Transcriptome-Optimized Hydrogel Design of a Stem Cell Niche for Enhanced Tendon Regeneration

Overview

Journal Adv Mater

Date 2024 Oct 17

PMID 39417770

Authors

Wanqi Zhang

Ying Rao

Shing Hei Wong

Yeung Wu

Yuanhao Zhang

Rui Yang

Stephen Kwok-Wing Tsui

Dai Fei Elmer Ker

Chuanbin Mao

Jessica E Frith

Qin Cao

Rocky S Tuan

Dan Michelle Wang

Affiliations

Soon will be listed here.

Abstract

Bioactive hydrogels have emerged as promising artificial niches for enhancing stem cell-mediated tendon repair. However, a substantial knowledge gap remains regarding the optimal combination of niche features for targeted cellular responses, which often leads to lengthy development cycles and uncontrolled healing outcomes. To address this critical gap, an innovative, data-driven materiomics strategy is developed. This approach is based on in-house RNA-seq data that integrates bioinformatics and mathematical modeling, which is a significant departure from traditional trial-and-error methods. It aims to provide both mechanistic insights and quantitative assessments and predictions of the tenogenic effects of adipose-derived stem cells induced by systematically modulated features of a tendon-mimetic hydrogel (TenoGel). The knowledge generated has enabled a rational approach for TenoGel design, addressing key considerations, such as tendon extracellular matrix concentration, uniaxial tensile loading, and in vitro pre-conditioning duration. Remarkably, our optimized TenoGel demonstrated robust tenogenesis in vitro and facilitated tendon regeneration while preventing undesired ectopic ossification in a rat tendon injury model. These findings shed light on the importance of tailoring hydrogel features for efficient tendon repair. They also highlight the tremendous potential of the innovative materiomics strategy as a powerful predictive and assessment tool in biomaterial development for regenerative medicine.

Citing Articles

Transcriptome-Optimized Hydrogel Design of a Stem Cell Niche for Enhanced Tendon Regeneration.

Zhang W, Rao Y, Wong S, Wu Y, Zhang Y, Yang R Adv Mater. 2024; 37(2):e2313722.

PMID: 39417770 PMC: 11733723. DOI: 10.1002/adma.202313722.

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