![]() Kanso, Eva: Aerospace & Mechanical Engineering: : Khoshnevis. Address History Pasadena, California, United States Emails Social Profiles Linkedin Linkedin Experience Found 4 records. : Heather Culbertson Computer Science : SK Gupta. I will conclude by commenting on the implications of these models to understanding the biophysical mechanisms underlying the interaction of ciliated tissues with microbial partners. New paper by USC Viterbi School of Engineering Professor Eva Kanso and Professor Margaret McFall-Ngai of the Pacific Biosciences Research Center at the. Updated September 20th, 2022 Contact results show Our system indicates that there are other records for Eva Kanso available with a premium report, continue to a full report below. Here, I will present a series of physics-based models that take into account minimal cilia features in order to examine: (1) the emergence of self-sustained oscillations in individual cilia, (2) the coordinated beating of neighboring cilia, and (3) the role of cilia-driven flows in particle transport, mixing, capture and filtering. Yet, the relationship between the structure and organization of ciliated tissues and their biological function remains elusive. On the tissue level, cilia beat in a coordinated way and serve diverse biological functions, from mucociliary clearance in the airways to cerebrospinal fluid transport in the brain ventricles. The design of robotic vehicles for hazardous environments is one potential application of Kanso’s work. Individual cilia are driven into oscillatory motion by dynein molecular motors acting on an intricate structure of microtubule doublets referred to as the central axoneme. Motile cilia are micron-scale hair-like protrusions from epithelial cells that beat collectively to transport fluid. ![]()
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