Location History:
- Kikuchi, JP (2011)
- Kumamoto, JP (1999 - 2017)
Company Filing History:
3 out of 114 
1 out of 37 Years Active: 1999-2017
Title: Noriko Shinya: Innovator in Medical Technology
Introduction
Noriko Shinya is a prominent inventor based in Kumamoto, Japan. She has made significant contributions to the field of medical technology, particularly in the development of artificial blood vessels and bioabsorbable materials. With a total of 4 patents, her work has the potential to greatly enhance surgical procedures and patient outcomes.
Latest Patents
One of her latest inventions is an artificial blood vessel using a decellularized blood vessel sheet. This innovative design allows for transplantation to blood vessels with a small diameter and can be adjusted to various sizes. It improves invasiveness during grafting and addresses challenges related to graft provision. The artificial blood vessel is created from a decellularized tubular structure, which is processed into a roll structure, ensuring compatibility with blood flow.
Another notable patent is a bioabsorbable synthetic nonwoven fabric that holds thrombin. This invention provides a safe and effective hemostatic solution. The bioabsorbable fabric is prepared by immersing it in a thrombin solution and lyophilizing the resulting material. This innovative fabric allows for quicker and more effective hemostasis, which is crucial in surgical settings.
Career Highlights
Noriko Shinya has worked with esteemed organizations such as the Chemo-Sero-Therapeutic Research Institute. Her experience in these institutions has allowed her to collaborate on groundbreaking research and development projects in the medical field.
Collaborations
Some of her notable coworkers include Takanori Uchida and Hiroshi Kaetsu. Their collaborative efforts have contributed to the advancement of medical technologies and innovations.
Conclusion
Noriko Shinya's contributions to medical technology through her patents and collaborations highlight her role as a leading inventor in her field. Her work continues to pave the way for advancements that can significantly improve patient care and surgical outcomes.