Your search keyword '"Matsusaki, Michiya"' showing total 8 results

1. Technology for the formation of engineered microvascular network models and their biomedical applications

Author

Li, He, Shang, Yucheng, Zeng, Jinfeng, and Matsusaki, Michiya

Published

2024

2. Bioink with cartilage-derived extracellular matrix microfibers enables spatial control of vascular capillary formation in bioprinted constructs

Author

Terpstra, Margo Luchiena, Li, Jinyu, Mensinga, Anneloes, de Ruijter, Mylène, van Rijen, Mattie H P, Androulidakis, Charalampos, Galiotis, Costas, Papantoniou, Ioannis, Matsusaki, Michiya, Malda, Jos, Levato, Riccardo, Equine Musculoskeletal Biology, dES RMSC, CS_Locomotion, Equine Musculoskeletal Biology, dES RMSC, and CS_Locomotion

Subjects

vascularized meniscus, Tissue Engineering, Tissue Scaffolds, anti-angiogenic bioink, collagen microfibers, Biomedical Engineering, Bioengineering, General Medicine, Biochemistry, Extracellular Matrix, Biomaterials, Cartilage, meniscus, Printing, Three-Dimensional, Human Umbilical Vein Endothelial Cells, Humans, anti-angiogenic, bioprinting, cartilage extracellular matrix, Biotechnology

Abstract

Microvasculature is essential for the exchange of gas and nutrient for most tissues in our body. Some tissue structures such as the meniscus presents spatially confined blood vessels adjacent to non-vascularized regions. In biofabrication, mimicking the spatial distribution of such vascular components is paramount, as capillary ingrowth into non-vascularized tissues can lead to tissue matrix alterations and subsequent pathology. Multi-material three-dimensional (3D) bioprinting strategies have the potential to resolve anisotropic tissue features, although building complex constructs comprising stable vascularized and non-vascularized regions remains a major challenge to date. In this study, we developed endothelial cell-laden pro- and anti-angiogenic bioinks, supplemented with bioactive matrix-derived microfibers (MFs) that were created from type I collagen sponges (col-1) and cartilage decellularized extracellular matrix (CdECM), respectively. Human umbilical vein endothelial cell (HUVEC)-driven capillary networks started to form 2 d after bioprinting. Supplementing cartilage-derived MFs to endothelial-cell laden bioinks reduced the total length of neo-microvessels by 29%, and the number of microvessel junctions by 37% after 14 d, compared to bioinks with pro-angiogenic col-1 MFs. As a proof of concept, the bioinks were bioprinted into an anatomical meniscus shape with a biomimetic vascularized outer and non-vascularized inner region, using a gellan gum microgel suspension bath. These 3D meniscus-like constructs were cultured up to 14 d, with in the outer zone the HUVEC-, mural cell-, and col-1 MF-laden pro-angiogenic bioink, and in the inner zone a meniscus progenitor cell (MPC)- and CdECM MF-laden anti-angiogenic bioink, revealing successful spatial confinement of the nascent vascular network only in the outer zone. Further, to co-facilitate both microvessel formation and MPC-derived matrix formation, we formulated cell culture medium conditions with a temporal switch. Overall, this study provides a new strategy that could be applied to develop zonal biomimetic meniscal constructs. Moreover, the use of ECM-derived MFs to promote or inhibit capillary networks opens new possibilities for the biofabrication of tissues with anisotropic microvascular distribution. These have potential for many applications including in vitro models of vascular-to-avascular tissue interfaces, cancer progression, and for testing anti-angiogenic therapies.

Published

2022

3. One-Step Photoactivation of a Dual-Functionalized Bioink as Cell Carrier and Cartilage-Binding Glue for Chondral Regeneration

Author

Lim, Khoon S, Abinzano, Florencia, Bernal, Paulina Nuñez, Albillos Sanchez, Ane, Atienza-Roca, Pau, Otto, Iris A, Peiffer, Quentin C, Matsusaki, Michiya, Woodfield, Tim B F, Malda, Jos, Levato, Riccardo, Equine Musculoskeletal Biology, dES RMSC, Equine Musculoskeletal Biology, and dES RMSC

Subjects

food.ingredient, Biomedical Engineering, Pharmaceutical Science, cartilage tissue engineering, 02 engineering and technology, Osteoarthritis, 010402 general chemistry, 01 natural sciences, Gelatin, Chondrocyte, Article, Biomaterials, food, medicine, Regeneration, Tissue Engineering, Tissue Scaffolds, Chemistry, Cartilage, biofabrication, Hydrogels, Adhesion, tissue integration, 021001 nanoscience & nanotechnology, Chondrogenesis, medicine.disease, 0104 chemical sciences, medicine.anatomical_structure, Self-healing hydrogels, Printing, Three-Dimensional, Biophysics, bioglue, 0210 nano-technology, bioprinting, Biofabrication

Abstract

Cartilage defects can result in pain, disability, and osteoarthritis. Hydrogels providing a chondroregeneration-permissive environment are often mechanically weak and display poor lateral integration into the surrounding cartilage. This study develops a visible-light responsive gelatin ink with enhanced interactions with the native tissue, and potential for intraoperative bioprinting. A dual-functionalized tyramine and methacryloyl gelatin (GelMA-Tyr) is synthesized. Photo-crosslinking of both groups is triggered in a single photoexposure by cell-compatible visible light in presence of tris(2,2'-bipyridyl)dichlororuthenium(II) and sodium persulfate as initiators. Neo-cartilage formation from embedded chondroprogenitor cells is demonstrated in vitro, and the hydrogel is successfully applied as bioink for extrusion-printing. Visible light in situ crosslinking in cartilage defects results in no damage to the surrounding tissue, in contrast to the native chondrocyte death caused by UV light (365-400 nm range), commonly used in biofabrication. Tyramine-binding to proteins in native cartilage leads to a 15-fold increment in the adhesive strength of the bioglue compared to pristine GelMA. Enhanced adhesion is observed also when the ink is extruded as printable filaments into the defect. Visible-light reactive GelMA-Tyr bioinks can act as orthobiologic carriers for in situ cartilage repair, providing a permissive environment for chondrogenesis, and establishing safe lateral integration into chondral defects.

Published

2020

4. Collagen Microfibers Induce Blood Capillary Orientation and Open Vascular Lumen

Author

Liu, Hao, Kitano, Shiro, Irie, Shinji, Levato, R., Matsusaki, Michiya, Equine Musculoskeletal Biology, and Equine Musculoskeletal Biology

Subjects

business.product_category, Tissue Engineering, Chemistry, Capillary action, collagen microfibers, vascular lumen, Biomedical Engineering, Hydrogels, Adhesion, blood capillary, General Biochemistry, Genetics and Molecular Biology, Vascular lumen, Capillaries, Biomaterials, Endothelial stem cell, Blood capillary, Tissue engineering, Microfiber, capillary orientation, Human Umbilical Vein Endothelial Cells, Humans, Collagen, business, Process (anatomy), Biomedical engineering

Abstract

Achieving vascularization of engineered tissues or structures is a major challenge in the field of tissue engineering. Hitherto, studies on vascularization have demonstrated limited control of vascular network geometry, such as vasculature direction and network density. An open vascular lumen is crucial to ensure that cells survive and that metabolic activity is fully functional in large-sized tissues. Herein, a method based on high water-dispersible collagen microfibers (CMF) to fabricate capillary orientation-controllable 3D tissue with an open vascular lumen using a dispensing machine is reported. A twenty micrometers-long CMF (CMF-20) with high dispersion property are shown to be more effective for dispensing a homogenous tissue and inducing formation of an interconnected capillary network than two hundred micrometers-long CMF (CMF-200). One of the advantages is the prevention of shrinkage on the z-axis of hydrogel-based tissue which acts as a microscaffold. The gaps between the fibers can support endothelial cell migration and maturation, thus forming a larger vascular lumen compared to CMF-free controls. Besides, shear forces produced by the dispensing process cause the collagen microfibers to align, and these microfibers guide cell alignment by integrin-induced adhesion. The findings based on CMF to allow blood capillary alignment and vascular lumen stabilization will be an important technology in tissue engineering.

Published

2020

5. Regulation of Chondrocyte Differentiation by Changing Intercellular Distances Using Type II Collagen Microfibers

Author

Li, Jinyu, Sasaki, Naoko, Itaka, Keiji, Terpstra, Margo L, Levato, R., Matsusaki, Michiya, Equine Musculoskeletal Biology, and Equine Musculoskeletal Biology

Subjects

0206 medical engineering, Biomedical Engineering, Type II collagen, 02 engineering and technology, Chondrocyte, Biomaterials, Extracellular matrix, Glycosaminoglycan, Chondrocytes, Downregulation and upregulation, Tissue engineering, medicine, collagen microfiber, cartilage, Collagen Type II, chondrocyte differentiation, intercellular distance, Chemistry, Cartilage, Cell Differentiation, 021001 nanoscience & nanotechnology, Chondrogenesis, 020601 biomedical engineering, Cell biology, medicine.anatomical_structure, tissue engineering, 0210 nano-technology

Abstract

Osteoarthritis is a common degenerative disease that mainly occurs in older age groups, and the search for an effective cure remains a major global challenge. The technology of constructing 3D in vitro cartilage tissue with zonal differentiated structures for use as alternative implants for treating osteoarthritis has attracted researchers' attention. For this challenge, it is important for understanding the relationship between chondrocyte differentiation and the amount of extracellular matrix by modulating intercellular distance. This study investigates the interplay between chondrocyte differentiation and intercellular distance. Type II collagen microfibers (CMF II) were used as a distance regulator by varying their amounts. The results indicated that the secretion of cartilage-specific glycosaminoglycan after 2 weeks of differentiation from the chondrogenic cells, ATDC5, was decreased with an increased intercellular distance. Also, the shortest intercellular distance, being ATDC5 cells without CMF II, presented an upregulated gene expression profile of cartilage markers. The groups with CMF II-mediated intracellular distances, however, did not show the upregulation. The elastic modulus of the 3D samples increased depending on the amount of CMF II, relating to the differentiation preventing property of the CMF II. These findings suggest the promising potential of this approach for the modulation of chondrocyte differentiation.

Published

2020

6. Construction of transplantable artificial vascular tissue based on adipose tissue-derived mesenchymal stromal cells by a cell coating and cryopreservation technique.

Author

Asano, Yoshiya, Okano, Daisuke, Matsusaki, Michiya, Watabe, Tetsuro, Yoshimatsu, Yasuhiro, Akashi, Mitsuru, and Shimoda, Hiroshi

Subjects

MESENCHYMAL stem cells, CRYOPRESERVATION of organs, tissues, etc., BIOMATERIALS, REGENERATIVE medicine, ENDOTHELIAL cells

Abstract

Prevascularized artificial three-dimensional (3D) tissues are effective biomaterials for regenerative medicine. We have previously established a scaffold-free 3D artificial vascular tissue from normal human dermal fibroblasts (NHDFs) and umbilical vein-derived endothelial cells (HUVECs) by layer-by-layer cell coating technique. In this study, we constructed an artificial vascular tissue constructed by human adipose tissue-derived stromal cells (hASCs) and HUVECs (ASCVT) by a modified technique with cryopreservation. ASCVT showed a higher thickness with more dense vascular networks than the 3D tissue based on NHDFs. Correspondingly, 3D-cultured ASCs showed higher expression of several angiogenesis-related factors, including vascular endothelial growth factor-A and hepatic growth factor, compared to that of NHDFs. Moreover, perivascular cells in ASCVT were detected by pericyte markers, suggesting the differentiation of hASCs into pericyte-like cells. Subcutaneous transplantation of ASCVTs to nude mice resulted in an engraftment with anastomosis of host's vascular structures at 2 weeks after operation. In the engrafted tissue, the vascular network was surrounded by mural-like structure-forming hASCs, in which some parts developed to form vein-like structures at 4 weeks, suggesting the generation of functional vessel networks. These results demonstrated that cryopreserved human cells, including hASCs, could be used directly to construct the artificial transplantable tissue for regenerative medicine. [ABSTRACT FROM AUTHOR]

Published

2021

7. Construction of Mouse‐Embryonic‐Cell‐Derived 3D Pacemaker Tissues by Layer‐by‐Layer Nanofilm Coating.

Author

Amano, Yuto, Igarashi, Takuya, Nishiguchi, Akihiro, Matsusaki, Michiya, Saito, Yukihiro, Nakamura, Kazufumi, Ito, Hiroshi, and Akashi, Mitsuru

Subjects

NANOFILMS, PACEMAKER cells, ARRHYTHMIA treatment, HYPERPOLARIZATION (Cytology), CYCLIC nucleotides

Abstract

Abstract: For the treatment of cardiac arrhythmia, electronic pacemakers are often employed. However, they have issues such as bio‐incompatibility and battery limitations. Recently, the use of cells expressing hyperpolarization‐activated cyclic nucleotide‐gated 4 (HCN4) channels for use as pacemaker cells instead of electronic pacemakers has attracted increasing attention. However, the cell transplantation treatment was not sufficiently effective because of the low engraftment rate of the transplanted cells and the risk of inflammatory reactions. Here, in order to overcome these issues, we constructed 3D‐pacemaker tissues composed of mouse‐embryonic‐cell‐derived cardiomyocytes (mESC‐CMs) in which the HCN4 gene had been introduced by the cell accumulation technique. The obtained tissues beat faster than control tissues and beats per minute (BPM) increased clearly with tissue thickness. This is the first report suggesting the relation between BPM and tissue thickness. Moreover, the pacemaker tissue could control the beating of the patched tissue. [ABSTRACT FROM AUTHOR]

Published

2016

8. Cancer Stem Cell Microenvironment Models with Biomaterial Scaffolds In Vitro.

Author

Hassan, Ghmkin, Afify, Said M., Kitano, Shiro, Seno, Akimasa, Ishii, Hiroko, Shang, Yucheng, Matsusaki, Michiya, and Seno, Masaharu

Subjects

CANCER stem cells, PHENOMENOLOGICAL biology, CANCER treatment, SUBSTANCE abuse relapse, DRUG accessibility, BIOMATERIALS

Abstract

Defined by its potential for self-renewal, differentiation and tumorigenicity, cancer stem cells (CSCs) are considered responsible for drug resistance and relapse. To understand the behavior of CSC, the effects of the microenvironment in each tissue are a matter of great concerns for scientists in cancer biology. However, there are many complicated obstacles in the mimicking the microenvironment of CSCs even with current advanced technology. In this context, novel biomaterials have widely been assessed as in vitro platforms for their ability to mimic cancer microenvironment. These efforts should be successful to identify and characterize various CSCs specific in each type of cancer. Therefore, extracellular matrix scaffolds made of biomaterial will modulate the interactions and facilitate the investigation of CSC associated with biological phenomena simplifying the complexity of the microenvironment. In this review, we summarize latest advances in biomaterial scaffolds, which are exploited to mimic CSC microenvironment, and their chemical and biological requirements with discussion. The discussion includes the possible effects on both cells in tumors and microenvironment to propose what the critical factors are in controlling the CSC microenvironment focusing the future investigation. Our insights on their availability in drug screening will also follow the discussion. [ABSTRACT FROM AUTHOR]

Published

2021