A Microscale–Optical Interface to Examine Electric Field-Induced Cell Motility Within Whole-Eye Facsimiles
Sakshi Koul, Luke A. Devecka, Mark C. Pierce, Maribel Vazquez

TL;DR
This paper introduces a new microscale-optical system to study how electric fields guide cell movement in 3D eye models, which could improve stem cell therapies for vision loss.
Contribution
A novel parallel eye device with electric field stimulation and optical imaging to study cell migration in 3D eye facsimiles.
Findings
EF stimulation guided cell migration within 3D eye facsimiles at various depths.
Optical imaging replaced cryostat sectioning for rapid cell infiltration analysis.
Microscale-optical systems can enhance understanding of cell transplantation processes.
Abstract
Microscale systems have been underexplored in contemporary regenerative therapies developed to treat vision loss. The pairing of in vitro cell systems with optical fluorescent imaging provides unique opportunities to examine the infiltration of donor stem cells needed for successful transplantation therapies. A parallel eye device was developed to provide electric field (EF) stimulation to guide the migration of cells within 3D eye facsimiles synthesized from different ocular biomaterials. Cell infiltration within facsimiles was rapidly resolved using confocal microscopy to eliminate dependence on the cryostat sectioning commonly used for cell study. Moreover, EF stimulated galvanotaxis of donor cells within different depths of eye facsimiles. Optical imaging provided rapid resolution of z-stack images at physiologically appropriate depths below 500 microns. This study demonstrates that…
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Taxonomy
TopicsNeuroscience and Neural Engineering · Planarian Biology and Electrostimulation · Photoreceptor and optogenetics research
