Company Filing History:
1 out of 471 
1 out of 832,912 Years Active: 2010-2012
Title: Melissa Draper Fisk: Innovator in Microchip Technology
Introduction
Melissa Draper Fisk is a prominent inventor based in Provo, UT (US). She has made significant contributions to the field of microchip technology, particularly in the development of high-performance polymeric capillary microchips. With a total of 2 patents, her work showcases her innovative approach to solving complex engineering challenges.
Latest Patents
One of her latest patents is titled "Phase-changing sacrificial materials for manufacture of high-performance polymeric capillary microchips." This invention describes a microchip with capillaries and a method for its production. The process involves filling microchannels formed in a polymeric substrate with a sacrificial material. Once the microchannels are filled, they are covered by a top cover to create filled capillaries. The sacrificial material is then removed to form the microcapillaries. Initially, the sacrificial material fills the microchannels as a liquid, solidifying within them. After the top cover is applied and affixed, the sacrificial material is liquefied for removal. The top cover can be solvent sealed on the substrate and may be made of the same or a different material. Additionally, it can be an in situ applied semipermeable membrane.
Career Highlights
Melissa has worked at Brigham Young University, where she has contributed to various research projects and innovations. Her work has been instrumental in advancing the field of microchip technology, particularly in applications that require precision and efficiency.
Collaborations
Some of her notable coworkers include Adam T Woolley and Ryan T Kelly. Their collaborative efforts have further enhanced the research and development of innovative technologies in their field.
Conclusion
Melissa Draper Fisk is a trailblazer in the realm of microchip technology, with her patents reflecting her commitment to innovation and excellence. Her contributions continue to influence the industry and inspire future advancements in microchip design and manufacturing.