Direct metal printed (DMP) porous iron implants possess promising mechanical and corrosion properties for various clinical application. Nevertheless, there is a requirement for better co-relation between in vitro and in vivo corrosion and biocompatibility behaviour of such biomaterials. Our present study evaluates absorption of porous iron implants under both static and dynamic conditions. Furthermore, this study characterizes their cytocompatibility using fibroblastic, osteogenic, endothelial and macrophagic cell types. In vitro degradation was performed statically and dynamically in a custom-built set-up placed under cell culture conditions (37 °C, 5% CO2 and 20% O2) for 28 days. The morphology and composition of the degradation products were analysed by scanning electron microscopy (SEM, JSM-IT100, JEOL). Iron implants before and after immersion were imaged by μCT (Quantum FX, Perkin Elmer, USA). Biocompatibility was also evaluated under static and dynamic in vitro culture conditions using L929, MG-63, HUVEC and RAW 264.7 cell lines. According to ISO 10993, cytocompatibility was evaluated directly using live/dead staining (Live and Dead Cell Assay kit, Abcam) in dual channel fluorescent optical imaging (FOI) and additionally quantified by flow cytometry. Furthermore, cytotoxicity was indirectly quantified using ISO conform extracts in proliferation assays. Strut size of DMP porous iron implants was 420 microns, with a porosity of 64% ± 0.2% as measured by micro-CT. After 28 days of physiological degradation in vitro, dynamically tested samples were covered with brownish degradation products. They revealed a 5.7- fold higher weight loss than statically tested samples, without significant changes in medium pH. Mechanical properties (E = 1600–1800 MPa) of these additively manufactured implants were still within the range of the values reported for trabecular bone, even after 28 days of biodegradation. Less than 25% cytotoxicity at 85% of the investigated time points was measured with L929 cells, while MG-63 and HUVEC cells showed 75% and 60% viability, respectively, after 24 h, with a decreasing trend with longer incubations. Cytotoxicity was analysed by two-way ANOVA and post-hoc Tukey's multiple comparisons test. Under dynamic culture conditions, live-dead staining and flow cytometric quantification showed a 2.8-fold and 5.7-fold increase in L929 and MG-63 cell survival rates, respectively, as compared to static conditions. Therefore, rationally designed and properly coated iron-based implants hold potential as a new generation of absorbable Orthopaedic implants

Summary Statement. A novel biomimetic polydioxanone tendon patch with woven and electrospun components is biocompatible, recapitulates native tendon architecture and creates a tissue-healing microenvironment directed by a subpopulation of regenerative macrophages. The woven component provides tensile strength while the tendon heals. Introduction. There is great interest in the use of biomimetic devices to augment tendon repairs. Ideally, implants improve healing without causing adverse local or systemic reactions. Biocompatibility remains a critical issue prior to implantation into humans, as some implants elicit a foreign body response (FBR) involving inflammation, poor wound healing and even fistulae formation. Additionally, the effect on articular cartilage locally or systemically with placement of a juxta-articular implant has not been examined. The purpose of this study is to test the in vivo biocompatibility of a novel hybrid woven and electrospun polydioxanone patch in a rat tendon transection model. Patients and Methods. Sixty Lewis rats were divided into 4 groups in which the infraspinatus was surgically transected 3 mm from its insertion. Tendons were repaired with a woven and electrospun polydioxanone patch (PDOe) and 5-0 Prolene sutures. Vicryl and Silk patches or a simple Prolene suture repair served as comparators. Animals were sacrificed at 1, 2, 4, 6 and 12 weeks to examine the biocompatibility of the implants. Immunohistochemistry was used to examine macrophage subpopulations and hematoxylin and eosin staining was used to assess foreign-body giant cells and both analyzed with a one-way ANOVA with significance set at p<.05. Articular cartilage was scrutinised with semi-quantitative analysis. Hind paw inflammatory indices were used to determine the systemic effects and biomechanical testing the tensile strength of the materials over time. Results. The PDOe patch remained grossly quiescent at all time-points. There was a severe inflammatory reaction to Vicryl at one and 2-week time-points with gross exudate. Silk patches were associated with larger fibrous capsules at each time point. There were no adverse systemic effects and articular cartilage remained normal with no differences between materials to controls. Immunohistochemistry showed a significantly higher ratio of regenerative to inflammatory macrophages for the PDOe patch compared to other constructs at each time-point and similar to controls. Silk and Vicryl patches had a greater than 10-fold increase in foreign-body giant cells compared to the PDOe patch and controls (p<.05) suggesting incorporation rather than rejection and walling off of the biomaterial. Tensile strength of the PDOe patch increased in the first 2 weeks to greater than 90 N and gradually declined to a mean of 22 N at 12 weeks. Discussion/Conclusion. The novel PDOe patch appears to be biocompatible and illicit very little FBR in this rat tendon injury model. Importantly, there was no joint reaction to the biomaterial which has not been addressed previously. We believe the electrospun component of the patch recapitulates native tendon architecture creating a tissue healing microenvironment directed by a regenerative macrophage subpopulation. These results corroborate earlier in vitro work that showed incorporation of tenocytes within the electrospun scaffold. The woven component of the scaffold provides tensile strength as the tendon heals and begins to degrade after healing is underway making it less likely to elicit a FBR. Based on these and earlier in vitro data we believe this implant shows excellent biocompatibility and is ready to proceed to human trials

Summary Statement. Innovative nanocomposite carbon coating doped with Si can significantly improve the osseintegration of orthopaedics implants. Additionally, this kind of coating increases the mechanical resistance of the implants, what is especially important on case of joints (frictional pairs). Introduction. Use of layers of carbon-doped silicon, which leads to the synthesis of layers improving mechanical and biological characteristics, let obtain good strength by volume features. Suitable introduction to the structure of amorphous silicon dioxide layer allow for the production of higher adhesion to metallic substrates and consequently the increased thickness and hardness. The increased thickness of the layer leads to a stronger diffusion barrier to harmful metal ions from the implant material and thus consequently improving the biocompatibility of the implant. Moreover, a silicon beneficial effect on stress relaxation layer formed during the synthesis. This allows for improved biocompatibility, also affects other property obtained in the case of silicon carbide layers, the bacteriastability. This further protects the surface of the implant against the risk of bacterial colonization in both the implantation and subsequent use in the body, and preferably suppressing inflammation and faster healing of surgical wounds. The thus obtained product is much better than the biological and mechanical parameters of currently offered. Patients & Methods. In order to evaluate the fabricated coatings conditions examination of the basic physicochemical and mechanical properties were conducted (AFM, Raman, XPS, nanoindentation technique). The in vitro and in vivo tests were also conducted. As a biological material osteoblast Saos-2 cells and endothelial cells line EA. 926 were used. For the evaluation of proliferation and cytotoxicity a “live/dead” test was used. For testing bactericidal activity of the C/Si coatings, an exponential growth phase of E. coli strain DH5 α was used. Test of bacterial immediate toxicity and bacterial colonization were performed. A model of rabbits and guinea pigs were used to obtained results with reference to irritation, intradermal reactivity, sensitization, local effects after implantation with the histopathological examination, cytotoxicity test. Results. XPS results have shown that the silicon content for each group of samples, both steel and titanium alloy is about 3, 4 and 5 percent. Increasing the concentration of silicon above 5% results in the weakening of the mechanical properties of the layer and lead to delamination of the sterilization process. Addition of silicon in the range of 3–5% does not negatively affect the mechanical and structural properties of the modified surface and from this point of view, all the criterion of strength. Performed studies confirmed very good mechanical properties of C/Si coatings. In vitro studies have indicated the optimal concentration of silicon in the coating, where the material is biocompatible and also has good antibacterial properties. Biocompatibility of silicon coatings was also confirmed by irritation and sensitization testing in the in vivo model. Discussion/Conclusion. Final result of the surface modification C/Si coating depends on modification of two effects, i.e. the formation of the transition layer of the substrate material and the synthesis of the outer carbon coating. Results of in vitro and in vivo tests confirmed very good biological properties of coatings which proved the fact that it is possible to improve the parameters of the implant work at the same time adding to the intrinsic the antibactericidal properties

Bone fractures are highly observed clinical situation in orthopaedic treatments. In some cases, there might be non-union problems. Therefore, recent studies have focused on tissue engineering applications as alternative methods to replace surgical procedures. Various biopolymer based scaffolds are produced using different fabrication techniques for bone tissue engineering applications.

In this study, hydroxyapatite (HAp) and loofah containing carboxymethyl chitosan (CMC) scaffolds were prepared. In this regard, first 4 ml of CMC solution, 0.02 g of hydroxyapatite (HAP) and 0.06 g of poly (ethylene glycol) diglycidyl ether (PEGDE) were mixed in an ultrasonic bath until the HAp powders were suspended. Next, 0.04 g of loofah was added to the suspension and with the help of PEGDE as the cross-linking agent, then, the mixture was allowed to cross-link at 40^oC overnight. Finally, the three-dimensional, porous and sponge-like scaffolds were obtained after lyophilization (TELSTAR - LyoQuest −85) at 0.1 mbar and −25°C for 2 days.

Morphologies, chemical structures and thermal properties of the scaffolds were characterized by scanning electron microscopy (SEM), Fourier Transform infrared spectroscopy (FT-IR) and thermogravimetric differential thermal analysis (TGA/DTA), respectively. In addition, swelling behavior and mechanical properties of the scaffolds under compression loading were determined.

In order to investigate biocompatibility of the scaffolds, WST-1 colorimetric assay at days 0, 1, 3, 5 and 7 was conducted by using human dermal fibroblast. Also, histological and morphological analysis were performed for cell attachment at day 7.

In conclusion, the produced scaffolds showed no cytotoxic effect. Therefore, they can be considered as a candidate scaffold for bone tissue regeneration. Further studies will be performed by using bone marrow and periosteum derived mesenchymal stem cells with these scaffolds.

Abstract

Introduction

Because of its high strength and allowance for bone integration, Ti-6Al-4V is the most commonly used material for load bearing bone implants. Compared to conventional production methods, 3D printing Ti-6Al-4V introduces advantages as (near-) net-shape manufacturing of complex geometries, and optimization of utilization rate of the material. However, as result of the additively production procedure, microstructure and surface properties differ from those manufactured using conventional techniques. Therefore, the resulting mechanical properties and biocompatibility of the 3D printed Ti-6Al-4V are investigated in this study. First, it was aimed to reveal the tensile properties of the material and verify if these depend on build orientation. Second, it was determined which post process method provides the best osteoconductivity.

Since 2010, there has been a sharp decline in the use of metal-on-metal joint replacement devices due to adverse responses associated with the release of metal wear particles and ions in patients. Surface engineered coatings offer an innovative solution to this problem by covering metal implant surfaces with biocompatible and wear resistant materials. The present study tests the hypothesis whether surface engineered coatings can reduce the overall biological impact of a device by investigating recently introduced silicon nitride coatings for joint replacements. Biological responses of peripheral blood mononuclear cells (PBMNCs) to Si3N4 model particles, SiNx coating wear particles and CoCr wear particles were evaluated by testing cytotoxicity, inflammatory cytokine release, oxidative stress and genotoxicity.

Clinically relevant wear particles were generated from SiNx-on-SiNx and CoCr-on-CoCr bearing combinations using a multidirectional pin-on-plate tribometer. All particles were heat treated at 180°C for 4 h to destroy endotoxin contamination. Whole peripheral blood was collected from healthy donors (ethics approval BIOSCI 10–108, University of Leeds). The PBMNCs were isolated using Lymphoprep (Stemcell) and incubated with particles at various volumetric concentrations (0.5 to 100 µm3 particles/cell) for 24 h in 5% (v/v) CO2 at 37°C. After incubation, cell viability was measured using the ATPlite assay (Perkin Elmer); TNF-alpha release was measured by ELISA (Invitrogen); oxidative stress was measured using H2DCFDA (Abcam); and DNA damage was measured by comet assay (Tevigen). The results were expressed as mean ± 95% confidence limits and the data was analysed using one-way ANOVA and Tukey-Kramer post-hoc analysis.

No evidence of cytotoxicity, oxidative stress, TNF-alpha release, or DNA damage was observed for the silicon nitride particles at any of the doses. However, CoCr wear particles caused cytotoxicity, oxidative stress, TNF-alpha release and DNA damage in PBMNCs at high doses (50 µm3 particles per cell). This study has demonstrated the in-vitro biocompatibility of SiNx coatings with primary human monocytic cells. Therefore, surface engineered coatings have potential to significantly reduce the biological impact of metal components in future orthopaedic devices.

We implanted nails made of titanium (Ti6Al4V) and of two types of glass ceramic material (RKKP and AP40) into healthy and osteopenic rats. After two months, a histomorphometric analysis was performed and the affinity index calculated. In addition, osteoblasts from normal and osteopenic bone were cultured and the biomaterials were evaluated in vitro.

In normal bone the rate of osseointegration was similar for all materials tested (p > 0.5) while in osteopenic bone AP40 did not osseointegrate (p > 0.0005).

In vitro, no differences were observed for all biomaterials when cultured in normal bone-derived cells whereas in osteopenic-bone-derived cells there was a significant difference in some of the tested parameters when using AP40.

Our findings suggest that osteopenic models may be used in vivo in the preclinical evaluation of orthopaedic biomaterials. We suggest that primary cell cultures from pathological models could be used as an experimental model in vitro.

Objectives

Sustained intra-articular delivery of pharmacological agents is an attractive modality but requires use of a safe carrier that would not induce cartilage damage or fibrosis. Collagen scaffolds are widely available and could be used intra-articularly, but no investigation has looked at the safety of collagen scaffolds within synovial joints. The aim of this study was to determine the safety of collagen scaffold implantation in a validated in vivo animal model of knee arthrofibrosis.

Infection in orthopedics is a challenge, since it has high incidence (rates can be up to 15-20%, also depending on the surgical procedure and on comorbidities), interferes with osseointegration and brings severe complications to the patients and high societal burden. In particular, infection rates are high in oncologic surgery, when biomedical devices are used to fill bone gaps created to remove tumors. To increase osseointegration, calcium phosphates coatings are used. To prevent infection, metal- and mainly silver-based coatings are the most diffused option. However, traditional techniques present some drawbacks, including scarce adhesion to the substrate, detachments, and/or poor control over metal ions release, all leading to cytotoxicity and/or interfering with osteointegration. Since important cross-relations exist among infection, osseointegration and tumors, solutions capable of addressing all would be a breakthrough innovation in the field and could improve clinical practice. Here, for the first time, we propose the use antimicrobial silver-based nanostructured thin films to simultaneously discourage infection and bone metastases. Coatings are obtained by Ionized Jet Deposition, a plasma-assisted technique that permits to manufacture films of submicrometric thickness having a nanostructured surface texture. These characteristics, in turn, allow tuning silver release and avoid delamination, thus preventing toxicity. In addition, to mitigate interference with osseointegration, here silver composites with bone apatite are explored. Indeed, capability of bone apatite coatings to promote osseointegration had been previously demonstrated in vitro and in vivo. Here, antibacterial efficacy and biocompatibility of silver-based films are tested in vitro and in vivo. Finally, for the first time, a proof-of-concept of antitumor efficacy of the silver-based films is shown in vitro. Coatings are obtained by silver and silver-bone apatite composite targets. Both standard and custom-made (porous) vertebral titanium alloy prostheses are used as substrates. Films composition and morphology depending on the deposition parameters are investigated and optimized. Antibacterial efficacy of silver films is tested in vitro against gram+ and gram- species (E. coli, P. aeruginosa, S. aureus, E. faecalis), to determine the optimal coatings characteristics, by assessing reduction of bacterial viability, adhesion to substrate and biofilm formation. Biocompatibility is tested in vitro on fibroblasts and MSCs and, in vivo on rat models. Efficacy is also tested in an in vivo rabbit model, using a multidrug resistant strain of S. aureus (MRSA, S. aureus USA 300). Absence of nanotoxicity is assessed in vivo by measuring possible presence of Ag in the blood or in target organs (ICP-MS). Then, possible antitumor effect of the films is preliminary assessed in vitro using MDA-MB-231 cells, live/dead assay and scanning electron microscopy (FEG-SEM). Statistical analysis is performed and data are reported as Mean ± standard Deviation at a significance level of p <0.05. Silver and silver-bone apatite films show high efficacy in vitro against all the tested strains (complete inhibition of planktonic growth, reduction of biofilm formation > 50%), without causing cytotoxicity. Biocompatibility is also confirmed in vivo. In vivo, Ag and Ag-bone apatite films can inhibit the MRSA strain (>99% and >86% reduction against ctr, respectively). Residual antibacterial activity is retained after explant (at 1 month). These studies indicate that IJD films are highly tunable and can be a promising route to overcome the main challenges in orthopedic prostheses

Critical size bone defects deriving from large bone loss are an unmet clinical challenge1. To account for disadvantages with clinical treatments, researchers focus on designing biological substitutes, which mimic endogenous healing through osteogenic differentiation promotion. Some studies have however suggested that this notion fails to consider the full complexity of native bone with respect to the interplay between osteoclast and osteoblasts, thus leading to the regeneration of less functional tissue2. The objective of this research is to assess the ability of our laboratory's previously developed 6-Bromoindirubin-3’-Oxime (BIO) incorporated guanosine diphosphate crosslinked chitosan scaffold in promoting multilineage differentiation of myoblastic C2C12 cells and monocytes into osteoblasts and osteoclasts1, 3, 4. BIO addition has been previously demonstrated to promote osteogenic differentiation in cell cultures5, but implementation of a co-culture model here is expected to encourage crosstalk thus further supporting differentiation, as well as the secretion of regulatory molecules and cytokines2. Biocompatibility testing of both cell types is performed using AlamarBlue for metabolic activity, and nucleic acid staining for distribution. Osteoblastic differentiation is assessed through quantification of ALP and osteopontin secretion, as well as osteocalcin and mineralization staining. Differentiation into osteoclasts is verified using SEM and TEM, qPCR, and TRAP staining. Cellular viability of C2C12 cells and monocytes was maintained when cultured separately in scaffolds with and without BIO for 21 days. Both scaffold variations showed a characteristic increase in ALP secretion from day 1 to 7, indicating early differentiation but BIO-incorporated sponges yielded higher values compared to controls. SEM and TEM imaging confirmed initial aggregation and fusion of monocytes on the scaffold's surface, but BIO addition appeared to result in smoother cell surfaces indicating a change in morphology. Late-stage differentiation assessment and co-culture work in the scaffold are ongoing, but initial results show promise in the material's ability to support multilineage differentiation. Acknowledgements: The authors would like to acknowledge the financial support of the Collaborative Health Research Program (CHRP) through CIHR and NSERC, as well as Canada Research Chair – Tier 1 in Regenerative Medicine and Nanomedicine, and the FRQ-S

Introduction and Objective. Alveolar bone resorption following tooth extraction or periodontal disease compromises the bone volume required to ensure the stability of an implant. Guided bone regeneration (GBR) is one of the most attractive technique for restoring oral bone defects, where an occlusive membrane is positioned over the bone graft material, providing space maintenance required to seclude soft tissue infiltration and to promote bone regeneration. However, bone regeneration is in many cases impeded by a lack of an adequate tissue vascularization and/or by bacterial contamination. Using simultaneous spray coating of interacting species (SSCIS) process, a bone inspired coating made of calcium phosphate-chitosan-hyaluronic acid was built on one side of a nanofibrous GBR collagen membrane in order to improve its biological properties. Materials and Methods. First, the physicochemical characterizations of the resulting hybrid coating were performed by scanning electron microscopy, X-ray photoelectron, infrared spectroscopies and high-resolution transmission electron microscopy. Then human mesenchymal stem cells (MSCs) and human monocytes were cultured on those membranes. Biocompatibility and bioactivity of the hybrid coated membrane were respectively evaluated through MSCs proliferation (WST-1 and DNA quantification) and visualization; and cytokine release by MSCs and monocytes (ELISA and endothelial cells recruitment). Antibacterial properties of the hybrid coating were then tested against S. aureus and P. aeruginosa, and through MSCs/bacteria interactions. Finally, a preclinical in vivo study was conducted on rat calvaria bone defect. The newly formed bone was characterized 8 weeks post implantation through μCT reconstructions, histological characterizations (Masson's Trichrome and Von Kossa stain), immunohistochemistry analysis and second harmonic generation. Biomechanical features of newly formed bone were determined. Results. The resulting hybrid coating of about 1 μm in thickness is composed of amorphous calcium phosphate and carbonated poorly crystalline hydroxyapatite, wrapped within chitosan/hyaluronic acid polysaccharide complex. Hybrid coated membrane possesses excellent bioactivity and capability of inducing an overwhelmingly positive response of MSCs and monocytes in favor of bone regeneration. Furthermore, the antibacterial experiments showed that the hybrid coating provides contact-killing properties by disturbing the cell wall integrity of Gram-positive and Gram-negative bacteria. Its combination with MSCs, able to release antibacterial agents and mediators of the innate immune response, constitutes an excellent strategy for fighting bacteria. A preclinical in vivo study was therefore conducted in rat calvaria bone defect. μCT reconstructions showed that hybrid coated membrane favored bone regeneration, as we observed a two-fold increase in bone volume / total volume ratios vs. uncoated membrane. The histological characterizations revealed the presence of mineralized collagen (Masson's Trichrome and Von Kossa stain), and immunohistochemistry analysis highlighted a bone vascularization at 8 weeks post-implantation. However, second harmonic generation analysis showed that the newly formed collagen was not fully organized. Despite a significant increase in the elastic modulus of the newly formed bone with hybrid coated membrane (vs. uncoated membrane), the obtained values were lower than those for native bone (approximately 3 times less). Conclusions. These significant data shed light on the regenerative potential of such bioinspired hybrid coating, providing a suitable environment for bone regeneration and vascularization, as well as an ideal strategy to prevent bone implant-associated infections

Bone regenerative medicine aims at designing biomimetic biomaterials able to guide stem cells fate towards osteoblast lineage and prevent orthopaedic common pathogen adhesion. Owing to bone inorganic/organic composition, we herein report, using a versatile process based on simultaneous spray coating of interacting species, a calcium phosphate (CaP) / chitosan (CHI) / hyaluronic acid (HA) functionalized collagen membrane as a new strategy for bone regenerative medicine. Physicochemical characterizations of CaP-CHI-HA coating were performed by scanning electron microscopy, X-ray photoelectron and infrared spectroscopies and high-resolution transmission electron microscopy, revealing the formation of a thin coating mainly composed of non-stoichiometric crystalline hydroxyapatite dispersed into polymorphic organic film. Biocompatibility of CaP-CHI-HA coated membrane, evaluated after 7 days in contact with human mesenchymal stem cells (MSCs), showed spread, elongated and aligned cells. Metabolic activity and DNA quantification studies showed an increase in MSCs proliferation on coated membrane compared to uncoated membrane over the study time. Similarly, cytokines (IL-6, IL-8, osteoprotegerin) and growth factors (VEGF, bFGF) release in supernatant, as well as endothelial cells recruitment, were significantly increased in presence of CaP-CHI-HA coated membrane. Thus, CaP-CHI-HA coated membrane provides a suitable environment for MSCs to induce bone healing. Moreover, pro-inflammatory cytokines (IL-1β and TNF-α) secretion by human monocytes was significantly reduced on CaP-CHI-HA coating compared to LPS stimulation. CaP-CHI-HA coating also reduced significantly Staphylococcus aureus and Pseudomonas aeruginosa adhesion on the membrane, conferring a bacterial anti-adhesive surface. Based on our results, CaP-CHI-HA functionalized collagen membrane provides an interesting material for bone regeneration

Hydrogels have been widely used for articular tissue engineering application, due to their controllable biodegradability and high water content mimicking the biological extracellular matrix. However, they often lack the mechanical support and signaling cues needed to properly guide cells. Graphene and its derivatives have recently emerged as promising materials due to their unique mechanical, physical, chemical proprieties [1]. Although not yet widely used for medical applications, preliminary works suggest that both structural and functional properties of polymeric substrates may be enhanced when combined with graphene oxide (GO) [2]. In this work, reinforced 3D GO/alginate (Alg) hydrogels have been realized and the opportunity of tuning hydrogels mechanical properties in relation to the required physiological needs has been investigated. After preparing GO nanosheets (Sigma Aldrich) aqueous suspension (1 mg/ml) by ultrasonic treatment, alginate (Manugel GMB, FMC Biopolymer) composite solutions were produced (0, 0.5, 2 wt% GO/Alg). Moulds of agarose (1% w/v in CaCl 0,1M) were prepared to allocate GO/Alg solutions and chemically cross-link gels via diffusion (2 hr. at 37 °C). GO/Alg hydrogels were characterized through optical/ AFM and FTIR analysis. Biocompatibility tests were performed embedding 3T3 fibroblasts (8 millions/ml) in the GO/Alg hydrogels; cell viability was evaluated at different time points up to two weeks with Dead/alive kit. Gels mechanical proprieties were assessed via Dynamic Mechanical- Analysis (DMA) up to 28 days of culture (with and w/o cells) at different time points. All tests were performed in triplicate and statistical analyisis carried out (Mann–Whitney U test, n=9, p<0,005). 3D composite GO/alginate hydrogels were successfully realized (3 mm height, 5 mm diameter). Cell viability tests showed that the presence of GO does not decrease cell viability, confirming absence of toxicity, at least up to 2% wt GO/Alg. For all time points cell viability was statistically higher in presence of GO, while there was no significant difference between 0.5 wt% and 2 wt% GO/Alg. Hydrogels functionalized with GO exhibit an Elastic modulus about 3 fold higher than the Alg control at T0. After an initial decreasing of the Young Modulus for the all GO/Alg samples, possibly due to a partial degradation of alginate, a drastic recovery was observed up to 28 days of culture only for GO functionalized samples. The mechanical features improvement was neither mediated nor triggered by cells activity. We successfully realized a natural-based 3D hydrogel nano-functionalized with graphene, where both mechanical and biological properties were successfully improved. The delayed stabilization of GO/Alg mechanical proprieties may be due either to a chemical interplay between GO and alginate matrix or to GO self-assembling processes over time. Future developments will be carried out to decouple the chemical and topological role of GO on the results observed up to now. Moreover, functional tests will be performed to evaluate the GO effects on in vitro cell differentiation for possible articular clinical applications

Objectives

To compare the therapeutic potential of tissue-engineered constructs (TECs) combining mesenchymal stem cells (MSCs) and coral granules from either Acropora or Porites to repair large bone defects.