Abstract

Hydrogels represent an attractive material platform for realization of three-dimensional (3D) tissue-engineered constructs, as they have tunable mechanical properties, are compatible with different types of cells, and resemble elements found in natural extracellular matrices. So far, numerous hydrogel-cartilage/bone tissue engineering (TE)-related studies were performed by utilizing a single cell encapsulation approach. Although multicellular spheroid cultures exhibit advantageous properties for cartilage or bone TE, the chondrogenic or osteogenic differentiation potential of stem cell microspheroids within hydrogels has not been investigated much. This study explores, for the first time, how stiffness of gelatin-based hydrogels (having a storage modulus of 538, 3584, or 7263 Pa) affects proliferation and differentiation of microspheroids formed from telomerase-immortalized human adipose-derived stem cells (hASC/hTERT). Confocal microscopy indicates that all tested hydrogels supported cell viability during their 3- to 5-week culture period in the control, chondrogenic, or osteogenic medium. Although in the softer hydrogels cells from neighboring microspheroids started outgrowing and interconnecting within a few days, their protrusion was slower or limited in stiffer hydrogels or those cultured in chondrogenic medium, respectively. High expressions of chondrogenic markers (SOX9, ACAN, COL2A1), detected in all tested hydrogels, proved that the chondrogenic differentiation of hASC/hTERT microspheroids was very successful, especially in the two softer hydrogels, where superior cartilage-specific properties were confirmed by Alcian blue staining. These chondrogenically induced samples also expressed COL10A1, a marker of chondrocyte hypertrophy. Interestingly, the hydrogel itself (with no differentiation medium) showed a slight chondrogenic induction. Regardless of the hydrogel stiffness, in the samples stimulated with osteogenic medium, the expression of selected markers RUNX2, BGLAP, ALPL, and COL1A1 was not conclusive. Nevertheless, the von Kossa staining confirmed the presence of calcium deposits in osteogenically stimulated samples in the two softer hydrogels, suggesting that these also favor osteogenesis. This observation was also confirmed by Alizarin red quantification assay, with which higher amounts of calcium were detected in the osteogenically induced hydrogels than in their controls. The presented data indicate that the encapsulation of adipose-derived stem cell microspheroids in gelatin-based hydrogels show promising potential for future applications in cartilage or bone TE.Impact StatementOsteochondral defects represent one of the leading causes of disability in the world. Although numerous tissue engineering (TE) approaches have shown success in cartilage and bone tissue regeneration, achieving native-like characteristics of these tissues remains challenging. This study demonstrates that in the presence of a corresponding differentiation medium, gelatin-based hydrogels support moderate osteogenic and excellent chondrogenic differentiation of photo-encapsulated human adipose-derived stem cell microspheroids, the extent of which depends on hydrogel stiffness. Because photosensitive hydrogels are a convenient material platform for creating stiffness gradients in three dimensions, the presented microspheroid-hydrogel encapsulation strategy holds promise for future strategies of cartilage or bone TE.

Highlights

  • Hydrogels are among the most promising materials for 3D cell culture, as they mimic important properties of extracellular matrices (ECM), have similar mechanics to many soft tissues and support cell adhesion (1–3)

  • This study demonstrates that in the presence of a corresponding differentiation medium, gelatin-based hydrogels support moderate osteogenic and excellent chondrogenic differentiation of photo-encapsulated human adipose-derived stem cell microspheroids, the extent of which depends on hydrogel stiffness

  • In this study, the impact of Gel-MOD stiffness on chondrogenic and osteogenic differentiation of photo-encapsulated hASC/hTERT microspheroids was investigated, which to our knowledge has not yet been studied. hASC/hTERT have been employed as their differentiation potential has been confirmed to be stable through numerous population doublings (38)

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Summary

Introduction

Hydrogels are among the most promising materials for 3D cell culture, as they mimic important properties of extracellular matrices (ECM), have similar mechanics to many soft tissues and support cell adhesion (1–3). The impact of Gel-MOD stiffness towards osteo- or chondrogenic propagation was addressed in studies of photo-encapsulation of single cell suspensions of bovine and porcine chondrocytes, human or rat mesenchymal stem cells (MSC) and a human osteosarcoma cell line MG63. ≤ 10% (w/v)) of the crosslinked Gel-MOD on osteo- or chondrogenic phenotypes of selected cells, due to different culturing conditions used it is impossible to compare the results of these studies. The effect of GelMOD stiffness to induce chondrogenic or osteogenic differentiation of photo-encapsulated microspheroid tissues (i.e. microspheroids) per se or in conjunction with an adequate differentiation medium has not yet been addressed

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