Reprogramming of IPSCs to NPCEC-like Cells by Biomimetic Scaffolds for Zonular Fiber Reconstruction

Overview

Journal Bioact Mater

Specialty Biomedical Engineering

Date 2024 Dec 19

PMID 39697240

Authors

Tianhui Chen

Zhongxing Chen

Juan Du

Min Zhang

Zexu Chen

Qingyi Gao

Aodong Chen

Qinghao Meng

Yang Sun

Yan Liu

Linghao Song

Xinyue Wang

Pranav Prakash Edavi

Chen Xu

Hongmei Zhang

Jinhai Huang

Yongxiang Jiang

Affiliations

Soon will be listed here.

Abstract

Ectopia lentis (EL), characterised by impaired zonular fibers originating from non-pigmented ciliary epithelial cells (NPCEC), presents formidable surgical complexities and potential risks of visual impairment. Cataract surgery is the only treatment method for EL, but it leads to the loss of accommodative power of the lens post-operatively. Furthermore, the challenge of repairing zonular ligaments remains a significant global issue. Ocular tissue and aqueous humour samples from patients with EL were subjected to RNA sequencing and Olink high-throughput proteomic analysis, revealing the downregulation of pathogenic genes (, ) and upregulation of secretory proteins (IL-12, MMP-1). The high expression of and in NPCECs suggests their potential as candidates for zonular fiber construction; however, the limited availability of donor sources restricts the feasibility of NPCEC transplantation therapy. The reprogramming and directional differentiation of induced pluripotent stem cells (iPSC) to NPCEC was successfully achieved using the developed biomimetic scaffolds that mimic the microstructures of natural radial zonular fibers. Excitingly, the single injection of induced NPCEC-like cells significantly contributed to restoring and enhancing mechanical properties in zonular fiber structures in a rabbit model with EL. This proposed iPSC-based regeneration technique might serve as an innovative therapeutic strategy for clinical EL patients, reduce the cataract surgery rate, and retain the adjustment capacity of inherent lentis.

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