Litcius/Paper detail

Liquid–Liquid Phase Separation-Mediated Cellular-Scale Compartmentalization of Hydrogel Covalent Cross-Linking Promotes Microtubule-Based Mechanosensing

Jianyang Zhao, Yuan‐Chao Hu, Hao Li, Caikun Liu, Zhiqiang Nie, Zekun Chen, Qiangjun Ling, Zhuo Li, Pengchao Zhao, Bin Song, Kunyu Zhang, Liming Bian

2025Journal of the American Chemical Society18 citationsDOI

Abstract

Controlled liquid-liquid phase separation (LLPS) plays an important role in the formation of a heterogeneously structured extracellular matrix (ECM) consisting of densely cross-linked stiff structures compartmentalized in a loosely cross-linked matrix. Moreover, the mechanical cues presented by the cellular-scale structural heterogeneity of the ECM facilitate the mechanotransduction of cells and subsequent cellular development. Therefore, developing ECM-mimetic hydrogels with compartmentalized structural heterogeneity as inductive cell carriers is highly desirable but challenging. Inspired by the ECM formation process, we capitalized on the temperature-assisted LLPS of a custom-designed temperature-responsive macromer (TRM) to concentrate and compartmentalize the TRM in the dense phase of the phase-separated precursor solution while keeping the gelatin comacromer complex in the dilute phase. The subsequent cross-linking produces the cellular (micron)-scale microdomains with dense covalent cross-linking interspersed in the loosely cross-linked cell-adaptable interdomain hydrogel matrix. The obtained ECM-mimetic heterogeneous hydrogel, which is solely cross-linked by covalent bonds, promotes extensive spreading, microtubule-based mechanotransduction, and autophagic flux of encapsulated human mesenchymal stem cells (hMSCs), thereby enhancing osteogenesis and bone regeneration. Our findings not only provide valuable guidance for the fabrication of ECM-mimetic biomaterials via LLPS-mediated assembly but also shed light on the mechanobiological mechanism underlying the regulation of cellular development by mechanical cues of the ECM.

Topics & Concepts

ChemistryCompartmentalization (fire protection)MicrotubuleCovalent bondBiophysicsSeparation (statistics)Liquid liquidScale (ratio)ChromatographyCell biologyBiochemistryEnzymeOrganic chemistryBiologyComputer sciencePhysicsQuantum mechanicsMachine learningCellular Mechanics and InteractionsAdvanced Materials and MechanicsSkin and Cellular Biology Research
Liquid–Liquid Phase Separation-Mediated Cellular-Scale Compartmentalization of Hydrogel Covalent Cross-Linking Promotes Microtubule-Based Mechanosensing | Litcius