Balazs Keszler

Title: Balazs Keszler: Innovator in Amphiphilic Networks and Biological Devices

Introduction

Balazs Keszler is a notable inventor based in Budapest, Hungary. He has made significant contributions to the field of polymer science and biomedical engineering. With a total of 3 patents, Keszler's work focuses on innovative solutions for biological devices and materials.

Latest Patents

Keszler's latest patents include groundbreaking inventions such as amphiphilic networks and implantable immunoisolatory devices. His first patent provides high mechanical strength amphiphilic polymer networks and biological devices capable of encasing and immunoisolating biological material from the host's immune response. This invention also outlines methods for forming these networks and devices, particularly for treating type I diabetes mellitus by encasing islet of Langerhans cells within the biological device.

Another significant patent involves three-arm star compositions of matter with diblock arms based on polyisobutylene. This invention describes a process for preparing a composition of matter that includes a trifunctional aromatic core with three diblock copolymer arms. The method involves several steps, including the use of a macroinitiator and living radical polymerization to create the outer polymer segments.

Career Highlights

Throughout his career, Keszler has worked with esteemed institutions such as the University of Akron and Muanyagipari Kutato Intezet. His research has contributed to advancements in polymer technology and its applications in medicine.

Collaborations

Keszler has collaborated with notable individuals in his field, including Joseph P. Kennedy and Györgyi Fenyvesi. These partnerships have further enriched his research and innovation efforts.

Conclusion

Balazs Keszler's contributions to the field of polymer science and biomedical devices highlight his innovative spirit and dedication to improving healthcare solutions. His patents reflect a commitment to advancing technology that can significantly impact the treatment of diseases like diabetes.