Company Filing History:
Years Active: 2008
Title: Satoru Miyano: Innovator in Gene Regulatory Networks
Introduction
Satoru Miyano is a prominent inventor based in Tokyo, Japan. He has made significant contributions to the field of biological discovery, particularly through his innovative work on gene regulatory networks. His research focuses on the application of new inferential methods to analyze complex biological information, which has implications for understanding gene networks.
Latest Patents
Miyano holds a patent titled "Biological discovery using gene regulatory networks generated from multiple-disruption expression libraries." This invention encompasses various embodiments that apply new inferential methods to the analysis of complex biological data, including gene networks. The methods involve obtaining disruptant data and drug induction/inhibition data simultaneously for multiple genes in an organism. Notably, his work includes modifications of Boolean and Bayesian inferential methods to determine relationships and cause-and-effect dynamics between expressed genes. These methods have been validated using information from prior studies and newly conducted research on gene expression.
Career Highlights
Satoru Miyano is associated with Gni Kk, where he continues to advance his research in gene regulatory networks. His innovative approaches have positioned him as a key figure in the field of biological research, contributing to a deeper understanding of gene interactions and their implications for various biological processes.
Collaborations
Miyano has collaborated with notable colleagues, including Seiyo Imoto and Takao Goto. Their joint efforts have further enriched the research landscape in gene regulatory networks and biological discovery.
Conclusion
Satoru Miyano's contributions to the field of biological discovery through his innovative patent and collaborative efforts highlight his role as a leading inventor in gene regulatory networks. His work continues to influence the understanding of complex biological systems and their underlying mechanisms.