Parallel in-vitro and in-vivo techniques for optimizing cellular microenvironments by implementing biochemical, biomechanical and electromagnetic stimulations

Author

Shamloo, Amir ; Heibatollahi, M. ; Ghafar-Zadeh, Ebrahim

Author_Institution

Univ. of California, Berkeley, Berkeley, CA, USA

fYear

2012

fDate

Aug. 28 2012-Sept. 1 2012

Firstpage

1397

Lastpage

1400

Abstract

Development of novel engineering techniques that can promote new clinical treatments requires implementing multidisciplinary in-vitro and in-vivo approaches. In this study, we have implemented microfluidic devices and in-vivorat model to study the mechanism of neural stem cell migration and differentiation.These studies can result in the treatment of damages to the neuronal system. In this research, we have shown that by applying appropriate ranges of biochemical and biomechanical factors as well as by exposing the cells to electromagnetic fields, it is possible to improve viability, proliferation, directional migration and differentiation of neural stem cells. The results of this study can be implemented in the design of optimized platforms that can be transplanted into the damaged areas of the neuronal system.

Keywords

bioMEMS; biochemistry; biomechanics; biomedical equipment; cell motility; microfluidics; neurophysiology; optimisation; patient treatment; prosthetics; biochemical stimulation; biomechanical stimulation; cellular microenvironment optimization; clinical treatments; damage treatment; directional migration; electromagnetic fields; electromagnetic stimulation; engineering techniques; in-vivo rat model; microfluidic devices; multidisciplinary in-vitro approaches; multidisciplinary in-vivo approaches; neural stem cell differentiation; neural stem cell migration; neural stem cell proliferation; neural stem cell viability; parallel in-vitro techniques; parallel in-vivo techniques; Biological system modeling; Biomechanics; Electromagnetic fields; Microelectronics; Microfluidics; Nerve fibers; Stem cells; Animals; Biomechanical Phenomena; Cell Culture Techniques; Cell Growth Processes; Cellular Microenvironment; Disease Models, Animal; Electromagnetic Fields; Fibrillar Collagens; Microfluidic Analytical Techniques; Multiple Sclerosis; Neural Stem Cells; Rats;

fLanguage

English

Publisher

ieee

Conference_Titel

Engineering in Medicine and Biology Society (EMBC), 2012 Annual International Conference of the IEEE

Conference_Location

San Diego, CA

ISSN

1557-170X

Print_ISBN

978-1-4244-4119-8

Electronic_ISBN

1557-170X

Type

conf

DOI

10.1109/EMBC.2012.6346200

Filename

6346200