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Microfluidic fabrication of cell adhesive chitosan microtubes

Authors
Oh, JonghyunKim, KeekyoungWon, Sung WookCha, ChaenyungGaharwar, Akhilesh K.Selimovic, SeilaBae, HojaeLee, Kwang HoLee, Dong HwanLee, Sang-HoonKhademhosseini, Ali
Issue Date
6월-2013
Publisher
SPRINGER
Keywords
Chitosan-gelatin hydrogel; Microfluidic flow-focusing; Microtube; Cell viability
Citation
BIOMEDICAL MICRODEVICES, v.15, no.3, pp.465 - 472
Indexed
SCIE
SCOPUS
Journal Title
BIOMEDICAL MICRODEVICES
Volume
15
Number
3
Start Page
465
End Page
472
URI
https://scholar.korea.ac.kr/handle/2021.sw.korea/103161
DOI
10.1007/s10544-013-9746-z
ISSN
1387-2176
Abstract
Chitosan has been used as a scaffolding material in tissue engineering due to its mechanical properties and biocompatibility. With increased appreciation of the effect of micro- and nanoscale environments on cellular behavior, there is increased emphasis on generating microfabricated chitosan structures. Here we employed a microfluidic coaxial flow-focusing system to generate cell adhesive chitosan microtubes of controlled sizes by modifying the flow rates of a chitosan pre-polymer solution and phosphate buffered saline (PBS). The microtubes were extruded from a glass capillary with a 300 mu m inner diameter. After ionic crosslinking with sodium tripolyphosphate (TPP), fabricated microtubes had inner and outer diameter ranges of 70-150 mu m and 120-185 mu m. Computational simulation validated the controlled size of microtubes and cell attachment. To enhance cell adhesiveness on the microtubes, we mixed gelatin with the chitosan pre-polymer solution. During the fabrication of microtubes, fibroblasts suspended in core PBS flow adhered to the inner surface of chitosan-gelatin microtubes. To achieve physiological pH values, we adjusted pH values of chiotsan pre-polymer solution and TPP. In particular, we were able to improve cell viability to 92 % with pH values of 5.8 and 7.4 for chitosan and TPP solution respectively. Cell culturing for three days showed that the addition of the gelatin enhanced cell spreading and proliferation inside the chitosan-gelatin microtubes. The microfluidic fabrication method for ionically crosslinked chitosan microtubes at physiological pH can be compatible with a variety of cells and used as a versatile platform for microengineered tissue engineering.
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