Objectives. There is increasing application of bone morphogenetic proteins (BMPs) owing to their role in promoting fracture healing and bone fusion. However, an optimal delivery system has yet to be identified. The aims of this study were to synthesise bioactive BMP-2, combine it with a novel α-tricalcium phosphate/poly(D,L-lactide-co-glycolide) (α-TCP/PLGA) nanocomposite and study its release from the composite. Methods. BMP-2 was synthesised using an Escherichia coli expression system and purified. In vitro bioactivity was confirmed using C2C12 cells and an alkaline phosphatase assay. The modified solution-evaporation method . was used to fabricate α-TCP/PLGA nanocomposite and this was characterised using X-ray diffraction and scanning electron microscopy. Functionalisation of α-TCP/PLGA nanocomposite by adsorption of BMP-2 was performed and release of BMP-2 was characterised using an enzyme-linked immunosorbent assay (ELISA). Results. Alkaline phosphatase activity of C2C12 cells was increased by the presence of all BMP-2/nanocomposite discs compared with the presence of a blank disc (p = 0.0022), and increased with increasing incubation concentrations of BMP-2, showing successful adsorption and bioactivity of BMP-2. A burst release profile was observed for BMP-2 from the nanocomposite. . Conclusions. Functionalisation of α-TCP/PLGA with BMP-2 produced osteoinduction and was dose-dependent. This material therefore has potential application as an osteoinductive agent in regenerative medicine

Introduction. The annual incidence of fractures in the UK is almost 4%. Bone grafting procedures and segmental bone transport have been employed for bone tissue regeneration. However, their limited availability, donor site morbidity and increased cost mean that there is still a large requirement for alternative methods and there is considerable research into regeneration using bone morphogenetic proteins (BMPs). The aims of this study are to synthesise and combine BMP-2 with a novel nanocomposite and study its release. Materials and Methods. BMP-2 was synthesised using an E. coli expression system and purified. C2C12 cells were used to test its bioactivity using an alkaline phosphatase (ALP) assay. The modified solution evaporation method was used to fabricate 30% a-TCP/PLGA nanocomposite and it was characterized using SEM, TEM, TGA, XRD, EDX and particle size analysis. The release pattern of adsorbed BMP-2 was studied using an ELISA assay. Results. SEM suggests that there was a homogeneous distribution of a-TCP nanoparticles within the PLGA matrix. The concentration of BMP-2 adsorbed onto a-TCP/PLGA nanocomposites directly correlated with the incubation concentration of BMP-2. Approximately 10-15% of BMP-2 was adsorbed on to the discs, up to an incubation concentration of 25 μg/ml. At a higher incubation concentration (50 μg/ml), however, only 4% of the BMP-2 appears to have been adsorbed. The ALP activity shows that the BMP-2 was bioactive and successfully adsorbed onto the surface of the a-TCP/PLGA nanocomposite. A burst release pattern of BMP-2 was observed over 24h, being maximal at 2 h. Discussion. Increasing incubation concentrations of BMP-2 resulted in an increase of detected adsorbed BMP-2 on the discs, however this was not observed at the highest incubation concentration (50 μg/ml). As adsorption of BMP-2 onto the ground surface of the a-TCP/PLGA nanocomposite occurs primarily through electrostatic interactions between cationic BMP-2 and anionic a-TCP, this might reflect saturation in adsorption secondary to saturation of surface anionic a-TCP by BMP-2, or heterogeneity of the discs' content and/or surface area. Adsorbed BMP-2 was shown to have bioactivity which significantly increased with increasing incubation concentrations of BMP-2 and suggests this nanocomposite could have osteoinductive potential in-vivo. The burst pattern of BMP-2 release has been shown previously from BMP adsorbed onto mPCL/collagen/HA composite and this significantly increased the bone formation of critical-sized defects. Whilst a more sustained release profile of BMP-2 is generally considered desirable, this nanocomposite of a-TCP/PLGA has been shown to possess some osteoconductive and weak osteoinductive properties itself (unpublished). The addition of BMP-2 to the nanocomposite by adsorption results in an early burst release, which can promote the differentiation of mesenchymal cells into osteoblasts. The proliferation of these might then be sustained by the nanocomposite itself, without the need for sustained delivery of BMP-2. Conclusions. Bioactive BMP-2 was synthesised and combined with a-TCP/PLGA nanocomposite, producing a biodegradable and osteoinductive material which has potential for use in bone regeneration

Introduction. Ink engineering can advance 3D-printability for better therapeutics, with optimized proprieties. Herein, we describe a methodology for yielding 3D-printable nanocomposite inks (NC) using low-viscous matrices, via the interaction between the organic and inorganic phases by chemical coupling. Method. Natural photocurable matrices were synthesized: a protein – bovine serum albumin methacrylate (BSAMA), and a polysaccharide – hyaluronic acid methacrylate (HAMA). Bioglass nanoparticles (BGNP) were synthesized and functionalized via aminosilane chemistry. The functionalization of BSAMA, HAMA, and BGNP were quantified via NMR. To arise extrudable inks, 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide (EDC) and N-Hydroxysuccinimide (NHS) chemistry was used to link innate carboxylic groups of BSAMA/HAMA and amine-functionalized BGNP. Different crosslinker and BGNP amounts were tested. Visible light photopolymerization is performed, using lithium phenyl-2,4,6-trimethylbenzoylphosphinate. The NC's rheological, mechanical, and biological behavior was evaluated before 3D extrusion printability. Result. All composite formulations effectively immobilized and homogeneously dispersed the BGNP, turning low-viscous materials (< 1 Pa) into shear-thinning formulations with tunable increased elastic/viscous moduli (50-500 Pa). More pronounced increments were found with increasing EDC/NHS and BGNP concentrations. The resulting inks produce robust and stable scaffolds successfully retrieved after post-print photocrosslinking (1-5 kPa). Bioactivity in simulated body fluid and in vitro assays using adipose-derive stem cells revealed a similar calcium/phosphate ratio to that of hydroxyapatite, and increased viability and metabolic activity. BSAMA and HAMA demonstrated distinct natures not only in printability but also in overall cellular performance and mechanical properties, making these ideal for interfacial tissue engineering. Conclusion. This strategy demonstrated being effective and reproducible to advance nanocomposites for 3D printing using different types of biomaterials. Further, we envision using both inks to produce hierarchical constructs via extrusion printing, better mimicking bone-to-cartilage interfaces. Acknowledgements. FCT grants (DOI:10.54499/2022.04605.CEECIND/CP1720/CT0021), (BI/UI89/10303/2022), (PRT/BD/154735/2023); EU's Horizon 2020 research and innovation programs InterLynk (Nº953169) and SUPRALIFE (Nº101079482) projects; CICECO-Aveiro Institute of Materials projects (DOI:10.54499/UIDB/50011/2020), (DOI:10.54499/UIDP/50011/2020), and (DOI:10.54499/LA/P/0006/2020), financed by FCT/MCTES(PIDDAC)

The enhancement of current bone cement properties is a challenging issue that has been the focus of much research. Developing bone composites with high level of cytocompatibility, mechanical and antibacterial properties is a challenging task. We overcome this challenge by designing a nanocomposite that contain two-dimensional (2D) nanosheets. To develop our novel bone cement nanocomposite, 2D nanosheets were synthesized, mixed in different ratios, and then added to the PMMA matrix. The results reveal that the incorporation of 2D nanosheets into the PMMA matrix leads to increase in the antibacterial properties of the bone cement composite against E. coli bacteria. In addition, the 2D nanosheets improve the compression strength of the bone cement nanocomposite significantly. We also show that nanosheets increased the bioactivity of the bone cements. Finally, MTT assay results indicate that PMMA as a control sample has the lowest cytocompatibility, however, our novel nanocomposites have the highest amount of cytocompatibility. Thus, the current study suggests that 2D nanosheets are potential filler components for the next generation of PMMA bone cement nanocomposites. The findings of this work reveal that the excellent performance of the proposed bone composite can result in a paradigm shift in design of state-of-the art bone cement composites

Total joint replacement (TJR), such as hip and knee replacement, is commonly used for the treatment of end stage arthritis. The use of Poly (methylmethacrylate) bone cement is a gold standard in such replacement, where it fixes the implant in place and transfer stresses between bone and implant, and frequently used for local delivery of drugs such as antibiotics. The use of antibiotic loaded bone cement is considered a well-established standard in the treatment and prophylaxis of Prosthetic joint infections (PJI). PJIs is a serious problem that decreases success rate of surgery and can be life threatening to patients, where the incidence can reach up 2% in total and hip replacements and up to 40% for revision surgery. Currently used antibiotic loaded bone cements have many limitations, including burst release of < 10% of antibiotic added. This burst release falls rapidly below inhibitory level within few days, which leads to selection of resistant antimicrobial strains and does not provide prophylaxis from early and delayed stage infection. This study aims to provide a controlled release for gentamicin when loaded on Silica nanoparticles (NP) using layer-by-layer technique (LbL) to provide prophylaxis and treatment from postsurgical infections. The gentamicin loaded NPs were incorporated into PMMA bone cement and the new nanocomposite is characterized for gentamicin release, antimicrobial and mechanical properties. Our results showed that the nanocomposite gentamicin release continued for 30 days at concentration 3 times higher than the commercial formulation containing the same amount of gentamicin, where burst release for few days were observed. Moreover, the nanocomposite showed superior antimicrobial inhibition for bacterial growth and good cytocompatibility without adversely affecting the cement compressive strength, bending and fracture toughness properties

In cartilage tissue engineering (TE),new solutions are needed to effectively drive chondrogenic differentiation of mesenchymal stromal cells in both normal and inflammatory milieu. Ultrasound waves represent an interesting tool to facilitate chondrogenesis. In particular, low intensity pulsed ultrasound (LIPUS)has been shown to regulate the differentiation of adipose mesenchymal stromal cells. Hydrogels are promising biomaterials capable of encapsulating MSCs by providing an instructive biomimetic environment, graphene oxide (GO) has emerged as a promising nanomaterial for cartilage TE due to its chondroinductive properties when embedded in polymeric formulations, and piezoelectric nanomaterials, such as barium titanate nanoparticles (BTNPs),can be exploited as nanoscale transducers capable of inducing cell growth/differentiation. The aim of this study was to investigate the effect of dose-controlled LIPUS in counteracting inflammation and positively committing chondrogenesis of ASCs embedded in a 3D piezoelectric hydrogel. ASCs at 2*10. 6. cells/mL were embedded in a 3D VitroGel RGD. ®. hydrogel without nanoparticles (Control) or doped with 25 µg/ml of GO nanoflakes and 50 µg/ml BTNPs.The hydrogels were exposed to basal or inflammatory milieu (+IL1β 10ng/ml)and then to LIPUS stimulation every 2 days for 10 days of culture. Hydrogels were chondrogenic differentiated and analyzed after 2,10 and 28 days. At each time point cell viability, cytotoxicity, gene expression and immunohistochemistry (COL2, aggrecan, SOX9, COL1)and inflammatory cytokines were evaluated. Ultrasound stimulation significantly induced chondrogenic differentiation of ASCs loaded into 3D piezoelectric hydrogels under basal conditions: COL2, aggrecan and SOX9 were significantly overexpressed, while the fibrotic marker COL1 decreased compared to control samples. LIPUS also has potent anti-inflammatory effects by reducing IL6 and IL8 and maintaining its ability to boost chondrogenesis. These results suggest that the combination of LIPUS and piezoelectric hydrogels promotes the differentiation of ASCs encapsulated in a 3D hydrogel by reducing the inflammatory milieu, thus representing a promising tool in the field of cartilage TE. Acknowledgements: This work received funding from the European Union's Horizon 2020 research and innovation program, grant agreement No 814413, project ADMAIORA (AdvanceD nanocomposite MAterIals for in situ treatment and ultRAsound-mediated management of osteoarthritis)

Calcium phosphate ceramics and bioactive glasses are frequently used in orthopedic surgery to stimulate the regeneration of bone tissue due to their superior compatibility to bone tissue. Nevertheless, the brittleness and lack of self-healing behavior of bioceramics are still considered as serious drawbacks. Therefore, these bioceramics have been combined with organic biomaterials for several decades. Since the 1990s, the emergence of nanotechnology has accelerated the progress with respect to the development of organic-inorganic nanocomposites of improved functionality compared to conventional composite biomaterials. This presentation focuses on the development of injectable (nano)composites with self-healing and/or load-bearing capacity. To this end, the affinity between polymeric and inorganic components was tuned by modifying non-covalent interactions between both composite components. Specifically, we exploited reversible interactions between hydrogel matrices and inorganic nanoparticles (traditional nanocomposites), hydrogel nanoparticles and inorganic nanoparticles (colloidal nanocomposites), as well as fibers and bioceramic matrices (fiber-reinforced cement composites). The resulting composite biomaterials were mechanically strong and self-healing, which may open up new avenues of research on the applicability of self-healing and load-bearing composite biomaterials for regenerative medicine

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