HOMEs for plants and microbes-a phenotyping approach with quantitative control of signaling between organisms and their individual environments

Oskar Siemianowski; Kara R. Lind; Xinchun Tian; Matt Cain; Songzhe Xu; Baskar Ganapathysubramanian; Ludovico Cademartiri

doi:10.1039/c7lc01186e

HOMEs for plants and microbes-a phenotyping approach with quantitative control of signaling between organisms and their individual environments

Oskar Siemianowski
, Kara R. Lind
, Xinchun Tian
, Matt Cain
, Songzhe Xu
, Baskar Ganapathysubramanian
, Ludovico Cademartiri^*

^*此作品的通讯作者

科研成果: 期刊稿件 › 文章 › 同行评审

7 引用（Scopus）

摘要

We describe a simple, scalable, modular, and frugal approach to create model ecosystems as millifluidic networks of interconnected habitats (hosting microbes or plants), which offers (i) quantitative and dynamic control over the exchange of chemicals between habitats, and (ii) independent control over their environment. Oscillatory laminar flows produce regions of vortex mixing around obstacles. When these overlap, rapid mass transport by dispersion occurs, which is quantitatively describable as diffusion, but is directional and tunable in rate over 3 orders of magnitude. This acceleration in the rate of diffusion is equivalent to reducing the distance between the habitats, and therefore, the organisms, down to the length scales characteristic of signaling in soil (<2 mm).

源语言	英语
页（从-至）	620-626
页数	7
期刊	Lab on a Chip
卷	18
期	4
DOI	https://doi.org/10.1039/c7lc01186e
出版状态	已出版 - 21 2月 2018
已对外发布	是

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abstract = "We describe a simple, scalable, modular, and frugal approach to create model ecosystems as millifluidic networks of interconnected habitats (hosting microbes or plants), which offers (i) quantitative and dynamic control over the exchange of chemicals between habitats, and (ii) independent control over their environment. Oscillatory laminar flows produce regions of vortex mixing around obstacles. When these overlap, rapid mass transport by dispersion occurs, which is quantitatively describable as diffusion, but is directional and tunable in rate over 3 orders of magnitude. This acceleration in the rate of diffusion is equivalent to reducing the distance between the habitats, and therefore, the organisms, down to the length scales characteristic of signaling in soil (<2 mm).",

author = "Oskar Siemianowski and Lind, \{Kara R.\} and Xinchun Tian and Matt Cain and Songzhe Xu and Baskar Ganapathysubramanian and Ludovico Cademartiri",

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doi = "10.1039/c7lc01186e",

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AU - Siemianowski, Oskar

AU - Lind, Kara R.

AU - Tian, Xinchun

AU - Cain, Matt

AU - Xu, Songzhe

AU - Ganapathysubramanian, Baskar

AU - Cademartiri, Ludovico

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N2 - We describe a simple, scalable, modular, and frugal approach to create model ecosystems as millifluidic networks of interconnected habitats (hosting microbes or plants), which offers (i) quantitative and dynamic control over the exchange of chemicals between habitats, and (ii) independent control over their environment. Oscillatory laminar flows produce regions of vortex mixing around obstacles. When these overlap, rapid mass transport by dispersion occurs, which is quantitatively describable as diffusion, but is directional and tunable in rate over 3 orders of magnitude. This acceleration in the rate of diffusion is equivalent to reducing the distance between the habitats, and therefore, the organisms, down to the length scales characteristic of signaling in soil (<2 mm).

AB - We describe a simple, scalable, modular, and frugal approach to create model ecosystems as millifluidic networks of interconnected habitats (hosting microbes or plants), which offers (i) quantitative and dynamic control over the exchange of chemicals between habitats, and (ii) independent control over their environment. Oscillatory laminar flows produce regions of vortex mixing around obstacles. When these overlap, rapid mass transport by dispersion occurs, which is quantitatively describable as diffusion, but is directional and tunable in rate over 3 orders of magnitude. This acceleration in the rate of diffusion is equivalent to reducing the distance between the habitats, and therefore, the organisms, down to the length scales characteristic of signaling in soil (<2 mm).

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HOMEs for plants and microbes-a phenotyping approach with quantitative control of signaling between organisms and their individual environments

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