Nanoscale viscoelastic properties and adhesion of polydimethylsiloxane for tissue engineering 被引量：3

Nanoscale viscoelastic properties and adhesion of polydimethylsiloxane for tissue engineering

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摘要 It has shown that altering crosslink density of biopolymers will regulate the morphology of Mesenchymal Stem Cells （MSCs） and the subsequent MSCs differentia- tion. These observations have been found in a wide range of biopolymers. However, a recent work published in Nature Materials has revealed that MSCs morphology and differen- tiation was unaffected by crosslink density of polydimethyl- siloxane （PDMS）, which remains elusive. To understand such unusual behaviour, we use nanoindentation tests and modelling to characterize viscoelastic properties and sur- face adhesion of PDMS with different base：crosslink ratio varied from 50：1 （50D） to 10：1 （10D）. It has shown that lower crosslink density leads to lower elastic moduli. De- spite lower nanoindentation elastic moduli, PDMS with lowest crosslink density has higher local surface adhesion which would affect cell-biomaterials interactions. This work suggests that surface adhesion is likely another important physical cue to regulate cell-biomaterials interactions. It has shown that altering crosslink density of biopolymers will regulate the morphology of Mesenchymal Stem Cells （MSCs） and the subsequent MSCs differentia- tion. These observations have been found in a wide range of biopolymers. However, a recent work published in Nature Materials has revealed that MSCs morphology and differen- tiation was unaffected by crosslink density of polydimethyl- siloxane （PDMS）, which remains elusive. To understand such unusual behaviour, we use nanoindentation tests and modelling to characterize viscoelastic properties and sur- face adhesion of PDMS with different base：crosslink ratio varied from 50：1 （50D） to 10：1 （10D）. It has shown that lower crosslink density leads to lower elastic moduli. De- spite lower nanoindentation elastic moduli, PDMS with lowest crosslink density has higher local surface adhesion which would affect cell-biomaterials interactions. This work suggests that surface adhesion is likely another important physical cue to regulate cell-biomaterials interactions.

作者 J.Chen K.E.Wright M.A.Birch

机构地区 School of Mechanical & Systems Engineering Arthritis Research UK (ARUK) Tissue Engineering Centre Research UK (ARUK) Tissue Engineering Centre St James’ University Hospital University of Leeds

出处《Acta Mechanica Sinica》 SCIE EI CAS CSCD 2014年第1期2-6,共5页 力学学报（英文版）

基金 funded by EPSRC–Newcastle University Sandpit Workshop Award

关键词 Bioploymer- Nanoindentation- Viscoelasticity Surface adhesion Bioploymer- Nanoindentation- Viscoelasticity Surface adhesion

分类号 TQ320.1 [化学工程—合成树脂塑料工业]

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Nanoscale viscoelastic properties and adhesion of polydimethylsiloxane for tissue engineering 被引量：3

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