Decellularized scaffolds are promising clinically translational biomaterials that can be applied to direct cell responses and promote tissue regeneration. Bioscaffolds derived from the extracellular matrix (ECM) of decellularized tissues can naturally mimic the complex extracellular microenvironment through the retention of compositional, biomechanical, and structural properties specific to the native ECM. Increasingly, studies have investigated the use of ECM-derived scaffolds as instructive substrates to recapitulate properties of the stem cell niche and guide cell proliferation, paracrine factor production, and differentiation in a tissuespecific manner. Here, we review the application of decellularized tissue scaffolds as instructive matrices for stem or progenitor cells, with a focus on the mechanisms through which ECMderived scaffolds can mediate cell behavior to promote tissue-specific regeneration. We conclude that although additional preclinical studies are required, ECM-derived scaffolds are a promising platform to guide cell behavior and may have widespread clinical applications in the field of regenerative medicine.
Melt electrowriting (MEW) is an additive manufacturing technology that produces readily handleable fibrous scaffolds with controlled geometry to support cell infiltration. Although MEW scaffolds have excellent potential for cell delivery in regenerative medicine applications, studies to date have primarily focused on polymers such as poly(ε-caprolactone) (PCL) that lack bioactive cues to affect cell function. To address this aspect, MEW scaffolds with extracellular matrix (ECM) coatings were developed as a proadipogenic platform for human mesenchymal stromal cells (hMSCs). More specifically, highly flexible PCL scaffolds fabricated through MEW were coated with a complex ECM suspension prepared from human decellularized adipose tissue (DAT), purified fibronectin, or laminin to determine the effects of two key bioactive proteins present within adipose-derived ECM. In vitro studies exploring the response of human bone marrow-derived mesenchymal stromal cells cultured under adipogenic differentiation conditions indicated a high level of differentiation on all substrates studied, including unmodified PCL scaffolds and two-dimensional controls. To more fully assess the intrinsic proadipogenic capacity of the composite biomaterials, a modified culture regime was established that involved a short-term adipogenic induction in differentiation medium, followed by continued culture in maintenance medium supplemented with insulin for up to 3 weeks. Under these conditions, adipogenic differentiation was enhanced on all fiber scaffolds as compared to the tissue culture controls. Notably, the highest adipogenic response was consistently observed on the PCL + DAT scaffolds, based on the analysis of multiple markers including adipogenic gene [lipoprotein lipase, fatty acid binding protein 4 (FABP4), adiponectin, perilipin 1] and protein (FABP4, leptin) expression and intracellular triglyceride accumulation. Taken together, the PCL scaffolds incorporating DAT provide an adipoinductive microenvironment for the hMSCs, with particular applicability of this cell-instructive delivery platform for applications in plastic and reconstructive surgery.
While extracellular matrix (ECM)‐derived coatings have the potential to direct the response of cell populations in culture, there is a need to investigate the effects of ECM sourcing and processing on substrate bioactivity. To develop improved cell culture models for studying adipogenesis, the current study examines the proliferation and adipogenic differentiation of human adipose‐derived stem/stromal cells (ASCs) on a range of ECM‐derived coatings. Human decellularized adipose tissue (DAT) and commercially available bovine tendon collagen (COL) are digested with α‐amylase or pepsin to prepare the coatings. Physical characterization demonstrates that α‐amylase digestion generates softer, thicker, and more stable coatings, with a fibrous tissue‐like ultrastructure that is lost in the pepsin‐digested thin films. ASCs cultured on the α‐amylase‐digested ECM have a more spindle‐shaped morphology, and proliferation is significantly enhanced on the α‐amylase‐digested DAT coatings. Further, the α‐amylase‐digested DAT provides a more pro‐adipogenic microenvironment, based on higher levels of adipogenic gene expression, glycerol‐3‐phosphate dehydrogenase (GPDH) enzyme activity, and perilipin staining. Overall, this study supports α‐amylase digestion as a new approach for generating bioactive ECM‐derived coatings, and demonstrates tissue‐specific bioactivity using adipose‐derived ECM to enhance ASC proliferation and adipogenic differentiation.
Decellularized tissues represent promising biomaterials, which harness the innate capacity of the tissue-specific extracellular matrix (ECM) to direct cell functions including stem cell proliferation and lineage-specific differentiation. However, bioscaffolds derived exclusively from decellularized ECM offer limited versatility in terms of tuning biomechanical properties, as well as cell-cell and cell-ECM interactions that are important mediators of the cellular response. As an alternative approach, in the current chapter we describe methods for incorporating cryo-milled decellularized tissues as a cell-instructive component within a hydrogel carrier designed to crosslink under mild conditions. This composite strategy can enable in situ cell encapsulation with high cell viability, allowing efficient seeding with a homogeneous distribution of cells and ECM. Detailed protocols are provided for the effective decellularization of human adipose tissue and porcine auricular cartilage, as well as the cryo-milling process used to generate the ECM particles. Further, we describe methods for synthesizing methacrylated chondroitin sulphate (MCS) and for performing UV-initiated and thermally induced crosslinking to form hydrogel carriers for adipose and cartilage regeneration. The hydrogel composites offer great flexibility, and the hydrogel phase, ECM source, particle size, cell type(s) and seeding density can be tuned to promote the desired cellular response. Overall, these systems represent promising platforms for the development of tissue-specific 3-D in vitro cell culture models and in vivo cell delivery systems.
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