Takashi Hoshiba

Decellularized matrices for tissue engineering

Importance of the field: Biomimetic scaffolds and substrates of extracellular matrices (ECMs) play an important role in the regulation of cell function and in the guidance of new tissue regeneration, as an ECM has the intrinsic cues necessary to communicate with and dictate to cells. Areas covered in this review: This paper reviews the latest developments in ECM scaffolds and substrates obtained from decellularized tissues, organs or cultured cells and their application in tissue engineering. The ECM composition, structure, interaction with surrounding cells, preparation method and usage in the regeneration of various tissues and organs are summarised. What the reader will gain: The advantages and challenges of decellularized matrices are highlighted. Take home message: Similarity in the composition, microstructure and biomechanical properties of the decellularized scaffolds and substrates to those of the native tissues and organs maximizes the promotion effect in the regeneration of both structural and functional tissues and organs. Simple tissues as well as complicated organs have been decellularized and decellularization methods have been optimized to completely remove the cellular components while keeping the ECM intact.

Cultured cell-derived extracellular matrix scaffolds for tissue engineering.

Cell-derived extracellular matrix (ECM) scaffolds have received considerable interest for tissue engineering applications. In this study, ECM scaffolds derived from mesenchymal stem cell (MSC), chondrocyte, and fibroblast were prepared by culturing cells in a selectively removable poly(lactic-co-glycolic acid) (PLGA) template. These three types of ECM scaffolds were used for in vitro cultures of MSC and fibroblasts to examine their potential as scaffolds for cartilage and skin tissue engineering. The MSC were cultured in MSC- and chondrocyte-derived ECM scaffolds. The ECM scaffolds supported cell adhesion, promoted both cell proliferation and the production of ECM and demonstrated a stronger stimulatory effect on the chondrogenesis of MSC compared with a conventional pellet culture method. Histological and immunohistochemical staining indicated that cartilage-like tissues were regenerated after the MSC were cultured in ECM scaffolds. Fibroblasts were cultured in the fibroblast-derived ECM scaffolds. Fibroblasts proliferated and produced ECM to fill the pores and spaces in the scaffold. After 2 weeks of culture, a uniform multilayered tissue was generated with homogenously distributed fibroblasts. Cell-derived ECM scaffolds have been demonstrated to facilitate tissue regeneration and will be a useful tool for tissue engineering.

Development of Stepwise Osteogenesis-mimicking Matrices for the Regulation of Mesenchymal Stem Cell Functions

An extracellular microenvironment, including an extracellular matrix (ECM), is an important factor in regulating stem cell differentiation. During tissue development, the ECM is dynamically remodeled to regulate stem cell functions. Here, we developed matrices mimicking ECM remodeling during the osteogenesis of mesenchymal stem cells (MSCs). The matrices were prepared from cultured MSCs controlled at different stages of osteogenesis and referred to as “stepwise osteogenesis-mimicking matrices.” The matrices supported the adhesion and proliferation of MSCs and showed different effects on the osteogenesis of MSCs. On the matrices mimicking the early stage of osteogenesis (early stage matrices), the osteogenesis occurred more rapidly than did that on the matrices mimicking undifferentiated stem cells (stem cell matrices) and the late stage of osteogenesis (late stage matrices). RUNX2 was similarly expressed when MSCs were cultured on both the early stage and late stage matrices but decreased on the stem cell matrices. PPARG expression in the MSCs cultured on the late stage matrices was higher than for those cultured on the stem cell and early stage matrices. This increase of PPARG expression was caused by the suppression of the amount of β-catenin and downstream signal transduction. These results demonstrate that the osteogenesis-mimicking matrices had different effects on the osteogenesis of MSCs, and the early stage matrices provided a favorable microenvironment for the osteogenesis.

Development of extracellular matrices mimicking stepwise adipogenesis of mesenchymal stem cells.

Stem cells are one of the most promising cell sources for tissue engineering and regenerative medicine. [ 1–3 ] The use of stem cells for tissue engineering and regenerative medicine requires effective systems of differentiation. When stem cells differentiate into somatic cells, they pass through stepwise stages of maturation. [ 4,5 ] During the stepwise differentiation, the extracellular microenvironment, especially the extracellular matrix (ECM), dynamically changes to regulate the process of stem cell differentiation. [ 6–8 ] It has been thought that ECM plays an important role in the differentiation of stem cells. However, the role of ECM remodeling during stem cell differentiation has been unclear because there are no in vitro models mimicking ECM during stem cell differentiation. It is anticipated that in vitro models mimicking ECM during stem cell differentiation will provide more precise and detailed insights into the role of ECM in stem cell differentiation. In addition, these insights will be useful to establish effective systems for stem cell differentiation. It is diffi cult to fabricate in vitro models mimicking ECM remodeling by physicochemical methods because ECM is formed from complex components. [ 9 ] There are many reports of the development of acellular matrices from tissues using various decellularization treatments to mimic in vivo ECM. [ 10 , 11 ]

The balance of osteogenic and adipogenic differentiation in human mesenchymal stem cells by matrices that mimic stepwise tissue development.

The disruption of balance between osteogenesis and adipogenesis of mesenchymal stem cells (MSCs) leads to the disorders such as osteoporosis. Controlling the balance of these processes during MSC differentiation is important to maintain bone homeostasis. The extracellular microenvironment, especially the extracellular matrix (ECM), plays an important role in regulating MSC differentiation. Here, we investigated the role of ECM in controlling the balance between osteogenesis and adipogenesis of MSCs with matrices that mimic the stepwise tissue development of ECM during osteogenesis and adipogenesis. The osteogenesis of MSCs was enhanced by matrices with upregulated RUNX2 expression and suppressed PPARG expression, which mimic the attributes of the ECM during the early stages of osteogenesis. MSC adipogenesis was enhanced by matrices with suppressed expression of RUNX2, MSX2, and TAZ, which mimics the characteristics of ECM during the early stages of adipogenesis. These results showed that ECM may regulate the expression of various transcription factors to control the balance of osteogenesis and adipogenesis of MSCs. Tissue- and stage-specific ECM are required to control differentiation of MSCs into a specific cell types.

Osteogenic differentiation of human mesenchymal stem cells on chargeable polymer-modified surfaces.

Polystyrene cell-culture plates modified with positively charged polyallylamine (PAAm) and negatively charged poly(acrylic acid) (PAAc) and unmodified plate were used for the culture of human mesenchymal stem cells (MSCs) to study the effect of surface electrostatic properties on their osteogenic differentiation. All of these surfaces supported cell adhesion and proliferation. However, the cells adhered, spread, and proliferated somewhat more quickly on the PAAm-modified surface than they did on the PAAc-modified and control surfaces. Osteogenic differentiation was examined by alkaline phosphatase (ALP) staining, alizarin red S staining, and gene-expression analysis. The MSCs cultured on the three kinds of surfaces in the presence of dexamethasone were positively stained with ALP and alizarin red S staining, while the cells cultured without dexamethasone were not positively stained. Gene-expression analyses using real-time PCR indicated that MSCs cultured on these surfaces in the presence of dexamethasone expressed osteogenic marker genes, encoding ALP, osteocalcin, bone sialoprotein, osteopontin, and type I collagen. These results indicate that the positively charged, negatively charged, and unmodified surfaces supported osteogenic differentiation, and that their effect required the synergistic effect of dexamethasone.

High-precision microscopic phase imaging without phase unwrapping for cancer cell identification

A high-dynamic-range two-dimensional phase measurement system that does not need phase unwrapping processing was developed. The optical path difference distribution about three wavelengths could be measured, demonstrating the high dynamic-range of this system. We also experimentally investigate the potential of this approach for biological applications that are cancer identification and assessing the limitations of the passage culture of biological cells.

Application of Recombinant Fusion Proteins for Tissue Engineering

Extracellular matrix (ECM) plays important roles in tissue engineering because cellular growth and differentiation, in the two-dimensional cell culture as well as in the three-dimensional space of the developing organism, require ECM with which the cells can interact. Also, the development of new synthetic ECMs is very important because ECMs facilitate the localization and delivery of cells to the specific sites in the body. Therefore, the development of synthetic ECMs to replace the natural ECMs is increasingly essential and promising in tissue engineering. Recombinant genetic engineering method has enabled the synthesis of protein-based polymers with precisely controlled functionalities for the development of new synthetic ECMs. In this review, the design and construction of structure-based recombinant fusion proteins such as elastin-like polymers (ELPs) and silk-like polymers (SLPs), cell-bound growth factor-based recombinant fusion proteins such as basic fibroblast growth factor (bFGF) and epidermal growth factor (EGF), hybrid system composed of recombinant protein and synthetic polymer, and E-cadherin-based fusion protein by recombinant genetic engineering were explained for application of the synthetic ECMs. Modulation of mechanical properties, stimuli-sensitivity, biodegradation and cell recognition can be achieved through precise control of sequence, length, hydrophobicity and cell binding domain by recombinant genetic engineering.

Decellularized Extracellular Matrix as an In Vitro Model to Study the Comprehensive Roles of the ECM in Stem Cell Differentiation

Stem cells are a promising cell source for regenerative medicine. Stem cell differentiation must be regulated for applications in regenerative medicine. Stem cells are surrounded by extracellular matrix (ECM) in vivo. The ECM is composed of many types of proteins and glycosaminoglycans that assemble into a complex structure. The assembly of ECM molecules influences stem cell differentiation through orchestrated intracellular signaling activated by many ECM molecules. Therefore, it is important to understand the comprehensive role of the ECM in stem cell differentiation as well as the functions of the individual ECM molecules. Decellularized ECM is a useful in vitro model for studying the comprehensive roles of ECM because it retains a native-like structure and composition. Decellularized ECM can be obtained from in vivo tissue ECM or ECM fabricated by cells cultured in vitro. It is important to select the correct decellularized ECM because each type has different properties. In this review, tissue-derived and cell-derived decellularized ECMs are compared as in vitro ECM models to examine the comprehensive roles of the ECM in stem cell differentiation. We also summarize recent studies using decellularized ECM to determine the comprehensive roles of the ECM in stem cell differentiation.

Comparison of decellularization techniques for preparation of extracellular matrix scaffolds derived from three‐dimensional cell culture

Extracellular matrix (ECM) scaffolds derived from cultured cells have drawn increasing attention for use in tissue engineering. We have developed a method to prepare cultured cell-derived ECM scaffolds by combining three-dimensional cell culture, decellularization, and selective template removal. Cell-ECM-template complexes were first formed by culture of cells in a poly(lactic-co-glycolic acid) (PLGA) mesh template to deposit their own ECM. The complexes were subsequently decellularized to remove cellular components. Finally, the PLGA template was selectively removed to obtain the ECM scaffolds. Seven decellularization methods were compared for their decellularization effects during scaffold preparation. They were: freeze-thaw cycling (-80°C, six times) with ammonia water (25 mM); 0.1% Triton™ X-100 (TX100) with 1.5M KCl aqueous solution; freeze-thaw cycling alone; ammonia water alone; TX100 extraction; osmotic shock with 1.5M KCl; and freeze-thaw cycling with 3M NaCl. Among these methods, the methods of freeze-thaw cycling with NH(4) OH and TX100 with 1.5M KCl showed the best effect on the removal of cellular components from the complexes, while the other five methods could only partially remove cellular components. The ECM scaffolds prepared by these two methods had similar gross appearances and microstructures. In vivo implantation of the ECM scaffolds prepared by these two methods induced mild host responses. The two decellularization methods were demonstrated to be effective for preparation of cultured cell-derived ECM scaffolds.