Andrea Kirby

Title: Andrea Kirby: Innovator in Printed Digital Microfluidic Devices

Introduction: Andrea Kirby is an accomplished inventor based in Toronto, Canada, recognized for her pioneering work in the field of printed digital microfluidic devices. With one patent to her name, she has made significant contributions to the development of methods and applications that enhance the capabilities of microfluidic technology.

Latest Patents: Andrea's patent, titled "Printed Digital Microfluidic Devices Methods of Use and Manufacture Thereof," encompasses various embodiments of digital microfluidic arrays. These arrays can be fabricated using innovative printing methods, such as inkjet printing, onto suitable substrates. Her work explores modifications to substrates and inks to support the optimal printing of electrode arrays, which includes alterations to surface energy. The patent also highlights the use of porous and fibrous substrates that can be enhanced through barrier layers or suitable materials, rendering surfaces capable of supporting printed electrodes. Notably, various hybrid devices comprised of printed digital microfluidic arrays on substrates with hydrophilic layers are disclosed within her patent.

Career Highlights: Andrea Kirby is currently employed at the Governing Council of the University of Toronto, where she continues to engage in high-level research and development. Her career is marked by a commitment to advancing technologies that leverage the benefits of microfluidics, contributing to innovations that can revolutionize various applications within the sciences.

Collaborations: Throughout her career, Andrea has collaborated with notable peers, including Ryan Fobel and Aaron Ray Wheeler. These partnerships foster a collaborative atmosphere in which innovative ideas can flourish, driving forward the research in digital microfluidics.

Conclusion: Andrea Kirby stands out as a trailblazer in the field of printed digital microfluidic devices. Her patent reflects her dedication to innovation and her role as an influential figure in advancing microfluidic technology. Through her work and collaborations, she continues to shape the future of this promising field.