Induction of angiogenesis via topical delivery of basic‐fibroblast growth factor from polyvinyl alcohol–dextran blend hydrogel in an ovine model of acute myocardial infarction

Hydrogels are currently used as interesting constructs for the delivery of proteins. In this study, a novel polyvinyl alcohol–dextran (PVA–Dex) blend hydrogel was used for controlled delivery of basic‐fibroblast growth factor (bFGF). These biocompatible constructs were sutured to the epicardium as patches on the heart surface to provide slow release of bFGF to the infarcted site in an ovine model of myocardial infarction (MI). Eighteen sheep were randomly divided into three groups (n = 6 each), including group I (control without any patch and bFGF), group II (patch without bFGF) and group III (patch incorporating 100 µg bFGF). They were subjected to coronary artery ligation after lateral thoracotomy, and then in groups II and III the patches were implanted 20–30 min after MI. Cardiac function was assessed by both echocardiography and magnetic resonance imaging (MRI) 2 months after implantation. Then the animals were sacrificed and the hearts subjected to histopathological examination, immunohistochemistry and electron microscopy. Heart lysates were subject to protein expression analysis through western blotting. The results showed that sustained release of bFGF using PVA–Dex blend hydrogel strongly stimulated angiogenesis and increased wall thickness index in the infarcted myocardium. The patch also significantly attenuated the increase in left ventricular end‐systolic diameter, but it did not improve cardiac function within 2 months of myocardial infarction. In conclusion, PVA–Dex gel incorporating bFGF can be used as a sustained release construct for therapeutic angiogenesis in ischaemic heart disease. Copyright © 2012 John Wiley & Sons, Ltd.     

Modulation of human mesenchymal stem cell function in a three‐dimensional matrix promotes attenuation of adverse remodelling after myocardial infarction

The application of tissue engineering (TE) practices for cell delivery offers a unique approach to cellular cardiomyoplasty. We hypothesized that human mesenchymal stem cells (hMSCs) applied to the heart in a collagen matrix would outperform the same cells grown in a monolayer and directly injected for cardiac cell replacement after myocardial infarction in a rat model. When hMSC patches were transplanted to infarcted hearts, several measures for left ventricle (LV) remodelling and function were improved, including fractional area change, wall thickness, –dP/dt and LV end‐diastolic pressure. Neovessel formation throughout the LV infarct wall after hMSC patch treatment increased by 37% when compared to direct injection of hMSCs. This observation was correlated with increased secretion of angiogenic factors, with accompanying evidence that these factors enhanced vessel formation (30% increase) and endothelial cell growth (48% increase) in vitro. These observations may explain the in vivo observations of increased vessel formation and improved cardiac function with patch‐mediated cell delivery. Although culture of hMSC in collagen patches enhanced angiogenic responses, there was no effect on cell potency or viability. Therefore, hMSCs delivered as a cardiac patch showed benefits above those derived from monolayers and directly injected. hMSCs cultured and delivered within TE constructs may represent a good option to maximize the effects of cellular cardiomyoplasty. Copyright © 2011 John Wiley & Sons, Ltd.     

Cardioprotection of PLGA/gelatine cardiac patches functionalised with adenosine in a large animal model of ischaemia and reperfusion injury: A feasibility study

The protection from ischaemia‐reperfusion‐associated myocardial infarction worsening remains a big challenge. We produced a bioartificial 3D cardiac patch with cardioinductive properties on stem cells. Its multilayer structure was functionalised with clinically relevant doses of adenosine. We report here the first study on the potential of these cardiac patches in the controlled delivery of adenosine into the in vivo ischaemic‐reperfused pig heart. A Fourier transform infrared chemical imaging approach allowed us to perform a characterisation, complementary to the histological and biochemical analyses on myocardial samples after in vivo patch implantation, increasing the number of investigations and results on the restricted number of pigs (n = 4) employed in this feasibility step. In vitro tests suggested that adenosine was completely released by a functionalised patch, a data that was confirmed in vivo after 24 hr from patch implantation. Moreover, the adenosine‐loaded patch enabled a targeted delivery of the drug to the ischaemic‐reperfused area of the heart, as highlighted by the activation of the pro‐survival signalling reperfusion injury salvage kinases pathway. At 3 months, though limited to one animal, the used methods provided a picture of a tissue in dynamic conditions, associated to the biosynthesis of new collagen and to a non‐fibrotic outcome of the healing process underway. The synergistic effect between the functionalised 3D cardiac patch and adenosine cardioprotection might represent a promising innovation in the treatment of reperfusion injury. As this is a feasibility study, the clinical implications of our findings will require further in vivo investigation on larger numbers of ischaemic‐reperfused pig hearts.     

Meniscus ECM‐functionalised hydrogels containing infrapatellar fat pad‐derived stem cells for bioprinting of regionally defined meniscal tissue

Injuries to the meniscus of the knee commonly lead to osteoarthritis. Current therapies for meniscus regeneration, including meniscectomies and scaffold implantation, fail to achieve complete functional regeneration of the tissue. This has led to increased interest in cell and gene therapies and tissue engineering approaches to meniscus regeneration. The implantation of a biomimetic implant, incorporating cells, growth factors, and extracellular matrix (ECM)‐derived proteins, represents a promising approach to functional meniscus regeneration. The objective of this study was to develop a range of ECM‐functionalised bioinks suitable for 3D bioprinting of meniscal tissue. To this end, alginate hydrogels were functionalised with ECM derived from the inner and outer regions of the meniscus and loaded with infrapatellar fat pad‐derived stem cells. In the absence of exogenously supplied growth factors, inner meniscus ECM promoted chondrogenesis of fat pad‐derived stem cells, whereas outer meniscus ECM promoted a more elongated cell morphology and the development of a more fibroblastic phenotype. With exogenous growth factors supplementation, a more fibrogenic phenotype was observed in outer ECM‐functionalised hydrogels supplemented with connective tissue growth factor, whereas inner ECM‐functionalised hydrogels supplemented with TGFβ3 supported the highest levels of Sox‐9 and type II collagen gene expression and sulfated glycosaminoglycans (sGAG) deposition. The final phase of the study demonstrated the printability of these ECM‐functionalised hydrogels, demonstrating that their codeposition with polycaprolactone microfibres dramatically improved the mechanical properties of the 3D bioprinted constructs with no noticeable loss in cell viability. These bioprinted constructs represent an exciting new approach to tissue engineering of functional meniscal grafts.     

Morphological transformation of hBMSC from 2D monolayer to 3D microtissue on low‐crystallinity SF‐PCL patch with promotion of cardiomyogenesis

The effects of the stiffness of substrates on the cell behaviours of human bone marrow‐derived mesenchymal stem cells (hBMSC) have been investigated, but the effects of the secondary structures of proteins in the substrates on the morphological transformation and differentiation of hBMSC have yet been elucidated. To investigate these issues, silk fibroin‐poly(ε‐caprolactone) SP cardiac patches of poly(ε‐caprolactone; P), on which is grafted by silk fibroin (SF) with various β‐sheet contents (or crystallinity) to provide various degrees of stiffness, were produced to examine the in vitro behaviours of hBMSC during proliferation, and cardiomyogenesis on the SP patches. β‐sheet contents of SF from 20% to 44% (SP20 to SP44, respectively) were induced on patches, which were examined by attenuated total reflection Fourier‐transform infrared (ATR‐FTIR) spectroscopy, and analysed using the Fourier self‐deconvolution method. The stiffness of the SP patches, quantified by their Young's moduli and elasticities, increased with the crystallinity of the SF. During 3 days of proliferation, hBMSC migrated and morphologically transformed into 3D microtissues with diameters of approximately 150–200 μm on low‐stiffness SP20 and SP30 patches, whereas 2D monolayers were observed on the SP37 and SP44 patches. The 3D microtissues/patch yielded more extensive in vitro cardiomyogenesis of hBMSC than the 2D cell monolayer with significantly higher expressions of all examined cardiac‐specific proteins after induction by 5‐aza. Notably, in vivo subcutaneously growing 3D microtissues on SP20 patches and a 2D monolayer on SP44 patches were preliminarily demonstrated in a rat model. Morphological transformations of hBMSC from a 2D monolayer to a 3D microtissue by low‐stiffness SP cardiac patches, promoting cardiomyogenesis, provide a new opportunity for cardiac tissue engineering.     

Bone marrow‐derived mesenchymal stem cell‐loaded fibrin patches act as a reservoir of paracrine factors in chronic myocardial infarction

The combination of mesenchymal stem cells and tissue‐engineered fibrin patches improves the therapeutic efficacy of stem cells. In vivo cardiac magnetic resonance (4.7 Tesla) and ex vivo high‐spatial resolution CMR were used to track the fate of human bone marrow‐derived mesenchymal stem cell (BMSC) delivered on an epicardial scaffold and more specifically assess their potential intramyocardial migration. Fifty‐seven nude rats underwent permanent coronary artery ligation. Two months later, those with a left ventricular ejection fraction ≤55% were randomly allocated to receive a patch loaded with human BMSC (BMSC‐P, n = 10), a patch loaded with BMSCs labelled with iron oxide nanoparticles (BMSC*‐P, n = 12), an acellular patch (A‐P, n = 8) or to serve as sham‐operated animals (SHAM, n = 7). BMSC secretion of cytokines and growth factors was evaluated with flow‐cytometry. Cardiac functional parameters of cell‐treated groups (BMSC*‐P and BMSC‐P) yielded significantly better outcomes than the SHAM group (p = 0.044 and p = 0.026, respectively, for ejection fraction). Angiogenesis was higher in the cell‐patch than in control groups (e.g. BMSC*P vs. SHAM: p = 0.007). No BMSCs were identified into the myocardium on cardiac magnetic resonance or histological sections, although persisting BMSCs were identified on the epicardial surface 21 days post‐transplantation in 10% of rats hearts (Lamin A/C and CD90 positive). Cytokine and growth factor profiling demonstrated an increase in their release by cells seeded in patches. The absence of stem cell migration into the myocardium and the persistence of stem cells on the epicardial surface suggest that fibrin patches are likely to act predominantly as reservoirs of paracrine factors. Copyright © 2017 John Wiley & Sons, Ltd.     

Tissue‐engineered trachea from a 3D‐printed scaffold enhances whole‐segment tracheal repair in a goat model

Traditional treatment therapies for tracheal stenosis often cause severe post‐operative complications. To solve the current difficulties, novel and more suitable long‐term treatments are needed. A whole‐segment tissue‐engineered trachea (TET) representing the native goat trachea was 3D printed using a poly(caprolactone) (PCL) scaffold engineered with autologous auricular cartilage cells. The TET underwent mechanical analysis followed by in vivo implantations in order to evaluate the clinical feasibility and potential. The 3D‐printed scaffolds were successfully cellularized, as observed by scanning electron microscopy. Mechanical force compression studies revealed that both PCL scaffolds and TETs have a more robust compressive strength than does the native trachea. In vivo implantation of TETs in the experimental group resulted in significantly higher mean post‐operative survival times, 65.00 ± 24.01 days (n = 5), when compared with the control group, which received autologous trachea grafts, 17.60 ± 3.51 days (n = 5). Although tracheal narrowing was confirmed by bronchoscopy and computed tomography examination in the experimental group, tissue necrosis was only observed in the control group. Furthermore, an encouraging epithelial‐like tissue formation was observed in the TETs after transplantation. This large animal study provides potential preclinical evidence around the employment of an orthotopic transplantation of a whole 3D‐printed TET.     

BMP protein‐mediated crosstalk between inflammatory cells and human pluripotent stem cell‐derived cardiomyocytes

Following cardiac injury, the ischaemic heart tissue is characterized by the invasion of pro‐inflammatory (M1) and pro‐healing (M2) macrophages. Any engineered cardiac tissue will inevitably interact with the inflammatory environment found at the site of myocardial infarction at the time of implantation. However, the interactions between the inflammatory and the cardiac repair cells remain poorly understood. Here we recapitulated in vitro some of the important cellular events found at the site of myocardial injury, such as macrophage recruitment and their effect on cardiac differentiation and maturation, by taking into account the involvement of paracrine‐mediated signalling. By using a 3D inverted invasion assay, we found that cardiomyocyte (CM) conditioned medium can trigger the recruitment of pro‐inflammatory (M1) macrophages, through a mechanism that involves, in part, CM‐derived BMP4. Pro‐inflammatory (M1) macrophages were also found to affect CM proliferation and differentiation potential, in part due to BMP molecules secreted by macrophages. These effects involved the activation of the canonical outside‐in signalling pathways, such as SMAD1,5,8, which are known to be activated during myocardial injury in vivo. In the present study we propose a new role for CM‐ and macrophage‐derived BMP proteins during the recruitment of macrophage subtypes and the maturation of repair cells, representing an important step towards creating a functional cardiac patch with superior therapeutic properties. Copyright © 2015 John Wiley & Sons, Ltd.     

Post‐ischaemic angiogenic therapy using in vivo prevascularized ascorbic acid‐enriched myocardial artificial grafts improves heart function in a rat model

Angiogenesis plays a key role in post‐ischaemic myocardial repair. We hypothesized that epicardial implantation of an ascorbic acid (AA)‐enriched myocardial artificial graft (MAG), which has been prevascularized in the recipients' own body, promotes restoration of the ischaemic heart. Gelatin patches were seeded with GFP–luciferase‐expressing rat cardiomyoblasts and enriched with 5 μm AA. Grafts were prevascularized in vivo for 3 days, using a renal pouch model in rats. The MAG patch was then implanted into the same rat's ischaemic heart following myocardial infarction (MI). MAG‐treated animals (MAG group, n = 6) were compared to untreated infarcted animals as injury controls (MI group, n = 6) and sham‐operated rats as healthy controls (healthy group, n = 7). In vivo bioluminescence imaging indicated a decrease in donor cell survival by 83% during the first week post‐implantation. Echocardiographic and haemodynamic assessment 4 weeks after MI revealed that MAG treatment attenuated left ventricular (LV) remodelling (LV end‐systolic volume, 0.31 ± 0.13 vs 0.81 ± 0.01 ml, p < 0.05; LV end‐diastolic volume 0.79 ± 0.33 vs 1.83 ± 0.26 ml, p < 0.076) and preserved LV wall thickness (0.21 ± 0.03 vs 0.09 ± 0.005 cm, p < 0.05) compared to the MI group. Cardiac output was higher in MAG than MI (51.59 ± 6.5 vs 25.06 ± 4.24 ml/min, p < 0.01) and comparable to healthy rats (47.08 ± 1.9 ml/min). Histology showed decreased fibrosis, and a seven‐fold increase in blood vessel density in the scar area of MAG compared to MI group (15.3 ± 1.1 vs 2.1 ± 0.3 blood vessels/hpf, p < 0.0001). Implantation of AA‐enriched prevascularized grafts enhanced vascularity in ischaemic rat hearts, attenuated LV remodelling and preserved LV function. Copyright © 2011 John Wiley & Sons, Ltd.     

A bilayer photoreceptor‐retinal tissue model with gradient cell density design: A study of microvalve‐based bioprinting

ARPE‐19 and Y79 cells were precisely and effectively delivered to form an in vitro retinal tissue model via 3D cell bioprinting technology. The samples were characterized by cell viability assay, haematoxylin and eosin and immunofluorescent staining, scanning electrical microscopy and confocal microscopy, and so forth. The bioprinted ARPE‐19 cells formed a high‐quality cell monolayer in 14 days. Manually seeded ARPE‐19 cells were poorly controlled during and after cell seeding, and they aggregated to form uneven cell layer. The Y79 cells were subsequently bioprinted on the ARPE‐19 cell monolayer to form 2 distinctive patterns. The microvalve‐based bioprinting is efficient and accurate to build the in vitro tissue models with the potential to provide similar pathological responses and mechanism to human diseases, to mimic the phenotypic endpoints that are comparable with clinical studies, and to provide a realistic prediction of clinical efficacy.     

Tissue spheroid fusion‐based in vitro screening assays for analysis of tissue maturation

Organ printing or computer‐aided robotic layer‐by‐layer additive biofabrication of thick three‐dimensional (3D) living tissue constructs employing self‐assembling tissue spheroids is a rapidly evolving alternative to classic solid scaffold‐based approaches in tissue engineering. However, the absence of effective methods of accelerated tissue maturation immediately after bioprinting is the main technological imperative and potential impediment for further progress in the development of this emerging organ printing technology. Identification of the optimal combination of factors and conditions that accelerate tissue maturation (‘maturogenic’ factors) is an essential and necessary endeavour. Screening of maturogenic factors would be most efficiently accomplished using high‐throughput quantitative in vitro tissue maturation assays. We have recently reviewed the formation of solid scaffold‐free tissue constructs through the fusion of bioprinted tissue spheroids that have measurable material properties. We hypothesize that the fusion kinetics of these tissue spheroids will provide an efficacious in vitro assay of the level of tissue maturation. We report here the results of experimental testing of two simple quantitative tissue spheroid fusion‐based in vitro high‐throughput screening assays of tissue maturation: (a) a tissue spheroid envelopment assay; and (b) a tissue spheroid fusion kinetics assay. Copyright © 2010 John Wiley & Sons, Ltd.     

Optimizing a spontaneously contracting heart tissue patch with rat neonatal cardiac cells on fibrin gel

Engineered cardiac tissues have been constructed with primary or stem cell‐derived cardiac cells on natural or synthetic scaffolds. They represent a tremendous potential for the treatment of injured areas through the addition of tensional support and delivery of sufficient cells. In this study, 1–6 million (M) neonatal cardiac cells were seeded on fibrin gels to fabricate cardiac tissue patches, and the effects of culture time and cell density on spontaneous contraction rates, twitch forces and paced response frequencies were measured. Electrocardiograms and signal volume index of connexin 43 were also analysed. Patches of 1–6 M cell densities exhibited maximal contraction rates in the range 305–410 beats/min (bpm) within the first 4 days after plating; low cell density (1–3 M) patches sustained rhythmic contraction longer than high cell density patches (4–6 M). Patches with 1–6 M cell densities generated contractile forces in the range 2.245–14.065 mN/mm³ on days 4–6. Upon patch formation, a paced response frequency of approximately 6 Hz was obtained, and decreased to approximately 3 Hz after 6 days of culture. High cell density patches contained a thicker real cardiac tissue layer, which generated higher R‐wave amplitudes; however, low‐density patches had a greater signal volume index of connexin 43. In addition, all patches manifested endothelial cell growth and robust nuclear division. The present study demonstrates that the proper time for in vivo implantation of this cardiac construct is just at patch formation, and patches with 3–4 M cell densities are the best candidates. Copyright © 2014 John Wiley & Sons, Ltd.     

Poly(3‐hydroxyoctanoate), a promising new material for cardiac tissue engineering

Cardiac tissue engineering (CTE) is currently a prime focus of research because of an enormous clinical need. In the present work, a novel functional material, poly(3‐hydroxyoctanoate), P(3HO), a medium chain‐length polyhydroxyalkanoate (PHA), produced using bacterial fermentation, was studied as a new potential material for CTE. Engineered constructs with improved mechanical properties, crucial for supporting the organ during new tissue regeneration, and enhanced surface topography, to allow efficient cell adhesion and proliferation, were fabricated. Results showed that the mechanical properties of the final patches were close to that of cardiac muscle. Biocompatibility of neat P(3HO) patches, assessed using neonatal ventricular rat myocytes (NVRM), showed that the polymer was as good as collagen in terms of cell viability, proliferation and adhesion. Enhanced cell adhesion and proliferation properties were observed when porous and fibrous structures were incorporated into the patches. In addition, no deleterious effect was observed on adult cardiomyocyte contraction when cardiomyocytes were seeded on the P(3HO) patches. Hence, P(3HO)‐based multifunctional cardiac patches are promising constructs for efficient CTE. This work will have a positive impact on the development of P(3HO) and other PHAs as a novel new family of biodegradable functional materials with huge potential in a range of different biomedical applications, particularly CTE, leading to further interest and exploitation of these materials. Copyright © 2016 John Wiley & Sons, Ltd.     

In situ handheld three‐dimensional bioprinting for cartilage regeneration

Articular cartilage injuries experienced at an early age can lead to the development of osteoarthritis later in life. In situ three‐dimensional (3D) printing is an exciting and innovative biofabrication technology that enables the surgeon to deliver tissue‐engineering techniques at the time and location of need. We have created a hand‐held 3D printing device (biopen) that allows the simultaneous coaxial extrusion of bioscaffold and cultured cells directly into the cartilage defect in vivo in a single‐session surgery. This pilot study assessed the ability of the biopen to repair a full‐thickness chondral defect and the early outcomes in cartilage regeneration, and compared these results with other treatments in a large animal model. A standardized critical‐sized full‐thickness chondral defect was created in the weight‐bearing surface of the lateral and medial condyles of both femurs of six sheep. Each defect was treated with one of the following treatments: (i) hand‐held in situ 3D printed bioscaffold using the biopen (HH group), (ii) preconstructed bench‐based printed bioscaffolds (BB group), (iii) microfractures (MF group) or (iv) untreated (control, C group). At 8 weeks after surgery, macroscopic, microscopic and biomechanical tests were performed. Surgical 3D bioprinting was performed in all animals without any intra‐ or postoperative complication. The HH biopen allowed early cartilage regeneration. The results of this study show that real‐time, in vivo bioprinting with cells and scaffold is a feasible means of delivering a regenerative medicine strategy in a large animal model to regenerate articular cartilage.     

The fabrication and characterization of a multi‐laminate,angle‐ply collagen patch for annulus fibrosus repair

One major limitation of intervertebral disc (IVD) repair is that no ideal biomaterial has been developed that effectively mimics the angle‐ply collagen architecture and mechanical properties of the native annulus fibrosus (AF). Furthermore, it would be beneficial to devise a simple, scalable process by which to manufacture a biomimetic biomaterial that could function as a mechanical repair patch to be secured over a large defect in the outer AF that will support AF tissue regeneration. Such a biomaterial would: (1) enable the employment of early‐stage interventional strategies to treat IVD degeneration (i.e. nucleus pulposus arthroplasty); (2) prevent IVD re‐herniation in patients with large AF defects; and (3) serve as a platform to develop full‐thickness AF and whole IVD tissue engineering strategies. Due to the innate collagen fibre alignment and mechanical strength of pericardium, a procedure was developed to assemble multi‐laminate angle‐ply AF patches derived from decellularized pericardial tissue. Patches were subsequently assessed histologically to confirm angle‐ply microarchitecture, and mechanically assessed for biaxial burst strength and tensile properties. Additionally, patch cytocompatibility was evaluated following seeding with bovine AF cells. This study demonstrated the effective removal of porcine cell remnants from the pericardium, and the ability to reliably produce multi‐laminate patches with angle‐ply architecture using a simple assembly technique. Resultant patches demonstrated their inherent ability to resist biaxial burst pressures reminiscent of intradiscal pressures commonly borne by the AF, and exhibited tensile strength and modulus values reported for native human AF. Furthermore, the biomaterial supported AF cell viability, infiltration and proliferation. Copyright © 2016 John Wiley & Sons, Ltd.     

Local application of lactoferrin promotes bone regeneration in a rat critical‐sized calvarial defect model as demonstrated by micro‐CT and histological analysis

Lactoferrin is a multifunctional glycoprotein with therapeutic potential for bone tissue engineering. The aim of this study was to assess the efficacy of local application of lactoferrin on bone regeneration. Five‐millimetre critical‐sized defects were created over the right parietal bone in 64 Sprague–Dawley rats. The rats were randomized into four groups: group 1 (n  =  20) had empty defects; group 2 (n  =  20) had defects grafted with collagen gels (3 mg/ml); group 3 (n  =  20) had defects grafted with collagen gels impregnated with bovine lactoferrin (10 μg/gel); and group 4 (n  =  4) had sham surgeries (skin and periosteal incisions only). The rats were sacrificed at 4 or 12 weeks post‐operatively, and the calvaria were excised and evaluated with micro‐CT (Skyscan 1172) followed by histology. The bone volume fraction (BV/TV) was higher in lactoferrin‐treated animals at both timepoints, with groups 1, 2, 3 and 4 measuring 10.5  ±  1.1%, 8.6  ±  1.4%, 16.5  ±  0.6% and 24.27  ±  2.6%, respectively, at 4 weeks (P  <  0.05); and 12.2  ±  1.3%, 13.6  ±  1.5%, 21.9  ±  1.2% and 29.3  ±  0.8%, respectively, at 12 weeks (P  <  0.05). Histological analysis revealed that the newly formed bone within the calvarial defects of all groups was a mixture of woven and lamellar bone, with more bone in the group treated with lactoferrin at both timepoints. Our study demonstrated that local application of lactoferrin significantly increased bone regeneration in a rat critical‐sized calvarial defect model. The profound effect of lactoferrin on bone regeneration has therapeutic potential to improve the poor clinical outcomes associated with bony non‐union. LF In Vivo JTERM Authors Contributions. Copyright © 2016 The Authors Journal of Tissue Engineering and Regenerative Medicine Published by John Wiley & Sons, Ltd.     

TGFβ3 secretion by three‐dimensional cultures of human dental apical papilla mesenchymal stem cells

Mesenchymal stem cells (MSCs) can be isolated from dental tissues, such as pulp and periodontal ligament; the dental apical papilla (DAP) is a less‐studied MSC source. These dental‐derived MSCs are of great interest because of their potential as an accessible source for cell‐based therapies and tissue‐engineering (TE) approaches. Much of the interest regarding MSCs relies on the trophic‐mediated repair and regenerative effects observed when they are implanted. TGFβ3 is a key growth factor involved in tissue regeneration and scarless tissue repair. We hypothesized that human DAP‐derived MSCs (hSCAPs) can produce and secrete TGFβ3 in response to micro‐environmental cues. For this, we encapsulated hSCAPs in different types of matrix and evaluated TGFβ3 secretion. We found that dynamic changes of cell–matrix interactions and mechanical stress that cells sense during the transition from a monolayer culture (two‐dimensional, 2D) towards a three‐dimensional (3D) culture condition, rather than the different chemical composition of the scaffolds, may trigger the TGFβ3 secretion, while monolayer cultures showed almost 10‐fold less secretion of TGFβ3. The study of these interactions is provided as a cornerstone in designing future strategies in TE and cell therapy that are more efficient and effective for repair/regeneration of damaged tissues. Copyright © 2015 John Wiley & Sons, Ltd.     

Short‐term evaluation of electromagnetic field pretreatment of adipose‐derived stem cells to improve bone healing

An electromagnetic field is an effective stimulation tool because it promotes bone defect healing, albeit in an unknown way. Although electromagnetic fields are used for treatment after surgery, many patients prefer cell‐based tissue regeneration procedures that do not require daily treatments. This study addressed the effects of an electromagnetic field on adipose‐derived stem cells (ASCs) to investigate the feasibility of pretreatment to accelerate bone regeneration. After identifying a uniform electromagnetic field inside a solenoid coil, we observed that a 45 Hz electromagnetic field induced osteogenic marker expression via bone morphogenetic protein, transforming growth factor β, and Wnt signalling pathways based on microarray analyses. This electromagnetic field increased osteogenic gene expression, alkaline phosphate activity and nodule formation in vitro within 2 weeks, indicating that this pretreatment may provide osteogenic potential to ASCs on three‐dimensional (3D) ceramic scaffolds. This pretreatment effect of an electromagnetic field resulted in significantly better bone regeneration in a mouse calvarial defect model over 4 weeks compared to that in the untreated group. This short‐term evaluation showed that the electromagnetic field pretreatment may be a future therapeutic option for bone defect treatment. Copyright © 2012 John Wiley & Sons, Ltd.