Collagen microsphere production on a chip. Academic Article

abstract

• We have developed an integrated microfluidic material processing chip and demonstrated the rapid production of collagen microspheres encapsulating cells with high uniformity and cell viability. The chip integrated three material processing steps. Monodisperse microdroplets were generated at a microfluidic T junction between aqueous and mineral oil flows. The flow was heated immediately to 37 C to initiate collagen fiber assembly within a gelation channel. Gelled microspheres were extracted from the mineral oil phase into cell culture media within an extraction chamber. Collagen gelation immediately after microdroplet generation significantly reduced coalescence among microdroplets that led to non-uniform microsphere production. The microfluidic extraction approach led to higher microsphere recovery and cell viability than when a conventional centrifugation extraction approach was employed. These results indicate that chip-based material processing is a promising approach for cell-ECM microenvironment generation for applications such as tissue engineering and stem cell delivery.

authors

• Kameoka, Jun
• Kaunas, Roland

published proceedings

• Lab Chip

altmetric score

• 1

author list (cited authors)

• Hong, S., Hsu, H., Kaunas, R., & Kameoka, J.

citation count

• 62

complete list of authors

• Hong, Sungmin||Hsu, Hui-Ju||Kaunas, Roland||Kameoka, Jun

publication date

• January 2012

publisher

• Royal Society of Chemistry (RSC)  Publisher

published in

• Lab on a Chip  Journal

keywords

• Cell Line, Tumor
• Cell Survival
• Collagen
• Gels
• Humans
• Microfluidic Analytical Techniques
• Microspheres
• Mineral Oil

Digital Object Identifier (DOI)

• 10.1039/c2lc40558j

start page

• 3277

end page

• 3280

volume

• 12

issue

• 18

URL

• http://dx.doi.org/10.1039/c2lc40558j