Company Filing History:
Years Active: 2020
Title: Silvina Ferradal: Innovator in Wearable Optical Tomography
Introduction
Silvina Ferradal is a notable inventor based in St. Louis, MO (US). She has made significant contributions to the field of wearable technology, particularly in the area of diffuse optical tomography. Her innovative work has the potential to enhance the understanding of brain activity through advanced imaging techniques.
Latest Patents
Silvina Ferradal holds a patent for a groundbreaking invention titled "Super-pixel detection for wearable diffuse optical tomography." This system includes a wearable head apparatus and an electronic console. The head apparatus is designed to receive resultant light from the head of a subject. The electronic console comprises a fiber array, a detector, and a computing device. The fiber array consists of multiple fibers that transport the resultant light received by the head apparatus. The detector features several super-pixels, each defined by a group of pixels from an array. Each super-pixel is linked to a fiber and is capable of generating multiple detection signals in response to the detected resultant light. The computing device processes these detection signals to create a high density-diffuse optical tomography (HD-DOT) image signal that reflects the brain activity of the subject.
Career Highlights
Silvina Ferradal is affiliated with Washington University, where she continues to advance her research and development in wearable technology. Her work is at the forefront of integrating optical imaging with practical applications in health and neuroscience.
Collaborations
Silvina collaborates with esteemed colleagues such as Joseph P. Culver and Karla Bergonzi, who contribute to her research endeavors and enhance the impact of her innovations.
Conclusion
Silvina Ferradal's contributions to wearable diffuse optical tomography exemplify the intersection of technology and health. Her innovative patent and collaborative efforts position her as a key figure in advancing our understanding of brain activity through non-invasive imaging techniques.