Yahtanhoya Moreno, MarCom specialist, consumer goods & healthcare, Syensqo, discusses revolutionising medical devices with the use of PPSU, which combines performance with visual appeal.
Syensqo
The field of medical device manufacturing has witnessed significant advancements over the past few decades, largely driven by the evolution of materials used in production. A notable milestone in this evolution was the introduction of Radel PPSU (polyphenylsulfone) over 30 years ago. This advanced polymer has gradually replaced traditional materials like metals, offering a blend of durability, reliability, and aesthetic appeal.
Sterilisation resistance
The Radel family of grades, particularly Radel PPSU, has shown remarkable longevity and resilience, outperforming traditional materials in crucial aspects. Accelerated ageing studies on Radel PPSU indicate that it remains stable under typical product storage conditions, ensuring a long product life. Additionally, Radel PPSU's compatibility with various sterilisation methods - including gamma radiation, steam, and ethylene oxide (ETO) - enables it to maintain its mechanical, thermal, and chemical integrity through repeated cycles. This makes Radel PPSU an ideal choice for medical devices requiring frequent sterilisation, thereby enhancing patient safety and device reliability.
Biocompatibility and reliability
Biocompatibility is a critical requirement for materials used in medical applications. Radel PPSU meets the stringent ISO 10993:5 and 10993:18 standards for cytotoxicity and physicochemical properties. These certifications confirm its suitability for applications involving direct contact with bodily tissues and fluids for periods of less than 24 hours, ensuring its reliability and efficacy in clinical settings.
Mechanical properties and colour stability
Radel PPSU stands out for its ability to retain strength and toughness, even when exposed to harsh sterilisation environments. Tests have shown minimal changes in its tensile strength and elongation, demonstrating its robustness under stress. Moreover, steam sterilisation, a common method for Radel PPSU, does not affect the product's colour even after 1,000 cycles. Consistent colour fidelity is crucial for devices that rely on colour coding to enhance functionality and reduce errors, thereby improving both usability and procedural efficiency.
Impact on medical device manufacturing
The incorporation of Radel PPSU into medical device manufacturing has enabled the design of lighter, more ergonomic medical instruments, reducing fatigue and enhancing procedural efficiency. Its availability in various transparent and opaque colours has facilitated the development of colour-coded surgical instruments, which improve operational efficiency and reduce the risk of errors in fast-paced surgical environments.
Conclusion
Radel PPSU represents an advancement in materials science, driving innovation in medical device manufacturing. Its durability, compliance with biocompatibility standards, and adaptability to rigorous sterilisation processes set new benchmarks for performance and reliability in healthcare applications. As the medical industry continues to evolve, Radel PPSU is poised to play a pivotal role in the development of innovative and efficient medical devices that meet the complex demands of modern medicine.