants can use biodegradable materials that break down naturally.
Moving Forward With Sustainable Solutions
It’s possible to achieve a harmonious balance between aiding people with orthopedic needs and preserving the planet. Novel innovations hold the key to a more sustainable future for the industry.Amanda Winstead is a writer from the Portland area with a background in communications and a passion for telling stories. Along with writing she enjoys traveling, reading, working out, and going to concerts. If you want to follow her writing journey, or even just say hi you can find her on Twitter.