2016
DOI: 10.1088/0960-1317/26/3/035011
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A diffusion based long-range and steady chemical gradient generator on a microfluidic device for studying bacterial chemotaxis

Abstract: Studies on chemotaxis in microfluidics device have become a major area of research to generate physiologically similar environment in vitro. In this work, a novel micro-fluidic device has been developed to study chemo-taxis of cells in near physiological condition which can create controllable, steady and long-range chemical gradients using various chemoeffectors in a micro-channel. Hydrogels like agarose, collagen, etc, can be used in the device to maintain exclusive diffusive flux of various chemical species… Show more

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Cited by 20 publications
(26 citation statements)
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References 40 publications
(67 reference statements)
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“…Recent development of non-flowing gradient generators include static gradients generated by diffusion of molecules through porous nitrocellulose 7 or polyester 38 membranes, agarose hydrogel, 15,39,40 collagen, 10,41 polyethylene glycol (PEG) hydrogels, 42,43 through micro-jet array perfusion channels with minimal flow, 44,45 or through in situ biofabricated biopolymer membranes. 46,47 By restricting convective flow with membranes or hydrogels while allowing diffusion of small molecules to generate chemical gradients, flow-free and diffusion-based static gradient generators are able to decouple cell motion of nonadherent cells from flow.…”
Section: Conclusion and Future Directionmentioning
confidence: 99%
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“…Recent development of non-flowing gradient generators include static gradients generated by diffusion of molecules through porous nitrocellulose 7 or polyester 38 membranes, agarose hydrogel, 15,39,40 collagen, 10,41 polyethylene glycol (PEG) hydrogels, 42,43 through micro-jet array perfusion channels with minimal flow, 44,45 or through in situ biofabricated biopolymer membranes. 46,47 By restricting convective flow with membranes or hydrogels while allowing diffusion of small molecules to generate chemical gradients, flow-free and diffusion-based static gradient generators are able to decouple cell motion of nonadherent cells from flow.…”
Section: Conclusion and Future Directionmentioning
confidence: 99%
“…These problems suggest that a static, non-flowing gradient generator may be a more suitable platform for chemotaxis studies in the long run, despite posing greater difficulties in design, fabrication, and packaging. 7,12,[14][15][16] …”
Section: Introductionmentioning
confidence: 99%
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“…As chemical and thermal gradients are among the most important agents affecting the migration pattern of microbial cells within a physiological system, the effects of these individual gradients on E. coli have been reported by researchers. 5,[8][9][10][11][12][13][14][15] Earlier, conventional methods such as capillary assay 8 and Boyden chamber 9 have been used to generate chemical gradients to study the chemotaxis of E. coli cells in vitro. Agar plates placed over aluminum blocks with provision for the flow of hot and cold fluids 10 were used to generate thermal gradients to study the thermotaxis of E. coli cells.…”
Section: Introductionmentioning
confidence: 99%
“…5 This is due to the fact that microfluidic environments can successfully mimic the requisite physiological conditions, both qualitatively and quantitatively. There have been reports on individual studies of E. coli cell migration due to chemical 5,[11][12][13] and thermal gradients 14,15 using microfluidic devices.…”
Section: Introductionmentioning
confidence: 99%