Table 1.
Clinical trials in ocular diseases
|
Ophthalmic disease
|
Ref.
|
Stem cells used
|
In animals or humans
|
Conclusions
|
| Ocular surface, cornea and limbus | Kenyon and Tseng[52], 1989 | Limbal tissue autograft transplantation (LSCs) | Humans | Patients have consistently shown improved visual acuity, rapid surface healing, stable epithelial adhesion without recurrent erosion, arrest or regression of corneal neovascularization |
| Lindberg et al[53], 1993 | LSCs | Humans | Corneal epithelial stem cells are located in the limbus and indicate that cultured autologous limbal cells may function as grafts to permanently restore the corneal epithelium after severe ocular surface injury | |
| Ma et al[54], 2006 | MSCs like LSCs on amniotic membrane | Animals | Therapeutic effect due to the inhibition of inflammation and neovascularization | |
| Kwitko et al[57], 1995 | Conjunctival autograft transplantation | Humans | Conjunctival transplantation proved to be an adequate method of treating severe bilateral surface disorders, with minimal complications | |
| Croasdale et al[58], 1999 | Keratolimbal allograft | Humans | KLAL transplantation for patients with severe ocular-surface disease is an important management option | |
| Tsai et al[59], 2000 | Limbal epithelial cells | Humans | By 1 mo, the ocular surface was covered with corneal epithelium, and the clarity of the cornea was improved in 83% of patients | |
| Sangwan et al[60], 2012 | Limbal tissue | Humans | After surgery, a completely epithelialized, avascular and stable corneal surface was seen in all recipient eyes by 6 wk | |
| Kushnerev et al[61], 2016 | Dental pulp stem cells | Animals | Dental pulp stem cells were successfully isolated, labeled, and delivered to the corneal surface | |
| Chan et al[66], 2013 | iPSCs | Animals | hES cells can be induced to differentiate into keratocytes in vitro. Pluripotent stem cells may provide a renewable source of material for development of treatment of corneal stromal opacities | |
| Susaimanickam et al[67], 2017 | iPSCs | Animals | PSC-derived corneal epithelial cells offer an alternative tissue source for regenerating different layers of the cornea and eliminate the need for complicated cell enrichment procedures | |
| Zeppier et al[3], 2017 | MSCs | Animals | Better corneal repair in epithelium and stromal layers in stem cell treated eyes | |
| Reinshagen et al[68], 2011 | BM-MSCs | Animals | BM-MSCs could differentiate into cornel epithelial like cells in vivo in rat damaged corneas | |
| Gu et al[70], 2009 | BM-MSCs | Animals | BM-MSCs could differentiate into cornel epithelial like cells | |
| Beyazyildiz et al[46], 2014 | MSCs | Animals | Topical application of MSCs could be a safe and effective method for the treatment of DES | |
| Reza et al[73], 2011 | LSCs | Animals | Transplantation of a bioengineered CLEC-muc sheet in limbal stem cell-deficient rabbit eyes resulted in regeneration of a smooth, clear corneal surface | |
| Nishida et al[76], 2004 | Oral mucosal stem cells | Humans | Complete reepithelialization of the corneal surfaces occurred within 1 wk in all four treated eyes. Corneal transparency was restored and postoperative visual acuity improved | |
| Corneal stroma and endothelium | Sepsakos et al[79], 2017 | Ocular surface SCs | Humans | Without addressing the underlying stem cell deficiency, keratoplasty in patients with total limbal stem cell deficiency will ultimately fail in all cases |
| Naylor et al[81], 2016 | iPSCs | Humans | The hiPSC-derived NCCs acquired a keratocyte-like morphology and an expression profile similar to corneal keratocytes in vivo | |
| Alió Del Barrio et al[84], 2017 | ASCs | Humans | Safety of corneal stromal transplantation of autologous ASCs in humans, showing cell survival in vivo and the ability of these cells to produce a low amount of new collagen in patients with advanced keratoconus | |
| Coulson-Thomas et al[85], 2013 | UC-MSCs | Animals | UC-MSCs transplantation may be a feasible alternative to keratoplasty in treating congenital disorders of the cornea secondary to keratocyte dysfunction | |
| Yam et al[88], 2018 | Perodontal ligament SCs | Animals | Potential translation of PDL cells for regenerative corneal cell therapy for corneal opacities | |
| Joyce et al[89], 2012 | UC-MSCs | Animals | UCB MSCs are able to "home" to areas of injured corneal endothelium and that the phenotype of UCB MSCs can be altered toward that of HCEC-like cells | |
| Trabecular meshwork | Abu-Hassan et al[93], 2015 | iPSCs | Animals | TM-like iPSCs became similar to TM cells in both morphology and expression patterns. When transplanted, they were able to fully restore intraocular pressure homeostatic function |
| Manuguerra-Gagné et al[95], 2013 | MSCs | Animals | MSC and their secreted factors induced reactivation of a progenitor cell pool found in the ciliary body and increased cellular proliferation | |
| Lens | Lin et al[96], 2016 | LECs | Both | Surgical method of cataract removal that preserves endogenous LECs and achieves functional lens regeneration in rabbits and macaques, as well as in human infants with cataracts |
| Murphy et al[98], 2018 | PSCs | Animals | We demonstrate large-scale production of light-focusing human micro-lenses from spheroidal masses of human lens epithelial cells purified from differentiating pluripotent stem cells | |
| ON | Kuwahara et al[102], 2015 | hESCs | Animals | Multipotent stem cells within the CM contribute to de novo retinal tissue growth |
| Mesentier-Louro et al[105], 2019 | iPSCs | Animals | Between 1% and 7% of iPSCs-derived RGCs integrated into the ganglion cell layer after intravitreal injection, and about 20% after combined injection of RGCs and iPSCs | |
| Zhang et al[107], 2015 | UC-MSCs | Animals | Human umbilical cord blood stem cells and brain-derived neurotrophic factor effectively repair the injured optical nerve, improve biomechanical properties, and contribute to the recovery after injury |
ASC: Adipose-derived stem cell; BM-MSC: Bone marrow-mesenchymal stem cell; CLEs: Cutaneous lupus erythematosus; CM: Ciliary margin; DES: Discrete event simulation; HCEC: Human corneal endothelial cell; hESCs: Human embryonic stem cells; hiPSC: Human-induced pluripotent stem cells; iPSC: induced pluripotent stem cell; KLAL: Keratolimbal allograft; LEC: Lens epithelial stem/progenitor cell; LSC: Limbal stem cell; MSC: Mesenchymal stem cell; NCC: Neurocysticercosis; ON: Optic nerve; PDL: Periodontal ligament; PSC: Pluripotent stem cell; RGC: Retinal ganglion cell; TM: Trabecular meshwork; UC-MSCs: Umbilical cord-mesenchymal stem cell; UCB: Umbilical cord blood.