Structural engraftment and topographic spacing of transplanted human stem cell-derived retinal ganglion cells

Abstract: Retinal ganglion cell (RGC) replacement and optic nerve regeneration hold potential for restoring vision lost to optic neuropathy. Following transplantation, RGCs must integrate into the neuroretinal circuitry in order to receive afferent visual signals for processing and transmission to central targets. To date, the efficiency of RGC retinal integration following transplantation has been limited. We sought to characterize spontaneous interactions between transplanted human embryonic stem cell-derived RGCs and… Show more

“…The inner limiting membrane (ILM) formed by Müller glia and astrocytes prevents facile integration both in vivo and in vitro [ 57 , 59 ]. Disruption by enzymatic digestion in explants improved dispersion of transplanted RGCs with a marked increase of neurite extension into retinal parenchyma [ 60 ]. Intravitreal injections themselves cause a localized inflammatory response, which may inhibit RGC survival.…”

Protect, Repair, and Regenerate: Towards Restoring Vision in Glaucoma

“…The inner limiting membrane (ILM) formed by Müller glia and astrocytes prevents facile integration both in vivo and in vitro [ 57 , 59 ]. Disruption by enzymatic digestion in explants improved dispersion of transplanted RGCs with a marked increase of neurite extension into retinal parenchyma [ 60 ]. Intravitreal injections themselves cause a localized inflammatory response, which may inhibit RGC survival.…”

Protect, Repair, and Regenerate: Towards Restoring Vision in Glaucoma