Company Filing History:
6 out of 3,688 
4 out of 6,615 
Years Active: 2018-2021
Title: Helena Claire Zec: Innovator in Microfluidic Systems
Introduction
Helena Claire Zec is a prominent inventor based in Baltimore, MD, known for her significant contributions to the field of microfluidics. With a total of six patents to her name, she has developed innovative systems that enhance the control and analysis of fluid dynamics at the microscale.
Latest Patents
Among her latest patents is the "Impedance Based Feedback Control of Microfluidic Valves." This invention features a microfluidic system that includes a microfluidic chip with a channel layer and a fluid control layer. The system is designed to manage the flow of fluids through various channels, which are capable of containing multiple droplets. A droplet impedance detection and feedback control system is integrated to monitor the position of droplets and operate valves accordingly.
Another notable patent is the "System and Method for Screening a Library of Samples." This continuous throughput microfluidic system is equipped with an input system that provides a sequential stream of sample plugs. It includes a droplet generator, a droplet treatment system, and a detection system that works in tandem to process and analyze treated droplets efficiently.
Career Highlights
Helena has worked with esteemed organizations such as The Johns Hopkins University and Pioneer Hi-Bred International, Inc. Her experience in these institutions has allowed her to refine her expertise in microfluidic technologies and contribute to groundbreaking research.
Collaborations
Throughout her career, Helena has collaborated with notable colleagues, including Tza-Huei J Wang and Tushar Dnyandeo Rane. These partnerships have fostered innovation and have been instrumental in advancing her research projects.
Conclusion
Helena Claire Zec stands out as a leading inventor in the field of microfluidics, with her patents reflecting her commitment to advancing technology in fluid control systems. Her work continues to influence the landscape of microfluidic applications and research.