Title :
Developing in vitro models of the sub-retinal microenvironment
Author :
Vargis, Elizabeth ; Foster, C. ; Peterson, Cristen B. ; Morrell-Falvey, J.L. ; Retterer, S.T. ; Collier, C. Patrick
Author_Institution :
Joint Inst. of Biol. Sci., Univ. of Tennessee, Knoxville, TN, USA
Abstract :
Physiologically-relevant in vitro models of retinal disease are necessary for understanding the complex interactions of oxidative stress, molecular signaling and physical contact between cells and their local environment. In this study, microfluidic devices and microcontact printing are used to mimic in vivo conditions of the sub-retinal microenvironment and the effects of oxidative stress and atrophy on protein expression by retinal pigment epithelial cells. The results demonstrate that differences in RNA and protein expression due to oxidative stress and loss of function can be observed from cells within microfluidic devices and in micropatterned patches. These findings indicate that nano- and microstructured materials can be used to interrogate normal and malignant retinal cell growth.
Keywords :
RNA; cellular biophysics; diseases; eye; microfluidics; physiological models; proteins; soft lithography; RNA; atrophy; epithelial cells; in vivo conditions; malignant retinal cell growth; microcontact printing; microfluidic devices; micropatterned patches; microstructured materials; molecular signaling; nanostructured materials; normal retinal cell growth; oxidative stress; physical contact; physiologically-relevant in vitro models; protein expression; retinal disease; retinal pigment; subretinal microenvironment; Biomedical optical imaging; Diseases; Immune system; Media; Retina; Soft lithography; microcontact printing; microfluidics; protein absorption; retinal pigment epithelial cells;
Conference_Titel :
Biomedical Sciences and Engineering Conference (BSEC), 2013
Conference_Location :
Oak Ridge, TN
Print_ISBN :
978-1-4799-2118-8
DOI :
10.1109/BSEC.2013.6618483
