Identifying Vessel Branching from Fluid Stresses on Microscopic Robots

Allen; Andrews; Augustin; Bagchi; Bleckmann; Bouffanais; Cassot; Castano; Douglas; Drexler; Dusenbery; Eberhardt; Ferber; Freitas; Green; Happel; Hill; Hogg; Hogg; Hoskins; Jager; Jain; Ke; Koman; Korin; Kottapalli; Li; Martel; Martel; Martel; Merkle; Monroe; Murray; Nagy; Painter; Park; Pawlik; Purcell; Schulz; Sershen; Sherman; Sichert; Sitti; Sochi; Thompson; Thubagere; Vollmayr; Wu; Yang

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Identifying Vessel Branching from Fluid Stresses on Microscopic Robots

Authors: Allen
Andrews
Augustin
Bagchi
Bleckmann
Bouffanais
Cassot
Castano
Douglas
Drexler
Dusenbery
Eberhardt
Ferber
Freitas
Green
Happel
Hill
Hogg
Hogg
Hoskins
Jager
Jain
Ke
Koman
Korin
Kottapalli
Li
Martel
Martel
Martel
Merkle
Monroe
Murray
Nagy
Painter
Park
Pawlik
Purcell
Schulz
Sershen
Sherman
Sichert
Sitti
Sochi
Thompson
Thubagere
Vollmayr
Wu
Yang
Publication date: 1 January 2020
Publisher: 'Elsevier BV'
Doi

Abstract

Objects moving in fluids experience patterns of stress on their surfaces determined by the geometry of nearby boundaries. Flows at low Reynolds number, as occur in microscopic vessels such as capillaries in biological tissues, have relatively simple relations between stresses and nearby vessel geometry. Using these relations, this paper shows how a microscopic robot moving with such flows can use changes in stress on its surface to identify when it encounters vessel branches.Comment: Version 2 has minor clarification

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