2014
DOI: 10.1016/j.actbio.2014.08.032
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Retinal ganglion cell polarization using immobilized guidance cues on a tissue-engineered scaffold

Abstract: Cell transplantation therapies to treat diseases related to dysfunction of retinal ganglion cells (RGCs) are limited in part by an inability to navigate to the optic nerve head within the retina. During development, RGCs are guided by a series of neurotrophic factors and guidance cues; however, these factors and their receptors on the RGCs are developmentally regulated and often not expressed during adulthood. Netrin-1 is a guidance factor capable of guiding RGCs in culture and relevant to guiding RGC axons to… Show more

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Cited by 54 publications
(36 citation statements)
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“…However, once grown on the scaffold, not only did neurites grow in the same orientation, but were also seen to bundle together in areas of higher density, a phenomenon of axonal organization seen in vivo. More recently, the same group published their latest advancement, an implantable scaffold containing a chemical gradient of Netrin-1, a chemotropic factor expressed in the developing eye that polarizes axonal growth towards the center, not just in a radial orientation [86]. For an in-depth review on the various forms of ocular scaffolds being used in stem cell research, we direct the reader to Kador and Goldberg's 'Scaffolds and stem cells: delivery of cell transplants for retinal degenerations' [87].…”
Section: The 3d Optic Nerve Modelmentioning
confidence: 98%
See 1 more Smart Citation
“…However, once grown on the scaffold, not only did neurites grow in the same orientation, but were also seen to bundle together in areas of higher density, a phenomenon of axonal organization seen in vivo. More recently, the same group published their latest advancement, an implantable scaffold containing a chemical gradient of Netrin-1, a chemotropic factor expressed in the developing eye that polarizes axonal growth towards the center, not just in a radial orientation [86]. For an in-depth review on the various forms of ocular scaffolds being used in stem cell research, we direct the reader to Kador and Goldberg's 'Scaffolds and stem cells: delivery of cell transplants for retinal degenerations' [87].…”
Section: The 3d Optic Nerve Modelmentioning
confidence: 98%
“…For example, there are many obstacles in successfully co-culturing RGCs with superior colliculi explants in a 2D system, while attempting to study axonal growth guided by 3D signaling gradients and mechanical boundaries. Although techniques have been designed to bridge the gap between the artificial arrangement of co-cultured tissues and their in vivo counterparts, such as NASA's HRB, electrospun biodegradable scaffolding and ex vivo perfused human outflow pathway models, the field is lacking reliable substrates/ techniques for accurate modeling of the proposed co-culture systems [46,[58][59][60][61]85,86,88]. Even the complex 3D retina or optic nerve models that we described and proposed for future experiments are not physiologically representative of an in vivo system due to various reasons.…”
Section: The 3d Optic Nerve Modelmentioning
confidence: 99%
“…Additionally, it may be possible to engineer artificial scaffolds to guide RGC axons to their proper brain targets. 69,70 Through combinatorial approaches involving genetic engineering of pluripotent stem cells, differentiation of such cells into RGCs, and the incorporation of bioengineering guidance scaffolds, it may be possible to direct stem cell–derived RGCs to integrate into the retina, repopulate the optic nerve with new axons, and then reach and synapse with brain targets to make visual recovery possible. Although there have not yet been any reports of stem cell–derived RGC axon growth into the optic nerve, a parallel experiment has been reported describing mouse embryo–derived retinal precursor cell transplantation into the adult mouse, demonstrating a limited but clear donor RGC contribution to the optic nerve.…”
Section: Stem Cell–derived Rgcs For Transplantation and Vision Restormentioning
confidence: 99%
“…7 The addition of guidance factor gradients on the surface of tissueengineered scaffolds enhanced the polarization of axon growth toward the optic nerve head, mimicking the physiology of axon guidance found during early retinal devel-opment. 8 These methods, however, have not been able to recreate the more complex organization of the ganglion cell layer (GCL) and retinal nerve fiber layer (RNFL) around the fovea, thus limiting their clinical potential.…”
Section: Introductionmentioning
confidence: 99%