A microfluidic pump/valve inspired by xylem embolism and transpiration in plants.

A microfluidic pump/valve inspired by xylem embolism and transpiration in plants.

In plants, transpiration draws the water upward from the roots to the leaves. However, this flow can be blocked by air bubbles in the xylem conduits, which is called xylem embolism. In this research, we present the design of a biomimetic microfluidic pump/valve based on water transpiration and xylem...

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Main Authors: Li Jingmin, Liu Chong, Xu Zheng, Zhang Kaiping, Ke Xue, Wang Liding
Format: Article
Language:English
Published: Public Library of Science (PLoS) 2012-01-01
Series:PLoS ONE
Online Access:http://europepmc.org/articles/PMC3510208?pdf=render
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spelling doaj-113ac862e15f45dd8e2d692b087c455f2020-11-24T22:17:20ZengPublic Library of Science (PLoS)PLoS ONE1932-62032012-01-01711e5032010.1371/journal.pone.0050320A microfluidic pump/valve inspired by xylem embolism and transpiration in plants.Li JingminLiu ChongXu ZhengZhang KaipingKe XueWang LidingIn plants, transpiration draws the water upward from the roots to the leaves. However, this flow can be blocked by air bubbles in the xylem conduits, which is called xylem embolism. In this research, we present the design of a biomimetic microfluidic pump/valve based on water transpiration and xylem embolism. This micropump/valve is mainly composed of three parts: the first is a silicon sheet with an array of slit-like micropores to mimic the stomata in a plant leaf; the second is a piece of agarose gel to mimic the mesophyll cells in the sub-cavities of a stoma; the third is a micro-heater which is used to mimic the xylem embolism and its self-repairing. The solution in the microchannels of a microfluidic chip can be driven by the biomimetic "leaf" composed of the silicon sheet and the agarose gel. The halting and flowing of the solution is controlled by the micro-heater. Results have shown that a steady flow rate of 1.12 µl/min can be obtained by using this micropump/valve. The time interval between the turning on/off of the micro-heater and the halt (or flow) of the fluid is only 2∼3 s. This micropump/valve can be used as a "plug and play" fluid-driven unit. It has the potential to be used in many application fields.http://europepmc.org/articles/PMC3510208?pdf=render
collection DOAJ
language English
format Article
sources DOAJ
author Li Jingmin
Liu Chong
Xu Zheng
Zhang Kaiping
Ke Xue
Wang Liding
spellingShingle Li Jingmin
Liu Chong
Xu Zheng
Zhang Kaiping
Ke Xue
Wang Liding
A microfluidic pump/valve inspired by xylem embolism and transpiration in plants.
PLoS ONE
author_facet Li Jingmin
Liu Chong
Xu Zheng
Zhang Kaiping
Ke Xue
Wang Liding
author_sort Li Jingmin
title A microfluidic pump/valve inspired by xylem embolism and transpiration in plants.
title_short A microfluidic pump/valve inspired by xylem embolism and transpiration in plants.
title_full A microfluidic pump/valve inspired by xylem embolism and transpiration in plants.
title_fullStr A microfluidic pump/valve inspired by xylem embolism and transpiration in plants.
title_full_unstemmed A microfluidic pump/valve inspired by xylem embolism and transpiration in plants.
title_sort microfluidic pump/valve inspired by xylem embolism and transpiration in plants.
publisher Public Library of Science (PLoS)
series PLoS ONE
issn 1932-6203
publishDate 2012-01-01
description In plants, transpiration draws the water upward from the roots to the leaves. However, this flow can be blocked by air bubbles in the xylem conduits, which is called xylem embolism. In this research, we present the design of a biomimetic microfluidic pump/valve based on water transpiration and xylem embolism. This micropump/valve is mainly composed of three parts: the first is a silicon sheet with an array of slit-like micropores to mimic the stomata in a plant leaf; the second is a piece of agarose gel to mimic the mesophyll cells in the sub-cavities of a stoma; the third is a micro-heater which is used to mimic the xylem embolism and its self-repairing. The solution in the microchannels of a microfluidic chip can be driven by the biomimetic "leaf" composed of the silicon sheet and the agarose gel. The halting and flowing of the solution is controlled by the micro-heater. Results have shown that a steady flow rate of 1.12 µl/min can be obtained by using this micropump/valve. The time interval between the turning on/off of the micro-heater and the halt (or flow) of the fluid is only 2∼3 s. This micropump/valve can be used as a "plug and play" fluid-driven unit. It has the potential to be used in many application fields.
url http://europepmc.org/articles/PMC3510208?pdf=render
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