Temporal Enzymatic Treatment to Enhance the Remodeling of Multiple Cartilage Microtissues into a Structurally Organized Tissue

Biofabrication of Spatially Organized Temporo-mandibular Fibrocartilage Assembloids

The combination of mesenchymal stem cell (MSC) spheroids and polymeric scaffolds has been actively explored for engineering organized hyaline cartilage; however, its application to other types of cartilage remains under-explored. The temporo-mandibular joint (TMJ) fibrocartilage is a stratified tissue whose recapitulation remains challenging. In this study, the shape and growth orientation of assembloids are controlled by seeding early mature human adipose-derived MSC spheroids into scaffolds with a dual architecture of micron-scale fibers. This results in flattened asymmetric tissues with a single-sided articular surface. The engineered fibrocartilage mimics the histotypical organization of native human condylar fibrocartilage, featuring a thick fibrous zone with flattened cells. A native-like distribution of glycosaminoglycans, type I and II collagens, aggrecan core protein, and fibronectin is observed. Collagen organization is also found to be similar to that of native human tissue, up to the fibril level. Zonal-dependent micromechanical properties are identified in both the engineered and native tissues, although lower mechanical properties are observed in the fibrous zone of the engineered tissue. This work provides further evidence that the combination of MSC spheroids and micron-sized fiber scaffolds is a versatile approach for engineering stratified cartilage and a promising strategy for engineering biomimetic fibrocartilage grafts for TMJ reconstruction.

The maturation state and density of human cartilage microtissues influence their fusion and development into scaled-up grafts

Functional cartilaginous tissues can potentially be engineered by bringing together numerous microtissues (µTs) and allowing them to fuse and re-organize into larger, structurally organized grafts. The maturation level of individual microtissues is known to influence their capacity to fuse, however its impact on the long-term development of the resulting tissue remains unclear. The first objective of this study was to investigate the influence of the maturation state of human bone-marrow mesenchymal stem/stromal cells (hBM-MSCSs) derived microtissues on their fusion capacity and the phenotype of the final engineered tissue. Less mature (day 2) cartilage microtissues were found to fuse faster, supporting the development of a matrix that was richer in sulphated glycosaminoglycans (sGAG) and collagen, while low in calcium deposits. This enhanced fusion in less mature microtissues correlated with enhanced expression of N-cadherin, followed by a progressive increase in markers associated with cell-extracellular matrix (ECM) interactions. We then engineered larger constructs with varying initial numbers (50, 150 or 300 µTs per well) of less mature microtissues, observing enhanced sGAG synthesis with increased microtissue density. We finally sought to engineer a scaled-up cartilage graft by fusing 4,000 microtissues and maintaining the resulting constructs under either dynamic or static culture conditions. Robust and reliable fusion was observed between microtissues at this scale, with no clear benefit of dynamic culture on the levels of matrix accumulation or the tensile modulus of the resulting construct. These results support the use of BM-MSCs derived microtissues for the development of large-scale, engineered functional cartilaginous grafts. STATEMENT OF SIGNIFICANCE: Microtissues are gaining attention for their use as biological building blocks in the field of tissue engineering. The fusion of multiple microtissues is crucial for achieving a cohesive engineered tissue of scale, however the impact of their maturation level on the long-term properties of the engineered graft is poorly understood. This paper emphasizes the importance of using less mature cartilage microtissues for supporting appropriate cell-cell interactions and robust chondrogenesis in vitro. We demonstrate that tissue development is not negatively impacted by increasing the initial numbers of microtissues within the graft. This biofabrication strategy has significant translation potential, as it enables the engineering of scaled-up cartilage grafts of clinically relevant sizes using bone marrow derived MSCs.

Small spheroids for head and neck cartilage tissue engineering

The demand for cartilage reconstruction in the head and neck region arises frequently due to trauma, malignancies, and hereditary diseases. Traditional tissue engineering produces cartilage from a small biopsy by combining biomaterials and expanded cells. However, this top-down approach is associated with several limitations, including the non-uniform distribution of cells, lack of physiological cell-cell and cell-matrix interactions, and compromised mechanical properties and tissue architecture. The capacity of cells to aggregate into microtissues enables an alternative bottom-up approach to producing cartilage with or without further scaffolding support. Here we explored the optimal conditions for obtaining small spheroids from head and neck cartilage tissues. We used chondrocytes (CCs) and chondroprogenitors (CPCs) isolated from auricular and nasoseptal cartilage to prepare spheroids using ultra-low attachment (ULA) plates or micromass cultures. Different cell densities were tested to estimate the minimal cell number required for optimal spheroid formation. Furthermore, we evaluated the influence of key chondrogenic cytokines, such as transforming growth factor (TGF)-β, connective tissue growth factor (CTGF), and insulin-like growth factor (IGF)-1, on spheroid morphology and the production of cartilage extracellular matrix (ECM) components. Spheroids expressing cartilage markers were formed with 2.5 × 104 cells in a commercially available chondrogenic differentiation medium on ULA plates but not in conventional micromass cultures. Differences were seen in auricular and nasal spheroids with respect to growth patterns and response to cytokine composition. Auricular spheroids were larger and showed size increase in culture, whereas nasal aggregates tended to shrink. Cytokines differentially influenced spheroid growth, and ECM structure and composition. Under all tested conditions, both spheroid types generated one or more cartilage ECM components, including elastin, which was also found in nasal spheroids despite their hyaline origin. Our results suggest that spheroid cultures can offer a viable approach to generating mature cartilage tissue without a biomaterial scaffold. Furthermore, nasal CCs and CPCs can be used to generate elastic cartilage. The findings of the study provide technical insights toward the goal of obtaining cartilage microtissues that can be potentially used for reconstructive procedures of HNC cartilage defects.

Tissue growth as a mechanism for collagen fiber alignment in articular cartilage

Articular cartilage is distinguished by the unique alignment of type II collagen, a feature crucial for its mechanical properties and function. This characteristic organization is established during postnatal development of the tissue, yet the underlying mechanisms remain poorly understood. In this study, a potential mechanism for type II collagen alignment by cartilage-specific growth from within the tissue was investigated. Bovine chondrocyte-derived cartilage organoids were cultured in a transwell system, subjecting the created tissue to transforming growth factor β1 stimulation from either the bottom (bottom-up) or the top (top-down) compartment to induce interstitial growth and appositional growth, respectively. The results demonstrate that interstitial growth within the tissue, stimulated from underneath, successfully produced aligned type II collagen parallel to the direction of this growth. In contrast, appositional growth did not yield such alignment. These findings underscore the critical role of the direction of growth in recreating the characteristic collagen organization of articular cartilage, offering valuable insights for the advancement of creating functional tissue in tissue engineering strategies.

Biofabrication and biomanufacturing in Ireland and the UK

As we navigate the transition from the Fourth to the Fifth Industrial Revolution, the emerging fields of biomanufacturing and biofabrication are transforming life sciences and healthcare. These sectors are benefiting from a synergy of synthetic and engineering biology, sustainable manufacturing, and integrated design principles. Advanced techniques such as 3D bioprinting, tissue engineering, directed assembly, and self-assembly are instrumental in creating biomimetic scaffolds, tissues, organoids, medical devices, and biohybrid systems. The field of biofabrication in the United Kingdom and Ireland is emerging as a pivotal force in bioscience and healthcare, propelled by cutting-edge research and development. Concentrating on the production of biologically functional products for use in drug delivery, in vitro models, and tissue engineering, research institutions across these regions are dedicated to innovating healthcare solutions that adhere to ethical standards while prioritising sustainability, affordability, and healthcare system benefits.

Graphic abstract

Rapidly Degrading Hydrogels to Support Biofabrication and 3D Bioprinting Using Cartilage Microtissues

In recent years, there has been increased interest in the use of cellular spheroids, microtissues, and organoids as biological building blocks to engineer functional tissues and organs. Such microtissues are typically formed by the self-assembly of cellular aggregates and the subsequent deposition of a tissue-specific extracellular matrix (ECM). Biofabrication and 3D bioprinting strategies using microtissues may require the development of supporting hydrogels and bioinks to spatially localize such biological building blocks in 3D space and hence enable the engineering of geometrically defined tissues. Therefore, the aim of this work was to engineer scaled-up, geometrically defined cartilage grafts by combining multiple cartilage microtissues within a rapidly degrading oxidized alginate (OA) supporting hydrogel and maintaining these constructs in dynamic culture conditions. To this end, cartilage microtissues were first independently matured for either 2 or 4 days and then combined in the presence or absence of a supporting OA hydrogel. Over 6 weeks in static culture, constructs engineered using microtissues that were matured independently for 2 days generated higher amounts of glycosaminoglycans (GAGs) compared to those matured for 4 days. Histological analysis revealed intense staining for GAGs and negative staining for calcium deposits in constructs generated by using the supporting OA hydrogel. Less physical contraction was also observed in constructs generated in the presence of the supporting gel; however, the remnants of individual microtissues were more observable, suggesting that even the presence of a rapidly degrading hydrogel may delay the fusion and/or the remodeling of the individual microtissues. Dynamic culture conditions were found to modulate ECM synthesis following the OA hydrogel encapsulation. We also assessed the feasibility of 3D bioprinting of cartilage microtissues within OA based bioinks. It was observed that the microtissues remained viable after extrusion-based bioprinting and were able to fuse after 48 h, particularly when high microtissue densities were used, ultimately generating a cartilage tissue that was rich in GAGs and negative for calcium deposits. Therefore, this work supports the use of OA as a supporting hydrogel/bioink when using microtissues as biological building blocks in diverse biofabrication and 3D bioprinting platforms.

Injectable MSC Spheroid and Microgel Granular Composites for Engineering Tissue

Many cell types require direct cell-cell interactions for differentiation and function; yet, this can be challenging to incorporate into 3-dimensional (3D) structures for the engineering of tissues. Here, a new approach is introduced that combines aggregates of cells (spheroids) with similarly-sized hydrogel particles (microgels) to form granular composites that are injectable, undergo interparticle crosslinking via light for initial stabilization, permit cell-cell contacts for cell signaling, and allow spheroid fusion and growth. One area where this is important is in cartilage tissue engineering, as cell-cell contacts are crucial to chondrogenesis and are missing in many tissue engineering approaches. To address this, granular composites are developed from adult porcine mesenchymal stromal cell (MSC) spheroids and hyaluronic acid microgels and simulations and experimental analyses are used to establish the importance of initial MSC spheroid to microgel volume ratios to balance mechanical support with tissue growth. Long-term chondrogenic cultures of granular composites produce engineered cartilage tissue with extensive matrix deposition and mechanical properties within the range of cartilage, as well as integration with native tissue. Altogether, a new strategy of injectable granular composites is developed that leverages the benefits of cell-cell interactions through spheroids with the mechanical stabilization afforded with engineered hydrogels.