In vivo pressure gradient heterogeneity increases flow contribution of small diameter vessels in grapevine
Plants require long-distance water transport to avoid desiccation. Here, via μCT and MRI of grapevine stem, Bouda et al. show evidence of pressure gradient heterogeneity and flow redirection from wide to narrow vessels that suggests narrow vessels contribute more to xylem sap flow than previously ap...
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Nature Portfolio
2019
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oai:doaj.org-article:4775badb115e4f6f99359007a44bbc532021-12-02T15:36:18ZIn vivo pressure gradient heterogeneity increases flow contribution of small diameter vessels in grapevine10.1038/s41467-019-13673-62041-1723https://doaj.org/article/4775badb115e4f6f99359007a44bbc532019-12-01T00:00:00Zhttps://doi.org/10.1038/s41467-019-13673-6https://doaj.org/toc/2041-1723Plants require long-distance water transport to avoid desiccation. Here, via μCT and MRI of grapevine stem, Bouda et al. show evidence of pressure gradient heterogeneity and flow redirection from wide to narrow vessels that suggests narrow vessels contribute more to xylem sap flow than previously appreciated.Martin BoudaCarel W. WindtAndrew J. McElroneCraig R. BrodersenNature PortfolioarticleScienceQENNature Communications, Vol 10, Iss 1, Pp 1-10 (2019) |
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Science Q Martin Bouda Carel W. Windt Andrew J. McElrone Craig R. Brodersen In vivo pressure gradient heterogeneity increases flow contribution of small diameter vessels in grapevine |
description |
Plants require long-distance water transport to avoid desiccation. Here, via μCT and MRI of grapevine stem, Bouda et al. show evidence of pressure gradient heterogeneity and flow redirection from wide to narrow vessels that suggests narrow vessels contribute more to xylem sap flow than previously appreciated. |
format |
article |
author |
Martin Bouda Carel W. Windt Andrew J. McElrone Craig R. Brodersen |
author_facet |
Martin Bouda Carel W. Windt Andrew J. McElrone Craig R. Brodersen |
author_sort |
Martin Bouda |
title |
In vivo pressure gradient heterogeneity increases flow contribution of small diameter vessels in grapevine |
title_short |
In vivo pressure gradient heterogeneity increases flow contribution of small diameter vessels in grapevine |
title_full |
In vivo pressure gradient heterogeneity increases flow contribution of small diameter vessels in grapevine |
title_fullStr |
In vivo pressure gradient heterogeneity increases flow contribution of small diameter vessels in grapevine |
title_full_unstemmed |
In vivo pressure gradient heterogeneity increases flow contribution of small diameter vessels in grapevine |
title_sort |
in vivo pressure gradient heterogeneity increases flow contribution of small diameter vessels in grapevine |
publisher |
Nature Portfolio |
publishDate |
2019 |
url |
https://doaj.org/article/4775badb115e4f6f99359007a44bbc53 |
work_keys_str_mv |
AT martinbouda invivopressuregradientheterogeneityincreasesflowcontributionofsmalldiametervesselsingrapevine AT carelwwindt invivopressuregradientheterogeneityincreasesflowcontributionofsmalldiametervesselsingrapevine AT andrewjmcelrone invivopressuregradientheterogeneityincreasesflowcontributionofsmalldiametervesselsingrapevine AT craigrbrodersen invivopressuregradientheterogeneityincreasesflowcontributionofsmalldiametervesselsingrapevine |
_version_ |
1718386349435781120 |