Millions of patients each year suffer from challenging non-healing bone defects secondary to trauma or disease (e.g. cancer, osteoporosis or osteomyelitis). Tissue engineering approach to non-healing bone defects has been investigated over the past few decades in a search for a novel solution for critical size bone defects. The success of the tissue engineering approach relies on three main pillars, the right type of cells; and appropriate scaffold; and a biologically relevant biochemical/ biophysical stimuli. When it comes to cells the mesodermal origin of mesenchymal stem cells and its well demonstrated multipotentiality makes it an ideal option to be used in musculoskeletal regeneration.

For the presented set of experimental assays, fully characterised (passage 3 to 5)ovine adipose-derived mesenchymal stems cells (Ad-MSC) were cultured either in growth medium (GM) consisting of Dulbecco's Modification of Eagle's Medium (DMEM) supplemented with 10% (v/v) foetal bovine serum and 1% penicillin-streptomycin as a control or in osteogenic differentiation medium (DM), consisting of GM further supplemented with L- ascorbic acid (50 μg/ml), β-glycerophosphate (10 mM) and dexamethasone (100nM). Osteogenic differentiation was assessed biochemically by quantifying alkaline phosphatase (ALP) enzyme activity and alizarin red staining after 3, 7, 14 and 21 days in culture (where 1×105 cells/well were seeded in 24 well-plate, n=6/media type/ time point). Temporal patterns in osteogenic gene expression were quantified using real-time PCR for Runx-2, osteocalcin (OC), osteonectin (ON) and type 1 collagen (Col 1) at days 7, 15 and 21 (where 1×105 cells were seeded in T25 cell culture flasks for RNA extraction, n= 4 / gene/ media type/time point). The morphology of osteogenic cells was additionally evaluated by scanning electron microscopy (SEM) of cells seeded at low-density (1×102 cells) on glass coverslips for 2 weeks in GM or DM.

The level of ALP activity of cells grown in osteogenic DM was significantly higher than the control growing in the standard growth medium (p ≤ 0.05) at days 3, 7 and 14. At 21 days there was a sharp drop in ALP values in the differentiating cells. Mineralisation, as evidenced by alizarin red staining, increased significantly by day 14 and then peaked at day 21. Quantitative real-time PCR confirmed early increases in Runx-2, Col 1 and osteonectin, peaking in the second week of culture, while osteocalcin peaked at 21 days of culture. Taken as a whole, these data indicate that ovine-MSCs exhibit a tightly defined pathway of initial proliferation and matrix maturation (up to 14 days), followed by terminal differentiation and mineralisation (days 14 to 21). SEM analysis confirmed the flattened, roughened appearance of these cells and abandoned extracellular matrix which resembled mature osteoblasts.

Given the ready availability of adipose tissues, the use of Ad-MSCs as progenitors for bone tissue engineering applications is both feasible and reasonable. The data from this study indicate that Ad-MSCs follow a predictable pathway of differentiation that can be tracked using validated molecular and biochemical assays. Additional work is needed to confirm that these cells are osteogenic in vivo, and to identifying the best combination of scaffold materials and cell culture techniques (e.g. static versus dynamic) to accelerate or stimulate osteogenic differentiation for bone tissue engineering applications.

Adipose derived mesenchymal stromal cells (ASC) are adult stem cells exhibiting functional properties that have open the way for cell-based clinical therapies. Primarily, their capacity of multilineage differentiation has been explored in a number of strategies for skeletal tissue regeneration. More recently, MSCs have been reported to exhibit immunosuppressive as well as healing capacities, to improve angiogenesis and prevent apoptosis or fibrosis through the secretion of paracrine mediators. Among the degenerative diseases associated with aging, osteoarthritis is the most common pathology and affects 16% of the female population over 65 years. Up to now, no therapeutic option exists to obtain a sustainable improvement of joint function beside knee arthroplasty. This prompted us to propose adipose derived stem cells as a possible cell therapy. We performed pre-clinical models of osteoarthritis and showed that a local injection of ASC showed a reduction of synovitis, reduction of osteophytes, joint stabilization, reducing the score of cartilage lesions. This work was completed by toxicology data showing the excellent tolerance of the local injection of ADSC and biodistribution showing the persistence of cells after 6 months in murine models. The aim of the ADIPOA trial is to demonstrate the efficacy of adipose derived stem cells therapy in knee osteoarthritis (OA) in a phase 2/3 controlled multicenter study controlled against standard of care. Safety and feasibility as well as dose response was previously assessed in the ADIPOA FP7 project. The bi-centric phase I clinical trial in Montpellier (France) and Würzburg (Germany) included 18 patients with moderate to severe knee OA, each patient received a single injection of autologous ADSC, in a open scale up dose trial, starting form 2 10 6 cells to 50 106 cells. The 107 dose appears to be well tolerated and showed preliminary response in terms of decreasing local inflammation. This first study confirmed the feasibility and safety of local injection of ADSC in knee OA and suggested the most effective dose (107 autologous ADSC). This work constituted a significant step forward treating this disease with ADSC to demonstrate safety of the procedure. we conduct a prospective multicenter randomized Phase 2/3 study with 86 patients with moderate to severe knee OA to demonstrate superiority of stem cell-based therapy compared to standard of care (SOC) in terms in reduction in clinical symptoms (WOMAC score) and structural benefit (assessed by T1rhoMRI that allow quantification of cartilage proteoglycan content). This project will offer EU a unique leadership in OA with strong positions in EU and US due to patents and quality of the methodology to demonstrate efficiency of ADSC. ADIPOA brings together a unique combination of expertises and leaders in clinical rheumatology, MRI specialists, Stem cell Institutes, national GMP grade adipose derived stem cell production platform (ECELLFRANCE) and SME specialized in cell therapy trials in the EU. The production of the cells will be granted to EFS through ECELLFRANCE national platform, which have the GMP facility and will work as a contracting manufacturing organization. The expertise, leadership and critical mass achieved by this Consortium should enable breakthroughs in ASC engineering directly amenable for clinical applications in OA

Intervertebral disc degeneration can lead to physical disability and significant pain, while the present therapeutics still fail to biochemically and biomechanically restore the tissue. Stem cell-based therapy in treating intervertebral disc (IVD) degeneration is promising while transplanting cells alone might not be adequate for effective regeneration. Recently, gene modification and 3D-printing strategies represent promising strategies to enhanced therapeutic efficacy of MSC therapy. In this regard, we hypothesized that the combination of thermosensitive chitosan hydrogel and adipose derived stem cells (ADSCs) engineered with modRNA encoding Interleukin − 4 (IL-4) can inhibit inflammation and promote the regeneration of the degenerative IVD. Rat ADSCs were acquired from adipose tissue and transfected with modRNAs. First, the kinetics and efficacy of modRNA-mediated gene transfer in mouse ADSCs were analyzed in vitro. Next, we applied an indirect co-culture system to analyze the pro-anabolic potential of IL-4 modRNA engineered ADSCs (named as IL-4-ADSCs) on nucleus pulposus cells. ModRNA transfected mouse ADSCs with high efficiency and the IL-4 modRNA-transfected ADSCs facilitated burst-like production of bio-functional IL-4 protein. In vitro, IL-4-ADSCs induced increased anabolic markers expression of nucleus pulposus cells in inflammation environment compared to untreated ADSCs. These findings collectively supported the therapeutic potential of the combination of thermosensitive chitosan hydrogel and IL-4-ADSCs for intervertebral disc degeneration management. Histological and in vivo validation are now being conducted

Photobiomodulation (PBM), the use of light for regenerative purposes, has a long history with first documentations several thousand years ago in ancient Egypt and a Nobel Price on this topic at the beginning of last century (by Niels Finsen). Nowadays, it is in clinical use for indications such as wound healing, pain relief and anti-inflammatory treatment. Given the rising numbers of in vitro studies, there is increasing evidence for the underlying mechanisms such as wavelength dependent reactive oxygen production and adenosine triphosphate generation. In cartilage regeneration, the use of PBM is controversially discussed with divergent results in clinics and insufficient in vitro studies. As non-invasive therapy, PMB is, though, of particular importance, since a general regenerative stimulus would be of great benefit in the otherwise only surgically accessible tissues. We therefore investigated the influence of different wavelengths - blue (475 nm), green (516 nm) or red (635 nm) of a low-level laser (LLL) - on the chondrogenic differentiation of chondrocytes and adipose derived stromal cells of different human donors and applied the light in different settings (2D, 3D) with cells in a proliferative or differentiating stage. All assessed parameters (spheroid growth, histology, matrix quantification and gene expression) revealed an influence of LLL on chondrogenesis in a donor-, wavelength- and culture-model-dependent manner. Especially encouraging was the finding, that cells with poor chondrogenic potential could be improved by one single 2D treatment. Amongst the three wave lengths, red light was the most promising one with the most positive impact. Although in vivo data are still missing, these in vitro results provide evidence for a proper biofunctional effect of LLL

In the field of tissue engineering (TE), mainly two approaches have been widely studied and utilised throughout the last two decades. Ovsianikov et al. proposed a third strategy for tissue engineering to combine the advantages of the scaffold-based and scaffold-free approach [1]. We utilise the third strategy for TE by fabrication of cell spheroids that are reinforced by microscaffolds, called tissue units (TUs). Aim of the presented study is to differentiate TUs towards a chondrogenic phenotype to show the self-assembly of a millimetre sized cartilage-like tissue in a bottom-up TE approach in vitro. Two-Photon polymerization (2PP) was utilised to fabricate highly porous microscaffolds with a diameter of 300 µm. The biocompatible and biodegradable, resin Degrad INX (supplied from Xpect INX, Ghent, Belgium) was used for 3D-printing. Each microscaffold was seeded with 4000 human adipose derived stem cells (hASCs) in low-adhesive 96-well plates to allow spheroid formation. TUs were differentiated towards the chondrogenic lineage by application of chondrogenic media, subsequently merged in a cylindrical agarose mold, to fuse into a connected tissue with a diameter of ~1.8 mm and a height of 8 mm. The characterization of TUs differentiated towards the chondrogenic phenotype included gene expression and protein analysis. Furthermore, immunohistochemically staining for Collagen II and Alcian blue staining were performed to investigate the matrix deposition and fusion of the self-assembled tissue. Our results suggest that the utilised method could be a promising approach for a variety of tissue engineering approaches, due to the good applicability to a defect side combined with the self-assembly properties of the TUs. Furthermore, the differentiation potential of hASCs is not limited to chondrogenic lineages only, which could pave the way to further TE applications in the future. Acknowledgements:. This research work was financially supported by the European Research Council (Consolidator Grant 772464 A.O.)

Porcine and fish by-products in particular are rich sources for collagen, which is the main component of the extracellular matrix (ECM). Although there are studies investigating different collagen derived from various tissue sources for the purpose of creating biomaterials, the comparison of biophysical, biochemical and biological properties of type II collagen isolated from cartilaginous tissues has yet to be assessed. In addition, it has been shown from previous studies that sex steroid hormones affect the collagen content in male and female animals, herein, type II collagens from male and female porcine cartilage were assessed in order to investigate gender effects on the property of collagen scaffolds. Moreover, type II collagen has a supportive role in articular cartilage in the knee joint. Therefore, the aim is to assess the properties of type II collagen scaffolds as a function of species, tissue and gender for cartilage regeneration. Type II collagen was extracted from male and female porcine trachea, auricular, articular cartilage and cartilaginous fish through acid-pepsin digestion at 4°C. SDS-PAGE was conducted to confirm the purity of extracted collagen. Collagen sponges were created via freeze-drying. Scaffold structure and pore size were evaluated by scanning electron microscopy (SEM). Thermal stability was assessed by differential scanning calorimetry (DSC). Sponges were seeded with human adipose derived stem cells to assess chondro-inductive potential of collagen sponges after 7, 14 and 21 days of culture. In conclusion, collagen sponges support the proliferation and differentiation of human adipose derived stem cells to different extents

Mesenchymal stem/stromal cells (MSC) have the ability to home and migrate towards injured and inflamed tissues which can be useful as a minimally invasive systemic approach to deliver MSC to the site of damaged articular surface in arthritis in human and veterinary patients. From a molecular point of view, the CXCR4/SDF-1 plays an important role in this phenomenon and can be used as a target to enhance the therapeutic efficacy of culture expanded MSC. It has been demonstrated that extensive in vitro expansion down-regulates CXCR4 expression in human, murine and canine MSCs hindering their therapeutic efficacy. Therefore, the aim of the present study was to assess the effect of hypoxia and basic fibroblast growth factor (bFGF) pre-conditioning on CXCR4 and SDF-1 expression in canine adipose derived MSC (cAT-MSC). MSC were isolated from subcutaneous adipose tissue of two adult Beagle dogs (n=2; 3–5 years old, 9–12kg) and cultured under standard conditions (5%CO. 2. , 37°C). Cells at passage 3 were then cultured in hypoxia (2%O. 2. ) and normoxia, with supplementation of 1 and 5 ng/ml bFGF for 24h. MTT assay, flow cytometry, immunohistochemistry and qRT-PCR analysis were conducted to assess respectively the modulation effect on cell proliferation, CXCR4 protein expression and CXCR4 and SDF-1 gene expression. Cell proliferation increased proportionally with the increasing bFGF concentrations, with a statistically significant higher proliferative rate in normoxic conditions (p<0.05). The gene expression of CXCR4 and SDF-1 increased in hypoxic conditions with bFGF supplementation (p<0.05). bFGF supplementation increased cytoplasmatic expression of CXCR4 in hypoxic conditions (p<0.05), however the surface expression remained low in all culture conditions. The described pre-conditioning method can be used for the enhancement of the therapeutic potential of systemically administered canine AT-MSC and can have a relevant translational character for the optimization of culturing protocols of human adipose derived MSC

The in vitro mimicking of bone microenvironment for the study of pathologies is a challenging field that requires the design of scaffolds with suitable morphological, structural and cytocompatible properties. During last years, 3D in vitro tumour models have been developed to reproduce mechanical, biochemical and structural bone microenvironment elements, allowing cells to behave as in vivo. In this work, gas foamed polyether urethane foams (PUF) and 3D printed thermoplastic polyether urethane (3DP-PU) designed with different patterns are proposed as scaffolds for in vitro model of bone tissue. Surface coatings for a biomimetic behaviour of the 3D scaffold models were also investigated. Morphological, chemico-physical, mechanical properties, and biological in vitro behaviour were investigated. PUFs for metastases investigation. The suitability of PUF as 3D in vitro model to study the interactions between bone tumour initiating cells and the bone microenvironment was investigated. PUF open porosity (>70%) appeared suitable to mimic trabecular bone structure. Human adipose derived stem cells (ADSC) were cultured and differentiated into osteoblast lineage on the PU foam, as confirmed by Alizarin Red staining and RT-PCR, thus offering a bone biomimetic microenvironment to the further co-culture with bone derived tumour-initiating cells (MCFS). Tumour aggregates were observed after three weeks of co-culture by e-cadherin staining and SEM; modification in CaP distribution was identified by SEM-EDX and associated to the presence of tumour cells. 3DP-PU as tumour bone model. 3D printed scaffolds have pores with a precise and regular geometry (0°-90°, 0°-45°-90°-135°, 0°-60°-120°). PU scaffold porosity evidenced values from 55 to 67%, values that belong to the porosity range of the trabecular bone tissue (30-90%). The compressive modulus varied between 2 and 4 MPa, depending on the printed pattern. Biomimetic nanostructured coating was performed on 0-90° 3DP-PU by Ionized Jet Deposition. Coatings had a submicrometric thickness, variable tuning deposition time, nanostructured surface morphology and biomimetic composition. Coating on 3DP-PU promoted cells colonization of the whole porous scaffolds, compared to the controls, where cells concentrated mostly on the outer layers. In conclusion, based on the obtained results, scaffolds with different geometries have been successfully produced. Morphological and structural properties of the scaffolds here presented are suitable for mimicking the bone tissue, in order to produce a 3D in vitro model useful for bone pathologies research

Introduction and Objective. Osteoarthritis (OA) represents one of the leading cause of disability all over the world. Cell therapies, mainly based on mesenchymal stem cells (MSCs), have shown to modulate the pathogenesis of OA in basic, preclinical and clinical studies. Adipose tissue (AT) have emerged as a rich and promising source of MSCs called adipose derived stem cells (ASCs). Different systems are available for processing lipoaspirate to purify the samples from oily and haemorrhagic fractions, minimizing the risk of complications and maximizing the biological yield for subsequent grafting. However, few studies compared the efficacy of the different processing devices already used in clinical practice. This study aims to characterize the products obtained by the use of two different systems such as micro-fragmentation or nano-fragmentation comparing them with the starting material (AT) and the collagenase isolated ASCs. Materials and Methods. AT from 12 donors arrived without selection to the laboratories: 4 lipoaspirated (LA), 4 micro-fragmented (mF) and 4 nano-fragmented (nF). The samples were divided into three aliquots for paraffin embedding, RNA extraction and digestion with collagenase for ASCs isolation. Paraffin embedded tissue sections were stained with hematoxylin-eosin to analyze morphology. RNA was extracted, retro-transcribed and analyzed with real-time PCR to analyze the expression of pluripotency genes (SOX2, NANOG and POU5F1) and inflammatory genes (IL-1beta and iNOS). Data were analyzed using Graphpad Prism 8.0 and expressed as mean ± SD. One-way ANOVA followed by Tukey test was used to compare the different groups. Results. The LA comprised small lobules, with intact cell membranes and structurally integer adipocytes. mF samples showed the presence of integer adipocytes, small lobules and higher amount of cell clusters. nF samples showed the almost completely absence of adipocytes, a high amount of cells without lipid content and a high amount of stromal matrix. Real-time PCR results showed the lowest expression levels of pluripotency genes in LA samples that were assumed equal to 1.0 and used to calculate the expression levels of the other samples. mF showed expression levels of pluripotency genes similar to AT. nF showed expression levels of pluripotency genes higher than AT and mF, but without statistically significant differences. ASCs showed statistically significant higher expression levels of these genes compared to LA and mF (p ≤ 0.001). Likewise, the expression of inflammatory genes resulted to be lowest in LA samples (assumed equal to 1.0), higher in mF samples and in nF samples without statistical significance. As expected, the highest values were found in ASCs isolated cells compared to all the other samples (p ≤ 0.0001). Conclusions. These results confirmed that micro-fragmentation (mF) and nano-fragmentation (nF) permitted to separate a cell mixture enriched in ASCs from a lipoaspirate sample without activating the inflammatory pathways. Both processing methods gave a minimally manipulated product suitable for OA cell therapy application. Further studies are needed to elucidate possible different activities of the ASCs enriched AT-derivatives

The fibrocartilaginous enthesis displays a complex interface between two mechanically dissimilar tissues, namely tendon and bone. This graded transition zone consists of parallel collagen type I fibres arising from the tendon and inserting into bone across zones of fibrocartilage with aligned collagen type I and collagen type II fibres and mineralised fibrocartilage. Due the high stress concentrations arising at the interface, entheses are prone to traumatic and chronic overuse injuries such as rotator cuff and anterior cruciate ligament (ACL) tears. Treatment strategies range from surgical reattachment for complete tears and conservative treatments (physiotherapy, anti-inflammatory drugs) in chronic inflammatory conditions. Generally, the native tissue architecture is not re-established and mechanically inferior scar tissue is formed. Current interfacial tissue engineering approaches pose scaffold-associated drawbacks and limitations, such as foreign body response. Using a thermo-responsive electrospun scaffold that provides architectural signals similar to native tissues and can be removed prior to implantation, we aim to develop an ECM-rich, cell-based implant for tendon-enthesis regeneration. Alcian blue staining revealed highest sGAG deposition in cell (human adipose derived stem cells) sheets grown on random electrospun fibres and lowest sGAG deposition in collagen type I sponges. Cells did not show an equal distribution throughout the collagen type II scaffolds but tended to form localised aggregates. Thermo-responsive electrospun fibres with random and aligned fibre orientation provided an adequate three-dimensional environment for chondrogenic differentiation of multilayer hADSC-sheets shown by high ECM-production, especially high sGAG deposition. Chondrogenic cell sheets showed increased expression of SOX9, COL2A1, COL1A1, COMP and ACAN after 7 days of chondrogenic induction when compared to pellet culture. Anisotropic fibres enabled the generation of aligned chondrogenic cell sheets, shown by cell and collagen fibre alignment. Thermoresponsive electrospun fibres showed high chondro-inductivity due to their three-dimensionality and therefore pose a promising tool for the generation of scaffold-free multilayer constructs for tendon-enthesis repair within short culture periods. Aligned chondrogenic cell sheets mimic the zonal orientation of the native enthesis as the fibrocartilaginous zone exhibits high collagen alignment

Summary Statement. A resorbable and biocompatible polymer-based scaffold was used for the proliferation and delivery of adipose derived stromal cells, as well as delivery of a cell growth/differentiation promoting factor for improved tendon defect regeneration. Introduction. Surgeons perform thousands of direct tendon repairs annually. Repaired tendons fail to return to normal function following injury, and thus require continued efforts to improve patient outcomes. The ability to produce regenerate tendon tissue with properties equal to pre-injured tendon could lead to improved treatment outcomes. The aim of this study was to investigate in vivo tendon regeneration using a biodegradable polymer for the delivery of adipose derived stromal cells (ADSCs) and a polypeptide, growth/differentiation factor-5/(GDF-5), in a tendon gap model. Patients & Methods. Female Fischer 344 rats underwent unilateral Achilles tenotomies. Defects were left un-repaired (Group 1-control), bridged using electrospun 65:35 polylactide-co-glycolide (PLAGA) tubular scaffolds (Group 2), PLAGA/ADSCs (Group 3), or PLAGA/GDF-5 (Group 4) scaffold composites. The plantaris was left intact. Operative limbs were immobilised for 10–14 days, followed by unrestricted activity. The rats were sacrificed at 4 weeks or 8 weeks after surgery, and tendons were assessed with histological, biochemical, and mechanical analyses. Results. PLAGA, PLAGA/ADSCs, and PLAGA/GDF-5 groups showed increased collagen I gene expression at both the 4 and 8 week time points (p<0.05). Tenomodulin (Tnmd) is the mature tendon phenotype marker unique to tendon tissue. Both the PLAGA/ADSCs and PLAGA/GDF-5 groups demonstrated increased tenomodulin expression at 4 and 8 weeks (p<0.05). Ultimate tensile load strength was improved in all PLAGA groups (2, 3, and 4) versus the control. Both composite groups (2 and 3) showed improved collagen deposition, as indicated by increased Collagen Area Fraction (CAF), approaching that of normal tendon at 8 weeks (p<0.05). Scaffold resorption was evident at 4 weeks, with complete replacement of the polymer with regenerate tissue and minimal gap formation at 8 weeks without evidence of an adverse inflammatory reaction. Defects bridged using the scaffold seeded with ADSCs showed improved collagen organization and increased modulus of elasticity compared with controls as well as properties approaching those of native tendon. Discussion/Conclusions. These results demonstrate that a tubular bioresorbable scaffold can promote extracellular matrix synthesis and organization, and the formation of neo-tendinous tissue; as well as serve as a carrier of adipose stromal cells and growth factors that are effective for tendon regeneration. Cells, growth factors and synthetic biomaterial polymers may be combined as a paradigm for regenerative engineering thereby serving as promising options for improved treatments of tendon injuries and potentially improving patient outcomes

Tissue engineering by self-assembly is a technique that consists of growing cells on surfaces made of thermoresponsive polymers, that allow the production of contiguous cell sheets by simply lowering the temperature below the polymer's low critical solution temperature. In this approach cell-cell junctions and deposited extracellular matrix (ECM) remain intact, which provides a better cell localisation at the site of injury. However, these systems lack the possibility to fabricate multi-layered and three-dimensional cell sheets that would better recapitulate native tissues. Moreover, the fabrication of ECM-rich cell sheets would be highly desirable. This limitation could be overcome by inducing macromolecular crowding (MMC) conditions. Herein we venture to fabricate electrospun thermoresponsive nanofibres to sustain the growth and detachment of ECM-rich tissue substitutes in the presence of a MMC microenvironment. A copolymer of 85% poly-N-isopropylacrylamide and 15% N-tert-butylacrylamide (pNIPAAm/NTBA) were used for all experiments. To create aligned nanofibers, the polymer was electrospun and collected on a mandrel rotating at 2000 rpm. Human adipose derived stem cells (hADSC) were treated with media containing macromolecular crowders to enhance matrix deposition. Cell viability and morphology were assessed, and immunocytochemistry was conducted in order to estimate matrix deposition and composition. Adipogenic, osteogenic and chondrogenic assays were performed both with and without the presence of MMC. Non-invasive cell detachment was enabled by decreasing the temperature of culture to 10 °C for 20 minutes. The electrospinning process resulted in the production of pNIPAm/NTBA fibres in the diameter range from 1 to 2 µm and an overall alignment of 80%. Cell viability, proliferation and metabolic activity revealed that hADSCs were able to grow on the thermoresponsive scaffold. The cells were able to detach as an intact cell sheet in presence of MMC. Moreover, it was demonstated that MMC, by a volume extrusion effect, enhances Collagen type I deposition, which is one of the main components of the ECM. Histological analysis revealed that in the presence of MMC the cells were able to self-assembled into three dimensional multi-layers. The cells were able to differentiate towards the osteogenic and adipogenic lineage in the presence of MMC. Interestingly we were able to fabricate three-dimensional chondrogenic cell sheet both with and without MMC. Collectively the pNIPAm/NTBA thermoresponsive fibres were able to sustain the growth and the detachment of ECM-rich multi-layered cell sheets. The pNIPAm/NTBA fibres were able to successfully sustain growth and detachment of ECM-rich tissue equivalents. We believe that replacement, repair and restoration of tissue function can be accomplished best using cells that create their own tissue-specific extracellular matrix with a precision and stoichiometric efficiency still unmatched by man-made devices

One of the latest trends in the field of tissue engineering is the development of in vitro 3D systems mimicking the target tissue or organ and thus recapitulating the tridimensional structure and microenvironment experienced by cells in vivo. Interestingly, certain tissues are known to be regulated by endogenous bioelectrical cues, in addition to chemical and mechanical cues. One such tissue is the bone. It has, indeed, been demonstrated to exhibit piezoelectric properties in vivo, with electrical signaling playing a role in its formation during the early embryo developmental stages. Electrical stimulation has been proven to sustain cell proliferation and to boost the expression of relevant genes and induce higher levels of enzymatic activities related to bone matrix deposition. Herein, we describe the development of a 3D model of bone tissue based on the conductive polymer PEDOT:PSS and human adipose derived stem cells. 3D electroactive porous scaffolds have been produced using the ice-templating technique, and different compositions (different ratios of conductive polymer to Collagen Type 1) have been explored. The developed scaffolds as well as cells interaction and response have been characterized. Overall, the results obtained so far highlight the usefulness of the porous conductive scaffolds as an in vitro platform for the development of 3D models for bone tissue engineering

A novel injectable hydrogel based on DNA and silicate nanodisks was fabricated and optimized to obtain a suitable drug delivery platform for biomedical applications. Precisely, the hydrogel was designed by combining two different type of networks: a first network (type A) made of interconnections between neighboring DNA strands and a second one (type B) consisting of electrostatic interactions between the silicate nanodisks and the DNA backbone. The silicate nanodisks were introduced to increase the viscosity of the DNA physical hydrogel and improve their shear-thinning properties. Additionally, the silicate nanodisks were selected to modulate the release capability of the designed network. DNA 4% solutions were heated at 90°C for 45 seconds and cooled down at 37°C degree for two hours. In the second step, the silicate nanodisks suspension in water at different concentrations (0.1 up to 0.5%) were then mixed with the pre-gel DNA hydrogels to obtain the nanocomposite hydrogels. Rheological studies were carried out to investigate the shear thinning properties of the hydrogels. Additionally, the hydrogels were characterized by scanning electron microscopy (SEM), Fourier-transform infrared spectroscopy (FTIR), and X-ray photoelectron microscopy. The hydrogels were loaded with the osteoinductive drug dexamethasone and its release was tested in vitro in phosphate buffer pH 7.4. The drug activity upon release was tested evaluating the osteogenic differentiation of human adipose derived stem cells (hASCs) in vitro through analysis of main osteogenic markers and quantification of alkaline phosphatase activity and calcium deposition. Finally, the hydrogels were tested in vivo and injected into cranial defects in rats to assess their biocompatibility and bone regeneration potential. The inclusion of the silicate nanodisks increased the viscosity of the hydrogels and the best results were obtained with the highest concentration of the nanoclay (0.5%). The hydrogels possessed shear-thinning properties as demonstrated by cyclic strain sweep tests and were able to recover their original storage modulus G' upon removal of strain. Such improvement in the injectable properties of the formulated hydrogels was mainly attributed to the formation of electrostatic interactions between the silicate nanodisks and the phosphate groups of the DNA backbone as confirmed by XPS analysis of the O, N, and P spectra. Additionally, laponite was able to sustain the release of the osteoinductive drug dexamethasone which was instead completely released from the DNA-based hydrogels after a week. The drug after being released was still active and promoted the osteogenic differentiation of hASCs as confirmed by ALP expression and expression of main osteogenic markers including ALP and COLA1. Finally, the gels proved to be biocompatible in vivo when injected into cranial defects and promoted bone formation at the periphery of the defect after a month post-treatment. A novel injectable shear-thinning DNA-based hydrogel was characterized and tested for its drug delivery properties. The hydrogel can promote the sustain release of a small molecule like dexamethasone and be biocompatible in vitro and in vivo. Due to these promising findings, the designed system could find also applicability for the delivery of growth factors or other therapeutic molecules

Osteoarthritis (OA) is the fastest growing global health problem, with a total joint replacement being the only effective treatment for patients with end stage OA. Many groups are examining the use of bone marrow or adipose derived mesenchymal stem cells (MSCs) to repair cartilage, or modulate inflammation to promote healing, however, little efficacy in promoting cartilage repair, or reducing patient symptoms over temporary treatments such as micro-fracture has been observed. There is a growing body of literature demonstrating that MSCs derived from the synovial lining of the joint are superior in terms of chondrogenic differentiation and while improvements in clinical outcome measures have been observed with synovial MSCs, results from clinical studies are still highly variable. Based on our results, we believe this variability in clinical studies with MSCs results in part from the isolation, expansion and re-injection of distinct MSCs subtypes in normal vs. OA tissues, each with differing regenerating potential. However, it remains unknown if this heterogeneity is natural (e.g. multiple MSC subtypes present) or if MSCs are influenced by factors in vivo (disease state/stage). Therefore, in this study, we undertook an ‘omics’ screening approach on MSCs from normal and OA knee synovial tissue. Specifically, we characterized their global proteome and genomic expression patterns to determine if multiple MSC from normal and OA joints are distinct at the protein/gene expression level and/if so, what proteins/genes are differentially expressed between MSCs derived from normal and OA synovial tissue. Synovium tissue was collected from OA patients undergoing joint replacement and normal cadaveric knees. The in vitro adipogenic, chondrogenic and osteogenic differentiation potential of the MSCs was analyzed via qPCR and histology. Fully characterized MSC populations where then analyzed through an unbiased shotgun proteomics, and microarray analysis. Synovial MSCs isolated from both OA and normal knees demonstrated similar multipotent differentiation capacity. Likewise, both OA and normal MSCs display the typical MSCs cell surface marker profile in vitro (CD90+, CD44+, CD73+, CD105+). Using shotgun proteomics, 7720 unique peptides corresponding to 2183 proteins were identified and quantified between normal and OA MSCs. Of these 2183 proteins, 994 were equally expressed in normal and OA, MSCs, 324 were upregulated in OA MSCs (with 50 proteins exclusively expressed in OA MSCs), 630 proteins were upregulated in normal MSCs (with 16 proteins exclusively expressed in normal MSCs). Microarray analysis of normal and OA MSCs demonstrated a similar result in where, 967 genes were differentially expressed between normal and OA MSCs, with 423 genes upregulated in OA, and 544 genes upregulated in normal MSCs. In this project, we have demonstrated that although normal and OA synovial derived MSCs demonstrate similar multipotent differentiation potential and cell surface markers expression, these cells demonstrated significant differences at the molecular level (protein and gene expression). Further research is required to determine if these differences influence functional differences in vitro and/or in vivo and what drives this dramatic change in the regulatory pathways within normal vs. OA synovial MSCs

Tissue engineering by self-assembly offers the possibility to fabricate contiguous cell sheets that are stabilised by intact cell-cell contacts and endogenously produced extracellular matrix (ECM) However, these systems lack the possibility to introduce topographical cues, that are fundamental for the organisation of many types of tissues. Herein we venture to fabricate aligned electrospun thermoresponsive nanofibres to sustain growth and detachment of ECM-rich living substitutes in the presence of a MMC microenvironment. A copolymer of 85% poly-N-isopropylacrylamide and 15% N-tert-butylacrylamide (pNIPAAm/NTBA) were used. To create aligned nanofibers, the polymer was electrospun and collected on a mandrel rotating at 2000 rpm. Human adipose derived stem cells (hADSC) were treated with media containing macromolecular crowders to enhance matrix deposition. Cell viability and morphology were assessed, and immunocytochemistry was conducted to estimate matrix deposition and composition. Non-invasive cell detachment was enabled by decreasing the temperature of culture to 10 °C for 20 minutes. The electrospinning process resulted in the production of pNIPAm/NTBA fibres in the diameter range from 1 to 2 µm and an overall alignment of 80%. Cell viability revealed that hADSCs were able to grow on the scaffold. The cells aligned on the fibres after 3 days and they were able to detach as intact cell sheets in presence of MMC. Moreover, it was demonstrated that MMC, by a volume extrusion effect, enhances collagen type I deposition, one of the main components of the ECM. Collectively the pNIPAm/NTBA fibres were able to successfully sustain growth and detachment of ECM-rich cell sheets

Bone tissue engineering has the intent to grow bone copies in the laboratory that could be used either for bone regeneration or as model systems to study bone physiology and pathology. Bone marrow- or adipose derived derived mesenchymal stromal cells are commonly used as they have been shown to be capable to differentiate into osteoblasts and depositing a calcium phosphate rich extracellular matrix. However, real bone is more than that: there are commonly three cell types described that are essential contributors to the tissue's native function: osteoblasts, osteocytes and osteoclasts. While all three cell types are being investigated separately, co-cultures of them including their precursors and inactive forms still provide a huge challenge these days, both in terms of culturing and (quantitative) evaluation. In addition, the matrix deposited by the osteoblasts in vitro is still far from bone's hierarchical organization in vivo that contributes to bone's impressive mechanical properties. Using a large set of microscopic tools (micro-computed tomography, SEM, 3D FIB/SEM, TEM and fluorescence), combined with spectroscopic (FTIR) and molecular tools (qPCR) we show that our 3D model system develops the main features of bone by human stromal cells differentiating first into osteoblasts who further embed themselves to become osteocytes. In their right environment and when stimulated mechanically, the cells are embedded within a collagenous matrix which is mineralized with carbonated hydroxyapatite. While this system still needs the addition of osteoclasts to represent ‘real’ bone, it allows to study the interaction between osteoblasts and osteocytes and to invest parameters contributing to collagen mineralization in high resolution and cryogenic conditions

Among the innovative therapeutic techniques in orthopedics, a considerable interest arose around Mesenchymal Stem Cells (MSCs) - based therapies for one-step clinical applications. In order to achieve a better cell targeting at the injury site, these applications would need a specific cell delivery system. Hence, in this study a protocol for an efficient cell delivery based on the rapid cell adhesion on the surface of lyophilized fibroin-coated alginate microcarriers (L-FAMs) was optimized by the Design of Experiment (DoE) method in accordance with the minimum requirements for one-step clinical application. Specific parameters (seeding time, intermittent or not dynamic culture, stirring speed and volume of cell suspension) were combined in 13 different protocols, tested on human Adipose derived stem cells - ASCs (n=3). Cell adhesion rate in term of DNA quantification and metabolic activity of cells adhered on L-FAMs, and their qualitative observations by Calcein Staining were evaluated. The data showed that a suspension of 3.75 × 10. 5. cells/ml and 10 mg/ml of FAMs, 12.3 rpm of stirring speed and 85.6 minutes of seeding time are the most performing combination of parameters. The final protocol was then tested and validated on both hASCs (n=3) and human bone marrow derived stem cells - BMSCs (n=3). The results confirmed a high adhesion rate of cells, homogenously arranged on the surface of L-FAMs without cell cluster formation. Even though further optimizations are still needed, the present protocol may represent the proof of concept for the introduction of L-FAMs as carriers in one-step intraoperative applications

Abstract. Osteoarthritis (OA) is a degenerative disorder associated with cartilage loss and is a leading cause of disability around the world. In old age, the capacity of cartilage to regenerate is diminished. With an aging population, the burden of OA is set to rise. Currently, there is no definitive treatment for OA. However, cell-based therapies derived from adipose tissue are promising. A PRISMA systematic review was conducted employing four databases (MEDLINE, EMBASE, Cochrane, Web of Science) to identify all clinical studies that utilized adipose tissue derived mesenchymal stem cells (AMSCs) or stromal vascular fraction (SVF) for the treatment of knee OA. Eighteen studies were included, which met the inclusion criteria. Meta-analyses were conducted on fourteen of these studies, which all documented WOMAC scores after the administration of AMSCs. Pooled analysis revealed that cell-based treatments definitively improve WOMAC scores, post treatment. These improvements increased with time. The studies in this meta-analysis have established the safety and efficacy of both AMSC therapy and SVF therapy for knee OA in old adults and show that they reduce pain and improve knee function in symptomatic knee OA suggesting that they may be effective therapies to improve mobility in an aging population

Mesenchymal stem cells (MSCs) are usually believed to be immune-privileged. However, immunogenic MSCs were also reported. We hypothesize that there are differences between MSC clones from the same individual in terms of their morphology, proliferation, differentiation and immunogenicity. Our goal is to discover immune-privileged stem cells for universal allogenic MSCs transplantation. Serial dilutions of bone-marrow derived (BMMSCs) and adipose derived mesenchymal stem cells (ADMSCs) from same animal were carried out to isolate single-cell clones. From a single animal we obtained 3 clones from BMMSCs and 3 from ADMSCs. The proliferation rate of each clonal culture and mixed clonal culture were measured. The tri-differentiation potential of the clonal cultures was compared, as well as with the original isolates from bone marrow and fat. The immune-privileged properties were measured by flow cytometry and immuno-staining for the major histocompatibility complex (MHC) antigens. Mixed leucocyte reaction (MLR) were also performed to investigate immunogenicity. Tri-differentiation was confirmed in all isolates. All clonal cultures revealed significant different morphology and proliferation rates, compared with each other and mixed cultures. All clonal cultures showed different surface markers, inclusive of MHC antigens. One clone from ADMSCs showed lack of MHC antigens. Our MLR and MHC staining disclosed variety of immune properties. All clones tri-differentiated which indicated a degree of ‘stemness’. MSCs are generally believed not to express MHC II, resulting in immune-privileged. Our results confirmed our hypothesis because clonal cultures isolated from different origins of same animal show differences in morphology, proliferation rate, and surface marker presentation. Individual immune differences highlighted through single-cell clonal cultures may be crucial to find universal immune-privileged MSCs as universal allogeneic donor