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1,345 results on '"Teruo, Okano"'

1. Umbilical cord-derived mesenchymal stem cell sheets transplanted subcutaneously enhance cell retention and survival more than dissociated stem cell injections

Author

Mitsuyoshi Nakao, Makoto Matsui, Kyungsook Kim, Nobuhiro Nishiyama, David W. Grainger, Teruo Okano, Hideko Kanazawa, and Kenichi Nagase

Subjects
Cell sheet transplantation, Cytokine expression, Engraftment, Temperature-responsive cell cultureware, Cell retention, Medicine (General), R5-920, Biochemistry, QD415-436
Abstract

Abstract Background Human umbilical cord-derived mesenchymal stem cell (hUC-MSC) sheets have recently attracted attention as an alternative approach to injected cell suspensions for stem cell therapy. However, cell engraftment and cytokine expression levels between hUC-MSC sheets and their cell suspensions in vivo have not yet been compared. This study compares hUC-MSC in vivo engraftment efficacy and cytokine expression for both hUC-MSC sheets and cell suspensions. Methods hUC-MSC sheets were prepared using temperature-responsive cell culture; two types of hUC-MSC suspensions were prepared, either by enzymatic treatment (trypsin) or by enzyme-free temperature reduction using temperature-responsive cell cultureware. hUC-MSC sheets and suspensions were transplanted subcutaneously into ICR mice through subcutaneous surgical placement and intravenous injection, respectively. hUC-MSC sheet engraftment after subcutaneous surgical transplantation was investigated by in vivo imaging while intravenously injected cell suspensions were analyzing using in vitro organ imaging. Cytokine levels in both transplant site tissues and blood were quantified by enzyme-linked immunosorbent assay. Results After subcutaneous transplant, hUC-MSC sheets exhibited longer engraftment duration than hUC-MSC suspensions. This was attributed to extracellular matrix (ECM) and cell–cell junctions retained in sheets but enzymatically altered in suspensions. hUC-MSC suspensions harvested using enzyme-free temperature reduction exhibited relatively long engraftment duration after intravenous injection compared to suspensions prepared using trypsin, as enzyme-free harvest preserved cellular ECM. High HGF and TGF-β1 levels were observed in sheet-transplanted sites compared to hUC-MSC suspension sites. However, no differences in human cytokine levels in murine blood were detected, indicating that hUC-MSC sheets might exert local paracrine rather than endocrine effects. Conclusions hUC-MSC sheet transplantation could be a more effective cell therapeutic approach due to enhanced engraftment and secretion of therapeutic cytokines over injected hUC-MSC suspensions.

Published
2023
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2. Rapid and effective preparation of clonal bone marrow-derived mesenchymal stem/stromal cell sheets to reduce renal fibrosis

Author

Sumako Kameishi, Celia M. Dunn, Masatoshi Oka, Kyungsook Kim, Yun-Kyoung Cho, Sun U. Song, David W. Grainger, and Teruo Okano

Subjects
Medicine, Science
Abstract

Abstract Allogeneic “off-the-shelf” mesenchymal stem/stromal cell (MSC) therapy requires scalable, quality-controlled cell manufacturing and distribution systems to provide clinical-grade products using cryogenic cell banking. However, previous studies report impaired cell function associated with administering freeze-thawed MSCs as single cell suspensions, potentially compromising reliable therapeutic efficacy. Using long-term culture-adapted clinical-grade clonal human bone marrow MSCs (cBMSCs) in this study, we engineered cBMSC sheets in 24 h to provide rapid preparation. We then sought to determine the influence of cBMSC freeze-thawing on both in vitro production of pro-regenerative factors and in vivo ability to reduce renal fibrosis in a rat model compared to freshly harvested cBMSCs. Sheets from freeze-thawed cBMSCs sheets exhibited comparable in vitro protein production and gene expression of pro-regenerative factors [e.g., hepatocyte growth factor (HGF), vascular endothelial growth factor (VEGF), and interleukin 10 (IL-10)] to freshly harvested cBMSC sheets. Additionally, freeze-thawed cBMSC sheets successfully suppressed renal fibrosis in vivo in an established rat ischemia–reperfusion injury model. Despite previous studies reporting that freeze-thawed MSCs exhibit impaired cell functions compared to fresh MSC single cell suspensions, cell sheets engineered from freeze-thawed cBMSCs do not exhibit impaired cell functions, supporting critical steps toward future clinical translation of cBMSC-based kidney disease treatment.

Published
2023
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3. Polydactyly-derived allogeneic chondrocyte cell-sheet transplantation with high tibial osteotomy as regenerative therapy for knee osteoarthritis

Author

Kosuke Hamahashi, Eriko Toyoda, Miya Ishihara, Genya Mitani, Tomonori Takagaki, Nagatoshi Kaneshiro, Miki Maehara, Takumi Takahashi, Eri Okada, Ayako Watanabe, Yoshihiko Nakamura, Reiko Kato, Ryo Matoba, Takehiko Takagi, Hidenori Akutsu, Akihiro Umezawa, Hiroyuki Kobayashi, Tadashi Akamatsu, Masayuki Yamato, Teruo Okano, Masahiko Watanabe, and Masato Sato

Subjects
Medicine
Abstract

Abstract Allogeneic cell therapies are not fully effective in treating osteoarthritis of the knee (OAK). We recently reported that transplantation of autologous chondrocyte cell-sheets along with open-wedge high tibial osteotomy promoted hyaline cartilage repair in humans. Here we describe our regenerative therapy for OAK using polydactyly-derived allogeneic chondrocyte cell-sheets (PD sheets) and temperature-responsive culture inserts. Ten patients with OAK and cartilage defects categorized arthroscopically as Outerbridge grade III or IV received the therapy. Cartilage viscoelasticity and thickness were assessed before and after transplantation. Arthroscopic biopsies obtained 12 months after transplantation were analyzed histologically. Gene expression was analyzed to evaluate the PD sheets. In this small initial longitudinal series, PD sheet transplantation was effective in treating OAK, as indicated by changes in cartilage properties. Gene marker sets in PD sheets may predict outcomes after therapy and provide markers for the selection of donor cells. This combined surgery may be an ideal regenerative therapy with disease-modifying effects in OAK patients.

Published
2022
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4. Development of alternative gene transfer techniques for ex vivo and in vivo gene therapy in a canine model

Author

Masashi Noda, Kohei Tatsumi, Hideto Matsui, Yasunori Matsunari, Takeshi Sato, Yasushi Fukuoka, Akitsu Hotta, Teruo Okano, Kimihiko Kichikawa, Mitsuhiko Sugimoto, Midori Shima, and Kenji Nishio

Subjects
Gene therapy, Dog, Cell sheet, Hydrodynamic injection, Hemophilia, Medicine (General), R5-920, Cytology, QH573-671
Abstract

Introduction: Gene therapy have recently attracted much attention as a curative therapeutic option for inherited single gene disorders such as hemophilia. Hemophilia is a hereditary bleeding disorder caused by the deficiency of clotting activity of factor VIII (FVIII) or factor IX (FIX), and gene therapy for hemophilia using viral vector have been vigorously investigated worldwide. Toward further advancement of gene therapy for hemophilia, we have previously developed and validated the efficacy of novel two types of gene transfer technologies using a mouse model of hemophilia A. Here we investigated the efficacy and safety of the technologies in canine model. Especially, validations of technical procedures of the gene transfers for dogs were focused. Methods: Green fluorescence protein (GFP) gene were transduced into normal beagle dogs by ex vivo and in vivo gene transfer techniques. For ex vivo gene transfer, blood outgrowth endothelial cells (BOECs) derived from peripheral blood of normal dogs were transduced with GFP gene using lentivirus vector, propagated, fabricated as cell sheets, then implanted onto the omentum of the same dogs. For in vivo gene transfer, normal dogs were subjected to GFP gene transduction with non-viral piggyBac vector by liver-targeted hydrodynamic injections. Results: No major adverse events were observed during the gene transfers in both gene transfer systems. As for ex vivo gene transfer, histological findings from the omental biopsy performed 4 weeks after implantation revealed the tube formation by implanted GFP-positive BOECs in the sub-adipose tissue layer without any inflammatory findings, and the detected GFP signals were maintained over 6 months. Regarding in vivo gene transfer, analyses of liver biopsy samples revealed more than 90% of liver cells were positive for GFP signals in the injected liver lobes 1 week after gene transfers, then the signals gradually declined overtime. Conclusions: Two types of gene transfer techniques were successfully applied to a canine model, and the transduced gene expressions persisted for a long term. Toward clinical application for hemophilia patients, practical assessments of therapeutic efficacy of these techniques will need to be performed using a dog model of hemophilia and FVIII (or FIX) gene.

Published
2021
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5. Enhancing chondrogenic potential via mesenchymal stem cell sheet multilayering

Author

Hallie Thorp, Kyungsook Kim, Sophia Bou-Ghannam, Makoto Kondo, Travis Maak, David W. Grainger, and Teruo Okano

Subjects
Tissue engineering, Chondrogenic differentiation, Scaffold-free, Cellular interactions, Cell sheet technology, Medicine (General), R5-920, Cytology, QH573-671
Abstract

Advanced tissue engineering approaches for direct articular cartilage replacement in vivo employ mesenchymal stem cell (MSC) sources, exploiting innate chondrogenic potential to fabricate hyaline-like constructs in vitro within three-dimensional (3D) culture conditions. Cell sheet technology represents one such advanced 3D scaffold-free cell culture platform, and previous work has shown that 3D MSC sheets are capable of in vitro hyaline-like chondrogenic differentiation. The present study aims to build upon this understanding and elucidate the effects of an established cell sheet manipulation technique, cell sheet multilayering, on fabrication of MSC-derived hyaline-like cartilage 3D layered constructs in vitro. To achieve this goal, multilayered MSC sheets are prepared and assessed for structural and biochemical transitions throughout chondrogenesis. Results support MSC multilayering as a means of increasing construct thickness and 3D cellular interactions related to in vitro chondrogenesis, including N-cadherin, connexin 43, and integrin β-1. Data indicate that increasing construct thickness from 14 μm (1-layer construct) to 25 μm (2-layer construct) increases these cellular interactions and subsequent in vitro MSC chondrogenesis. However, a clear initial thickness threshold (33 μm - 3-layer construct) is evident that decreases the rate and extent of in vitro chondrogenesis, specifically chondrogenic gene expressions (Sox9, aggrecan, type II collagen) and sulfated proteoglycan accumulation in deposited extracellular matrix (ECM). Together, these data support the utility of cell sheet multilayering as a platform for tailoring construct thickness and subsequent MSC chondrogenesis for future articular cartilage regeneration applications.

Published
2021
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6. Terminal cationization of poly(N-isopropylacrylamide) brush surfaces facilitates efficient thermoresponsive control of cell adhesion and detachment

Author

Masamichi Nakayama, Tomonori Kanno, Hironobu Takahashi, Akihiko Kikuchi, Masayuki Yamato, and Teruo Okano

Subjects
word, poly(n-isopropylacrylamide), thermoresponsive surface, polymer brush, terminal cationization, electrostatic interaction, cell adhesion, cell sheet, Materials of engineering and construction. Mechanics of materials, TA401-492, Biotechnology, TP248.13-248.65
Abstract

A variety of poly(N-isopropylacrylamide) (PIPAAm)-grafted surfaces have been reported for temperature-controlled cell adhesion/detachment. However, the surfaces reported to date need further improvement to achieve good outcomes for both cell adhesion and detachment, which are inherently contradictory behaviors. This study investigated the effects of terminal cationization and length of grafted PIPAAm chains on temperature-dependent cell behavior. PIPAAm brushes with three chain lengths were constructed on glass coverslips via surface-initiated reversible addition-fragmentation chain transfer (RAFT) polymerization. Terminal substitution of the grafted PIPAAm chains with either monocationic trimethylammonium or nonionic isopropyl moieties was performed through the reduction of terminal RAFT-related groups and subsequent thiol-ene reaction with the corresponding acrylamide derivatives. Although the thermoresponsive properties of the PIPAAm brush surfaces were scarcely affected by the terminal functional moiety, the zeta potentials of the cationized PIPAAm surfaces were higher than those of the nonionized ones, both below and above the phase transition temperature of PIPAAm (30°C). When bovine endothelial cells were cultured on each surface at 37°C, the number of adherent cells decreased with longer PIPAAm. Notably, cell adhesion on the cationized PIPAAm surfaces was higher than that on the nonionized surfaces. This terminal effect on cell adhesion gradually weakened with increasing PIPAAm length. In particular, long-chain PIPAAm brushes virtually showed cell repellency even at 37°C, regardless of the termini. Interestingly, moderately long-chain PIPAAm brushes promoted cell detachment at 20°C, with negligible terminal electrostatic interruption. Consequently, both cell adhesion and detachment were successfully improved by choosing an appropriate PIPAAm length with terminal cationization.

Published
2021
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7. Safety and efficacy of human juvenile chondrocyte-derived cell sheets for osteochondral defect treatment

Author

Makoto Kondo, Sumako Kameishi, Kyungsook Kim, Nicolas F. Metzler, Travis G. Maak, Douglas T. Hutchinson, Angela A. Wang, Miki Maehara, Masato Sato, David W. Grainger, and Teruo Okano

Subjects
Medicine
Abstract

Abstract Knee cartilage does not regenerate spontaneously after injury, and a gold standard regenerative treatment algorithm has not been established. This study demonstrates preclinical safety and efficacy of scaffold-free, human juvenile cartilage-derived-chondrocyte (JCC) sheets produced from routine surgical discards using thermo-responsive cultureware. JCCs exhibit stable and high growth potential in vitro over passage 10, supporting possibilities for scale-up to mass production for commercialization. JCC sheets contain highly viable, densely packed cells, show no anchorage-independent cell growth, express mesenchymal surface markers, and lack MHC II expression. In nude rat focal osteochondral defect models, stable neocartilage formation was observed at 4 weeks by JCC sheet transplantation without abnormal tissue growth over 24 weeks in contrast to the nontreatment group showing no spontaneous cartilage repair. Regenerated cartilage was safranin-O positive, contained type II collagen, aggrecan, and human vimentin, and lacked type I collagen, indicating that the hyaline-like neocartilage formed originates from transplanted JCC sheets rather than host-derived cells. This study demonstrates the safety of JCC sheets and stable hyaline cartilage formation with engineered JCC sheets utilizing a sustainable tissue supply. Cost-benefit and scaling issues for sheet fabrication and use support feasibility of this JCC sheet strategy in clinical cartilage repair.

Published
2021
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8. 3D cell sheet structure augments mesenchymal stem cell cytokine production

Author

Sophia Bou-Ghannam, Kyungsook Kim, David W. Grainger, and Teruo Okano

Subjects
Medicine, Science
Abstract

Abstract Mesenchymal stem cells (MSCs) secrete paracrine factors that play crucial roles during tissue regeneration. An increasing body of evidence suggests that this paracrine function is enhanced by MSC cultivation in three-dimensional (3D) tissue-like microenvironments. Toward this end, this study explored scaffold-free cell sheet technology as a new 3D platform. MSCs cultivated on temperature-responsive culture dishes to a confluent 2D monolayer were harvested by temperature reduction from 37 to 20 °C that induces a surface wettability transition from hydrophobic to hydrophilic. Release of culture-adherent tension induced spontaneous cell sheet contraction, reducing the diameter 2.4-fold, and increasing the thickness 8.0-fold to render a 3D tissue-like construct with a 36% increase in tissue volume. This 2D-to-3D transition reorganized MSC actin cytoskeleton from aligned to multidirectional, corresponding to a cell morphological change from elongated in 2D monolayers to rounded in 3D cell sheets. 3D culture increased MSC gene expression of cell interaction proteins, β-catenin, integrin β1, and connexin 43, and of pro-tissue regenerative cytokines, vascular endothelial growth factor (VEGF), hepatocyte growth factor (HGF), and interleukin-10 (IL-10), and increased VEGF secretion per MSC 2.1-fold relative to 2D cultures. Together, these findings demonstrate that MSC therapeutic potency can be enhanced by 3D cell sheet tissue structure.

Published
2021
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9. Improvement of the therapeutic capacity of insulin-producing cells trans-differentiated from human liver cells using engineered cell sheet

Author

Yu Na Lee, Hye-Jin Yi, Eun Hye Seo, Jooyun Oh, Song Lee, Sarah Ferber, Teruo Okano, In Kyong Shim, and Song Cheol Kim

Subjects
Liver cell, Insulin-producing cell, Diabetics, Cell sheet, Transplantation, Medicine (General), R5-920, Biochemistry, QD415-436
Abstract

Abstract Background Although pancreatic islet transplantation therapy is ideal for diabetes patients, several hurdles have prevented it from becoming a standard treatment, including donor shortage and low engraftment efficacy. In this study, we prepared insulin-producing cells trans-differentiated from adult human liver cells as a new islet source. Also, cell sheet formation could improve differentiation efficiency and graft survival. Methods Liver cells were expanded in vitro and trans-differentiated to IPCs using adenovirus vectors carrying human genes for PDX1, NEUROD1, and MAFA. IPCs were seeded on temperature-responsive culture dishes to form cell sheets. Differentiation efficiency was confirmed by ß cell-specific gene expression, insulin production, and immunohistochemistry. IPC suspension was injected by portal vein (PV), and IPC sheet was transplanted on the liver surface of the diabetic nude mouse. The therapeutic effect of IPC sheet was evaluated by comparing blood glucose control, weight gain, histological evaluation, and hepatotoxicity with IPC injection group. Also, cell biodistribution was assessed by in vivo/ex vivo fluorescence image tagging. Results Insulin gene expression and protein production were significantly increased on IPC sheets compared with those in IPCs cultured on conventional culture dishes. Transplanted IPC sheets displayed significantly higher engraftment efficiency and fewer transplanted cells in other organs than injected IPCs, and also lower liver toxicity, improved blood glucose levels, and weight gain. Immunohistochemical analyses of liver tissue revealed positive staining for PDX1 and insulin at 1, 2, and 4 weeks after IPC transplantation. Conclusions In conclusion, cell sheet formation enhanced the differentiation function and maturation of IPCs in vitro. Additionally, parameters for clinical application such as distribution, therapeutic efficacy, and toxicity were favorable. The cell sheet technique may be used with IPCs derived from various cell sources in clinical applications.

Published
2021
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10. A stable protocol for the fabrication of transplantable human oral mucosal epithelial cell sheets for clinical application

Author

Yoshiyuki Kasai, Ryo Takagi, Shinichiro Kobayashi, Toshiyuki Owaki, Naoyuki Yamaguchi, Hiroko Fukuda, Yusuke Sakai, Yoshinori Sumita, Nobuo Kanai, Hajime Isomoto, Kengo Kanetaka, Takeshi Ohki, Izumi Asahina, Kazuhiro Nagai, Kazuhiko Nakao, Naoya Takeda, Teruo Okano, Susumu Eguchi, and Masayuki Yamato

Subjects
Primary cell culture, Minimum trypsinization, Epithelial cell sheet, Clinical application, Medicine (General), R5-920, Cytology, QH573-671
Abstract

Introduction: Cultured stratified epithelial cell sheets have been clinically utilized as transplantable grafts for the regeneration of epithelial tissues, such as the esophagus, cornea, skin, and intraoral cavity. These cell sheets are expected to gain widespread use as regenerative medicine products and save many patients. For this purpose, establishing and disseminating the stale protocol of fabricating the cell sheet is crucial. The fabrication of cultured stratified epithelial cell sheets consists of many important steps, and since the patients’ epithelial cell conditions vary widely and are sometimes unstable, the qualities of the epithelial cell grafts are likewise potentially unstable. Therefore, in this paper, we report the stable protocol for fabrication of the transplantable cell sheet particularly from patient-derived oral mucosal tissues. Methods: Serum extracted from blood and buccal mucosal tissue were collected in Nagasaki University and transported to Tokyo Women's Medical University. Oral mucosal epithelial cells were collected by minimum trypsin method, and this treatment was studied whether to be a critical procedure. After 14 days cultivation, cultured cells were examined whether to be transplantable as cell sheets. Results: We successfully transported buccal mucosal tissue and serum without damage and contamination. Oral mucosal epithelial cells were collected with high viability by minimum trypsin method. Finally, we succeeded to stably fabricate oral mucosal epithelial cell sheets in all 10 patients. Conclusions: We established a stable protocol for the fabrication of human oral mucosal epithelial cell sheets and their transportation in clinical settings in this study. These methodologies could also be basis for transplantation therapy using cultured cell sheets of various types other than oral mucosal epithelial cell and will contribute largely to the future development of regenerative medicine.

Published
2020
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11. Interferon-Gamma Primed Human Clonal Mesenchymal Stromal Cell Sheets Exhibit Enhanced Immunosuppressive Function

Author

Celia M. Dunn, Sumako Kameishi, Yun-Kyoung Cho, Sun U. Song, David W. Grainger, and Teruo Okano

Subjects
mesenchymal stem cells, immunomodulation, pre-conditioning, licensing, tissue engineering, cellular therapy, Cytology, QH573-671
Abstract

Mesenchymal stromal cells (MSCs) represent a promising treatment for immune-related diseases due to their diverse immunomodulatory paracrine functions. However, progress of culture-expanded MSCs is hindered by inconsistent cell function, poor localization, and insufficient retention when administered as suspended cell injections, thus placing spatiotemporal dosing constraints on therapeutic functions. To address these limitations, we introduce the combination of in vitro interferon-gamma (IFN-γ) priming, a key stimulator of MSC immunosuppressive potency, and thermoresponsive cultureware to harvest cultured MSCs as directly transplantable scaffold-free immunosuppressive cell sheets. Here, we demonstrate that MSC sheets produced with IFN-γ priming upregulate expression of immunosuppressive factors indoleamine 2,3-dioxygenase (IDO-1), interleukin-10 (IL-10), programmed death ligand-1 (PD-L1), and prostaglandin E2 (PGE2) in both dose- and duration-dependent manners. In addition, IFN-γ primed MSC sheets showed increased ability to inhibit T-cell proliferation via indirect and direct contact, specifically related to increased IDO-1 and PGE2 concentrations. Furthermore, this study’s use of human clinical-grade single-cell-derived clonal bone marrow-derived MSCs, contributes to the future translatability and clinical relevancy of the produced sheets. Ultimately, these results present the combination of IFN-γ priming and MSC sheets as a new strategy to improve MSC-mediated treatment of localized inflammatory diseases.

Published
2022
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13. Phenotypic traits of mesenchymal stem cell sheets fabricated by temperature-responsive cell culture plate: structural characteristics of MSC sheets

Author

Mitsuyoshi Nakao, Kyungsook Kim, Kenichi Nagase, David W. Grainger, Hideko Kanazawa, and Teruo Okano

Subjects
Medicine (General), R5-920, Biochemistry, QD415-436
Abstract

Abstract Background In most stem cell therapy strategies reported to date, stem cells are introduced to damaged tissue sites to repair and regenerate the original tissue structure and function. MSC therapeutic efficacies are inconsistent, largely attributed to transplanted MSC difficulties both in engrafting at tissue sites and in retaining their therapeutic functions from suspension formulations. MSC functional components, including cell adhesion and cell–cell junction proteins, and ECM that contribute to essential cellular therapeutic effects, are damaged or removed by proteolytic enzymes used in stem cell harvesting strategies from culture. To overcome these limitations, methods to harvest and transplant cells without disrupting critical stem cell functions are required. Cell sheet technology, exploiting temperature-responsive cell culture surfaces, permits cell harvest without cell protein damage. This study is focused on phenotypic traits of MSC sheets structurally and functionally to understand therapeutic benefits of cell sheets. Methods/results This study verified cleaved cellular proteins (vinculin, fibronectin, laminin, integrin β-1, and connexin 43) and increased apoptotic cell death produced under standard trypsin harvesting treatment in a time-dependent manner. However, MSC sheets produced without trypsin using only temperature-controlled sheet harvest from culture plastic exhibited intact cellular structures. Also, MSCs harvested using enzymatic treatment (i.e., chemical disruption) showed higher pYAP expression compared to MSC sheets. Conclusion Retention of cellular structures such as ECM, cell–cell junctions, and cell–ECM junctions is correlated with human umbilical cord mesenchymal stem cell (hUC-MSC) survival after detachment from cell culture surfaces. Retaining these proteins intact in MSC cultures using cell sheet technology is proposed to enhance stem cell survival and their function in stem cell-based therapy.

Published
2019
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14. Allogeneic multipotent mesenchymal stromal cell sheet transplantation promotes healthy healing of wounds caused by zoledronate and dexamethasone in canine mandibular bones

Author

Nobuyuki Kaibuchi, Takanori Iwata, Satoru Onizuka, Kosei Yano, Yuka Tsumanuma, Masayuki Yamato, Teruo Okano, and Tomohiro Ando

Subjects
Medicine (General), R5-920, Cytology, QH573-671
Abstract

Introduction: Many cases of bisphosphonate-related osteonecrosis of the jaw (BRONJ), which is an intractable disease, have been reported. Although a general intravenous injection of multipotent mesenchymal stromal cells (MSCs) may be effective for treating BRONJ, it has some severe problems. Therefore, our aim was to develop a treatment of locally administered MSCs. In this study, we investigated the effect of MSC sheet transplantation in the mandibular bone healing in beagle dogs, which were administered zoledronate and dexamethasone. Methods: MSCs isolated from subcutaneous fat were seeded onto temperature-responsive culture dishes to produce MSC sheets. Zoledronate and dexamethasone were administered to beagle dogs. Then, the parts of mandibular cortical bones were removed, and MSC sheets were transplanted to cover those bone defects (MSC sheet transplant side) or not (Control side). The specimens were evaluated in micro CT, histology, and immunohistochemistry. Results: Four weeks after surgery, redness and swellings were observed in the mucosal wounds of the control sides of 2 of 3 dogs. In contrast, the mucosal wounds of the MSC sheet transplant sides of all dogs completely healed. Histological images showed some free sequestrums and many bacterial colonies, and Immunohistological analysis showed some cathepsin K-positive multinuclear cells detached from jaw bone surfaces in the control sides. Conclusions: MSC sheet transplantation promotes healthy healing of wounds caused by zoledronate and dexamethasone in canine mandibular bones. And the injured canine mandibular bones administered zoledronate and dexamethasone showed BRONJ-like findings. Keywords: Osteonecrosis of the jaw, Bisphosphonate, Multipotent mesenchymal stromal cells, Cell sheet, Beagle dogs, Regenerative therapy

Published
2019
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15. Mesenchymal Stem Cell Sheet Centrifuge-Assisted Layering Augments Pro-Regenerative Cytokine Production

Author

Sophia Bou-Ghannam, Kyungsook Kim, Makoto Kondo, David W. Grainger, and Teruo Okano

Subjects
three-dimensional tissue, scaffold-free tissue, cell therapy, tissue engineering, regenerative medicine, Cytology, QH573-671
Abstract

A focal advantage of cell sheet technology has been as a scaffold-free three-dimensional (3D) cell delivery platform capable of sustained cell engraftment, survival, and reparative function. Recent evidence demonstrates that the intrinsic cell sheet 3D tissue-like microenvironment stimulates mesenchymal stem cell (MSC) paracrine factor production. In this capacity, cell sheets not only function as 3D cell delivery platforms, but also prime MSC therapeutic paracrine capacity. This study introduces a “cell sheet multilayering by centrifugation” strategy to non-invasively augment MSC paracrine factor production. Cell sheets fabricated by temperature-mediated harvest were first centrifuged as single layers using optimized conditions of rotational speed and time. Centrifugation enhanced cell physical and biochemical interactions related to intercellular communication and matrix interactions within the single cell sheet, upregulating MSC gene expression of connexin 43, integrin β1, and laminin α5. Single cell sheet centrifugation triggered MSC functional enhancement, secreting higher concentrations of pro-regenerative cytokines vascular endothelial growth factor (VEGF), hepatocyte growth factor (HGF), and interleukin-10 (IL-10). Subsequent cell sheet stacking, and centrifugation generated cohesive, bilayer MSC sheets within 2 h, which could not be accomplished within 24 h by conventional layering methods. Conventional layering led to H1F-1α upregulation and increased cell death, indicating a hypoxic thickness limitation to this approach. Comparing centrifuged single and bilayer cell sheets revealed that layering increased VEGF production 10-fold, attributed to intercellular interactions at the layered sheet interface. The “MSC sheet multilayering by centrifugation” strategy described herein generates a 3D MSC-delivery platform with boosted therapeutic factor production capacity.

Published
2022
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17. Periodontal regeneration with autologous periodontal ligament-derived cell sheets – A safety and efficacy study in ten patients

Author

Takanori Iwata, Masayuki Yamato, Kaoru Washio, Toshiyuki Yoshida, Yuka Tsumanuma, Azusa Yamada, Satoru Onizuka, Yuichi Izumi, Tomohiro Ando, Teruo Okano, and Isao Ishikawa

Subjects
Medicine (General), R5-920, Cytology, QH573-671
Abstract

Background: Periodontitis results in the destruction of tooth-supporting periodontal tissues and does not have the ability to heal spontaneously. Various approaches have been introduced to regenerate periodontal tissues; however, these approaches have limited efficacy for treating severe defects. Cytotherapies combine stem cell biology and tissue engineering to form a promising approach for overcoming these limitations. In this study, we isolated periodontal ligament (PDL)-derived cells from patients and created cell sheets with “Cell Sheet Engineering Technology”, using temperature responsive culture dishes, in which all the cultured cells can be harvested as an intact transplantable cell sheet by reducing the temperature of the culture dish. Subsequently, the safety and efficacy of autologous PDL-derived cell sheets were evaluated in a clinical setting. Methods: A single-arm and single-institute clinical study was performed to verify the safety and efficacy of autologous PDL-derived cell sheets in patients with periodontitis. Wisdom teeth were extracted from patients diagnosed with chronic periodontitis, ranging in age from 33 to 63 years (mean [±SD], 46 ± 12), and periodontal tissues were scraped for cell sources. Three-layered PDL-derived cell sheets were constructed using temperature-responsive culture dishes and transplanted in an autologous fashion following standard flap surgeries. Bony defects were filled with beta-tricalcium phosphate granules. Clinical variables were evaluated at baseline, 3 months, and 6 months. Cone-beam computed tomography was performed at baseline and 6 months. Additionally, mid-long-term follow-up has been performed with patients’ agreements. Results: Our method was found to be safe and no severe adverse events were identified. All the findings, including reduction of periodontal probing depth (mean ± SD, 3.2 ± 1.9 mm), clinical attachment gain (2.5 ± 2.6 mm), and increase of radiographic bone height (2.3 ± 1.8 mm), were improved in all 10 cases at 6 months after the transplantation. These therapeutic effects were sustained during a mean follow-up period of 55 ± 19 months, and there were no serious adverse events. Conclusions: The results of this study validate the safety and efficacy of autologous PDL-derived cell sheets in severe periodontal defects, and the stability of this efficacy during mid-long-term follow up. This cytotherapeutic approach, based on cell sheet engineering, offers an innovative strategy to treat the recognized unmet need of treating severe periodontal defects. Keywords: Periodontal regeneration, Cytotherapy, Cell sheet, Clinical study, Multipotent mesenchymal stromal cells (MSCs), Periodontal ligament, Cone-beam computed tomography (CBCT), Stem cells

Published
2018
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18. A novel, flexible and automated manufacturing facility for cell-based health care products: Tissue Factory

Author

Tetsutaro Kikuchi, Masahiro Kino-oka, Masanori Wada, Toyoshige Kobayashi, Midori Kato, Shizu Takeda, Hirotsugu Kubo, Tetsuya Ogawa, Hironobu Sunayama, Kazuhito Tanimoto, Manabu Mizutani, Tatsuya Shimizu, and Teruo Okano

Subjects
Medicine (General), R5-920, Cytology, QH573-671
Abstract

Introduction: Current production facilities for Cell-Based Health care Products (CBHPs), also referred as Advanced-Therapy Medicinal Products or Regenerative Medicine Products, are still dependent on manual work performed by skilled workers. A more robust, safer and efficient manufacturing system will be necessary to meet the expected expansion of this industrial field in the future. Thus, the ‘flexible Modular Platform (fMP)’ was newly designed to be a true “factory” utilizing the state-of-the-art technology to replace conventional “laboratory-like” manufacturing methods. Then, we built the Tissue Factory as the first actual entity of the fMP. Methods: The Tissue Factory was designed based on the fMP in which several automated modules are combined to perform various culture processes. Each module has a biologically sealed chamber that can be decontaminated by hydrogen peroxide. The asepticity of the processing environment was tested according to a pharmaceutical sterility method. Then, three procedures, production of multi-layered skeletal myoblast sheets, expansion of human articular chondrocytes and passage culture of human induced pluripotent stem cells, were conducted by the system to confirm its ability to manufacture CHBPs. Results: Falling or adhered microorganisms were not detected either just after decontamination or during the cell culture processes. In cell culture tests, multi-layered skeletal myoblast sheets were successfully manufactured using the method optimized for automatic processing. In addition, human articular chondrocytes and human induced-pluripotent stem cells could be propagated through three passages by the system at a yield comparable to manual operations. Conclusions: The Tissue Factory, based on the fMP, successfully reproduced three tentative manufacturing processes of CBHPs without any microbial contamination. The platform will improve the manufacturability in terms of lower production cost, improved quality variance and reduced contamination risks. Moreover, its flexibility has the potential to adapt to the modern challenges in the business environment including employment issues, low operational rates, and relocation of facilities. The fMP is expected to become the standard design basis of future manufacturing facilities for CBHPs. Keywords: Regenerative medicine, Automation, Cell processing facility, Manufacturing, Decontamination

Published
2018
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19. Engineered Human Contractile Myofiber Sheets as a Platform for Studies of Skeletal Muscle Physiology

Author

Hironobu Takahashi, Tatsuya Shimizu, and Teruo Okano

Subjects
Myofibers, Contractile Ability, Native Muscle Tissue, Tissue Model, Pulse Electrical Stimulation (EPS), Medicine, Science
Abstract

Abstract Skeletal muscle physiology and the mechanisms of muscle diseases can be effectively studied by an in-vitro tissue model produced by muscle tissue engineering. Engineered human cell-based tissues are required more than ever because of the advantages they bring as tissue models in research studies. This study reports on a production method of a human skeletal myofiber sheet that demonstrates biomimetic properties including the aligned structure of myofibers, basement membrane-like structure of the extracellular matrix, and unidirectional contractile ability. The contractile ability and drug responsibility shown in this study indicate that this engineered muscle tissue has potential as a human cell-based tissue model for clinically relevant in-vitro studies in muscle physiology and drug discovery. Moreover, this engineered tissue can be used to better understand the relationships between mechanical stress and myogenesis, including muscle growth and regeneration. In this study, periodic exercise induced by continuous electrical pulse stimulation enhanced the contractile ability of the engineered myofibers and the secretion of interleukin-6 (IL-6) and vascular endothelial growth factor (VEGF) from the exercising myofibers. Since the physiology of skeletal muscle is directly related to mechanical stress, these features point to application as a tissue model and platform for future biological studies of skeletal muscle including muscle metabolism, muscle atrophy and muscle regeneration.

Published
2018
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20. The liver surface as a favorable site for islet cell sheet transplantation in type 1 diabetes model mice

Author

Izumi Fujita, Rie Utoh, Masakazu Yamamoto, Teruo Okano, and Masayuki Yamato

Subjects
Medicine (General), R5-920, Cytology, QH573-671
Abstract

Introduction: Islet transplantation is one of the most promising therapeutic approaches for patients with severe type 1 diabetes mellitus (T1DM). Transplantation of engineered islet cell sheets holds great potential for treating T1DM as it enables the creation of stable neo-islet tissues. However, a large mass of islet cell sheets is required for the subcutaneous transplantation to reverse hyperglycemia in diabetic mice. Here, we investigated whether the liver surface could serve as an alternative site for islet cell sheet transplantation. Methods: Dispersed rat islet cells (0.8 × 106 cells) were cultured on laminin-332-coated thermoresponsive culture dishes. After 2 days of cultivation, we harvested the islet cell sheets by lowering the culture temperature using a support membrane with a gelatin gel. We transplanted two recovered islet cell sheets into the subcutaneous space or onto the liver surface of severe combined immunodeficiency (SCID) mice with streptozocin-induced diabetes. Results: In the liver surface group, the non-fasting blood glucose level decreased rapidly within several days after transplantation. In marked contrast, the hyperglycemia state was maintained in the subcutaneous space transplantation group. The levels of rat C-peptide and insulin in the liver surface group were significantly higher than those in the subcutaneous space group. An immunohistological analysis confirmed that most of the islet cells engrafted on the liver surface were insulin-positive. The CD31-positive endothelial cells formed vascular networks within the neo-islets and in the surrounding tissues. In contrast, viable islet cells were not found in the subcutaneous space group. Conclusions: Compared with the subcutaneous space, a relatively small mass of islet cell sheets was enough to achieve normoglycemia in diabetic mice when the liver surface was selected as the transplantation site. Our results demonstrate that the optimization of the transplantation site for islet cell sheets leads to significant improvements in the therapeutic efficiency for T1DM. Keywords: Cell sheet, Islet cells, Type 1 diabetes mellitus, Transplantation site, Cellular therapy

Published
2018
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24. Autologous adipose-derived stem cell sheets enhance the strength of intestinal anastomosis

Author

Yasuhiro Maruya, Nobuo Kanai, Shinichiro Kobayashi, Kurodo Koshino, Teruo Okano, Susumu Eguchi, and Masayuki Yamato

Subjects
Adipose-derived stem cells, Prevent anastomotic leakage, Medicine (General), R5-920, Cytology, QH573-671
Abstract

Objective: Adipose-derived stem cells (ASCs) are capable of multiple differentiation pathways, imparting immunomodulatory effects, and secreting factors that are important for wound healing. These characteristics can be exploited to decrease the incidence of anastomotic leakage. Methods: In order to delay local wound healing at the anastomotic site, we induced ischemia in a portion of porcine small intestine by ligating vessels. Then, we injected mitomycin C into the serosa of the small intestine above the ligated vessels. Anastomotic sites were created by 2 cm incisions made in the opposite mesenteric area. ASCs were isolated from the porcine subcutaneous fat tissues and expanded under culture conditions. ASCs were trypsinized and seeded on temperature-responsive dishes and cultured to form confluent sheets. Three ASC sheets were transplanted onto the serous membrane after suturing. The extent of anastomotic wound healing was evaluated by bursting pressure, hydroxyproline content, and mRNA expression of collagen-1 alpha1 and collagen-3 alpha1. Results: We found that transplantation of ASC sheets increased anastomotic site bursting pressure. Additionally, transplantation of ASC sheets increased the hydroxyproline content of the anastomoses. Furthermore, transplantation of ASC sheets increased mRNA expression of collagen-1 alpha1 and collagen-3 alpha1. Conclusions: Our findings showed that transplantation of autologous ASC sheets enhanced collagen synthesis and anastomotic strength. Further studies are necessary to identify substances that, in combination with ASC sheets, might enhance collagen synthesis and healing in sites of anastomosis.

Published
2017
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25. The role of Tsukushi (TSK), a small leucine-rich repeat proteoglycan, in bone growth

Author

Kosei Yano, Kaoru Washio, Yuka Tsumanuma, Masayuki Yamato, Kunimasa Ohta, Teruo Okano, and Yuichi Izumi

Subjects
Tsukushi, SLRPs, Skeletal development, Endochondral ossification, Growth plate, Chondrocyte, Medicine (General), R5-920, Cytology, QH573-671
Abstract

Introduction: Endochondral ossification is one of a key process for bone maturation. Tsukushi (TSK) is a novel member of the secreted small leucine-rich repeat proteoglycan (SLRP) family. SLRPs localize to skeletal regions and play significant roles during whole phases of bone development. Although prior evidence suggests that TSK may be involved in the regulation of bone formation, its role in skeletal development has not yet been elucidated. Methods: In the present study, we examined TSK's function during bone growth by comparing skeletal growth of TSK deficient (TSK−/−) mice and wild type (WT) mice. And an in vitro experiment using siRNA transfection of a chondrogenic cell line was performed. Results: TSK−/− mice exhibited decreased weight and short stature at 3 weeks of age due to decreased longitudinal bone growth coupled with low bone mass. Furthermore, an in vitro experiment using siRNA transfection into a chondrogenic cell line revealed that decreased TSK expression induced down-regulation of key chondrogenic marker gene expression and up-regulation of mid-to-late chondrogenic markers gene expression. Conclusions: Our results reveal that TSK regulates bone elongation and bone mass by modulating growth plate chondrocyte function and consequently, overall body size.

Published
2017
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26. Enhanced Therapeutic Effects of Human iPS Cell Derived-Cardiomyocyte by Combined Cell-Sheets with Omental Flap Technique in Porcine Ischemic Cardiomyopathy Model

Author

Masashi Kawamura, Shigeru Miyagawa, Satsuki Fukushima, Atsuhiro Saito, Kenji Miki, Shunsuke Funakoshi, Yoshinori Yoshida, Shinya Yamanaka, Tatsuya Shimizu, Teruo Okano, Takashi Daimon, Koichi Toda, and Yoshiki Sawa

Subjects
Medicine, Science
Abstract

Abstract Transplant of human induced pluripotent stem cell derived cardiomyocytes (hiPS-CMs) cell-sheet is a promising approach for treating ischemic cardiomyopathy (ICM). However, poor blood supply to the transplanted cell-sheet is a concern related to the effectiveness and durability of the treatment. Herein, we hypothesized that the combined the omentum flap might enhance survival and the therapeutic effects of hiPS-CM cell-sheet transplant for ICM treatment. Treatment by Wnt signaling molecules in hiPS cells produced hiPS-CMs, which were magnetically labeled by superparamagnetic iron oxide (SPIO), followed by culture in the thermoresponsive dishes to generate hiPS-CMs cell-sheets. A porcine ICM model included 4 groups; sham operation, omentum flap only, cell-sheet only, or combination therapy. Ejection fraction (EF) was significantly greater in the cell-sheet only and combination group compared to the other groups during the follow-up period. At 3 months, the EF of the combination group was significantly greater than that of the cell-sheet only group. Consistently, the survival rate of the SPIO-labeled hiPS-CMs, as assessed by MRI, was significantly greater in the combination group than in the cell-sheet only group. This cell delivery system would be useful in optimizing the hiPS-CM cell-sheet transplant for treating severe heart failure.

Published
2017
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27. Bio-implant as a novel restoration for tooth loss

Author

Dong-Joon Lee, Jong-Min Lee, Eun-Jung Kim, Takashi Takata, Yoshihiro Abiko, Teruo Okano, David W. Green, Masaki Shimono, and Han-Sung Jung

Subjects
Medicine, Science
Abstract

Abstract A dental implant is used to replace a missing tooth. Fixing the implant in its natural position requires the engineering of a substantial amount of conformal bone growth inside the implant socket, osseointegration. However, this conventional implant attachment does not include the periodontal ligament (PDL), which has a fundamental role in cushioning high mechanical loads. As a result, tooth implants have a shorter lifetime than the natural tooth and have a high chance of infections. We have engineered a “bio-implant” that provides a living PDL connection for titanium implants. The bio-implant consists of a hydroxyapatite coated titanium screw, ensheathed in cell sheets made from immortalized human periodontal cells. Bio-implants were transplanted into the upper first molar region of a tooth-extraction mouse model. Within 8 weeks the bio-implant generated fibrous connective tissue, a localised blood vessel network and new bone growth fused into the alveolar bone socket. The study presents a bio-implant engineered with human cells, specialised for the root connection, and resulted in the partial reconstruction of a naturalised tooth attachment complex (periodontium), consisting of all the principal tissue types, cementum, PDL and alveolar bone.

Published
2017
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28. Xenogeneic transplantation of human adipose-derived stem cell sheets accelerate angiogenesis and the healing of skin wounds in a Zucker Diabetic Fatty rat model of obese diabetes

Author

Mariko Hamada, Takanori Iwata, Yuka Kato, Kaoru Washio, Shunichi Morikawa, Hiroyuki Sakurai, Masayuki Yamato, Teruo Okano, and Yasuko Uchigata

Subjects
Diabetic foot ulcers, Adipose-derived stem cell, Cell sheet, Wound healing, Xenogeneic transplantation, Medicine (General), R5-920, Cytology, QH573-671
Abstract

Introduction: Diabetic patients with foot ulcers often suffer impaired wound healing due to diabetic neuropathy and blood flow disturbances. Direct injection of human adipose-derived stem cells (hASCs) effectively accelerates wound healing, although hASCs are relatively unstable. Methods: We developed an optimized protocol to engineer hASC sheets using temperature-responsive culture dishes to enhance the function and stability of transplanted cells used for regenerative medicine. Here, we evaluated the efficacy of hASC sheets for enhancing wound healing. For this purpose, we used a xenogeneic model of obese type 2 diabetes, the Zucker Diabetic Fatty rat (ZDF rat), which displays full-thickness skin defects. We isolated hASCs from five donors, created hASC sheets, and transplanted the hASC sheets along with artificial skin into full-thickness, large skin defects (15-mm diameter) of ZDF rats. Results: The hASC sheets secreted angiogenic growth factors. Transplantation of the hASC sheets combined with artificial skin increased blood vessel density and dermal thickness, thus accelerating wound healing compared with that in the controls. Immunohistochemical analysis revealed significantly more frequent neovascularization in xenografted rats of the transplantation group, and the transplanted hASCs were localized to the periphery of new blood vessels. Conclusion: This xenograft model may contribute to the use of human cell tissue-based products (hCTPs) and the identification of factors produced by hCTPs that accelerate wound healing.

Published
2017
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29. Cytological character of mini pig mesenchymal stromal cells from various tissues and the attempt of cell sheet formation

Author

Nobuyuki Kaibuchi, Takanori Iwata, Satoru Onizuka, Kosei Yano, Masayuki Yamato, Teruo Okano, and Tomohiro Ando

Subjects
Multipotent mesenchymal stromal cells, Cell sheet, Mini pigs, Regenerative therapy, Medicine (General), R5-920, Cytology, QH573-671
Abstract

Introduction: Large animal experiments are important for translational research in regenerative medicine. Recently, mini pigs have been used in large animal studies and surgical training. The use of multipotent mesenchymal stromal cell (MSC) sheets for the treatment of many diseases is increasing. The purpose of the present study was to establish optimal methods for generating mini pig MSC sheets from various tissues and to compare the properties of MSCs in these sheets. Methods: MSCs were isolated from the bone marrow, adipose, periodontal ligament, gingiva, or periosteum of mini pigs. The proliferation, markers, and mRNA expression of these MSCs were examined. Colony-forming and differentiation assays were performed. MSCs were seeded onto temperature-responsive culture dishes to develop MSC sheets. Results: MSCs derived from bone marrow (BMSCs), adipose (ASCs), periodontal ligament (PDLCs), gingiva (GMSCs), and periosteum (PSCs) were positive for MSC-related markers. BMSCs and PSCs showed increased proliferation compared with other MSCs. The osteogenic potential of PDLCs and the adipogenic potential of PSCs were the highest among these MSCs. The expression levels of COL1A1 and COL3A1 in BMSCs and PSCs were significantly higher than those in other MSCs. The expression levels of FGF2, VEGFA, ICAM-1, and TIE-1 in GMSCs were significantly higher than those in other MSCs. PSCs showed the highest levels of TGF-β1 and ANG-1 expression among all MSC types. We succeeded in developing MSC sheets from BMSCs, ASCs, and PSCs. Conclusions: We developed methods to generate MSC sheets from various tissues of mini pigs, and these methods are useful to pursue regenerative translational research using mini pigs.

Published
2017
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30. Middle ear mucosal regeneration by tissue-engineered cell sheet transplantation

Author

Kazuhisa Yamamoto, Masayuki Yamato, Tsunetaro Morino, Hiroaki Sugiyama, Ryo Takagi, Yuichiro Yaguchi, Teruo Okano, and Hiromi Kojima

Subjects
Medicine
Abstract

Nose tissue that helps the ear heal Transplanting a sheet of cells from the nose to the middle ear could improve postoperative prognosis for middle ear inflammatory conditions. Kazuhisa Yamamoto of Jikei University School of Medicine and colleagues in Japan developed a novel surgical technique to prevent postoperative recurrence of chronic middle ear conditions. In adhesive otitis media, the eardrum gets sucked into and stuck in the middle ear space. Cholesteatoma involves abnormal skin growth in the middle ear. Recurrence often follows surgical treatment for these conditions due to delays in regeneration of the middle ear’s mucosal epithelium. The new technique involves transplanting cultured cells from the lining of the nasal cavity to the middle ear during surgery. Five patients treated this way had favorable postoperative outcomes with no adverse effects or complications and satisfactory improvement in hearing levels.

Published
2017
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32. Cell source-derived variabilities in human juvenile chondrocyte-derived cell sheet cartilage regenerative effects in a nude rat chondral defect implantation model

Author

Keisuke Matsukura, Makoto Kondo, Nicolas Metzler, Adam Ford, Travis Maak, Douglas Hutchinson, Angela Wang, Masato Sato, David Grainger, and Teruo Okano

Abstract

BackgroundScaffold-free cell-dense implants, termed “cell sheets”, are routinely fabricated using temperature-responsive commercial cell culture surfaces. In vivo regenerative capacity of human juvenile cartilage-derived chondrocyte (JCC) sheets is reported in both human clinical studies and nude rat defect models. How human cell source variables affect sheet tissue regeneration remains unelucidated.PurposeTo evaluate the variation of detailed histological neo-cartilage outcomes in an established rat defect model treated with human JCC sheets fabricated from various donors and different JCC passages.Study DesignDescriptive laboratory study.MethodsJCCs were isolated from 8 amputated human polydactylous digits. Passage 2 (P2) JCC sheets from all donors and P9 JCC sheets from one donor were transplanted into nude rat chondral defects for 4 weeks. Defect-only group served as control. Histological samples were stained for safranin-O, collagen 1 (COL1), and collagen 2 (COL2). Modified O’Driscoll scores, %COL1 and %COL2 areas, and COL2/1 ratios were applied for histological semi-quantitative evaluations. (1) All samples were scored and correlation coefficients for each score calculated. (2) Donors treated with P2 JCC sheets were divided into “more effective” and “less effective” groups based on these scores. Then, differences between each group in each category of modified O’Driscoll scoring were evaluated. (3) Scores of P2 and P9 samples from the same JCC donor were compared.Results(1) Mean modified O’Driscoll score, IHC %COL1 and COL2 areas, and COL2/1 ratio was 20.7±3.8, 37.9±27.5, 63.1±30.1, and 3.9±4.0, respectively. Modified O’Driscoll scores were negatively correlated with %COL1 area, and positively correlated with %COL2 area and COL2/1 ratio. (2) Four of 8 donors exhibited significantly higher modified O’Driscoll scores and %COL2 areas compared to the defect-only control group. JCC donors were divided into two groups by average score values: groups 3, 4, 6, and 7 (group ‘more effective’) and groups 1, 2, 5, and 8 (group less effective’). Significant differences between the two groups were observed in Modified O’Driscoll categories of “Nature of predominant”, “Reconstruction of subchondral bone”, and “Safranin-O staining”. (3) Modified O’Driscoll scores and COL2/1 ratio for JCC P2 were significantly higher than that from P9.ConclusionThe combined histological evaluation method employed is useful for detailedin vivoefficacy assessments of cartilage defect regeneration models. The analysis demonstrated that regenerative effects with JCC sheets varied both by JCC donor and passage number. Variations in histological evaluations among JCC donors were correlated to the quality of regenerated cartilage hyaline structure and subchondral bone remodeling observed in the nude rat defect model.Clinical RelevanceThis study provides a useful screening and prediction algorithm for cartilage regenerative success from human cell-derived implants in a rodent defect model.What is known about the subjectHuman juvenile cartilage-derived chondrocyte (JCC) sheets have shown safety and cartilage regenerative capacity in both nude rat chondral defects and a recent limited allogenic human clinical research study. Allogenic cell source variability is known to affect cell-based cartilage regeneration outcomes. Few predictive correlates exist to predict cell source regenerative success. Both Passage 2 (P2) and Passage 9 (P9) JCC-derived chondrogenic pellets exhibit strong characteristic safranin-O staining, but cultured P9 cultured pellet size is smaller than that of P2 pellets.What this study adds to existing knowledgeCartilage regenerative effects vary highly with banked cell source. Current cartilage regenerative strategies in preclinical models do not predict human performance and are clinically unreliable; few off-the-shelf, scalable “living” options are available. Cartilage regeneration using banked human JCC sheets represents a scalable, allogenic, scaffold-free approach now successfully tested both in nude rat and human chondral defects. This study shows that histological evaluation of sheets from several JCC donor demonstrated variable regenerated cartilage hyaline structure and subchondral bone remodeling in a nude rat across donor and passage. Tools to better predict cell-based cartilage regenerative reliability by screening banked allogenic human cell sources in a rat model are described.

Published
2023
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34. Trends in Articular Cartilage Tissue Engineering: 3D Mesenchymal Stem Cell Sheets as Candidates for Engineered Hyaline-Like Cartilage

Author

Hallie Thorp, Kyungsook Kim, Makoto Kondo, Travis Maak, David W. Grainger, and Teruo Okano

Subjects
chondrogenesis, chondral defects, differentiation, cellular interactions, adhesion, transplantation, Cytology, QH573-671
Abstract

Articular cartilage defects represent an inciting factor for future osteoarthritis (OA) and degenerative joint disease progression. Despite multiple clinically available therapies that succeed in providing short term pain reduction and restoration of limited mobility, current treatments do not reliably regenerate native hyaline cartilage or halt cartilage degeneration at these defect sites. Novel therapeutics aimed at addressing limitations of current clinical cartilage regeneration therapies increasingly focus on allogeneic cells, specifically mesenchymal stem cells (MSCs), as potent, banked, and available cell sources that express chondrogenic lineage commitment capabilities. Innovative tissue engineering approaches employing allogeneic MSCs aim to develop three-dimensional (3D), chondrogenically differentiated constructs for direct and immediate replacement of hyaline cartilage, improve local site tissue integration, and optimize treatment outcomes. Among emerging tissue engineering technologies, advancements in cell sheet tissue engineering offer promising capabilities for achieving both in vitro hyaline-like differentiation and effective transplantation, based on controlled 3D cellular interactions and retained cellular adhesion molecules. This review focuses on 3D MSC-based tissue engineering approaches for fabricating “ready-to-use” hyaline-like cartilage constructs for future rapid in vivo regenerative cartilage therapies. We highlight current approaches and future directions regarding development of MSC-derived cartilage therapies, emphasizing cell sheet tissue engineering, with specific focus on regulating 3D cellular interactions for controlled chondrogenic differentiation and post-differentiation transplantation capabilities.

Published
2021
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35. A heparin-modified thermoresponsive surface with heparin-binding epidermal growth factor-like growth factor for maintaining hepatic functions in vitro and harvesting hepatocyte sheets

Author

Yoshinori Arisaka, Jun Kobayashi, Kazuo Ohashi, Kohei Tatsumi, Kyungsook Kim, Yoshikatsu Akiyama, Masayuki Yamato, and Teruo Okano

Subjects
Poly(N-isopropylacrylamide), Thermoresponsive cell culture surface, Heparin, Heparin-binding EGF-like growth factor, Hepatocyte sheet, Medicine (General), R5-920, Cytology, QH573-671
Abstract

A heparin-modified thermoresponsive surface bound with heparin-binding epidermal growth factor-like growth factor (HB-EGF) was designed to allow creation of transferrable and functional hepatocyte sheets. A heparin-modified thermoresponsive surface was prepared by covalently tethering heparin onto poly(N-isopropylacrylamide-co-2-carboxyisopropylacrylamide)-grafted tissue culture polystyrene surfaces (Heparin-IC). HB-EGFs were able to stably bind to heparin-IC via affinity interaction. The survival of primary rat hepatocytes was maintained through HB-EGF-bound heparin-IC (HB-EGF/heparin-IC). Moreover, cultured rat primary hepatocytes on HB-EGF/heparin-IC exhibited higher albumin-secretion than hepatocytes cultured on PIPAAm-grafted and collagen-coated surfaces with soluble HB-EGF in the culture medium, regardless of whether soluble EGF was added. These results suggested that HB-EGF/heparin-IC is able to effectively maintain hepatic function via continuous signaling of HB-EGF. After a 4-day cultivation, the cultured hepatocytes on HB-EGF/heparin-IC detached as a cell sheet with fibronectin and HB-EGF only after the temperature was lowered to 20 °C. In addition, higher expression of hepatocyte-specific genes (albumin, hepatocyte nuclear factor 4 alpha, coagulation factor VII, and coagulation factor IX) in hepatocyte sheets was detected on HB-EGF/heparin-IC than on a PIPAAm surface with soluble HB-EGF, indicating that HB-EGF/heparin-IC suppressed the dedifferentiation of cultured hepatocytes. Hence, heparin-modified thermoresponsive surfaces bound with HB-EGF facilitate the fabrication of transferrable hepatocyte sheets with intact hepatic functions and have the potential to provide an in vitro culture system using functional hepatocyte sheet tissues, which may serve as an effective hepatocyte-based tissue engineering platform for liver disease treatments.

Published
2016
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38. Engineered Bone Marrow Stem Cell-Sheets Alleviate Renal Damage in a Rat Chronic Glomerulonephritis Model

Author

Bin Wang, Kyungsook Kim, Mi Tian, Sumako Kameishi, Lili Zhuang, Teruo Okano, and Yufeng Huang

Subjects
Inorganic Chemistry, MSC, regenerative therapy, Organic Chemistry, cell sheet, General Medicine, Physical and Theoretical Chemistry, Molecular Biology, Spectroscopy, Catalysis, chronic kidney disease, Computer Science Applications
Abstract

Although mesenchymal stem cell (MSC)-based regenerative therapy is being developed for the treatment of kidney diseases, cell delivery and engraftment still need to be improved. Cell sheet technology has been developed as a new cell delivery method, to recover cells as a sheet form retaining intrinsic cell adhesion proteins, which promotes its transplantation efficiency to the target tissue. We thus hypothesized that MSC sheets would therapeutically reduce kidney disease with high transplantation efficiency. When the chronic glomerulonephritis was induced by two injections of the anti-Thy 1.1 antibody (OX-7) in rats, the therapeutic efficacy of rat bone marrow stem cell (rBMSC) sheet transplantation was evaluated. The rBMSC-sheets were prepared using the temperature-responsive cell-culture surfaces and transplanted as patches onto the surface of two kidneys of each rat at 24 h after the first injection of OX-7. At 4 weeks, retention of the transplanted MSC-sheets was confirmed, and the animals with MSC-sheets showed significant reductions in proteinuria, glomerular staining for extracellular matrix protein, and renal production of TGFß1, PAI-1, collagen I, and fibronectin. The treatment also ameliorated podocyte and renal tubular injury, as evidenced by a reversal in the reductions of WT-1, podocin, and nephrin and by renal overexpression of KIM-1 and NGAL. Furthermore, the treatment enhanced gene expression of regenerative factors, and IL-10, Bcl-2, and HO-1 mRNA levels, but reduced TSP-1 levels, NF-kB, and NAPDH oxidase production in the kidney. These results strongly support our hypothesis that MSC-sheets facilitated MSC transplantation and function, and effectively retarded progressive renal fibrosis via paracrine actions on anti-cellular inflammation, oxidative stress, and apoptosis and promoted regeneration.

Published
2023
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39. Cell Sheets Restore Secretory Function in Wounded Mouse Submandibular Glands

Author

Harim T. dos Santos, Kyungsook Kim, Teruo Okano, Jean M. Camden, Gary A. Weisman, Olga J. Baker, and Kihoon Nam

Subjects
cell sheet, extracellular matrix, hyposalivation, regeneration, wound healing, Cytology, QH573-671
Abstract

Thermoresponsive cell culture plates release cells as confluent living sheets in response to small changes in temperature, with recovered cell sheets retaining functional extracellular matrix proteins and tight junctions, both of which indicate formation of intact and functional tissue. Our recent studies demonstrated that cell sheets are highly effective in promoting mouse submandibular gland (SMG) cell differentiation and recovering tissue integrity. However, these studies were performed only at early time points and extension of the observation period is needed to investigate duration of the cell sheets. Thus, the goal of this study was to demonstrate that treatment of wounded mouse SMG with cell sheets is capable of increasing salivary epithelial integrity over extended time periods. The results indicate that cell sheets promote tissue organization as early as eight days after transplantation and that these effects endure through Day 20. Furthermore, cell sheet transplantation in wounded SMG induces a significant time-dependent enhancement of cell polarization, differentiation and ion transporter expression. Finally, this treatment restored saliva quantity to pre-wounding levels at both eight and twenty days post-surgery and significantly improved saliva quality at twenty days post-surgery. These data indicate that cell sheets engineered with thermoresponsive cell culture plates are useful for salivary gland regeneration and provide evidence for the long-term stability of cell sheets, thereby offering a potential new therapeutic strategy for treating hyposalivation.

Published
2020
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40. Evaluation of Multi-Layered Pancreatic Islets and Adipose-Derived Stem Cell Sheets Transplanted on Various Sites for Diabetes Treatment

Author

Yu Na Lee, Hye-Jin Yi, Yang Hee Kim, Song Lee, Jooyun Oh, Teruo Okano, In Kyong Shim, and Song Cheol Kim

Subjects
islet, transplantation, adipose-derived stem cell, multi-layered cell sheet, liver surface, peritoneal wall, Cytology, QH573-671
Abstract

Islet cell transplantation is considered an ideal treatment for insulin-deficient diabetes, but implantation sites are limited and show low graft survival. Cell sheet technology and adipose-derived stem cells (ADSCs) can be useful tools for improving islet cell transplantation outcomes since both can increase implantation efficacy and graft survival. Herein, the optimal transplantation site in diabetic mice was investigated using islets and stem cell sheets. We constructed multi-layered cell sheets using rat/human islets and human ADSCs. Cell sheets were fabricated using temperature-responsive culture dishes. Islet/ADSC sheet (AI sheet) group showed higher viability and glucose-stimulated insulin secretion than islet-only group. Compared to islet transplantation alone, subcutaneous AI sheet transplantation showed better blood glucose control and CD31+ vascular traits. Because of the adhesive properties of cell sheets, AI sheets were easily applied on liver and peritoneal surfaces. Liver or peritoneal surface grafts showed better glucose control, weight gain, and intraperitoneal glucose tolerance test (IPGTT) profiles than subcutaneous site grafts using both rat and human islets. Stem cell sheets increased the therapeutic efficacy of islets in vivo because mesenchymal stem cells enhance islet function and induce neovascularization around transplanted islets. The liver and peritoneal surface can be used more effectively than the subcutaneous site in future clinical applications.

Published
2020
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45. Contractile force measurement of human induced pluripotent stem cell-derived cardiac cell sheet-tissue.

Author

Daisuke Sasaki, Katsuhisa Matsuura, Hiroyoshi Seta, Yuji Haraguchi, Teruo Okano, and Tatsuya Shimizu

Subjects
Medicine, Science
Abstract

We have developed our original tissue engineering technology "cell sheet engineering" utilizing temperature-responsive culture dishes. The cells are confluently grown on a temperature-responsive culture dish and can be harvested as a cell sheet by lowering temperature without enzymatic digestion. Cell sheets are high-cell-density tissues similar to actual living tissues, maintaining their structure and function. Based on this "cell sheet engineering", we are trying to create functional cardiac tissues from human induced pluripotent stem cells, for regenerative therapy and in vitro drug testing. Toward this purpose, it is necessary to evaluate the contractility of engineered cardiac cell sheets. Therefore, in the present study, we developed a contractile force measurement system and evaluated the contractility of human iPSC-derived cardiac cell sheet-tissues. By attaching the cardiac cell sheets on fibrin gel sheets, we created dynamically beating cardiac cell sheet-tissues. They were mounted to the force measurement system and the contractile force was measured stably and clearly. The absolute values of contractile force were around 1 mN, and the mean force value per cross-sectional area was 3.3 mN/mm2. These values are equivalent to or larger than many previously reported values, indicating the functionality of our engineered cardiac cell sheets. We also confirmed that both the contractile force and beating rate were significantly increased by the administration of adrenaline, which are the physiologically relevant responses for cardiac tissues. In conclusion, the force measurement system developed in the present study is valuable for the evaluation of engineered cardiac cell sheet-tissues, and for in vitro drug testing as well.

Published
2018
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48. Safety and efficacy of human juvenile chondrocyte-derived cell sheets for osteochondral defect treatment

Author

David W. Grainger, Kyung Sook Kim, Sumako Kameishi, Teruo Okano, Angela A. Wang, Travis G. Maak, Douglas T. Hutchinson, Makoto Kondo, Miki Maehara, Nicolas F Metzler, and Masato Sato

Subjects
Hyaline cartilage, Chemistry, Cartilage, Mesenchymal stem cell, Biomedical Engineering, Type II collagen, Medicine (miscellaneous), Cell Biology, Trauma, Chondrocyte, Article, Cell biology, Transplantation, medicine.anatomical_structure, Preclinical research, medicine, Regeneration, Medicine, Tissue engineering, Aggrecan, Type I collagen, Developmental Biology
Abstract

Knee cartilage does not regenerate spontaneously after injury, and a gold standard regenerative treatment algorithm has not been established. This study demonstrates preclinical safety and efficacy of scaffold-free, human juvenile cartilage-derived-chondrocyte (JCC) sheets produced from routine surgical discards using thermo-responsive cultureware. JCCs exhibit stable and high growth potential in vitro over passage 10, supporting possibilities for scale-up to mass production for commercialization. JCC sheets contain highly viable, densely packed cells, show no anchorage-independent cell growth, express mesenchymal surface markers, and lack MHC II expression. In nude rat focal osteochondral defect models, stable neocartilage formation was observed at 4 weeks by JCC sheet transplantation without abnormal tissue growth over 24 weeks in contrast to the nontreatment group showing no spontaneous cartilage repair. Regenerated cartilage was safranin-O positive, contained type II collagen, aggrecan, and human vimentin, and lacked type I collagen, indicating that the hyaline-like neocartilage formed originates from transplanted JCC sheets rather than host-derived cells. This study demonstrates the safety of JCC sheets and stable hyaline cartilage formation with engineered JCC sheets utilizing a sustainable tissue supply. Cost-benefit and scaling issues for sheet fabrication and use support feasibility of this JCC sheet strategy in clinical cartilage repair.

Published
2021

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