Increased microenvironment stiffness leads to altered aldehyde metabolism and DNA damage in mammary epithelial cells through a RhoA-dependent mechanism

Authors

A.K. Wood

Published

October 6, 2020

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DOI

10.1101/2020.10.06.327726

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Increased microenvironment stiffness leads to altered aldehyde metabolism and DNA damage in mammary epithelial cells through a RhoA-dependent mechanism

Authors

A.K. Wood

Published

October 6, 2020

Add a comment...

Supporters

Support the authors with ResearchCoin

Preprint Server

Topics

DOI

10.1101/2020.10.06.327726

License

cc-no

Supporters

Support the authors with ResearchCoin

Preprint Server

Topics

DOI

10.1101/2020.10.06.327726

License

cc-no

Paper

Paper

Paper

Paper

Increased microenvironment stiffness leads to altered aldehyde metabolism and DNA damage in mammary epithelial cells through a RhoA-dependent mechanism

Supporters

Preprint Server

Topics

DOI

License

Increased microenvironment stiffness leads to altered aldehyde metabolism and DNA damage in mammary epithelial cells through a RhoA-dependent mechanism

Supporters

Preprint Server

Topics

DOI

License

Supporters

Preprint Server

Topics

DOI

License