Your search keyword '"Al-Mubaarak A"' showing total 3 results

1. Single-cell transcriptomics reveals maturation of transplanted stem cell-derived retinal pigment epithelial cells toward native state.

Author

Parikh, Bhav Harshad, Blakeley, Paul, Regha, Kakkad, Zengping Liu, Binxia Yang, Bhargava, Mayuri, Soo Lin Wong, Daniel, Shu Woon Tan, Queenie, See Wei Wong, Claudine, Hao Fei Wang, Al-Mubaarak, Abdurrahmaan, Chai Chou, Chui Ming Gemmy Cheung, Kah Leong Lim, Barathi, Veluchamy Amutha, Hunziker, Walter, Lingam, Gopal, Xiaoming Hu, Tim, and Xinyi Su

Subjects

RHODOPSIN, CHROMATOPHORES, EPITHELIAL cells, MACULAR degeneration, GENE regulatory networks, STEM cell donors

Abstract

Transplantation of stem cell-derived retinal pigment epithelial (RPE) cells is considered a viable therapeutic option for age-related macular degeneration (AMD). Several landmark Phase I/II clinical trials have demonstrated safety and tolerability of RPE transplants in AMD patients, albeit with limited efficacy. Currently, there is limited understanding of how the recipient retina regulates the survival, maturation, and fate specification of transplanted RPE cells. To address this, we transplanted stem cell-derived RPE into the subretinal space of immunocompetent rabbits for 1 mo and conducted single-cell RNA sequencing analyses on the explanted RPE monolayers, compared to their age-matched in vitro counterparts. We observed an unequivocal retention of RPE identity, and a trajectory-inferred survival of all in vitro RPE populations after transplantation. Furthermore, there was a unidirectional maturation toward the native adult human RPE state in all transplanted RPE, regardless of stem cell resource. Gene regulatory network analysis suggests that tripartite transcription factors (FOS, JUND, and MAFF) may be specifically activated in posttransplanted RPE cells, to regulate canonical RPE signature gene expression crucial for supporting host photoreceptor function, and to regulate prosurvival genes required for transplanted RPE's adaptation to the host subretinal microenvironment. These findings shed insights into the transcriptional landscape of RPE cells after subretinal transplantation, with important implications for cell-based therapy for AMD. [ABSTRACT FROM AUTHOR]

Published

2023

2. Customized strategies for high-yield purification of retinal pigment epithelial cells differentiated from different stem cell sources.

Author

Regha, Kakkad, Bhargava, Mayuri, Al-Mubaarak, Abdurrahmaan, Chai, Chou, Parikh, Bhav Harshad, Liu, Zengping, Wong, Claudine See Wei, Hunziker, Walter, Lim, Kah Leong, and Su, Xinyi

Subjects

RHODOPSIN, STEM cells, CHROMATOPHORES, MACULAR degeneration, EPITHELIAL cells

Abstract

Retinal pigment epithelial (RPE) cell dysfunction and death are characteristics of age-related macular degeneration. A promising therapeutic option is RPE cell transplantation. Development of clinical grade stem-cell derived RPE requires efficient in vitro differentiation and purification methods. Enzymatic purification of RPE relies on the relative adherence of RPE and non-RPE cells to the culture plate. However, morphology and adherence of non-RPE cells differ for different stem cell sources. In cases whereby the non-RPE adhered as strongly as RPE cells to the culture plate, enzymatic method of purification is unsuitable. Thus, we hypothesized the need to customize purification strategies for RPE derived from different stem cell sources. We systematically compared five different RPE purification methods, including manual, enzymatic, flow cytometry-based sorting or combinations thereof for parameters including cell throughput, yield, purity and functionality. Flow cytometry-based approach was suitable for RPE isolation from heterogeneous cultures with highly adherent non-RPE cells, albeit with lower yield. Although all five purification methods generated pure and functional RPE, there were significant differences in yield and processing times. Based on the high purity of the resulting RPE and relatively short processing time, we conclude that a combination of enzymatic and manual purification is ideal for clinical applications. [ABSTRACT FROM AUTHOR]

Published

2022

3. A bio-functional polymer that prevents retinal scarring through modulation of NRF2 signalling pathway.

Author

Parikh, Bhav Harshad, Liu, Zengping, Blakeley, Paul, Lin, Qianyu, Singh, Malay, Ong, Jun Yi, Ho, Kim Han, Lai, Joel Weijia, Bogireddi, Hanumakumar, Tran, Kim Chi, Lim, Jason Y. C., Xue, Kun, Al-Mubaarak, Abdurrahmaan, Yang, Binxia, R, Sowmiya, Regha, Kakkad, Wong, Daniel Soo Lin, Tan, Queenie Shu Woon, Zhang, Zhongxing, and Jeyasekharan, Anand D.

Subjects

NUCLEAR factor E2 related factor, HYPERTROPHIC scars, CELLULAR signal transduction, SCARS, RETINAL surgery

Abstract

One common cause of vision loss after retinal detachment surgery is the formation of proliferative and contractile fibrocellular membranes. This aberrant wound healing process is mediated by epithelial-mesenchymal transition (EMT) and hyper-proliferation of retinal pigment epithelial (RPE) cells. Current treatment relies primarily on surgical removal of these membranes. Here, we demonstrate that a bio-functional polymer by itself is able to prevent retinal scarring in an experimental rabbit model of proliferative vitreoretinopathy. This is mediated primarily via clathrin-dependent internalisation of polymeric micelles, downstream suppression of canonical EMT transcription factors, reduction of RPE cell hyper-proliferation and migration. Nuclear factor erythroid 2–related factor 2 signalling pathway was identified in a genome-wide transcriptomic profiling as a key sensor and effector. This study highlights the potential of using synthetic bio-functional polymer to modulate RPE cellular behaviour and offers a potential therapy for retinal scarring prevention. One common cause of vision loss after retinal detachment surgery is retinal scarring. Here the authors demonstrate that a bio-functional polymer can prevent retinal scarring by suppression of epithelial-mesenchymal transition and hyper-proliferation of retinal pigment epithelial cells. [ABSTRACT FROM AUTHOR]

Published

2022