Probing cellular behaviors through nanopatterned chitosan membranes

Yang, Chung‐Yao; Sung, Chun-Yen; Shuai, Hung-Hsun; Cheng, Chao‐Min; Yeh, J. Andrew

doi:10.1088/1468-6996/14/4/044406

Cited by 8 publications

(9 citation statements)

References 33 publications

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“…The roughness was determined as 0.6–5.6 nm for the undeveloped surfaces and 101–141 nm for the developed surface. Roughness values around 100 nm have been reported to significantly restrict the spreading and the orientation of cells [42]. This is in agreement with a recent study concluding that the surface roughness of substrates would affect the adhesion and the morphology of cells [43].…”

Section: Resultssupporting

confidence: 88%

Atomic force acoustic microscopy reveals the influence of substrate stiffness and topography on cell behavior

Liu¹,

Li²,

Chen³

et al. 2019

Beilstein J. Nanotechnol.

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The stiffness and the topography of the substrate at the cell–substrate interface are two key properties influencing cell behavior. In this paper, atomic force acoustic microscopy (AFAM) is used to investigate the influence of substrate stiffness and substrate topography on the responses of L929 fibroblasts. This combined nondestructive technique is able to characterize materials at high lateral resolution. To produce substrates of tunable stiffness and topography, we imprint nanostripe patterns on undeveloped and developed SU-8 photoresist films using electron-beam lithography (EBL). Elastic deformations of the substrate surfaces and the cells are revealed by AFAM. Our results show that AFAM is capable of imaging surface elastic deformations. By immunofluorescence experiments, we find that the L929 cells significantly elongate on the patterned stiffness substrate, whereas the elasticity of the pattern has only little effect on the spreading of the L929 cells. The influence of the topography pattern on the cell alignment and morphology is even more pronounced leading to an arrangement of the cells along the nanostripe pattern. Our method is useful for the quantitative characterization of cell–substrate interactions and provides guidance for the tissue regeneration therapy in biomedicine.

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Section: Resultssupporting

confidence: 88%

Atomic force acoustic microscopy reveals the influence of substrate stiffness and topography on cell behavior

Liu¹,

Li²,

Chen³

et al. 2019

Beilstein J. Nanotechnol.

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“…Applying such thoughts to materials in biomedicine, altering hydrophilicity of materials through suitable modifications can generate materials with suitable compatibility or blood compatibility for specific biomedical applications . For example, changing hydrophilicity of chitosan via plasma treatment has been shown to affect biocompatibility, a feature that may be exploited for controlling cell growth on chitosan …”

Section: Resultsmentioning

confidence: 99%

Hydrophilic films: How hydrophilicity affects blood compatibility and cellular compatibility

Kuo

Fang²,

Wu³

et al. 2017

Adv Polym Technol

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Hydrophilic materials have been used in many fields, but have recently garnered growing attention in biomedicine. To promote the development and use of suitable hydrophilic materials for biomedical applications, we used three hydrophilic films of varying hydrophilicity and examined the effects of their hydrophilicity on blood compatibility, protein adsorption, blood clotting time, hemolytic activity, biocompatibility, and cell attachment. Across the spectrum of hydrophilicity examined, no obvious differences in biocompatibility were observed. While high material hydrophilicity was associated with higher hemolytic activity, it still fit the nonhemolytic criteria. Further, higher hydrophilicity decreased protein adsorption and cell attachment, but increased thromboresistance in our blood clotting time assay (~30% higher blood clotting index at 10 min). These results indicate that hydrophilicity increases blood compatibility with regard to thromboresistance, but reduces cellular compatibility (i.e., cell attachment), characteristics that could be exploited for a wide range of potential applications in various fields, such as glucose electrode test strips.

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“…These modified chitosan membranes may be used to study cellular behaviors and micropatterning of mammalian cells. Paragraphs four and five describe Shuai's studies, which display mammalian cell response and patterning on chitosan membranes with surface modification [87,88].…”

Section: Functionalized Chitosan Membranesmentioning

confidence: 99%

Fabricating in vitro nanomaterial scaffolds through IC-compatible microfabrication to modulate mammalian cellular behaviors

Sung¹,

Yeh²,

Cheng³

2016

Nanomaterials and Regenerative Medicine

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Probing cellular behaviors through nanopatterned chitosan membranes

Cited by 8 publications

References 33 publications

Atomic force acoustic microscopy reveals the influence of substrate stiffness and topography on cell behavior

Atomic force acoustic microscopy reveals the influence of substrate stiffness and topography on cell behavior

Hydrophilic films: How hydrophilicity affects blood compatibility and cellular compatibility

Fabricating in vitro nanomaterial scaffolds through IC-compatible microfabrication to modulate mammalian cellular behaviors

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