Company Filing History:
Years Active: 2005
Title: Innovations of Petr Vanysek in Microfluidic Technology
Introduction
Petr Vanysek is a notable inventor based in DeKalb, Illinois, recognized for his contributions to microfluidic technology. He holds a patent for a microfluidic chip that integrates various components essential for conducting chemical operations. His work has significant implications in the fields of chemistry and engineering.
Latest Patents
Vanysek's patent, titled "Microfluidic chip having integrated electrodes," describes a microfluidic device that includes electrodes for manipulating charged entities, heaters, electrochemical detectors, and sensors for temperature, pH, and fluid flow. The device is designed to be fabricated from a plastic substrate, such as a substantially saturated norbornene-based polymer. The integration of components is achieved by adhering an electrically conductive film to the substrate, which can be made of metal or electrically conducting ink. This film is applied through various methods, including metal deposition and printing. Additionally, the patent discloses methods for reducing bubble formation during electrokinetic separation and techniques for heating materials within the microfluidic device.
Career Highlights
Petr Vanysek is currently employed at Aclara Biosciences, Inc., where he continues to innovate in the field of microfluidics. His work at Aclara has allowed him to explore the practical applications of his inventions in real-world scenarios, contributing to advancements in biosciences.
Collaborations
Vanysek has collaborated with notable colleagues, including Mingqi Zhao and Antonio J Ricco. These collaborations have fostered a productive environment for innovation and research, enhancing the development of microfluidic technologies.
Conclusion
Petr Vanysek's contributions to microfluidic technology through his patented innovations demonstrate his expertise and commitment to advancing scientific research. His work continues to influence the field, paving the way for future developments in microfluidic devices.