Title
Microfluidic Devices Developed For And Inspired By Thermotaxis And Chemotaxis
Keywords
Bio-inspired; Chemocapillary; Chemotaxis; Microfluidic; Microorganism; Taxis; Thermocapillary; Thermotaxis
Abstract
Taxis has been reported in many cells and microorganisms, due to their tendency to migrate toward favorable physical situations and avoid damage and death. Thermotaxis and chemotaxis are two of the major types of taxis that naturally occur on a daily basis. Understanding the details of the thermo- and chemotactic behavioral response of cells and microorganisms is necessary to reveal the body function, diagnosing diseases and developing therapeutic treatments. Considering the length-scale and range of effectiveness of these phenomena, advances in microfluidics have facilitated taxis experiments and enhanced the precision of controlling and capturing microscale samples. Microfabrication of fluidic chips could bridge the gap between in vitro and in situ biological assays, specifically in taxis experiments. Numerous efforts have been made to develop, fabricate and implement novel microchips to conduct taxis experiments and increase the accuracy of the results. The concepts originated from thermo- and chemotaxis, inspired novel ideas applicable to microfluidics as well, more specifically, thermocapillarity and chemocapillarity (or solutocapillarity) for the manipulation of single- and multi-phase fluid flows in microscale and fluidic control elements such as valves, pumps, mixers, traps, etc. This paper starts with a brief biological overview of the concept of thermo- and chemotaxis followed by the most recent developments in microchips used for thermo- and chemotaxis experiments. The last section of this review focuses on the microfluidic devices inspired by the concept of thermo- and chemotaxis. Various microfluidic devices that have either been used for, or inspired by thermo- and chemotaxis are reviewed categorically.
Publication Date
3-26-2018
Publication Title
Micromachines
Volume
9
Issue
4
Document Type
Review
Personal Identifier
scopus
DOI Link
https://doi.org/10.3390/mi9040149
Copyright Status
Unknown
Socpus ID
85044412185 (Scopus)
Source API URL
https://api.elsevier.com/content/abstract/scopus_id/85044412185
STARS Citation
Karbalaei, Alireza and Cho, Hyoung Jin, "Microfluidic Devices Developed For And Inspired By Thermotaxis And Chemotaxis" (2018). Scopus Export 2015-2019. 8260.
https://stars.library.ucf.edu/scopus2015/8260