Deep learning reveals how cells pull, buckle, and navigate fibrous environments

dc.contributor.authorPadhi, Abinashen
dc.contributor.authorDaw, Arkaen
dc.contributor.authorAgashe, Atharvaen
dc.contributor.authorSawhney, Medhaen
dc.contributor.authorTalukder, Maahi M.en
dc.contributor.authorPour, Mehran M. H.en
dc.contributor.authorJafari, Mohammaden
dc.contributor.authorGenin, Guy M.en
dc.contributor.authorAlisafaei, Fariden
dc.contributor.authorKale, Sohanen
dc.contributor.authorKarpatne, Anujen
dc.contributor.authorNain, Amrinderen
dc.date.accessioned2026-01-30T14:15:45Zen
dc.date.available2026-01-30T14:15:45Zen
dc.date.issued2025-11-25en
dc.description.abstractCells in tissues navigate fibrous environments fundamentally differently than they do on flat substrates, but the establishment of cell forces in physiological fibrous settings remains poorly understood. Although factors such as the stiffness of the extracellular matrix (ECM) are known to drive behaviors, including cell motility on flat nonfibrous substrates, the interplay between fiber architecture and stiffness in fibrous ECM is not known. Here, we find that in fibrous environments, the directionality of mechanical forces overrides ECM stiffness as the primary regulator of contractility in migrating cells. Using an approach combining phase microscopy with deep learning to map forces in real time, termed deep learning-enabled live-cell fiber-force microscopy (DLFM), we reveal that when cells transition between anisotropic and isotropic stress fields, their contractility significantly drops despite encountering stiffer ECM, contrary to the behavior of cells on flat nonfibrous substrates. Unlike the peripheral adhesions observed on flat nonfibrous substrates, cells in fibrous matrices form force-generating adhesions throughout their body, stabilized by out-of-plane mechanical components unique to fiber geometry. Cells exhibit distinct force signatures during migration, division, and differentiation, with temporal signatures that predict stem cell fate. These findings, enabled by combining deep learning and the mechanics of cells and fibers, explain long-standing paradoxical behavior of cells navigating deformable fibrous environments, how they can pull and tug at them, and identify tension anisotropy as a master regulator of cell behavior, with implications for cancer invasion, tissue engineering, and regenerative medicine.en
dc.description.versionPublished versionen
dc.format.extent12 page(s)en
dc.format.mimetypeapplication/pdfen
dc.identifierARTN e2424047122 (Article number)en
dc.identifier.doihttps://doi.org/10.1073/pnas.2424047122en
dc.identifier.eissn1091-6490en
dc.identifier.issn0027-8424en
dc.identifier.issue47en
dc.identifier.orcidKale, Sohan [0000-0002-9985-3526]en
dc.identifier.orcidNain, Amrinder [0000-0002-9757-2341]en
dc.identifier.orcidKarpatne, Anuj [0000-0003-1647-3534]en
dc.identifier.pmid41269797en
dc.identifier.urihttps://hdl.handle.net/10919/141070en
dc.identifier.volume122en
dc.language.isoenen
dc.publisherNational Academy of Sciencesen
dc.relation.urihttps://www.ncbi.nlm.nih.gov/pubmed/41269797en
dc.rightsCreative Commons Attribution-NonCommercial-NoDerivatives 4.0 Internationalen
dc.rights.urihttp://creativecommons.org/licenses/by-nc-nd/4.0/en
dc.subjecttraction force microscopyen
dc.subjectcell-fiber interactionsen
dc.subjectmechanobiologyen
dc.subjectfocal adhesionsen
dc.subjectmachine learningen
dc.subject.meshExtracellular Matrixen
dc.subject.meshAnimalsen
dc.subject.meshHumansen
dc.subject.meshMiceen
dc.subject.meshCell Adhesionen
dc.subject.meshCell Differentiationen
dc.subject.meshCell Movementen
dc.subject.meshBiomechanical Phenomenaen
dc.subject.meshDeep Learningen
dc.titleDeep learning reveals how cells pull, buckle, and navigate fibrous environmentsen
dc.title.serialProceedings of the National Academy of Sciences of the United States of Americaen
dc.typeArticle - Refereeden
dc.type.dcmitypeTexten
dc.type.otherArticleen
dc.type.otherJournalen
pubs.organisational-groupVirginia Techen
pubs.organisational-groupVirginia Tech/Engineeringen
pubs.organisational-groupVirginia Tech/Engineering/Computer Scienceen
pubs.organisational-groupVirginia Tech/Engineering/Mechanical Engineeringen
pubs.organisational-groupVirginia Tech/Faculty of Health Sciencesen
pubs.organisational-groupVirginia Tech/All T&R Facultyen
pubs.organisational-groupVirginia Tech/Engineering/COE T&R Facultyen

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