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Method for living cell mechanical properties evaluation from force-indentation curves

dc.contributor.authorMorkvėnaitė-Vilkončienė, Inga
dc.contributor.authorVilkončius, Raimundas
dc.contributor.authorRožėnė, Justė
dc.contributor.authorZinovičius, Antanas
dc.contributor.authorBalitskyi, Oleksii
dc.contributor.authorRamanavičienė, Almira
dc.contributor.authorRamanavičius, Arūnas
dc.contributor.authorDzedzickis, Andrius
dc.contributor.authorBučinskas, Vytautas
dc.date.accessioned2023-09-18T18:58:28Z
dc.date.available2023-09-18T18:58:28Z
dc.date.issued2020
dc.identifier.urihttps://etalpykla.vilniustech.lt/handle/123456789/133918
dc.description.abstractLiving cells mechanical properties establishment from Atomic force microscopy (AFM) force-separation curves is a challenge because the calculated Young’s modulus depends on the applied mathematical model. The more reliable results can be obtained using finite element models. In this work, Yeasts cells with different mechanical properties were measured by AFM. To change cells mechanical properties, yeasts were immersed in 9,10-phenanthrenequinone, which changed cells’ membranes elasticity. 3D finite element model of the whole cell was created to calculate reacting force when AFM tip indents the cell in the same way as in the real experiment. It was found that our model is capable to draw the information about cells mechanical properties and visco-elastic behavior of cells membranes.eng
dc.formatPDF
dc.format.extentp. 657-663
dc.format.mediumtekstas / txt
dc.language.isoeng
dc.relation.ispartofseriesAdvances in intelligent systems and computing vol. 920 2194-5357 2194-5365
dc.relation.isreferencedbyScopus
dc.relation.isreferencedbySpringerLink
dc.relation.isreferencedbyConference Proceedings Citation Index - Science (Web of Science)
dc.source.urihttps://doi.org/10.1007/978-3-030-13273-6_61
dc.source.urihttps://talpykla.elaba.lt/elaba-fedora/objects/elaba:36347044/datastreams/COVER/content
dc.titleMethod for living cell mechanical properties evaluation from force-indentation curves
dc.typeStraipsnis konferencijos darbų leidinyje Web of Science DB / Paper in conference publication in Web of Science DB
dcterms.references13
dc.type.pubtypeP1a - Straipsnis konferencijos darbų leidinyje Web of Science DB / Article in conference proceedings Web of Science DB
dc.contributor.institutionVilniaus Gedimino technikos universitetas Vilniaus universitetas
dc.contributor.institutionVilniaus Gedimino technikos universitetas
dc.contributor.institutionVilniaus universitetas
dc.contributor.institutionValstybinis mokslinių tyrimų institutas Fizinių ir technologijos mokslų centras
dc.contributor.facultyMechanikos fakultetas / Faculty of Mechanics
dc.contributor.facultyStatybos fakultetas / Faculty of Civil Engineering
dc.subject.researchfieldT 008 - Medžiagų inžinerija / Material engineering
dc.subject.researchfieldN 003 - Chemija / Chemistry
dc.subject.vgtuprioritizedfieldsFM0202 - Ląstelių ir jų biologiškai aktyvių komponentų tyrimai / Investigations on cells and their biologically active components
dc.subject.ltspecializationsL104 - Nauji gamybos procesai, medžiagos ir technologijos / New production processes, materials and technologies
dc.subject.enAFM
dc.subject.enmechanical properties
dc.subject.enliving cells
dc.subject.enfinite element model
dcterms.sourcetitleAutomation 2019. Progress in automation, robotics and measurement techniques, 27-29 March 2019, Warsaw, Poland : conference proceedings
dc.publisher.nameSpringer
dc.publisher.cityCham
dc.identifier.doi2-s2.0-85062260450
dc.identifier.doi000583774200061
dc.identifier.doi10.1007/978-3-030-13273-6_61
dc.identifier.elaba36347044


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