Characterization of biomaterial‐free cell sheets cultured from human oral mucosal epithelial cells

The purpose of this study was to report the characteristics of biomaterial‐free sheets cultured from human oral mucosal epithelial cells without fibrin support, in vitro and after transplantation to limbal‐deficient models. Human oral mucosal epithelial cells and limbal epithelial cells were cultured for 2 weeks, and the colony‐forming efficiency (CFE) rates were compared. Markers of stem cells (p63), cell proliferation (Ki‐67) and epithelial differentiation (cytokeratin; K1, K3, K4, K13) were observed in colonies and in biomaterial‐free sheets. Biomaterial‐free sheets which had been detached with 1% dispase or biomaterial‐free sheets generated by fibrin support were transplanted to 12 limbal‐deficient rabbit models. In vitro cell viability, in vivo stability and cytokeratin characteristics of biomaterial‐free sheets were compared with those of sheets formed by fibrin‐coated culture 1 week after transplantation. Mean CFE rate was significantly higher in human oral mucosal epithelial cells (44.8%) than in human limbal epithelial cells(17.7%). K3 and K4 were well expressed in both colonies and sheets. Biomaterial‐free sheets had two to six layers of stratified cells and showed an average of 79.8% viable cells in the sheets after detachment. Cytokeratin expressions of biomaterial‐free sheets were comparable to those of sheets cultured by fibrin support, in limbal‐deficient models. Both p63 and Ki‐67 were well expressed in colonies, isolated sheets and sheets transplanted to limbal‐deficient models. Our results suggest that biomaterial‐free sheets cultured from human oral mucosal epithelial cells without fibrin support can be an alternative option for cell therapy in use for the treatment of limbal‐deficient diseases. Copyright © 2014 John Wiley & Sons, Ltd.     

Temporal profiling of the growth and multi‐lineage potentiality of adipose tissue‐derived mesenchymal stem cells cell‐sheets

Cell‐sheet tissue engineering retains the benefits of an intact extracellular matrix (ECM) and can be used to produce scaffold‐free constructs. Adipose tissue‐derived stem cells (ASCs) are multipotent and more easily obtainable than the commonly used bone marrow‐derived stem cells (BMSCs). Although BMSC cell sheets have been previously reported to display multipotentiality, a detailed study of the development and multilineage potential of ASC cell sheets (ASC‐CSs) is non‐existent in the literature. The aims of this study were to temporally profile: (a) the effect of hyperconfluent culture duration on ASC‐CSs development; and (b) the multipotentiality of ASC‐CSs by differentiation into the osteogenic, adipogenic and chondrogenic lineages. Rabbit ASCs were first isolated and cultured until confluence (day 0). The confluent cells were then cultured in ascorbic acid‐supplemented medium for 3 weeks to study cell metabolic activity, cell sheet thickness and early differentiation gene expressions at weekly time points. ASC‐CSs and ASCs were then differentiated into the three lineages, using established protocols, and assessed by RT–PCR and histology at multiple time points. ASC‐CSs remained healthy up to 3 weeks of hyperconfluent culture. One week‐old cell sheets displayed upregulation of early differentiation gene markers (Runx2 and Sox9); however, subsequent differentiation results indicated that they did not necessarily translate to an improved phenotype. ASCs within the preformed cell sheet groups did not differentiate as efficiently as the non‐hyperconfluent ASCs, which were directly differentiated. Although ASCs within the cell sheets retained their differentiation capacity and remained viable under prolonged hyperconfluent conditions, future applications of ASC‐CSs in tissue engineering should be considered with care. Copyright © 2016 John Wiley & Sons, Ltd.     

Scaffold‐free cell sheet injection results in bone formation

We previously reported a new cell transplantation method in which mesenchymal stem cells (MSCs) were cultured as cell sheets. The cultured MSC sheets showed high alkaline phosphatase (ALP) activities and osteocalcin (OC) contents. In the present study, we transplanted such sheets by injection to assess whether the injectable MSC sheets could form bone tissue at subcutaneous sites. At 4 weeks after the subcutaneous injection, the injected areas showed hard mass formation. Each mass consisted of newly formed bone, as evaluated by radiographic, histological and gene expression analyses as well as three‐dimensional computed tomography (3D‐CT). Histological analyses revealed extracellular bone matrix together with osteocytes and active osteoblasts. Real‐time PCR analyses showed high ALP and OC mRNA expressions. We also injected the cell sheets into dead bone to determine whether the lost osteogenic potential could be rescued, and histological analyses revealed that the injected cell sheets supplied osteogenic potential to the dead bone. The present study clearly indicates that osteogenic MSC sheets can be transplanted via injection through a needle and that bone formation results in the injected areas. Owing to its usage of a needle for fabrication of in vivo bone tissue, this injection method can be applied as a minimally invasive approach for hard tissue reconstruction. Copyright © 2010 John Wiley & Sons, Ltd.     

Peritoneal cell sheets composed of mesothelial cells and fibroblasts prevent intra‐abdominal adhesion formation in a rat model

Postoperative intra‐abdominal adhesions remain an unsolved problem despite significant progress in the surgical procedures themselves. They often lead to small‐bowel obstruction, chronic abdominal and pelvic pain, as well as female infertility. The loss of mesothelial cells and several components of the inflammatory system following injury to the peritoneum results in fibrin formation and angiogenesis. The remaining fibrin matrix and angiogenesis lead to replacement by fibroblasts and fibrous band formation. The aim of this study was to develop a new therapeutic method of preventing intra‐abdominal adhesions. We fabricated transplantable peritoneal cell sheets from the rat peritoneum by cell sheet engineering using a temperature‐responsive culture system. The peritoneal cell sheets developed were composed of an upper monolayer of mesothelial cells and underlying multilayered fibroblasts, similar to the peritoneum in vivo. Transplantation of peritoneal cell sheets prevented tissue adhesion, fibrin deposition and angiogenesis, and, moreover, lymphangiogenesis and macrophage infiltration in a rat caecum cauterization adhesion model. Copyright © 2013 John Wiley & Sons, Ltd.     

Regeneration of dental pulp/dentine complex with a three‐dimensional and scaffold‐free stem‐cell sheet‐derived pellet

Dental pulp/dentine complex regeneration is indispensable to the construction of biotissue‐engineered tooth roots and represents a promising approach to therapy for irreversible pulpitis. We used a tissue‐engineering method based on odontogenic stem cells to design a three‐dimensional (3D) and scaffold‐free stem‐cell sheet‐derived pellet (CSDP) with the necessary physical and biological properties. Stem cells were isolated and identified and stem cells from root apical papilla (SCAPs)‐based CSDPs were then fabricated and examined. Compact cell aggregates containing a high proportion of extracellular matrix (ECM) components were observed, and the CSDP culture time was prolonged. The expression of alkaline phosphatase (ALP), dentine sialoprotein (DSPP), bone sialoprotein (BSP) and runt‐related gene 2 (RUNX2) mRNA was higher in CSDPs than in cell sheets (CSs), indicating that CSDPs have greater odonto/osteogenic potential. To further investigate this hypothesis, CSDPs and CSs were inserted into human treated dentine matrix fragments (hTDMFs) and transplanted into the subcutaneous space in the backs of immunodeficient mice, where they were cultured in vivo for 6 weeks. The root space with CSDPs was filled entirely with a dental pulp‐like tissue with well‐established vascularity, and a continuous layer of dentine‐like tissue was deposited onto the existing dentine. A layer of odontoblast‐like cells was found to express DSPP, ALP and BSP, and human mitochondria lined the surface of the newly formed dentine‐like tissue. These results clearly indicate that SCAP‐CSDPs with a mount of endogenous ECM have a strong capacity to form a heterotopic dental pulp/dentine complex in empty root canals; this method can be used in the fabrication of bioengineered dental roots and also provides an alternative treatment approach for pulp disease. Copyright © 2013 John Wiley & Sons, Ltd.     

Collagen type I–PLGA film as an efficient substratum for corneal endothelial cells regeneration

Surface modulations of desired biological construct design for regenerative medical therapy is considered to be highly crucial for cell growth and the subsequent regeneration of biologically competent tissues. In this study, we fabricated stable, transparent, collagen type‐I‐coated PLGA films (Col I–PLGA) as a potential substratum for the regeneration of corneal endothelial cells. Morphological and structural properties were analysed by FE–SEM, AFM, FTIR, contact angle, etc., and in vitro biocompatibility of the Col I–PLGA films was further tested in primary rabbit corneal endothelial cells (rCEnCs) as models. Compared with bare PLGA films, the Col I–PLGA films displayed the requisite surface roughness, with higher Ra (nm) values, transparency, good hydrophilicity, stability and water uptake. Next, cultured rCEnCs on Col I–PLGA films showed the characteristic polygonal shape of rCEnCs with enhanced initial attachment, proliferation and expression of mRNAs. Collectively, these results indicate that Col I–PLGA can be employed as a suitable alternative for high‐quality corneal tissue expansion and transplantation. Copyright © 2016 John Wiley & Sons, Ltd.     

Combination of platelet‐rich plasma within periodontal ligament stem cell sheets enhances cell differentiation and matrix production

The longstanding goal of periodontal therapy is to regenerate periodontal tissues. Although platelet‐rich plasma (PRP) has been gaining increasing popularity for use in the orofacial region, whether PRP is useful for periodontal regeneration is still unknown. The purpose of this study was to determine whether a mixture of periodontal ligament stem cell (PDLSC) sheets and PRP promoted bone regeneration, one of the most important measurement indices of periodontal tissue regenerative capability in vitro and in vivo. In this study, we evaluated the effects of different doses of PRP on the differentiation of human PDLSCs. Then cell sheet formation, extracellular matrix deposition and osteogenic gene expression in response to different doses of PRP treatment during sheet grafting was investigated. Furthermore, we implanted PDLSC sheets treated with 1% PRP subcutaneously into immunocompromised mice to evaluate their bone‐regenerative capability. The results revealed that 1% PRP significantly enhanced the osteogenic differentiation of PDLSCs. Based on the production of extracellular matrix proteins, the results of scanning electron microscopy and the expression of the osteogenic genes ALP, Runx2, Col‐1 and OCN, the provision of 1% PRP for PDLSC sheets was the most effective PRP administration mode for cell sheet formation. The results of in vivo transplantation showed that 1% PRP‐mediated PDLSC sheets exhibited better periodontal tissue regenerative capability than those obtained without PRP intervention. These data suggest that a suitable concentration of PRP stimulation may enhance extracellular matrix production and positively affect cell behaviour in PDLSC sheets. Copyright © 2014 John Wiley & Sons, Ltd.     

Fabrication of tissue‐engineered cell sheets by automated cell culture equipment

Most cells for regenerative medicine are currently cultured manually. In order to promote the widespread use of regenerative medicine, it will be necessary to develop automated culture techniques so that cells can be produced in greater quantities at lower cost and with more stable quality. In the field of regenerative medicine technology, cell sheet therapy is an effective tissue engineering technique whereby cells can be grafted by attaching them to a target site. We have developed automated cell culture equipment to promote the use of this cell sheet regenerative treatment. This equipment features a fully closed culture vessel and circuit system that avoids contamination with bacteria and the like from the external environment, and it was designed to allow 10 cell sheets to be simultaneously cultured in parallel. We used this equipment to fabricate 50 sheets of human oral mucosal epithelial cells in five automated culture tests in this trial. By analyzing these sheets, we confirmed that 49 of the 50 sheets satisfied the quality standards of clinical research. To compare the characteristics of automatically fabricated cell sheets with those of manually fabricated cell sheets, we performed histological analyses using immunostaining and transmission electron microscopy. The results confirmed that cell sheets fabricated with the automated cell culture are differentiated in the same way as cultures fabricated manually.     

Fabrication of transplantable corneal epithelial and oral mucosal epithelial cell sheets using a novel temperature‐responsive closed culture device

Temperature‐responsive culture surfaces make it possible to harvest transplantable carrier‐free cell sheets. Here, we applied temperature‐responsive polymer for polycarbonate surfaces with previously developed closed culture devices for an automated culture system in order to fabricate transplantable stratified epithelial cell sheets. Histological and immunohistochemical analyses and colony‐forming assays revealed that corneal epithelial and oral mucosal epithelial cell sheets could be harvested with the temperature‐responsive closed culture devices. The results were similar to those obtained using temperature‐responsive culture inserts. These results indicate that the novel temperature‐responsive closed culture device is useful for fabricating transplantable stratified epithelial cell sheets. Copyright © 2013 John Wiley & Sons, Ltd.     

In vivo 3D analysis with micro‐computed tomography of rat calvaria bone regeneration using periosteal cell sheets fabricated on temperature‐responsive culture dishes

Transplantable cell sheets containing osteoblasts were fabricated from periostea on temperature‐responsive culture dishes. This study demonstrated the time‐course of bone regeneration in living small animals. This continuous observation of bone regeneration was achieved by micro‐computed tomography (µCT), which assessed the osteogenic capability of periosteal cells without biodegradable scaffolds. Real‐time bone regeneration was non‐invasively monitored in a rat calvarial bone defect model, using µCT. Three‐dimensional (3D) images obtained over time by µCT clearly showed that two different bone regeneration modes, specific to the control and experimental groups, were observed. In the control group, bone was regenerated only from the periphery of the defect edges. In the experimental group, bone regeneration was observed in several small regions within the central portions of the defects that were covered by the transplanted cell sheets. However, bone regeneration observed after periosteal cell sheet transplantation was limited. The results of ALP staining and the time‐course observations concluded that periosteal cell sheets contained a small fraction of cells that could differentiate osteoblasts. Fibroblasts in transplanted cell sheets or from around subcutaneous tissues suppressed bone regeneration. The periosteal cell sheets had a capability to produce ectopic regenerated bones. Therefore, to increase the content of osteogenic cells in harvested cell sheets, the enrichment of cells that could produce osteoblasts was expected by the modification of the initial cell preparation and the culture conditions. With further possible improvements, scaffold‐free periosteal cell sheet fabricated on temperature‐responsive culture dishes will be a valuable method for inducing and accelerating bone regeneration. Copyright © 2010 John Wiley & Sons, Ltd.     

Electrical interaction between cardiomyocyte sheets separated by non‐cardiomyocyte sheets in heterogeneous tissues

Electrical coupling between cardiomyocytes is important in synchronous beating and normal heart functions. Cardiomyocytes are also electrically coupled to non‐cardiomyocytes. The electrical interactions between cardiomyocytes and non‐cardiomyocytes, or those between separated cardiomyocytes, are important for normal heart function because abnormalities of the coupling and variation of the cell population induce pathological heart functions and arrhythmias. In this study the three‐dimensional time course of the electrical interaction between two rat neonatal cardiomyocyte sheets separated by non‐cardiomyocyte sheets was analysed by a multiple‐electrode extracellular recording system. The two cardiomyocyte sheets separated by a single‐ or double‐layered mouse fibroblast NIH3T3 cell sheet coupled electrically at 113 ± 28 or 287 ± 87 min after layering, respectively. The time course of the electrical coupling, when the single‐layer NIH3T3 cell sheet was inserted, is similar to that of a layered cardiomyocyte sheet. Immunocytological analysis and dye transfer assay suggested the formation of gap junctions at heterocellular junctions of cardiomyocytes and NIH3T3 cells. On the other hand, when a double‐layered NIH3T3 cell sheet was inserted, an incomplete electrical coupling of two cardiomyocyte sheets, including a conduction delay, was observed. The electrical coupling of cardiomyocyte sheets was completely blocked (conduction block) by insertion of a triple‐layered NIH3T3 cell sheet, a communication‐defective HeLa cell sheet or a Ca²⁺‐antagonist LaCl₃‐treated cell sheet. These electrophysiological analyses of heterogeneously stacked cell sheets might provide insights into complex electrical conduction systems that resemble those of native or damaged heart and transplanted tissues. Copyright © 2009 John Wiley & Sons, Ltd.     

Scaffold‐free tissue engineering of functional corneal stromal tissue

Blinding corneal scarring is predominately treated with allogeneic graft tissue; however, there is a worldwide shortage of donor tissue leaving millions in need of therapy. Human corneal stromal stem cells (CSSC) have been shown produce corneal tissue when cultured on nanofibre scaffolding, but this tissue cannot be readily separated from the scaffold. In this study, scaffold‐free tissue engineering methods were used to generate biomimetic corneal stromal tissue constructs that can be transplanted in vivo without introducing the additional variables associated with exogenous scaffolding. CSSC were cultured on substrates with aligned microgrooves, which directed parallel cell alignment and matrix organization, similar to the organization of native corneal stromal lamella. CSSC produced sufficient matrix to allow manual separation of a tissue sheet from the grooved substrate. These constructs were cellular and collagenous tissue sheets, approximately 4 μm thick and contained extracellular matrix molecules typical of corneal tissue including collagen types I and V and keratocan. Similar to the native corneal stroma, the engineered corneal tissues contained long parallel collagen fibrils with uniform diameter. After being transplanted into mouse corneal stromal pockets, the engineered corneal stromal tissues became transparent, and the human CSSCs continued to express human corneal stromal matrix molecules. Both in vitro and in vivo, these scaffold‐free engineered constructs emulated stromal lamellae of native corneal stromal tissues. Scaffold‐free engineered corneal stromal constructs represent a novel, potentially autologous, cell‐generated, biomaterial with the potential for treating corneal blindness. Copyright © 2016 John Wiley & Sons, Ltd.     

Transplantation of cancerous cell sheets effectively generates tumour‐bearing model mice

Tumour‐bearing mice were created by transplanting cancerous cell sheets onto the subcutaneous tissue of the dorsal region, using luciferase gene‐transfected mammary gland adenocarcinoma cells, 4T1‐luc2, to investigate the tumourigenicity of the cell sheet relative to a conventional injection of cell suspension. Contiguous breast cancerous cell sheets were harvested from temperature‐responsive culture dishes by reducing the temperature from 37 °C to 20 °C; the sheets were then transplanted onto the dorsal side of the mouse subcutaneous tissue, using a chitin‐based supporting membrane. Cell suspensions obtained by trypsin digestion were subcutaneously injected into the dorsal region of mice. The tumour growth of the transplanted cancer cells was evaluated by the tumour volume and by the bioluminescence from luciferase‐gene transfected cancer cells, using an in vivo imaging system. The cell sheet method improved the 4 T1‐luc2 engraftment efficiency in living mouse tissues at the initial stage by 13‐fold compared with that from injecting cell suspensions. On day 14 after the transplantation, the tumour formation at the transplanted area of cell sheet‐transplanted mice also accelerated, and the mean tumour volume became 1116 mm³, which was 10 times larger than that in cell suspension‐transplanted mice. The cell sheets engrafted on the recipient tissues efficiently due to the preserved extracellular matrix on their basal sides, such that cancer cells were supplied with sufficient oxygen and nutrients from the host tissues to develop tumour tissues. Therefore, cancerous cell sheet‐based transplantation is a promising method for efficiently creating cancer‐bearing mice. Copyright © 2013 John Wiley & Sons, Ltd.     

A novel method to align cells in a cardiac tissue‐like construct fabricated by cell sheet‐based tissue engineering

Fabrication of cardiac tissue from human induced pluripotent stem cell‐derived cardiomyocytes (hiPS‐CMs) has received great interest, but a major challenge facing researchers is the alignment of cardiomyocytes in the same direction to optimize force generation. We have developed a novel method of fabricating a cardiac tissue‐like construct with aligned cells based on the unidirectional stretching of an hiPS‐CM sheet. A square cell sheet was harvested from a temperature‐responsive culture dish and placed on a silicone surface, and an extending force was imposed on the silicone to stretch the cell sheet along one direction. To enable evaluation of cardiomyocyte morphology in vitro, a cell sheet was constructed by coculture of hiPS‐CMs and human adipose‐derived stem cells. In separate experiments, a stretched double‐layered cell sheet constructed from hiPS‐CMs alone was transplanted onto the muscle of an athymic rat, and its features were compared with those of a nonstretched (control) cell sheet. Immediately after stretching, the stretched cell sheet was significantly longer than the control cell sheet. Immunohistological analysis revealed that the cardiomyocytes showed unidirectional alignment in the stretched cell sheet but random directionality in the control cell sheet. Two weeks after transplantation, immunohistology demonstrated that the stretched cell sheet had retained the unidirectionality of its myocardial fibers and had an orientation intensity that was higher than that of the control cell sheet after transplantation or the stretched cell sheet before transplantation. Our technique provides a simple method of aligning an hiPS‐CM‐derived cardiac tissue‐like construct without the use of a scaffold.     

The suitability of human adipose‐derived stem cells for the engineering of ligament tissue

Rupture of the anterior cruciate ligament (ACL) is the one of the most common sports‐related injuries. With its poor healing capacity, surgical reconstruction using either autografts or allografts is currently required to restore function. However, serious complications are associated with graft reconstructions and the number of such reconstructions has steadily risen over the years, necessitating the search for an alternative approach to ACL repair. Such an approach may likely be tissue engineering. Recent engineering approaches using ligament‐derived fibroblasts have been promising, but the slow growth rate of such fibroblasts in vitro may limit their practical application. More promising results are being achieved using bone marrow mesenchymal stem cells (MSCs). The adipose‐derived stem cell (ASC) is often proposed as an alternative choice to the MSC and, as such, may be a suitable stem cell for ligament engineering. However, the use of ASCs in ligament engineering still remains relatively unexplored. Therefore, in this study, the potential use of human ASCs in ligament tissue engineering was initially explored by examining their ability to express several ligament markers under growth factor treatment. ASC populations treated for up to 4 weeks with TGFβ1 or IGF1 did not show any significant and consistent upregulation in the expression of collagen types 1 and 3, tenascin C and scleraxis. While treatment with EGF or bFGF resulted in increased tenascin C expression, increased expression of collagens 1 and 3 were never observed. Therefore, simple in vitro treatment of human ASC populations with growth factors may not stimulate their ligament differentiative potential. Copyright © 2011 John Wiley & Sons, Ltd.     

A collagen network phase improves cell seeding of open‐pore structure scaffolds under perfusion

Scaffolds with open‐pore morphologies offer several advantages in cell‐based tissue engineering, but their use is limited by a low cell‐seeding efficiency. We hypothesized that inclusion of a collagen network as filling material within the open‐pore architecture of polycaprolactone–tricalcium phosphate (PCL–TCP) scaffolds increases human bone marrow stromal cells (hBMSCs) seeding efficiency under perfusion and in vivo osteogenic capacity of the resulting constructs. PCL–TCP scaffolds, rapid prototyped with a honeycomb‐like architecture, were filled with a collagen gel and subsequently lyophilized, with or without final crosslinking. Collagen‐free scaffolds were used as controls. The seeding efficiency was assessed after overnight perfusion of expanded hBMSCs directly through the scaffold pores using a bioreactor system. By seeding and culturing freshly harvested hBMSCs under perfusion for 3 weeks, the osteogenic capacity of generated constructs was tested by ectopic implantation in nude mice. The presence of the collagen network, independently of the crosslinking process, significantly increased the cell seeding efficiency (2.5‐fold), and reduced the loss of clonogenic cells in the supernatant. Although no implant generated frank bone tissue, possibly due to the mineral distribution within the scaffold polymer phase, the presence of a non‐crosslinked collagen phase led to in vivo formation of scattered structures of dense osteoids. Our findings verify that the inclusion of a collagen network within open morphology porous scaffolds improves cell retention under perfusion seeding. In the context of cell‐based therapies, collagen‐filled porous scaffolds are expected to yield superior cell utilization, and could be combined with perfusion‐based bioreactor devices to streamline graft manufacture. Copyright © 2011 John Wiley & Sons, Ltd.     

A biomimetic scaffold for culturing limbal stem cells: a promising alternative for clinical transplantation

Limbal tissues can be cultured on various types of scaffolds to create a sheet of limbal-corneal epithelium for research as well as clinical transplantation. An optically clear, biocompatible, biomimetic scaffold would be an ideal replacement graft for transplanting limbal stem cells. In this study, we evaluated the physical and culture characteristics of the recombinant human cross-linked collagen scaffold (RHC-III scaffold) and compared it with denuded human amniotic membrane (HAM). Optical/mechanical properties and microbial susceptibility were measured for the scaffolds. With the approval of the institutional review board, 2 mm fresh human limbal tissues were cultured on 2.5 x 2.5 cm(2) scaffolds in a medium containing autologous serum in a feeder cell-free submerged system. The cultured cell systems were characterized by morphology and immunohistochemistry for putative stem cells and differentiated cell markers. The refractive index (RI) and tensile strength of the RHC-III scaffold were comparable to human cornea, with delayed in vitro degradation compared to HAM. RHC-III scaffolds were 10-fold less susceptible to microbial growth. Cultures were initiated on day 1, expanded to form a monolayer by day 3 and covered the entire growth surface in 10 days. Stratified epithelium on the scaffolds was visualized by transmission electron microscopy. The cultured cells showed p63 and ABCG2 positivity in the basal layer and were immunoreactive for cytokeratin K3 and K12 in the suprabasal layers. RHC-III scaffold supports and retains the growth and stemness of limbal stem cells, in addition to resembling human cornea; thus, it could be a good replacement scaffold for growing cells for clinical transplantation.     

Micropattern size‐dependent endothelial differentiation from a human induced pluripotent stem cell line

The multifaceted extracellular milieu presents biochemical and biophysical stimuli that influence stem cell differentiation. Two‐dimensional (2D) micropatterned substrates allow the presentation of these cues in spatially defined geometries that have been demonstrated to guide stem cell fate decisions. Leveraging stem cells to reconstruct microvasculature, made up of an inner lining of endothelial cells (ECs) supported by pericytes, is critical to tissue‐engineering advances; thus, methods to improve endothelial differentiation efficiency are vital to these efforts. In this study, we examine the hypothesis that the diameter of micropatterned islands influences endothelial differentiation from human induced pluripotent stem cells (hiPSCs). Comparing island diameters of 80, 140, 225 and 500 µm, we found that co‐cultures of control ECs and pericytes did not yield variable ratios of cell types; however, when hiPSCs were differentiated toward a bicellular population of ECs and pericytes on these varying micropattern feature sizes, we found that smaller islands promoted EC differentiation efficiency, yielding a derived population composed of 70% ECs, which exhibited a greater sprouting propensity. Differentiation on the largest feature size exhibited a smaller EC yield, similar to that on non‐patterned substrates. Taken together, these data demonstrate that micropatterned islands of varying diameters can be used to modulate EC differentiation efficiency. Copyright © 2015 John Wiley & Sons, Ltd.