Objectives. Recently, the field of tissue engineering has made numerous advances towards achieving artificial tendon substitutes with excellent mechanical and histological properties, and has had some promising experimental results. The purpose of this systematic review is to assess the efficacy of tissue engineering in the treatment of tendon injuries. Methods. We searched MEDLINE, Embase, and the Cochrane Library for the time period 1999 to 2016 for trials investigating tissue engineering used to improve tendon healing in animal models. The studies were screened for inclusion based on randomization, controls, and reported measurable outcomes. The RevMan software package was used for the meta-analysis. Results. A total of 388 references were retrieved and 35 studies were included in this systematic review. The different biomaterials developed were analyzed and we found that they improve the biomechanical and histological characteristics of the repaired tendon. At meta-analysis, despite a high heterogeneity, it revealed a statistically significant effect in favour of the maximum load, the maximum stress, and the Young’s modulus between experimental and control groups. In the forest plot, the diamond was on the right side of the vertical line and did not intersect with the line, favouring experimental groups. Conclusions. This review of the literature demonstrates the heterogeneity in the tendon tissue engineering literature. Several biomaterials have been developed and have been shown to enhance tendon healing and regeneration with improved outcomes. Cite this article: D. González-Quevedo, I. Martínez-Medina, A. Campos, F. Campos, V. Carriel. Tissue engineering strategies for the treatment of tendon injuries: a systematic review and meta-analysis of animal models. Bone Joint Res 2018;7:318–324. DOI: 10.1302/2046-3758.74.BJR-2017-0326

When transferring tissue regenerative strategies involving skeletal stem cells to human application, consideration needs to be given to factors that may affect the function of the cells that are transferred. Local anaesthetics are frequently used during surgical procedures, either administered directly into the operative site or infiltrated subcutaneously around the wound. The aim of this study was to investigate the effects of commonly used local anaesthetics on the morphology, function and survival of human adult skeletal stem cells.

Cells from three patients who were undergoing elective hip replacement were harvested and incubated for two hours with 1% lidocaine, 0.5% levobupivacaine or 0.5% bupivacaine hydrochloride solutions. Viability was quantified using WST-1 and DNA assays. Viability and morphology were further characterised using CellTracker Green/Ethidium Homodimer-1 immunocytochemistry and function was assessed by an alkaline phosphatase assay. An additional group was cultured for a further seven days to allow potential recovery of the cells after removal of the local anaesthetic.

A statistically significant and dose dependent reduction in cell viability and number was observed in the cell cultures exposed to all three local anaesthetics at concentrations of 25% and 50%, and this was maintained even following culture for a further seven days.

This study indicates that certain local anaesthetic agents in widespread clinical use are deleterious to skeletal progenitor cells when studied in vitro; this might have relevance in clinical applications.

Currently, fibrin glue obtained from fibrinogen and thrombin of human and animal blood are widely investigated to use as injectable hydrogel for tissue engineering which contributes to minimally invasive surgery, superior biodegradability, cell attachment, proliferation and regenerating new tissue. However, most of them fail to achieve to be used for tissue engineering application because of a risk of immune response and poor mechanical properties. To overcome the limitation of fibrin glue and to reduce the usage of products from human and animal blood, the artificial fibrin glue materials were developed. Recently, cellulose nanofiber (CNF) as reinforcing agent has been explored for many tissue engineering applications such as bone and cartilage due to its impressive biological compatibility, biodegradability and mechanical properties. CNF was extracted from cassava pulp. PEO-PPO-PEO diacrylate block copolymer is a biodegradable synthetic polymers which is water insoluble hydrogel after curing by UV light at low intensity. To enhance the cell adhesion abilities, gelatin methacrylate (GelMA), the denature form of collagen was used to incorporate into hydrogel. The aim of this study was to develop the artificial fibrin glue from CNF reinforced PEO-PPO-PEO diacrylate block copolymer/GelMA injectable hydrogel. CNF/PEO-PPO-PEO diacrylate block copolymer/GelMA injectable hydrogels were prepared with 2-hydroxy-1-(4-(hydroxy ethoxy) phenyl)-2-methyl-1-propanone (Irgacure 2959) as a photoinitiator. The physicochemical properties were investigated by measuring various properties such as thickness, gel fraction, mechanical properties and water uptake. At optimal preparation condition, CNF reinforced injectable hydrogel was successful prepared after curing with UV light within 7 minutes. This hydrogel showed gel fraction and water uptake of 81 and 85%, respectively. The cytotoxicity, cell adhesion and proliferation of CNF reinforced injectable hydrogel was presented. Cellulose nanofiber from casava pulp was successfully used to prepare injectable hydrogel as artificial fibrin glue for tissue engineering. The hydrogel showed good physical properties which can be applied to use for tissue engineering application

A major obstacle in biofabrication is replicating the organization of the extracellular matrix and cellular patterns found in anisotropic tissues within bioengineered constructs. While magnetically-assisted 3D bioprinting techniques have the potential to create scaffolds that mimic natural biological structures, they currently lack the ability to accurately control the dispersion of magnetic substances within the bioinks without compromising the fidelity of the intended composite. To overcome this dichotomy, the concepts of magnetically- and matrix-assisted 3D bioprinting are combined here. This method preserves the resolution of printed structures by keeping low viscosity bioinks uncrosslinked during printing, which allows for the arrangement of magnetically-responsive microfibers without compromising the structural integrity of the design. Solidification is induced after the microfibers are arranged in the desired pattern. Furthermore, the precise design of these magnetic microfillers permits the utilization of low levels of inorganic materials and weak magnetic field strengths, which reduces the potential risks that may be associated with their use. The effectiveness of this approach is evaluated in the context of tendon tissue engineering, and the results demonstrate that combining the tendons like anisotropic fibrous microstructure with remote magneto-mechanical stimulation during in vitro maturation provides both biochemical and biophysical cues that effectively guide human adipose-derived stem cells towards a tenogenic phenotype In summary, the developed strategy allows the fabrication of anisotropic high-resolution magnetic composites with remote stimulation functionalities, opening new horizons for tissue engineering applications. Acknowledgments: ERC Grant CoG MagTendon nr 772817, BioChips PoC project nr 10106930, (PD/BD/129403/2017), (CEECIND/01375/2017), (2020.03410.CEECIND), (2022.05526.PTDC), (ED481B2019/025)

Tissue engineering and regenerative medicine are increasingly taking advantage of active materials, allowing to provide specific clues to the cells. In particular, the use of electroactive polymers that deliver electrical signals to the cells upon mechanical solicitation, open new scientific and technological opportunities, as they in fact mimic signals and effects present in living tissues, allowing the development of suitable microenvironments for tissue regeneration. In fact, electrical and electromechanical clues are among the most relevant ones in determining tissue functionality in tissues such as muscle and bone, among others, indicating their requirement for proper tissue regeneration. Piezoelectric polymers have already shown strong potential for novel tissue engineering strategies, once they can account for the existence of piezoelectricity within some specific tissues and also can modulate the electrical signals existing in tissue development and function. In this context, this talk reports on piezoelectric and magnetoelectric materials used for tissue engineering applications. The most used materials and morphologies for tissue engineering strategies are reported, together with the need of novel bioreactor designs allowing to take full advantage of those materials. Further, the main achievements, challenges and future needs for research and actual therapies will be presented and discussed

The key factors in Tissue Engineering are multipotent stem cells, growth factors (necessary to manipulate cell destiny) and scaffolds (3D constructs which support the growing tissue). Mesenchymal stem cells are the most important part of this equation, and it is procurement and manipulation of these that lies at the heart of tissue engineering. Luckily, mensenchymal stem cells can be obtained from many tissues, including synovium, bone marrow and periosteum. The use of bioreactors to optimise culture conditions and improve cell viability provides an opportunity to control stem cell destiny. Various Tissue Engineering strategies exist: manipulating cells in situ with osteogenic growth factors, such as BMP; implanting whole tissue grafts; and the use of Gene therapy. The tissues that concern orthopaedic surgeons are very diverse and no single tissue engineered construct will be able to fulfil all our clinical needs. Tissue engineering of articular cartilage is very difficult technically, but once accomplished will revolutionalise practice. The challenge lies in being able to produce cartilage as similar to native hyaline cartilage as possible. Although promising, ACI, using culture expanded cells, is able at best to produce hyaline-like cartilage but not the real thing. Multipotent mesenchymal stem cells are being used in this field. Even simply injecting these intraarticularly has been shown to retard the progression of OA in animal models. When attempting to regenerate meniscal cartilage, the mechanical properties of the scaffold become crucial, as the biomechanics of the knee are highly hostile. Ligaments and tendons, though the least complex tissues architecturally, have very high tensile properties which will be hard to replicate. The challenging aspects of Orthopaedic Tissue Engineering are manifold, yet the field itself is growing in leaps and bounds. Despite some initial setbacks, the new developments in this discipline are very encouraging

Tissue engineering in reconstructive surgery has many potential attractions, not the least to avoid donor site morbidity and reduce the potential need for allografts and prostheses. Currently there are only two products that have FDA approval in the United States, namely skin and cartilage. Other potential products being trialled are artificial blood vessels and heart valves. The common denominator of these is that they are essentially two dimensional and relatively avascular. Three dimensional tissue engineering has three essential components, (1) cells, (2) scaffold and (3) blood supply. Cells are most easily derived from an autologous source, by conventional tissue culture where they are expanded and implanted into the required site. They are committed cells and usually a large source of donor tissue is required to obtain an adequate source of cells for reconstruction. Stem cells have the potential to grow and differentiate, they may be embryonal which introduces ethical problems or adult stem cells. Cells can be genetically engineered to produce specific growth factors for the purpose of further cell proliferation, such as vascular endothelial growth factor for angiogenesis. The second essential is a scaffold for cells to adhere to and grow. This is particularly important for the development of the vascular network. Fibrin, PTFE (Dexon) Matrigel (a form of Laminen) or collagen are the most popular forms of matrix. The third and most essential component for three-dimensional tissue engineering is vascularization. To date, most tissue engineering research involves invitro studies of cell differentiation and growth but the invivo potential is limited because of inability to transfer a blood supply. At the Bernard O’Brien Institute at St Vincent’s Hospital, Melbourne, we have developed a model of invivo tissue engineering which involves the initial creation of a vascular core inside a plastic chamber which can be moulded to any desired shape. This construct seems to be an ideal environment for seeding of cells, including stem cells which allows them to survive and differentiate into various mesenchymal tissues. To date we have been able to generate skin flaps, fat, tissue and skeletal muscle. Although our prime interest has not been bone or cartilage it is reasonable to assume that this can be relatively simply produced in the same model from either stem cell sources or by the use of differentiating factors

Skeletal muscle tissue engineering has made progress towards production of functional tissues in line with the development in materials science and fabrication techniques. In particular, combining the specificity of 3D printing with smart materials has introduced a new concept called the 4D printing. Inspired by the unique properties of smart/responsive materials, we designed a bioink made of gelatin, a polymer with well-known cell compatibility, to be 3D printed on a magnetically responsive substrate. Gelatin was made photocrosslinkable by the methacrylate reaction (GELMA), and its viscosity was finetuned by blending with alginate which was later removed by alginate lyase treatment, so that the printability of the bioink as well as the cell viability can be finetuned. C2C12 mouse myoblasts-laden bioink was then 3D printed on a magnetic substrate for 4D shape-shifting. The magnetic substrate was produced using silicon rubber (EcoFlex) and carbonyl iron powders. After 3D printing, the bioink was crosslinked on the substrate, and the substrate was rolled with the help of a permanent magnet. Unrolled (Open) samples were used as the control group. The stiffness of the bioink matrix was found to be in the range of 13–45 kPa, which is the appropriate value for the adhesion of C2C12 cells. In the cell viability analysis, it was observed that the cells survived and could proliferate within the 7-day duration of the experiment. As a result of the immunofluorescence test, compared to the Open Group, more cell nuclei were observed overlapping MyoD1 expression in the Rolled Group; this indicated that the cells in these samples had more cell-cell interactions and therefore tended to form more myotubes. Acknowledgements: This research was supported by the TÜBİTAK 2211-A and YÖK 100/2000 scholarship programs

Successful anterior cruciate ligament (ACL) reconstructions strive a firm ligament-bone integration. Therefore, the aim of this study was to address in more detail the enthesis as the thriphasic bone attachment of the ACL using a tissue engineering approach. To establish a tissue-engineered enthesis-like construct, triphasic scaffolds embroidered from poly(L-lactide-co-caprolactone) and polylactic acid functionalized with collagen foam were colonized with osteogenically differentiated human mesenchymal stromal cells (hMSCs) and lapine (L) ACL fibroblasts. These triphasic scaffolds with a bone-, a fibrocartilage transition- and a ligament phase were seeded directly after spheroid assembly or with 14 days precultured LACL fibroblast spheroids and 14 days osteogenically differentiated hMSCs spheroids (=longer preculture) and cultured for further 14 days. Cell survival was tested. Collagen type I and vimentin were immunolabeled and the content of DNA and sulfated glycosaminoglycan (sGAG) was quantified. The relative gene expression of tenascin C, type I and X collagens, Mohawk and Runx2 was analyzed. Compared to the LACL spheroids the hMSC spheroids adhered better to the scaffold surface with faster cell outgrowth on the fibers. Collagen type I and vimentin were mainly detected in the hMSCs colonizing the bone zone. The DNA content was generally higher in the bone (hMSCs) than in the ligament zones and after short spheroid preculture higher than after longer preculture whereas the sGAG content was greater after longer preculture for both cell types. The longer precultivated hMSCs expressed more type I collagen in comparison to those only shortly precultured before scaffold seeding. Type I collagen and tenascin C were higher expressed in scaffolds directly colonized with LACL compared to those seeded after longer spheroid preculture. The gene expression of ECM components and transcription factors depended on cell type and preculturing condition. Zonal colonization of triphasic scaffolds using the spheroid method is possible offering a novel approach for enthesis tissue engineering

Background. Auxetic materials have a negative poisons ratio, and a number of native biological tissues are proposed to possess auxetic properties. One such tissue is annulus fibrosus (AF), the fibrous outer layers of the intervertebral disc (IVD). However, few studies to date have investigated the potential of these materials as tissue engineering scaffolds. Here we describe the potential of manually converted polyurethane (PU) foams as three dimensional cellular scaffolds for AF repair. Methods. Rat MSCs were seeded onto fibronectin coated auxetic foams at a cell density of 6.4 × 10. 3. cells/mm. 3. , and cultured for up to 3 weeks. Cell viability was assessed throughout culture and following culture scanning electron microscopy (SEM) was used to assess morphological characteristics. Histological assessment was performed to assess production of matrix proteins. Results. Cells adhered to the surface auxetic foams and remained viable for the 3 weeks investigated. Histology and SEM demonstrated cells within the full thickness of the auxetic foams, where extracellular matrix was starting to be produced following 3 weeks, including collagens suggesting differentiation of the MSCs. Conclusion. Auxetic PU foams have a significant potential for use in tissue engineering applications, potentially mimicking the multiaxial strains of annulus fibrous tissue. MSCs were shown to adhere, survive and produce matrix within the foams after 3 weeks, future work will focus on longer term studies and in depth analysis of the phenotype of the cells. No conflicts of interest. Funding provided by a grant from Sheffield Children's Hospital NHS trust

Purpose: The purpose of our tissue engineering work was to produce a substitute for the anterior cruciate ligament (ACL) in laboratory cultures for human implantation and to conduct fundamental studies on healing mechanisms. Material: We used cells isolated from ACL biopsies obtained from the host, type I bovine collagen, and two bone blocks to produce ACL in culture. Methods: Several layers of collagen containing host autologous ACL cells were superposed and linked to two bones that were placed on either side, according to a process currently being patented. The cells, or fibroblasts, enter into contact with the collagen matrix and start remodelling it, in the laboratory, before implantation. This ACL produced by tissue engineering can be ready for implantation 10–12 days after isolating the autologous cells from a ruptured ACL. Results: Implantation of autologous ACL reconstructs was successful in eight goats. Histological analysis of the implanted grafts showed permanent integration into the tissues after 1–13 months. Th synovial membrane was reformed and rapidly vascularised, about one month after the graft. Thereafter, remodelling of the collagen matrix led to the formation of a very dense network of fibres, organised in bundles, very comparable to the normal histological aspect of the ACL. The bone blocks were also integrated by incorporation into the femur and tibia of the host. Sharpey fibres were present at the bone-ligament surface and a well structured fibro-cartilage was observed. In addition, the synovial membrane around the graft was innervated five months after implantation, suggesting that propioception could be recovered over time. Finally, progressive gain in force reached 20 – 36% of the normal ACL, 9 to 13 months after implantation;. Discussion: These promising data demonstrate that an autologous ACL with an interesting potential for regeneration can be produced in the laboratory, avoiding the risk of rejection and sparing healthy knee structures, thus favouring more rapid functional rehabilitation. Conclusion: Tissue engineering is a new avenue of research with potential applications in orthopaedic surgery, particularly for reconstruction of the ACL

Organ and tissue decellularisation are promising approaches for the generation of scaffolds for tissue regeneration since these materials provides the accurate composition and architecture for the specific tissues. Repopulation of the devitalized matrixes is the most critical step and a challenge, especially in dense tissues such as cartilage. To overcome this difficulty, several chemical and mechanical strategies have been developed. Chemical extraction targeting specific matrix components such as elastin, makes auricular cartilage accessible for cells via channels originating from the elastic fiber network. However, chemical treatment for glycosaminoglycan removal is not sufficient to allow cell ingrowth in articular cartilage. As alternative, laser perforation has been developed allowing to engrave fine structures with controlled size, distance and depth, with reproducibility and high throughput. Two of the most commonly used laser technologies used in the medical field, the CO. 2. and femtosecond laser, were applied to hyaline cartilage with very different structural effect. Within this talk, the structuralizing possibilities of laser and enzymatic treatments, the effect on the matrix and the general advantages and disadvantages for tissue engineering are discussed. We believe that the optimal combination of chemical and laser treatment has high potential for a new generation of biomaterials for tissue engineering

Bottom-up tissue engineering (TE) strategies employing microscale living materials as building blocks provide a promising avenue for generating intricate 3D constructs resembling native tissues. These microtissue units exhibit high cell densities and a diverse extracellular matrix (ECM) composition, enhancing their biological relevance. By thoughtfully integrating different cell types, the establishment of vital cell-cell and cell-matrix interactions can be promoted, enabling the recreation of biomimetic micro-niches and the replication of complex morphogenetic processes. Notably, by co-assembling blood vessel-forming endothelial cells with supportive stromal cells, microtissues with stable capillary beds, referred to as vascular units (VUs), can be generated. Through a modular TE approach, these VUs can be further combined with other microtissues and biomaterials to construct large-scale vascularized tissues from the bottom up. Integration of VUs with technologies such as 3D bioprinting and microfluidics allows for the creation of structurally intricate and perfusable constructs. In this presentation, we will showcase examples of VUs and explore their applications in regenerative medicine and tissue modeling. Acknowledgements: This work was supported by project EndoSWITCH (PTDC/BTM-ORG/5154/2020) funded by FCT (Portuguese Foundation for Science and Technology)

By definition, a smart biomaterial is a material, such as a ceramic, alloy, gel or polymer, that can convert energy from one form into another by responding to a change in a stimulus in its environment. These stimuli may involve temperature, pH, moisture, or electric and magnetic fields. In particular, thermoresponsive biomaterials have been successfully employed to host mammalian cells with a view to musculoskeletal tissue engineering. The presentation provides an overview of the use of thermosensitive polymers for the non-enzymatic stem cell harvesting, cell sheet engineering, three-dimensional scaffolds fabrications and organ-printing materials

Tissue engineering is a promising approach to regenerate damaged skeletal tissues. In particular, the use of injectable hydrogels alleviates common issues of poor cell viability and engraftment. However, uncontrolled cell fate, resulting from unphysiological environments and degradation rates, still remain a hurdle and impedes tissue healing. We thus aim at developing a new platform of injectable hyaluronic acid (HA) hydrogels with a large panel of properties (stiffness, degradation…) matching those of skeletal tissues. Hence, HA with different molecular weights were functionalized with silylated moieties. Upon injection, these hydrogels formed through a sol-gel chemistry within 5 to 20 minutes in physiological conditions, as demonstrated by rheological characterization. By varying the crosslinking density and concentration, we obtained hydrogels spanning a large range of elastic moduli (E = 0.1–20 kPa), similar to those of native ECMs, with tunable biodegradation rates (from 24 hours to > 50 days) and swelling ratios (500 to 5000% (w/w)). Cell viability was confirmed by Live/Dead assays and will be completed by in vivo subcutaneous implantations in mice to study the foreign body reaction and degradation rate. We further developed hybrid HA/biphasic calcium phosphate granules hydrogels and demonstrated a strong mechanical reinforcement (E = 0.1 MPa) and a faster relaxation behaviour (τ. 1/2. < 400s), with similar degradation rates. Ongoing in vitro differentiation assays and in vivo implantations in a rabbit femur model will further assess their ability to drive bone regeneration. Collectively, these results suggest that this hydrogel platform offers promising outcomes for improved strategies in skeletal tissue engineering

Current issues being debated in ACL reconstruction include injury prevention, graft choice, graft positioning, graft fixation, graft remodelling and rehabilitation. Tissue engineering, the alteration of biological mechanisms by application of novel proteins, enzymes and hormones, is rapidly changing the way we approach all aspects of surgery. Tissue engineering techniques in ACL/PCL reconstruction focus on new biosynthetic ACL material, fixation of soft tissue grafts to bony tunnels and graft remodelling. OP-1 is recombinant human Osteogenic Protein 1 (BMP-7). It is a member of the Transforming Growth Factor β (TGFβ) super family. OP-1 promotes the recruitment, attachment, proliferation and differentiation of pluripotential mesenchymal stem cells. It promotes both osteogenesis and chondrogenesis. The carrier is highly purified bovine bone type 1 collagen, which provides an osteoconductive matrix. We have completed a study assessing the use of OP-1 as a means of enhancing early biological fixation of soft tissue grafts within bone tunnels in a sheep ACL model. We have commenced a clinical trial using OP-1 in adult ACL reconstruction, believing that OP-1 will enhance early biological graft fixation, and hence, improve clinical results, speed up rehabilitation and prevent tunnel widening. Other studies have shown the beneficial effects of BMP-2 on an extraarticular bone tendon fixation model, the use of TGF-B to enhance graft remodelling and the application of gene therapy to deliver BMP’s for enhanced graft fixation. Several projects are underway looking at creating biosynthetic ACL grafts using tissue engineering techniques. As opposed to purely synthhetic grafts, bioACL grafts are made of a collagen scaffold, allowing for remodelling and revascularisation. ACL reconstructive surgery is constantly evolving. Tissue engineering may provide us with a means of minimising morbidity, accelerating rehabilitation and improving the clinical outcome following this common surgery

Biodegradable porous scaffolds play an important role in tissue engineering as the temporary templates for transplanted cells to guide the formation of the new organs. The most commonly used porous scaffolds are constructed from two classes of biomaterials. One class consists of synthetic biodegradable polymers such as poly (α-hydroxy acids), poly(glycolic acid), poly(lactic acid), and their copolymer of poly(DL-lactic-co-glycolic acid) (PLGA). The other class consists of naturally derived polymers such as collagen. These biomaterials have their respective advantages and drawbacks. Therefore, hybridization of these biomaterials has been expected to combine their advantages to provide excellent three-dimensional porous biomaterials for tissue engineering. Our group developed one such kind of hybrid biodegradable porous scaffolds by hybridizing synthetic poly (α-hydroxy acids) with collagen. Collagen microsponges were nested in the pores of poly (α-hydroxy acids) sponge to construct the poly (α-hydroxy acids)-collagen hybrid sponge. Observation by scanning electron microscopy (SEM) showed that microsponges of collagen with interconnected pore structures were formed in the pores of poly (α-hydroxy acids) sponge. The mechanical strength of the hybrid sponge was higher than those of either poly (α-hydroxy acids) or collagen sponges both in dry and wet states. The wettability with water was improved by hybridization with collagen, which facilitated cell seeding in the hybrid sponge. Use of the poly (α-hydroxy acids) sponge as a skeleton facilitated formation of the hybrid sponge into the desired shapes with high mechanical strength, while collagen microsponges contributed good cell interaction and hydrophilicity. One of such kind of hybrids. Additionally, our group developed a hydrostatic pressure bioreactor for chondrocyte culture. And our study showed that hydrostatic pressure (0–3 MPa) had promotional effects on the production of proteoglycan and type II collagen by cultured chondrocytes. Therefore, it would be a promising pathway for reconstructing cartilage-like tissue to culture chondrocytes in this three-dimensional hybrid sponge under physiological hydrostatic pressure

Tissue engineering regards the generation, regeneration, augmentation or limitation of the structure and function of living tissues by the application of scientific and engineering principles. Skeletal defects resulting from tumor resection, congenital abnormalities or trauma often require surgical intervention to restore the function. Current option for bone replacement include autografts,allografts,metals,ceramic and polymers.However, all these materials have drawbacks, and their selection usually require some compromises. Skeletal tissues are under extensive investigation in tissue engineering research and beside the biological issues, the scaffolds design plays an important role. A number of biodegradable and bioabsorbable materials as well as scaffold designs, have been experimentally and, in some cases clinically studied. An appropriate scaffold should posses highly porous with interconnected pore network for cell growth and flow transport of nutrient and metabolic waste; biocompatible and bioresorbable with a controlled degradation and resorption rate to match cell/ tissue growth, suitable surface chemistry for cell attachment, proliferation and differentiation, and mechanical properties to match those of the implanted tissue. Synthetic biodegradable polymers and inorganic materials are promising as extracellular matrix analogue to facilitated tissue development and growth; these include: polyglycolic acid, poly-l-lactic acid, copolymers, poly-caprolactones, hydroxyapatite, tricalcium phosphates. All these scaffolds are well performing from biological and chemical-physical but they have some limitations from mechanical point of view. To overcome this problem a composite structure made by Polycaprolactone and Hydroxyapatite is studied by mechanical and biological analysis. To obtain a porous structure, the casting and salt leaching technique is implemented. The composite shows mechanical properties in the range of the spongy bone and interesting biological properties with regards to osteoblasts. Injectable gels made of collagen are analysed to carry cells, a preliminary results of collagen gel loaded with MSC cells have been performed and rheological and proliferation study are showing the feasibility to obtain a bioactive materials/cells to be inject in the defined body site defects avoiding massive surgery

Hyaline cartilage and immature nucleus pulposus possess similar macromolecules in their extracellular matrix, and there is no unique molecular marker to distinguish the two tissues. We show that in normal disc (fifteen to twenty-five years old), the GAG to hydroxyproline ratio (proteoglycan to collagen ratio) within the nucleus pulposus is approximately 28:1. However, the GAG to hydroxyproline ratio within hyaline cartilage of the same group is 2.5:1. This information is important in identifying stem cell conversion to a nucleus pulposus cell phenotype rather than a chondrocyte phenotype for tissue engineering of intervertebral disc. Tissue engineering of intervertebral discs (IVDs) using mesenchymal stem cells (MSCs) induced to differentiate into a disc-cell phenotype has been considered as an alternative treatment for disc degeneration. Since there is no unique marker for disc tissue, and because cartilage and immature nucleus pulposus (NP) possess similar macromolecules in their extracellular matrix, it is currently difficult to recognize MSC conversion to a disc cell. In this study, we compare the proteoglycan to collagen ratio in the NP of normal disc to that of the hyaline cartilage of the endplate within the same group of individuals. To distinguish between a normal NP and hyaline cartilage phenotype for tissue engineering of IVDs. Human lumbar spine specimens were harvested from fresh cadavers, aged twelve week to seventy-nine year. Discs and endplates were examined for total collagen using the hydroxyproline assay and glycosaminoglycan (GAG) content using a standard assay. In a mature disc with no degeneration (fifteen to twentyfive years), the GAG to hydroxyproline ratio within the NP is approximately 28:1. However, the ratio within the hyaline cartilage endplate of the same group is 2.5:1. A high proteoglycan to collagen ratio can be used to distinguish NP cells from chondrocytes. The lower NP collagen content is probably responsible for its gelatinous nature rather than the firm texture of hyaline cartilage, and this is essential for normal disc function. This information is crucial in identifying a NP-like phenotype when MSCs are induced to differentiate into a disc cell as opposed to a chondrocyte, for tissue engineering of IVDs

Collagen materials are extensively used in regenerative medicine. However, they still present limitations such as a mono-domain composition and poor mechanical properties. On the other hand, tissue grafts overcome most of these limitations. In addition, the potential of tissue grafts in musculoskeletal tissue engineering has not been fully investigated. Herein, we ventured to assess the potential of a decellularised porcine peritoneum for musculoskeletal applications by comparing its characteristics with a commercial collagen scaffold employed in tendon. Results indicated that the porcine peritoneum had higher mechanical properties and a lower crosslinking ratio (p < 0.01). Furthermore, it presented a lower resistance to collagenase digestion, which suggests a faster remodelling in vivo of the tissue graft. Immunohistochemistry analysis showed a preserved and multicomponent structure in the porcine peritoneum contrary to the collagen matrix, confirming the multifunctional nature of the tissue graft. Regarding the cell-response assessment, tenocytes and ADSCs were able to grow on both materials, however, proliferation was enhanced by the porcine peritoneum (p<0.01). Immune response by THP-1 showed an acute inflammatory response by macrophages to the collagen matrix, contrary to that observed in the porcine peritoneum which triggered a mild reaction. The in-progress in vivo study in a rabbit tendon model will elucidate the potential of porcine peritoneum for tendon repair applications. The present study shows how the multifunctionality of the porcine peritoneum provides higher cytocompatibility than a mono-domain collagen matrix with human tenocytes and ADSC. Besides, its lower immune response in vitro suggests better remodelling after implantation

Osteoarthritis (OA) is one of the most prevalent joint diseases involving progressive and degenerative changes to cartilage resulting from a variety of etiologies including post-traumatic incident or aging. OA lesions can be treated at its early stages through cell-based tissue engineering therapies using Mesenchymal Stem Cells (MSCs). In vivo models for evaluating these strategies, have described both chondral (impaction) and osteochondral (biopsy punch) defects. The aim of the investigation was to develop a compact and reproducible defect inducing post-traumatic degenerative changes mimicking early OA. Additionally, a pilot study to evaluate the efficacy of MSC-hydrogel treatment was also assessed. Surgery was performed on New Zealand white rabbits (male, 5–8 months old) with defects created on medial femoral condyle. For developing an appropriate defect, three approaches were used for evaluation: a biopsy punch (n = three at six and twelve weeks), an impaction device1 (n = three at six and twelve weeks) and a dental drill model (n = six at six and twelve weeks). At stated time points, condyles were harvested and decalcified in 10% EDTA, then embedded in Tissue-Tek and sectioned using a cryostat. Upon identification of region of interest, sections were stained with Safranin-O/Fast green and scored using OARSI scoring system by two blinded observers2. For the pilot study, autologous bone marrow was harvested from rabbits and used to isolate and expand MSCs. The Dental drill model was applied to both knee condyles, left untreated for six weeks at which stage, PKH26 fluorescently labelled MSCs were seeded into a hyaluronic acid hydrogel (TETEC). Repair tissue was removed from both condyles and MSC-hydrogel was injected into the left knee, whilst right knee was left empty. Rabbits were sacrificed at one (n = 1), six (n = 3) and twelve (n = 3) weeks post-treatment, processed as previously described and cartilage regeneration evaluated using Sellers score3. Impacted condyles exhibited no observed changes histologically (Mean OARSI score = 1 + 1), whereas biopsy punched and dental drilled defects demonstrated equal signs of cartilage erosion (OARSI score = 3 + 1) at assessed time points. However, biopsy punched condyles formed a diffusive defect, whereas dental drilled condyles showed a more defined, compact and reproducible defect. In the pilot study, PKH-labelled MSCs were observed at one and six weeks post-implantation within the defect space where hydrogel was injected. Tissue regeneration assessment indicated no difference between empty (Mean Sellers score = 14 + 2) and MSC treated defects (Sellers score = 16 + 5) at six weeks post-injection. At twelve weeks, MSC treated defects showed improved tissue regeneration with substantial subchondral bone restoration and good integration of regenerative cartilage with surrounding intact tissue (Sellers score = 10 + 1), whereas untreated defects showed no change in regeneration compared to six weeks (Sellers score = 16 + 2). Dental drill model was found to be the appropriate strategy for investigating early OA progression and treatment. Application of MSCs in defects showed good cartilage regeneration after twelve weeks application, indicating their promise in the treatment of early OA defects

Long-term regeneration of cartilage defects treated with tissue engineering constructs often fails because of insufficient integration with the host tissue. We hypothesize that construct integration will be improved when implants actively interact with and integrate into the subchondral bone. Growth and Differentiation Factor 5 (GDF-5) is known to support maturation of chondrocytes and to enhance chondrogenic differentiation and hypertrophy of mesenchymal stromal cells (MSC). Therefore, we investigated whether GDF-5 is capable to stimulate endochondral ossification of MSC in vitro and in vivo and would, thus, be a promising candidate for augmenting fibrin glue in order to support integration of tissue engineering constructs into the subchondral bone plate. To evaluate the adhesive strength of fibrin glue versus BioGlue. ®. , a commercially available glue used in vascular surgery, an ex vivo cadaver study was performed and adhesion strength was measured via pull-out testing. MSC were suspended in fibrin glue and cultivated in chondrogenic medium with and without 150 ng/mL GDF-5. After 4 weeks, the formed cartilage was evaluated and half of the constructs were implanted subcutaneously into immunodeficient mice. Endochondral ossification was evaluated after 2 and 4 weeks histologically and by microCT analysis. BioGlue. ®. and GDF-5-augmented fibrin glue were tested for 4 weeks in a minipig cartilage defect model to assess their orthotopic biocompatibility. Pull-out testing revealed sufficient adhesive strength of fibrin glue to fix polymeric CellCoTec constructs in 6 mm cartilage defects, however, BioGlue. ®. showed significantly higher adhesive power. In vitro chondrogenesis of MSC under GDF-5 treatment resulted in equal GAG deposition and COLIIa1 and ACAN gene expression compared to controls. Importantly, significantly increased ALP-activity under treatment with GDF-5 on day 28 indicated enhanced hypertrophic differentiation compared to controls. In vivo, MSC-fibrin constructs pre-cultured with GDF-5 developed a significantly higher bone volume on day 14 and 28 compared to controls. When pre-cultured with GDF-5 constructs showed furthermore a significantly higher bone compactness (bone surface/bone volume coefficient) than controls, and thus revealed a higher maturity of the formed bone at 2 weeks and 4 weeks. Orthotopic biocompatibility testing in minipigs showed good defect filling and no adverse reactions of the subchondral bone plate for defects treated with GDF-5-augmented fibrin glue. Defects treated with BioGlue. ®. , however, showed considerable subchondral bone lysis. Thus, BioGlue. ®. – despite its adhesive strength – should not be used for construct fixation in cartilage defects. GDF-5-augmented fibrin glue is considered promising, because of a combination of the adhesive strength of fibrin with an enhanced osteochondral activity of GDF-5 on MSC. Next step is to perform a large animal study to unravel whether GDF-5 stimulated endochondral ossification can improve scaffold integration in an orthotopic cartilage defect model

Introduction: The anterior cruciate ligament (ACL) is the most frequently damaged ligament in the knee joint. The patella tendon autograft is the current replacement of choice, however autografts are not always available and grafting often leads to donor site morbidity. Allogeneic implants may cause an adverse immunological reaction [. 1. ] The aim of this study was to develop an acellular tendon scaffold with the mechanical and biochemical properties of tissue which could be rapidly recellularised for use in tissue engineering of the anterior cruciate ligament. Materials and Methods: Porcine patella tendons were dissected less than 24 hours after slaughter and washed in PBS. The tendons were decellularised using 0.1% (w/ v) SDS for 24 hours. Decellularisation was assessed by haematoxylin and eosin staining and light microscopy. The glycosaminoglycan and hydroxyproline (measure of collagen) content of the scaffold were also assessed quantitatively following decellularisation. Following decellularisation the scaffolds were subject to various levels of ultrasonication in order to modify the acellular scaffold prior to reseeding in an attempt to achieve recellularisation of the scaffold. Denaturation of the collagen within the scaffold following ultrasonication was assessed using the ƒÑ-chymotrypsin assay. Decellularised and ultrasonicated scaffolds were subject to uniaxial tensile loading to failure in a Howden tensile testing machine. The sonicated scaffolds were reseeded with human tenocytes (1x105 cells.cm2) and cultured in 5% CO2 in air at 37°C for three weeks. One scaffold was removed every seven days and either fixed in 10% neutral buffered formalin prior to dehydration and H& E staining or was stained with Live/Dead stain (Molecular Probes) and observed using confocal microscopy. Results: Porcine patella tendons were successfully decellularised using 0.1% (w/v) SDS. Following decellularisation there was no change in the biochemical composition of the scaffold. Ultrasonication of the scaffold at 360W was shown to open up spaces between collagen bundles without damaging the collagen matrix and this was confirmed with the ƒÑ-chymotrypsin assay. Following decellularisation and ultrasonication there was no change in the ultimate force (N) needed to break the tendon scaffold. When cells were seeded onto the sonicated scaffold, the cells were shown to penetrate to the centre of the scaffold within just 3 weeks of culture. Following staining with Live/Dead stain it was shown that after three weeks in static culture approximately 50% of the cells in the centre of the scaffold were viable. In comparison the cells cultured on the acellular non-sonicated scaffold remained on the surface of the scaffold and did not penetrate the matrix during this culture period. Conclusion: An acellular scaffold with excellent biochemical and mechanical properties has been developed which can be recellularised in an important first step towards tissue engineering of the anterior cruciate ligament. Future work will investigate culture of the reseeded scaffold under appropriate physical stimulation with a view to maintaining tissue homeostasis and increasing cell viability

Aims: The aim of this research work was the realization of an inorganic bioactive scaffold for bone regeneration. This biomaterial should be macroporous, in order to allow the bone in-growth, and bioactive aiming to promote the bone regeneration and healing. Methods: The macroporous biomaterial was prepared by consolidation of a suspension of starch and SiO2-CaO-Na2O-MgO glass powders. Starch powders were used as both pore former and consolidation agent. Starch-glass green bodies were prepared by uniaxial pressing and, after drying, they were heated to remove the organic phase and to sinter the inorganic one. The sintered scaffolds were characterized by X-Ray diffraction, scanning electron microscopy and mercury intrusion porosimetry. The scaffolds bioactivity was evaluated soaking the samples in a simulated body fluid for periods up to 4 weeks. On the most representative samples, in vitro tests of adhesion and proliferation were performed using human primary osteoblast-like cells. Results: The obtained scaffolds showed an interconnected macroporosity of 50–100 B5m and a satisfactory degree of sintering. The sintering treatment induced the nucleation and growth of Na2Ca2(SiO2)3 crystals which is a phase that possess a very high bioactivity index. By soaking the scaffolds in SBF for period up to 1 month, an extensive precipitation of hydroxylapatite, with the typical globular morphology, occurred both inside and outside the pores. The adhesion and proliferation tests showed a remarkable spreading of the osteoblasts on the scaffold surface and thus a good biological response. Conclusions: Scaffolds with interconnected porosity were successfully obtained. The pores are highly interconnected and homogenously distributed in the samples. The chosen thermal treatment and the use of starch powders led to a final macroporous glass-ceramic structure. The obtained scaffolds showed a very high in vitro bioactivity with precipitation of HAp. Moreover, preliminary biological tests, showed a satisfactory cellular interaction with the proposed biomaterials. For the above-mentioned reasons, the starch consolidation method, the optimized processing parameters and the tailored glass composition can be used to produce scaffolds suitable for bone substitutions and tissue engineering

During the last decade there has been an increasing interest in the management of cartilage lesions, owing to the introduction of new therapeutic options. Beside the improvement of the classical vascular techniques (mosaicplasty, microfractures, etc.), cell therapy and tissue engineering have opened new perspectives in this field. One of the most recent tissue engineering techniques is represented by the MACI‚ (Matrix-induced Autologous Chondrocyte Implantation). This method requires seeding of autologous chondrocytes on a type I-III collagene membrane, after their arthroscopy harvesting from the knee and subsequent in vitro expansion of the cellular population using autologous serum. The seeded membrane is implanted in the chondral defect using exclusively fibrin glue, through a limited exposure joint approach. Membrane structure and its cellular population were investigated by light microscopy, SEM and electrophoresis (SDS PAGE 7%) before implantation. There was evidence of chondroblasts and type II collagen inside the seeded membrane. Clinical series. At the Institute of Orthopaedics and Traumatology of the University of Insubria in Varese (Italy), the MACI‚ technique was used for the treatment of 13 patients, affected by chondral defects, between December 1999 and January 2001. There were 9 males and 4 females with an average age of 35 years (range, 18 to 49 years). The sites of the defects were the following: 8 medial femoral condyle, 2 lateral femoral condyle, 1 femoral trochlea, 2 talar dome. The average size of the defects was 3.5 cm2 (range, 2 to 4.5 cm2). The clinical and functional evaluation was performed using the ICRS (International Cartilage Repair Society) rating scale, the modified Cincinnati rating system, Lysholm II and Tegner scores for the knee, while the AOFAS (American Orthopaedic Foot and Ankle Society) score was used for the ankle. MRIs were taken before the operation as well as at 6 and 12 months postoperatively. The average follow-up was 6.5 months (range, 2 to 15 months). No complications were observed in the postoperative period. The six patients with a minimum follow-up of 6 months showed an improvement in the clinical and functional status after the operation, as testified by the scores reached with the different rating systems used. MRIs showed the presence of hyaline-like cartilage at the site of implantation. Conclusions. According to our preliminary experience, the MACI‚ technique offers several advantages (technical simplicity, short operating times, minimal invasivity and easier access to difficult sites) and appears a reliable method for the repair of deep cartilage defects

The selection of a proper material to be used as a scaffold or as a hydrogel to support, hold or encapsulate cells is both a critical and a difficult choice that will determine the success of failure of any tissue engineering and regenerative medicine (TERM) strategy. We believe that the use of natural origin polymers, including a wide range of marine origin materials, is the best option for many different approaches that allow for the regeneration of different tissues. In addition to the selection of appropriate material systems it is of outmost importance the development of processing methodologies that allow for the production of adequate scaffolds/matrices, in many cases incorporating bioactive/differentiation agents in their structures. An adequate cell source should be selected. In many cases efficient cell isolation, expansion and differentiation, and in many cases the selection of a specific sub-population, methodologies should be developed and optimized. We have been using different human cell sources namely: mesenchymal stem cells from bone marrow, mesenchymal stem cells from human adipose tissue, human cells from amniotic fluids and membranes and cells obtained from human umbilical cords. The development of dynamic ways to culture the cells and of distinct ways to stimulate their differentiation in 3D environments, as well as the use of nano-based systems to induce their differentiation and internalization into cells, is also a key part of some of the strategies that are being developed in our research group. The potential of each combination materials/cells, to be used to develop novel useful regeneration therapies will be discussed. The use of different cells and their interactions with different natural origin degradable scaffolds and smart hydrogels will be described. Several examples of TERM strategies to regenerate different types of musculoskeletal tissues will be presented. Relevance to orthopaedics will be highlighted

The use of stem cells in tissue engineering has emerged as a promising therapy for the repair of bone and cartilage defects. Targeted delivery of stem cells requires a substrate to maintain the cells at the repair site, as well as to provide the physical cues, such as mechanical strain, for encouraging differentiation and expression of the mature cell phenotype. The strains that will be generated in cells residing on the scaffold is dependent on the scaffold material, as well as both the fibre thickness and the fibre orientation in the scaffold. To encourage uniform bone matrix generation throughout the scaffold, it is desirable that the strain be uniformly distributed and that the internal pore architecture be precisely controlled to maximise media diffusion. This requires an optimised scaffold design and a manufacturing technique that allows for precise control over the scaffold’s internal architecture. Scaffold architecture was optimised by performing a series of finite element analyses (FEA) on computer aided design (CAD) models of Polycaprolactone (PCL) scaffolds. The mechanical properties of PCL were used to yield an accurate strain profile of scaffolds with different fibre orientations. Having determined the optimal scaffold geometry, PCL scaffolds were manufactured using a fibre deposition technique that yielded three-dimensional objects with this geometry. During manufacture, a PCL solution was extruded into a non-miscible solvent which precipitated out PCL fibres in repetitive layers. Of the geometries tested with FEA, a 90 degree rotation of adjacent layers with a 50% offset of parallel strands was found to provide the optimal strain distribution (60% increase in surface exposed to strain). Histomorphometry was used to assess the exact dimensions of the scaffold produced. Fibre spacing was found to be precisely controlled to 380 +/- 10 microns within the layers and the fibre thickness was controlled to 270 +/- 10 microns. This demonstrates that FEA can be used to predict the strain distribution of different CAD models and that the fibre deposition solvent extrusion technique can be used to accurately manufacture PCL scaffolds that match the desired architecture

Tissue engineering is founded on the principle of pro-actively manipulating the triad of tissue regeneration. The triad consists of matrices, pluripotential cells and signaling factors. Our hypothesis is that advances in orthopedic surgery to successfully regenerate bone are accomplished by incorporating optimised matrices into the surgeon’s armamentarium. Pro Osteon is a bioactive ceramic matrix with interconnected porosity. It has been evaluated in experimental animals and used clinically as a bone graft substitute for more than two decades. It is available in slowly resorbable form composed of hydroxyapatite and as a more rapidly resorbable composite of calcium carbonate and calcium phosphate. Experiments have been conducted in sheep, rats and dogs to demonstrate consistent and predictable bone regeneration when the implant is placed in direct apposition to host bone, the host bone is viable and the interfaces between the bone and implants are biomechanically stable. Most importantly, controlled, multi-center clinical trials showed consistent efficacy and safety in humans. Either as a block or granules, Pro Osteon is biocompatible and osteophilic and osteoconductive. Bone regeneration, as demonstrated radiographically and histologically, occurs directly within the porous ceramic in traumatic defects and tumors. Where surrounding viable bone or mechanical stability is inadequate, such as posterior spinal fusion, the ceramic must be co-mixed with autograft. For indications where autograft is limited or unavailable, bone regeneration within the porosity was enhanced and fusion achieved by supplementing Pro Osteon with bone marrow and/or with growth factors. This was demonstrated experimentally and clinically. Mitogenic and/or morphogenic growth factors were demonstrated to increase the rate or degree of bone formation. Methods and equipment for intra-operative collection of concentrated platelets were shown to be a cost-effective and safe source of autologous mitogens. Using a variety of ectopic and orthotopic animals models, we have shown that autologous, purified xenogenic and recombinant growth factors will bind to the surface of Pro Osteon and initiate or stimulate the bone induction process. In conclusion, Pro Osteon is an effective matrix for bone formation. It can be used alone or it can be used in combination with pluripotential, osteogenic stem cells or with signaling proteins

Introduction: The aim of this study is to develop a novel approach to tissue engineering in vivo, in which the adaptive response of skeletal tissues to the imposed mechanical environment will be utilised to induce a cartilaginous resurfacing of the acetabular articulation in a hemi-arthroplasty model of hip replacement. Our hypothesis was that a cartilaginous resurfacing of subchondral bone can be induced by applying stresses of 0 to 3 MPa to the articular surface of the acetabulum. We used an ovine hemiarthroplasty model where the stresses on the acetabulum were engineered by using different femoral head sizes. Methods: Three groups of six sheep received unilateral hip hemi-arthroplasties and were sacrificed 24 weeks post-operatively to harvest the acetabula. At operation, acetabular cartilage was removed completely and the subchondral bone was reamed down and left bleeding. Three femoral head sizes, 25, 28, and 32-mm, were used to induce different contact stress levels. Vertical ground reaction force (GRF) data were measured and normalised by body weight for both limbs pre-operatively and every 4 weeks post-operatively. Five specimens from each group and eight unoperated controls were processed and stained with Safranin O and Sirius Red. Cartilage proteoglycans in the regenerated tissues from four specimens in the 25-mm group were detected by immunoblotting using specific monoclonal antibodies. Results: The operated limbs were subjected to an average of 80 to 90% pre-operative GRF after the eighth post-operative week and maintained till the end of the study. No significant difference was noted during the period between the three groups. A layer of regenerated tissue was noted on all specimens processed and was Sirius positive. Four operated specimens processed in the 25-mm group and three in the 28-mm group were Safranin O positive. The presence of cartilage aggrecan, cartilage link proteins, biglycan, and decorin was confirmed by immunoblotting. Discussion and Conclusion: We conclude that a cartilaginous resurfacing of acetabulum can be induced in vivo under the mechanical environment imposed by our hemi-arthroplasty model. This approach may be advantageous in clinical practice as a regenerated acetabular cartilaginous surface would avoid the problems associated with wear of the plastic acetabular cup and replacement of the acetabulum

Cultured primary cells have a limited life span and undergo dedifferentiation. Tissue engineering (TE) approaches require high cell numbers, but availability of human derived cells is limited and animal cells show inter-species differences. The advantages of immortalized cells are delayed senescence and phenotypic stability. The present study was undertaken to validate key properties of immortalized human anterior cruciate ligament (ACL) fibroblasts in direct comparison with non-immortalized cells from the same donor to assess their applicability as TE model. Human ACL ligamentocytes (40 years old female donor) were either immortalized using repeated transient transfection with a simian virus SV40 plasmid or remained untreated. Both cell populations were analyzed for cell survival, DNA content, tendon marker, extracellular matrix (ECM) and cytoskeletal protein expression. Cell spheroids of both populations were seeded on scaffolds embroidered either from polylactic acid (PLA) threads alone or combined PLA- and PLA-co-caprolacton-(P(LA-CL)) threads, functionalized with fluor treatment and collagen foams. Cell survival on the scaffolds was monitored for up to 5 weeks. In contrast to non-immortalized ligamentocytes, immortalized cells reflected some chaotic and incomplete cell divisions, higher DNA content, numbers of dying cells and nucleoli, reduced vimentin and vinculin-associated focal adhesions. Analysed markers, other cytoskeletal and ECM components were similarly expressed. Compared to the non-immortalized ligamentocytes immortalized formed instable spheroids and died on the scaffolds after 21 d. Both cell populations reflected superior growth on the PLA-P(LA-CL) compared with PLA scaffolds. Immortalized cells share crucial properties with their non-immortalized counterparts, but TE is only possible for limited culturing periods

Introduction: There is an ever-increasing clinical need for the regeneration and replacement of tissue to replace soft tissue lost due to trauma, disease and cosmetic surgery. A potential alternative to the current treatment modalities is the use of tissue engineering applications using mesenchymal stem cells that have been identified in many tissues including the fat pad. In this study, stem cells isolated from the fat pad were characterised and their differentiation potential assessed. Materials and Methods: The infrapatellar fat pad was obtained from total knee replacement for osteoarthritis. Cells were isolated, expanded and stained for a number of stem cell markers. For adipogenic differentiation, cells were cultured in adipogenic inducing medium (10ug/ml insulin, 1uM dexamthasone, 100uM indomethacin and 500uM 3-isobutyl-1-methyl xanthine). Gene expression analyses and Oil red O staining was performed to assess adipogenesis. Results: Cells at passage 2 stained strongly for CD13, CD29, CD44, CD90 and CD105 (mesenchymal stem cell markers). The cells stained sparsely for 3G5 (peri-cyte marker). On gene expression analyses, the cells cultured under adipogenic conditions had almost a 1,000 fold increase in expression of peroxisome proliferator-activated receptor gamma-2 (PPAR gamma-2) and 1,000,000 fold increase in expression of lipoprotein lipase (LPL). Oil red O staining revealed triglyceride accumulation within typical adipogenic morphology, confirming the adipogenic nature of the observed vacuoles, and showed failure of staining in control cells. Discussion: Fat pad derived stem cells expressed a cell surface epitope profile of mesenchymal stem cells, and exhibited the potential to undergo adipogenic differentiation. Our results show that the human fat pad is a viable potential autogeneic source for mesenchymal stem cells capable of adipogenic differentiation as well as previously documented ostegenic and chondrogenic differentiation. This cell source has potential use in tissue engineering applications

Tendons and tendon-to-bone entheses don't usually regenerate after injury, and the hierarchical organization of such tissues makes them challenging sites of study for tissue engineers. In this study, we have tried a novel approach using miRNA and a bioactive bioink to stimulate the regeneration of the enthesis. microRNAs (miRNAs) are short, non-coding sequences of RNA that act as post-transcriptional regulators of gene and protein expression [1]. Mimics or inhibitors of specific miRNAs can be used to restore lost functions at the cell level or improve healing at the tissue level [2,3]. We characterized the healing of a rat patellar enthesis and found that miRNA-16-5p was upregulated in the fibrotic portion of the injured tissue 10 days after the injury. Based on the reported interactions of miRNA-16-5p with the TGF-β pathway via targeting of SMAD3, we aimed to explore the effects of miRNA-16-5p mimics on the tenogenic differentiation of adipose-derived stem cells (ASCs) encapsulated in a bioactive bioink [4,5]. Bioinks with different properties are used for the 3D printing of biomimetic constructs. By integrating cells, materials, and bioactive molecules it is possible to tailor the regenerative capacity of the ink to meet the particular requirements of the tissue to engineer [5]. Here we have encapsulated ASCs in a gelatin-methacryloyl (GelMa) bioink that incorporates miR-16-5p mimics and magnetically responsive microfibers (MRFs). When the bioink is crosslinked in the presence of a magnetic field, the MRFs align unidirectionally to create an anisotropic construct with the ability to promote the tenogenic differentiation of the encapsulated ASCs. Additionally, the obtained GelMA hydrogels retained the encapsulated miRNA probes, which permitted the effective 3D transfection of the ASC and therefore, the regulation of gene expression, allowing to investigate the effects of the miR-16-5p mimics on the tenogenic differentiation of the ASCs in a biomimetic scenario.

The osteo-regenerative properties of allograft have recently been enhanced by addition of autogenous skeletal stem cells to treat orthopaedic conditions characterised by lost bone stock. There are however, multiple disadvantages to allograft, including cost, availability, consistency and potential for disease transmission, and trabecular tantalum represents a potential alternative. Tantalum is already in widespread orthopaedic use, although in applications where there is poor initial implant stability, or when tantalum is used in conjunction with bone grafting, loading may need to be limited until sound integration has occurred. Development of enhanced bone-implant integration strategies will improve patient outcomes, extending the clinical applications of tantalum as a substitute for allograft. The aim of this study was to examine the osteoconductive potential of trabecular tantalum in comparison to human allograft to determine its potential as an alternative to allograft. Human bone marrow stromal cells (500,000 cells per ml) were cultured on blocks of trabecular tantalum or allograft for 28 days in basal and osteogenic media. Molecular profiling, confocal and scanning electron microscopy, as well as live-dead staining and biochemical assays were used to characterise cell adherence, proliferation and phenotype. Cells displayed extensive adherence and proliferation throughout trabecular tantalum evidenced by CellTracker immunocytochemistry and SEM. Tantalum-cell constructs cultured in osteogenic conditions displayed extensive matrix production. Electron microscopy confirmed significant cellular growth through the tantalum to a depth of 5mm. In contrast to cells cultured with allograft in both basal and osteogenic conditions, cell proliferation assays showed significantly higher activity with tantalum than with allograft (P<0.01). Alkaline phosphatase (ALP) assay and molecular profiling confirmed no significant difference in expression of ALP, Runx-2, Col-1 and Sox-9 between cells cultured on tantalum and allograft. These studies demonstrate the ability of trabecular tantalum to support skeletal cell growth and osteogenic differentiation comparable to allograft. Trabecular tantalum represents a good alternative to allograft for tissue engineering osteo-regenerative strategies in the context of lost bone stock. Such clinical scenarios will become increasingly common given the ageing demographic, the projected rates of revision arthroplasty requiring bone stock replacement and the limitations of allograft. Further mechanical testing and in vivo studies are on-going

Background. Skeletal stem cells (SSCs) have been used for the treatment of osteonecrosis of the femoral head to prevent subsequent collapse. In isolation SSCs do not provide structural support but an innovative case series in Southampton, UK, has used SSCs in combination with impaction bone grafting (IBG) to improve both the biological and mechanical environment and to regenerate new bone at the necrotic site. Aims. Analysis of retrieved tissue-engineered bone as part of ongoing follow-up of this translational case series. Methods. With Proof-of-Concept established in vitro and in vivo, the use of a living bone composite of SSCs and allograft has been translated to four patients (five hips) for treatment of osteonecrosis of their femoral heads. Parallel in vitro culture of the implanted cell-graft construct was performed. Patient follow-up was by serial clinical and radiological examination. In one patient collapse occurred in both hips due to more advanced disease than was originally appreciated. This necessitated bilateral hip arthroplasty, but allowed retrieval of the femoral heads. These were analyzed for Type 1 Collagen production, bone morphology, bone density and mechanical strength by micro computed tomography (CT), histology (A/S stain, Collagen Type 1 immunostain, biorefringence) and mechanical testing. Representative sections of cortical, trabecular and tissue engineered bone were excised from the femoral heads using a diamond-tipped saw-blade and tested to failure by axial compression. Results. Parallel in vitro analysis demonstrated sustained cell growth and viability on the allograft. Three patients currently remain asymptomatic at up to three year follow-up. Histological analysis of the two retrieved femoral heads demonstrated, critically, Type 1 collagen production in the regenerated tissue as well as mature trabecular architecture, indicative of de novo tissue engineered bone. The trabecular morphology of regenerated bone was evident on CT, and this had a bone density of 1400 Grey scale units, (compared to 1200 for natural trabecular bone and 1800 for cortical bone). On axial compressive testing the regenerated bone on the left showed a 24.8% increase in compressive strength compared to ipsilateral normal trabecular bone, and a 22.9% increase on the left. Conclusions. Retrieval analysis data has demonstrated the translational potential of a living bone composite, while ongoing clinical follow-up shows this to be an effective new treatment for osteonecrosis of the femoral head. Regeneration of the necrotic bone may prevent subsequent collapse, thereby delaying, or possibly avoiding, the need for hip arthroplasty in early stage osteonecrosis. Evaluation of this tissue engineering construct has confirmed the potential for clinical treatment of bone defects using SSC based strategies

Angiogenesis and the ability to provide appropriate vascular supply are crucial for skeletal tissue engineering. The aim of this study was to investigate the angiogenic potential of human dental pulp stromal cells (HDPSCs) and stro-1 positive populations as well as their role in tissue regeneration (the clinical reality). HDPSC were isolated from the pulp tissues of human permanent teeth by collagenase digestion. STRO-1 positive cells were enriched using monoclonal anti- STRO-1 and anti- CD45 PE conjugated antibodies together with and fluorescence activated cell sorting (FACS). Cells isolated by FACS were grown to passage4 and cultured as monolayers or on 3D Matrigel scaffold in endothelial cell growth medium-2 (EGM-2) with/without 50ng/mL of vascular endothelial growth factor (VEGF). Cells cultured in alpha MEM supplemented with 10% FCS were used as controls. After 24, 48 and 72 hours angiogenic marker expression (CD31, CD34, vWF and VEGFR-2) was determined by qRT-PCR and immuno-histochemistry. Using three different donors, 0.5-1.5% of total HDPSCs population was characterized as STRO-1+/CD45- cells At each time point cells cultured as monolayer in EGM-2 with VEGF showed up regulation of CD31 and VEGFR-2 expression compared to the control group while expression of CD34 and vWF remained unaffected. However on Matrigel, all four genes were up regulated to different extents. CD31 and VEGFR-2 were up regulated to a greater degree compared to CD34 and vWF. Changes in gene expression in both cell types were time dependent. Immuno-histochemical staining confirmed that the HDPSCs cultured in the test group showed positive staining for the four angiogenic markers (CD31, CD34 vWF and VEGFR-2) when grown in both monolayer and 3D Matrigel culture compared to control cultures. When cultured on Matrigel (but not Monolayer) for 7 days, HDPSC formed tube-like structures in the VEGF treated group. This indicates the potential of use HDPSCs and their STRO-1 positive population for angiogenesis to enhance skeletal tissue repair and/or regeneration toward translational research for clinical benefit

Silk fibroin (SF) has been used as a scaffold for cartilage tissue engineering. Different silkworms strain produced different protein. Also, molecular weight of SF depends on extraction method. We hypothesised that strain of silkworm and method of SF extraction would effect biological properties of SF scaffold. Therefore, cell viability and chondrogenic gene expression of human chondrogenic progenitor cells (HCPCs) treated with SF from 10 silkworm strains and two common SF extraction methods were investigate in this study.

Twenty g of 10 strains silk cocoons were separately degummed in 0.02M Na2CO3 solution and dissolved in 100๐C for 30 minutes. Half of them were then dissolved in CaCl2/Ethanol/H2O [1:2:8 molar ratio] at 70±5๐C (method 1) and other half was dissolved in 46% w/v CaCl2 at 105±5๐C (method 2) for 4 hours. HCPCs were cultured in SF added cultured medial according to strain and extraction method. Cell viability at day 1, 3, and 7, were determined. Expression of collagen I, collagen II, and aggrecan at day 7 and 14, was studied. All experiment were done in triplicated samples.

Generally, method 1 SF extraction showed higher cell viability in all strains. Cell viability from Nanglai Saraburi, Laung Saraburi and Nangtui strains were higher than those without SF in every time point while Wanasawan and J108 had higher viability at day 1 and decreased by time. Expression in collagen 1, collagen 2 and aggrecan in method 1 are higher at day 7 and day 14. Collagen 1 expression was highest in Nangnoi Srisaket, followed by Laung Saraburi and Nanglai Saraburi in day 7. Nangnoi Srisaket also had highest expression at day 14, followed by Nanglai Saraburi and Laung Saraburi respectively. Nangseaw had highest collagen 2 expression, follow by Laung Saraburi and Nangnoi Srisaket respectively. Higher aggrecan gene expression of Tubtimsiam, Wanasawan, UB 1 and Nangnoi Srisaket was observed at day 7 and increased expression of all strains at day 14.

SF extraction using CaCl2/Ethanol/H2O offered better cell viability and chondrogenic expression. Nangseaw, Laung Saraburi and Nangnoi Srisaket strains expressed more chondrogenic phenotype.

Tissue engineering techniques, combining autologous chondrocytes with biodegradable biomaterials, may offer significant advantages over current articular cartilage repair strategies. We present a series of experiments investigating the effect of 3D scaffold architecture and biomaterial composition on cartilage tissue formation in vitro and in vivo. Porous polymer (PEGT/PBT) scaffolds with low (300/55/45) or high (1000/70/30) PEG molecular weight (MW) compositions were produced using novel solid free-form fabrication (3DF) techniques, allowing precise control over pore architecture, and conventional compression moulding (CM) foam techniques. Scaffolds were seeded with expanded human nasal chondrocytes, and cultured in vitro or implanted subcutaneously in vivo in nude mice for 4 weeks and cartilage tissue formation accessed. 3DF scaffolds contained highly accessible networks of large interconnecting pores (Ø525 μm) compared to CM scaffolds, containing complex networks of small interconnecting pores (Ø182 μm). 3DF scaffold architectures enhanced cell re-differentiation (GAG/DNA) and cartilaginous matrix accumulation compared to CM scaffolds, but only if 1000/70/30 compositions were used. Collagen type-II mRNA was significantly increased in 3DF architectures irrespective of scaffold composition. These effects were likely mediated by preferential protein adsorption to 1000/70/30 materials, promoting a spherical chondrocyte-like morphology, as well as efficient nutrient/waste exchange throughout interconnecting pores within 3DF architectures. We observed synergistic effects of both composition and 3D scaffold architecture on human chondrocyte re-differentiation capacity, however, our data suggests that scaffold composition has a more significant influence than architecture alone. Such design criteria could be included in future scaffold architectures for repairing articular cartilage defects

Purpose: Tissue engineering offers new therapeutic perspectives with the possibility of producing cartilage tissue for a large number of patients. These structures are composed of an absorbable synthetic support and competent cells. Two types of cells can be proposed: articular chondrocytes harvested from the peripheral part of the joint, or mesenchymatous stem cells (MSC) present in the bone marrow and possessing chondrogenic potential. The purpose of this study was to determine the optimal cell source and the best supporting material for in vitro production of cartilage. Material and methods: Isolated rabbit MSC were harvested and amplified with cell culture for 21 days. After this period, 20–40 million cells/ml were combined with polyglycolic acid sponges (3 types of sponges 1x1x0.2 cm2) and cultured in TGFß-enriched medium under specific dynamic conditions allowing gas exchange. The tissue obtained was compared with structures of identical size obtained with differentiated chondrocytes harvested from the same animals. The study included a histological analysis and immunohistochemistry for type I, II, and X collagen and biochemistry for DNA content, glycosaminoglycanes (GAG) and type II collagen. Results: After 3 weeks in culture, the composites obtained with MSC preserved their size and had the white pearly aspect of hyalin cartilage. The histological analysis and immunohistochemistry tests for type II collagen confirmed the presence of a cartilaginous matrix throughout the thickness of the fragments. The GAG and type II collagen contents were significantly higher with MSC compared with chondrocytes, irrespective of the supporting material. Discussion: This study demonstrated that cartilaginous tissue fragments can be obtained with MSC cultured on PGA supporting material under very specific conditions. Use of these cells offers the advantage of easy harvesting followed by in vitro amplification, and thus less harvesting morbidity. Complementary studies are needed to evaluate the behaviour of these living materials after implantation in the articulation

Human in vitro models of the neuromuscular junction (NMJ) are currently moving from embryonic stem cells to induced Pluripotent Stem Cells (iPSCs). With this, a robust model could be optimised for physiology and pathophysiology studies, as well as representing a drug screening platform. For this reason, the work presented here represents the optimisation of a human co-culture model of skeletal muscle (hSkM)/ iPSC-derived motor neurons (MNs) both in monolayer and in 3D tissue engineering collagen constructs. Firstly, human iPSC-derived motor neurons (MNs) were characterised over a period of 35 days to test their cholinergic potential. Then, primary human skeletal muscle (hSkM) and MNs were co-cultured on different substrates (gelatin and SureBond+ReadySet (Axol Bioscience)) and differentiated in various combinations of media to allow both myotube formation and neurite extension. Morphological (β-III Tubulin and Rhodamine Phalloidin) and interaction (α-Bungarotoxin and Synaptic Vesicle 2) immunofluorescent stainings were used to evaluate cell differentiation and co-localisation of pre and post-synaptic markers. Results from this study showed that the MNs presented a cholinergic phenotype up to 21 days; hSkM and MNs co-existed in culture and differentiated in neuronal Maintenance Medium (MM, Axol Bioscience); the 3D constructs allowed alignment and maturation of the muscle tissue, while providing a matrix for neurite extension and NMJ formation. This model has the potential to become a valid tool for in vitro drug screening while reducing the use of animals in research and providing the scientific community with a platform for personalised medicine

Cell sheets are manufactured from a high-density cell layer stabilized by its own freshly produced extracellular matrix (ECM). They could serve as versatile scaffolds for tissue repair. Unfortunately, their production often remains time-consuming requiring weeks of culturing. Ligament cell sheets are so far barely available. Regarding musculoskeletal tissues exposed to high repetitive biomechanical forces, the stability of cell sheets is insufficient. It could help to combine them with a biomechanical competent scaffold e.g. produced by an embroidering technique. Hence, we wanted to (1) develop a very rapid strategy to produce ACL ligamentocyte sheets within 24 h by using a thermoresponsive polymer surface, (2) use the sheets for scaffold seeding and (3) reflect the fibrocartilaginous transition zone of an ACL enthesis by combining sheets of ligamentocytes with chondrocytes or chondrogenic precursor cells as a strategy for directed seeding of two cell types on topologically different scaffold areas.

Different cell numbers of lapine ACL ligamentocytes (L-ACLs), lapine articular chondrocytes (L-ACs) and human mesenchymal stromal cells (H-MSCs) were used for sheet formation. Experiments were performed with novel, self-assembled poly(glycidyl ether) (PGE) brushes based on random glycidyl methyl ether and ethyl glycidyl ether copolymers on polystyrene 12-well cell culture plates, which allow rapid sheet formation within 24 h. Uncoated plates served as controls. Temperature-triggered detachment was performed by 10 min incubation with PBS at ambient temperature before treatment with fresh warm PBS for 5 min at 37 degrees Celsius. Harvested cell sheets were transferred on polyglycolic acid (PGA) or embroidered poly-lactic acid / poly-co-caprolactone (PLA/P[LA-CL]) scaffolds, functionalized with collagen foam and fluorine gas treatment (prepared at the IPF in Dresden and the FILK in Freiberg). Cell distribution, growth, vitality and synthesis of ECM components were monitored up to 7 days. Cell numbers required for sheet preparation (3.9 cm2) depended strongly on the cell type (L-ACLs: 0.395 mio/cm2, L-AC: 0.342 mio/cm2, H-MSCs: 0.131 mio/cm2) and was highest for L-ACLs. The majority of cells survived sheet assembly, detachment, transfer onto the scaffolds and culturing. Cells migrated from the sheets into the scaffolds and spread through the scaffolds. L-ACLs and L-ACs produced ECM and maintained their phenotypes (type II collagen and sulfated glycosaminoglycans in L-AC sheets, decorin and tenascin C in L-ACL sheets). The presence and distribution of two cell types in scaffold cocultures (L-ACLs and H-MSCs) was proven by anti-human vimentin labeling. Hence, the PGE brush surface allows rapid formation (24 h) of cell sheets.

In tissue engineering, scaffolds are vitalized by cells in vitro. Human mesenchymal stem cells (hMSC) are very interesting because of their ability to differentiate towards the osteogenic lineage and their self renewing capacity. Yet, it is important that implanted cells do not disseminate and exhibit unwanted cell growth outside the implantation site. Therefore the aim of this study was to detect migrated cells in organs of mice after implantation of a composite (cell-scaffold) substitute. HMSC (Cambrex, USA) were inoculated on a clinically approved 3D scaffold (Tutobone(TM), Tutogen, Germany). One composite and one scaffold without cells were implanted subcutanously, left and right paravertebrally in athymic nude mice (nu/nu). After 2, 4, 8 and 12 weeks constructs were explanted and organs (liver, spleen, lungs, kidney, heart, testicles, brain and blood) were harvested. The entire organs were homogenized and genomic DNA was isolated for qualitative and quantitative PCR. Human DNA was found in all explanted composites at all examined time points. No human DNA could be detected in control scaffolds. Moreover we did not detect human DNA in all explanted organs at any time point. As internal controls we could detect 1 single hMSC in a pool of 106 mouse cells. In conclusion, we could proof that cells of implanted composite substitutes do not migrate to other organs. Furthermore, this study showed that implanted hMSC seeded on 3D scaffolds survive over time frames up to 12 weeks

Dynamic compressive loading of cartilage can support extracellular matrix (ECM) synthesis whereas abnormal loading such as disuse, static loading or altered joint biomechanics can disrupt the ECM, suppress the biosynthetic activity of chondrocytes and lead to osteoarthritis. Interactions with the pericellular matrix are believed to play a critical role in the response of chondrocytes to mechanical signals. Loading of intact cartilage explants can stimulate proteoglycan synthesis immediately while the response of chondrocytes in tissue engineering constructs dependent on the day of culture. In order to effectively utilize mechanical signals in the clinic as a non-drug-based intervention to improve cartilage regeneration after surgical treatment, it is essential to understand how ECM accumulation influences the loading response. This study explored how construct maturity affects regulation of ECM synthesis of chondrocytes exposed to dynamic loading and unraveled the molecular correlates of this response. Human chondrocytes were expanded to passage 2, seeded into collagen scaffolds and cultured for 3, 21, or 35 days before exposure to a single loading episode. Dynamic compression was applied at 25% strain, 1 Hz, in 9 × 10 minute-intervals over 3h. Gene expression and protein alterations were characterized by qPCR and Western blotting. Proteoglycan and collagen synthesis were determined by radiolabel-incorporation over 24 hours. Maturation of constructs during culture significantly elevated ECM deposition according to histology and GAG/DNA content and chondrocytes redifferentiated as evident from raising COL2A1 and ACAN expression. Loading of d3 constructs significantly reduced proteoglycan synthesis and ACAN expression compared to controls while the identical loading episode stimulated GAG production significantly (1.45-fold, p=0.016) in day 35 constructs. Only in mature constructs, pERK1/2 and its immediate response gene FOS were stimulated by loading. Also, SOX9 protein increased after loading only in d21 and d35 but not in d3 constructs. Interestingly, levels of phosphorylated Smad 1/5/9 protein declined during construct maturation, but no evidence was obtained for load-induced changes in pSmad 1/5/9 although BMP2 and BMP6 expression were stimulated by loading. Selected MAPK-, calcium-, Wnt- and Notch-responsive genes raised significantly independent of construct maturity albeit with a generally weaker amplitude in d3 constructs. In conclusion, construct maturity determined whether cells showed an anabolic or catabolic response to the same loading episode and this was apparently determined by a differential SOX9 and pERK signaling response on a background of high versus low total pSmad1/5/9 protein levels. Next step is to use signaling inhibitors to investigate a causal relationship between Smad levels and a beneficial loading response in order to design cartilage replacement tissue for an optimal mechanical response for in vivo applications

INTRODUCTION. Bone marrow derived mesenchymal stem cells are a potential source of cells for the repair of articular cartilage defects. Hypoxia has been shown to improve chondrogenesis in adult stem cells. In this study we characterised bone marrow derived stem cells and investigated the effects of hypoxia on gene expression changes and chondrogenesis. MATERIALS AND METHODS. Adherent colony forming cells were isolated and cultured from the stromal component of bone marrow. The cells at passage 2 were characterised for stem cell surface epitopes, and then cultured as cell aggregates in chondrogenic medium under normoxic (20% oxygen) or hypoxic (5% oxygen) conditions for 14 days. Gene expression analysis, glycosoaminoglycan and DNA assays, and immunohistochemical staining were determined to assess chondrogenesis. RESULTS. Bone marrow derived adherent colony forming cells stained strongly for markers of adult mesenchymal stem cells including CD44, CD90 and CD105, and they were negative for the haematopoietic cell marker CD34 and for the neural and myogenic cell marker CD56. Interestingly, a high number of cells were also positive for the pericyte marker 3G5. Cell aggregates showed a chondrogenic response and in lowered oxygen there was increased matrix accumulation of proteoglycan, but less cell proliferation, which resulted in 3.2-fold more glycosoaminoglycan per DNA after 14 days of culture. In hypoxia there was increased expression of key transcription factor SOX6, and the expression of collagens II and XI, and aggrecan was also increased. DISCUSSION. Pericytes are a candidate stem cell in many tissue and our results show that bone marrow derived mesenchymal stem cells express the pericyte marker 3G5. The response to chondrogenic culture in these cells was enhanced by lowered oxygen tension, which up-regulated SOX6 and increased the synthesis and assembly of matrix during chondrogenesis. This has important implications for tissue engineering applications of bone marrow derived stem cells

Adherent cells are known to respond to physical characteristics of their surrounding microenvironment, adapting their cytoskeleton and initiating signaling cascades specific to the type of cue encountered. Scaffolds mimicking native biophysical cues have proven to differentiate stem cells towards tissue-specific lineages and to maintain the phenotype of somatic cells for longer periods of time in culture. Biomaterial-based tendon implants are designed to withstand high physiological loads but often lack the appropriate biochemical, biophysical and biological structure to drive tendon regeneration by populating cells. The objective of this study is to use tendon main component, collagen type I, to create scaffolds that reproduce tendon natural anisotropy and rigidity, in an effort to engineer functional tendon tissue with native organization and strength, able to maintain tenocyte phenotype and to differentiate stem cells towards the tenogenic lineage. Porcine collagen type I in solution was treated with one of the following cross-linkers: glutaraldehyde, genipin or 4-arm polyethylene glycol (4SP). The resulting mixture was poured on micro-grooved (2×2×2 um) or planar PDMS moulds and air-dried to obtain 5 mg/ml collagen films. Surface topography and elastic modulus were analyzed using SEM/AFM and rheometry, respectively. Human tendon cells were cultured on the micro-grooved/planar scaffolds for up to 10 days. Cell morphology, collagen III and tenascin C expression were analyzed by immunocytochemistry. Among the different cross-linkers used, only the treatment with 4SP resulted in scaffolds with a recognizable micro-grooved surface topography. Precise control over the micro-grooved topography and the rigidity of the scaffolds was achieved by cross-linking the collagen with varying concentrations of 4SP (0, 0.5, 1 and 1.5mM) at low pH and temperature. The elastic modulus of the scaffolds cross-linked with 4SP (0.5mM) matched the values previously reported to induce tenogenic differentiation in stem cells (50–90 kPa). Approximately eighty percent of the human tendon cells cultured on the micro-grooved collagen films aligned in the direction of the anisotropy for 10 days in culture, mimicking the alignment of tenocytes in the native tissue. Cell nuclei morphology, known to play a central role in the process of mechanotransduction, was significantly more elongated for the tenocytes cultured on the micro-grooved scaffolds after 4 days in culture for all the 4SP concentrations. Synthesis, deposition and alignment of collagen III and tenascin C, two important tenogenic markers, were up regulated selectively on the micro-grooved and rigid scaffolds after 10 days in culture, respectively. These results highlight the synergistic effect of matrix rigidity and cell alignment on tenogenic cell lineage commitment. Collectively, this study provides new insights into how collagen can be modulated to create scaffolds with precise imprinted topographies and controlled rigidities.

Mesenchymal Stem Cells (MSCs) are key regulators in senile osteoporosis and in bone formation and regeneration. MSCs are therefore suitable candidates for stem cells mediated gene therapy of bone. Recombinant human Bone Morphogenetic Protein-2 (rhBMP-2) is a highly osteoinductive cytokine, promoting osteogenic differentiation of MSCs. We hypothesized that genetically engineered MSCs, expressing rhBMP2, can be utilized for targeted cell mediated gene therapy for local and systemic bone disorders and for bone/cartilage tissue engineering. Engineered MSCs expressing rhBMP-2 have both autocrine and paracrine effects enabling the engineered cells to actively participate in bone formation. We conditionally expressed rhBMP2 (tet-controlled gene expression, tet-off system) in mouse and human mesenchymal stem cells. RhBMP2 expressing clones (tet-off and adeno-BMP2 infected MSCs), spontaneously differentiated into osteogenic cells in vitro and in vivo. Engineered MSCs were transplanted locally and tracked in vivo in radial segmental defects (regenerating site) and in ectopic muscular and subcutaneous sites (non-regenerating sites). In vitro and in vivo analysis revealed rhBMP2 expression and function, confirmed by RT-PCR, ELISA, western blot, immunohistochemistry and bioassays. Secretion of rhBMP2 in vitro was controlled by tetracycline and resulted in secretion of 1231 ng/24 hours/106 cells. Quantitative Micro-CT 3-Dimentional reconstruction revealed complete bone regeneration regulated by tetracycline in vivo, indicating the potential of this platform for bone and cartilage tissue engineering. Angiogenesis, a crucial element in tissue engineering, was increased by 10-folds in transplants of rhBMP2 expressing MSCs (tet-off), shown by histomorphometry and MRI analysis (p< 0.05). In order to establish a gene therapy platform for systemic bone disorders, MSCs with tet-controlled rhBMP-2 expression, were injected systemically (iv). These engineered MSCs were genetically modified in order to achieve homing to the bone marrow. Systemic non invasive tracking of engineered MSCs was achieved by recording topographical bioluminescence derived from luciferase expression detected by a coupled charged CCD imaging camera. For clinical situations that require immuno-isolation of transplanted cells, we developed an additional platform utilizing cell encapsulation technique. Immuno-isolated engineered MSCs, with tet-controlled rhBMP-2 expression, encapsulated with sodium alginate induced bone formation by paracrine effect of secreted rhBMP-2. Finally, we have characterized a novel tissue-engineering platform composed of engineered MSCs and biodegradable polymeric scaffolds, creating a 3D bone tissue in rotating Bioreactors. Our results indicate that engineered MSCs and polymeric scaffolds can be utilized for ex vivo bone tissue engineering. We therefore conclude that genetically engineered MSCs expressing rhBMP-2 under tetracycline control are applicable for: a) local and systemic gene therapy to bone, and b) bone tissue engineering. Our studies should lead to the creation of gene therapy platforms for systemic and local bone diseases in humans and bone/cartilage tissue engineering

Purpose: Articular cartilage is a physiologically hypoxic tissue with a gradient of oxygen tension ranging from about 10% oxygen at the cartilage surface to less than 1% in the deepest layers. The overall goal of the study was to determine whether an injectable allogeneic/autologous fibrin scaffolds in combination with mesenchymal stem cells (MSCs) is suitable for articular cartilage tissue engineering, and to determine the effect of hypoxic culture conditions on the stability of cell-fibrin scaffolds. The secondary goal was to enhance the accumulation of extracellular matrix (ECM) inside the fibrin scaffold under these conditions. Method: Chondroprogenitor clonal cell line RCJ3.1C5.18 (C5.18) and human mesenchymal stem cells (hMSCs) were encapsulated in fibrin hydrogel and fibrin glue scaffolds. The stabilization of fibrin scaffolds and development of ECM components were evaluated using zymography, SDS-polyacrylamide electrophoresis (SDS-PAGE), immunochemistry, spectrophotometry, RT-PCR including real time and histology (. Ahmed TA., et al. . Tissue Engineering. 2007. ;. 13. (7): . 1469. –77. ). Results: After encapsulation of C5.18 and hMSCs, fibrin gels quickly degraded under normoxic conditions (21 % oxygen) due to upregulation of plasminogen and matrix metalloproteinases (MMPs) genes especially MMP-2, -3, and -9. Protease inhibitors such as aprotinin and galardin (GM6001), in combination or separately, prevented the fibrin-C5.18 hydrogels breakdown for up to 5 weeks. Only a combination of aprotinin and galardin resulted in accumulation of ECM components such as collagen II and aggrecan. In contrast, fibrin-hMSCs hydrogels were found to be stable under hypoxic conditions (5% O2) for up to 4 weeks in the absence of inhibitors, suggesting that hypoxic conditions may downregulate the expression of the enzymes responsible for fibrin-hydrogel breakdown. Conclusion: These results suggest that in C5.18 and MSCs cell lines, expression of matrix metalloproteinases (MMPs) and plasmin is upregulated under normoxic conditions and is responsible for fibrin-hydrogel breakdown. Moreover, inhibition of both proteases is required to enhance the accumulation of ECM. However, fibrin hydrogel scaffolds were stabilized under low oxygen tension, which is more physiological than normoxia and therefore these constructs may be stable after implantation in the absence of protease inhibitors

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.

The potential of piezoelectric biomaterials for bone tissue engineering is demonstrated. This work proves that the use of piezoelectric poly(vinylidene fluoride) (PVDF), able to provide electrical stimuli upon mechanical solicitation to the growing bone cells, enhances the bone regeneration in vivo. Poled and non-poled PVDF films, with and without macroscopic piezoelectric response, respectively and randomly oriented piezoelectric electrospun fiber mats have been used as substitutes for bone to test their osteogenic properties in Wistar rats by analyzing new bone formation in 3 mm bilateral femur defects in vivo. After 4 weeks, the qualification of the regenerated bone was performed according the H&E staining. Defect implanted with poled PVDF films demonstrated significantly more defect closure and bone remodeling, showing the large potential of piezoelectric biomaterials for bone repair, as well as for other electromechanical responsive tissues such as muscle and tendon.

To repair soft tissue, it is vital to ensure that the biomaterial is able to mimic the complex elasticity of the native tissue. It has been demonstrated that substrate stiffness has a huge influence on cellular growth, differentiation, motility and phenotype maintenance. The goal of the present study is to characterize extensively a set of polymeric films with variable mechanical profiles. A range of synthetic biodegradable polymers was selected according to the physico-chemical intrinsic properties of aliphatic polymers. They have similar chemistry (absorbable polyesters made from lactic acid, glycolic acid, trimethylene carbonate, dioxanone & β-caprolactone), however show different mechanical and degradation properties. The films were manufactured by thermal presser and then characterized by scanning electron microscopy (SEM), differential scanning calorimetry (DSC), nuclear magnetic resonance spectroscopy (NMR) and Fourier transform infrared spectroscopy (FTIR). The mechanical properties of the films were assessed by uniaxial tensile tests in wet conditions and also by atomic force microscopy (AFM) to assess the material's stiffness at a micro-level. In vitro assays were performed to assess the cell cytocompatibility, proliferation and differentiation potential of the films. The mechanical properties of the materials are within the range intended for musculoskeletal tissue repair. Biological assays showed good cell adhesion, cell proliferation and cell viability. Stem cells were able to differentiate into adipogenic, osteogenic, chondrogenic and tenogenic lineages. Overall the selection of polymers gave good options for a potential tissue repair scaffold. In the future, the combined effect of stiffness and topography will be assessed on cell phenotype maintenance.

Significant challenges remain to accomplishing the development of fully functional tendon tissue substitutes that can lead to clinically effective and successful applications. Scaffolding materials must meet demanding requirements such i) mimic the hierarchical and anisotropically aligned structure of tendon tissues from the nano- up to the macroscale, ii) meet tendon mechanical requirements and non-linear biomechanical behaviour, iii) provide the necessary biophysical/biochemical cues and mechanical responsiveness to induce the tenogenic differentiation of stem cells and potentiating the effects of biochemical supplementation. On the other side, tenogenic differentiation of stem cells is still to be established, as well as the role of such cells (either naïve or pre-differentiated) in promoting tissue regeneration. We have recently found evidences that magnetic actuation can provide means of mechanically stimulating cells in a contact-free manner and, more interestingly, can also modulate inflammatory response, a critical issue for achieving tissue regeneration instead of repair. In summary, synergies of scaffold design and magnetic responsiveness can impact significantly cells behaviour as well as in vivo response and thus widen the therapeutically range of cell-laden tissue engineered constructs in tendon regeneration.