Company Filing History:
Years Active: 2022
Title: Rayisa Moiseyenko: Innovator in Acoustophoretic Technology
Introduction
Rayisa Moiseyenko is a prominent inventor based in Taastrup, Denmark. She has made significant contributions to the field of acoustophoretic operations, particularly in the development of methods and devices that enhance the functionality of polymer chips. Her innovative work has the potential to impact various applications in microfluidics and biotechnology.
Latest Patents
Rayisa Moiseyenko holds a patent for her invention titled "Methods and devices for acoustophoretic operations in polymer chips." This invention relates to a method of performing an acoustophoretic operation, which includes several key steps. First, an acoustophoretic chip is provided, comprising a polymer substrate with a microfluidic flow channel. Next, at least one ultrasound transducer is placed in acoustic contact with the substrate's surface. The transducer is then actuated at a frequency that corresponds to an acoustic resonance peak of the substrate, which is filled with a liquid suspension. Finally, the liquid suspension is introduced into the flow channel to perform the acoustophoretic operation. This invention also encompasses an acoustophoretic device, a method for producing such a device, and a microfluidic system that incorporates the acoustophoretic device.
Career Highlights
Rayisa Moiseyenko is associated with Acousort AB, a company that focuses on innovative solutions in the field of acoustophoretic technology. Her work at Acousort AB has positioned her as a key player in advancing the applications of acoustophoretic methods in various industries.
Collaborations
Throughout her career, Rayisa has collaborated with notable colleagues, including Henrik Bruus and Torsten Freltoft. These collaborations have further enriched her research and development efforts in acoustophoretic technology.
Conclusion
Rayisa Moiseyenko is a trailblazer in the field of acoustophoretic operations, with her innovative patent contributing to advancements in microfluidic systems. Her work continues to inspire future developments in this exciting area of research.