Cartilage injuries often represent irreversible tissue damage because cartilage has only a low ability to regenerate. Thus, cartilage loss results in permanent damage, which can become the starting point for osteoarthritis. In the past, bioactive glass scaffolds have been developed for bone replacement and some of these variants have also been colonized with chondrocytes. However, the hydroxylapaptite phase that is usually formed in bioglass scaffolds is not very suitable for cartilage formation (chondrogenesis). This interdisciplinary project was undertaken to develop a novel slowly degrading bioactive glass scaffold tailored for cartilage repair by resembling the native extracellular cartilage matrix (ECM) in structure and surface properties. When colonized with articular chondrocytes, the composition and topology of the scaffolds should support cell adherence, proliferation and ECM synthesis as a prerequisite for chondrogenesis in the scaffold. To study cell growth in the scaffold, the scaffolds were colonized with human mesenchymal stromal cells (hMSCs) and primary porcine articular chondrocytes (pACs) (27,777.8 cells per mm. 3. ) for 7 – 35 d in a rotatory device. Cell survival in the scaffold was determined by vitality assay. Scanning electron microscopy (SEM) visualized cell ultramorphology and direct interaction of hMSCs and pACs with the bioglass surface. Cell proliferation was detected by CyQuant assay. Subsequently, the production of sulphated glycosaminoglycans (sGAGs) typical for chondrogenic differentiation was depicted by Alcian blue staining and quantified by dimethylmethylene blue assay assay. Quantitative real-time polymerase chain reaction (QPCR) revealed gene expression of cartilage-specific aggrecan, Sox9, collagen type II and dedifferentiation-associated collagen type I. To demonstrate the ECM-protein synthesis of the cells, the production of collagen type II and type I was determined by immunolabelling. The bioactive glass scaffold remained stable over the whole observation time and allowed the survival of hMSCs and pACs for 35 days in culture. The SEM analyses revealed an intimate cell-biomaterial interaction for both cell types showing cell spreading, formation of numerous filopodia and ECM deposition. Both cell types revealed initial proliferation, decreasing after 14 days and becoming elevated again after 21 days. hMSCs formed cell clusters, whereas pACs showed an even distribution. Both cell types filled more and more the pores of the scaffold. The relative gene expression of cartilage-specific markers could be proven for hMSCs and pACs. Cell associated sGAGs deposition could be demonstrated by Alcian blue staining and sGAGs were elevated in the beginning and end of the culturing period. While the production of collagen type II could be observed with both cell types, the synthesis of aggrecan could not be detected in scaffolds seeded with hMSCs. hMSCs and pACs adhered, spread and survived on the novel bioactive glass scaffolds and exhibited a chondrocytic phenotype

Introduction and Objective. Bone is a tissue which continually regenerates and also having the ability to heal after injuries however, healing of large defects requires intensive surgical treatment. Bioactive glasses are unique materials that can be utilized in both bone and skin regeneration and repair. They are degradable in physiological fluids and have osteoconductive, osteoinductive and osteostimulative properties. Osteoinductive growth factors such as Bone Morphogenetic Proteins (BMP), Vascular Endothelial Growth Factor (VEGF), Epidermal Growth Factor (EGF), Transforming Growth Factor (TGF) are well known to stimulate new bone formation and regeneration. Unfortunately, the synthesis of these factors is not cost- effective and, the broad application of growth factors is limited by their poor stability in the scaffolds. Instead, it is wise to incorporate osteoinductive nanomaterials such as graphene nanoplatelets into the structures of synthetic scaffolds. In this study, borate-based 13-93B3 bioactive glass scaffolds were prepared by polymer foam replication method and they were coated with graphene-containing poly (ε-caprolactone) layer to support the bone repair and regeneration. Materials and Methods. Effects of graphene concentration (1, 3, 5, 10 wt%) on the healing of rat segmental femur defects were investigated in vivo using male Sprague–Dawley rats. Fabricated porous bioactive glass scaffolds were coated by graphene- containing polycaprolactone solution using dip coating method. The prepared 0, 1, 3, 5 and 10 wt% graphene nanoparticle-containing PCL-coated composite scaffolds were designated as BG, 1G-P-BG, 3G-P-BG, 5G-P-BG and 10G-P-BG, for each group (n: 4) respectively. Histopathological and immunohistochemical (bone morphogenetic protein, BMP-2; smooth muscle actin, SMA and alkaline phosphatase, ALP) examinations were made after 4 and 8 weeks of implantation. Results. Results showed that after 8-weeks of implantation both cartilage and bone formation were observed in all animal groups. After 4 and 8 weeks of implantation the both osteoblast and osteoclast numbers were significantly higher in the group 4 compared to the control group. Bone formation was significant starting from 1 wt% graphene-coated bioactive glass implanted group and highest amount of bone formation was obtained in group containing 10 wt% graphene (p<0.001). Newly formed vessels expressed this marker and increased vascularization was observed in 8- weeks period compared to the 4-weeks period. In addition, an increase in new vessel formation were observed in graphene-coated scaffold implanted groups compared to the control group. While cartilage tissue was observed in control group, bone formation percentages were significant in graphene-coated scaffold implanted groups. Highest amount of bone formation occurred in group 4 (10 % wt G-C). Conclusions. Additionally, the presence of graphene nanoplatelets enhanced the BMP-2, SMA and ALP levels compared to the bare bioactive glass scaffolds. It was concluded that pristine graphene-coated bioactive glass scaffolds improve osteointegration and bone formation in rat femur defect when compared to bare bioglass scaffolds

Chronic osteomyelitis is historically treated in a two stage fashion with antibiotic-loaded polymethylmethacrylate (PMMA) as local antibacterial therapy. However, two-stage surgeries are associated with high morbidity, long hospitalization and high treatment costs. In recent years new biomaterials were developed that allow to change this treatment algorithm. S53P4 bioactive glass is such a novel biodegradable antibacterial bone graft substitute that enables a one-stage surgery in local treatment of chronic osteomyelitis. This study aimed to explore the eradication of infection and bone healing capacities of S53P4 bioactive glass in clinical practice. In this prospective longitudinal outcome study, clinical applicability of S53P4 bioactive glass in treatment of patients with chronic osteomyelitis was assessed. All patients with clinically, haematologically and radiologically evident chronic osteomyelitis were included. All patients were treated with an extensive debridement surgery, S53P4 bioactive glass implantation and systemic antibiotic administration. Primary endpoint of this study is eradication of infection. During follow-up eradication was analysed based on clinical outcomes, blood samples (inflammatory parameters) and radiological outcomes. The secondary endpoint, bone healing, is assessed using conventional radiographic images of the treated region. Between 2011 and 2016, 25 patients were included in this study, with a mean follow-up of 23 months (range 4 – 57). Hospital stay was short with a mean of 18 days (range 4 – 40) and patients required an average of 1,4 surgeries (range 1 – 4). The inflammatory parameter C-reactive protein (CRP) showed a normalization after a mean duration of 46 days (range 0 – 211). At the end of follow-up haematological and clinical outcomes showed eradication of infection in 24 (96%) of all patients. Radiologically none of all patients showed persisting signs of infection and bone healing was observed in 22 (88%) patients based on changes on conventional radiographic images. One patient had a persistent infection without any bone healing, this patient had an infected non-union prior to surgery. There were two other patients with an initial infected non-union fracture which was not consolidated at last follow-up, although they had successful infection treatment. Another patient had a femoral fracture after surgery that needed additional surgery which did not interfere with eradication of infection. Four (16%) of all patients had initial wound healing problems related to compromised skin and/or soft tissue prior to surgery. Based on the results of our clinical experience, S53P4 bioactive glass can successfully be used in a one-stage procedure for treatment of chronic osteomyelitis. Eradication of infection was successful in almost all patients and so far no patients required a second surgery due to infection recurrence. Bone healing (incorporation of the bioactive glass) was seen in all patients except for the patients with an initial infected non-union fracture. As a consequence of these results, we changed our institutional protocol for treatment of chronic osteomyelitis to a one-stage approach instead of a two-step approach

The bone infection osteomyelitis (typically Staphylococcus aureus) requires a multistep treatment process including: surgical debridement, long-term systemic high-dose antibiotics, and often bone grafting. With antibiotic resistance becoming increasingly concerning, alternative approaches are urgently needed. Herein, we develop a one-step treatment for osteomyelitis that combines local, controlled release of non-antibiotic antibacterials (copper) within a proven regenerative scaffold. To maximise efficacy we utilised bioactive glass – an established material with immense osteogenic capacity – as a copper ion delivery reservoir. Copper ions have also been shown to stimulate angiogenesis and induce MSC differentiation down an osteogenic lineage. To eliminate grafting requirements, the copper-doped BG was incorporated into our previously developed collagen scaffolds to produce multifunctional antibacterial, osteogenic, and angiogenic scaffolds. Scaffolds were fabricated by freeze-drying a co-suspension of collagen and bioactive glass particles (+/− copper doping, referred to as CuBG and BG, respectively) at a range of different concentrations (0–300% w/w bioactive glass/collagen). Scaffolds demonstrated a 2.7-fold increase in compressive modulus (300% CuBG vs. 0%; p≤0.01), whilst maintaining >98% porosity. The 300% CuBG scaffolds showed significant antibacterial activity against Staphylococcus aureus (p≤0.001). In terms of osteogenesis, both 100% and 300% CuBG scaffolds increased cell-mediated calcium deposition on the scaffolds at day 14 and 28 (p≤0.05 and p≤0.001), as confirmed by alizarin red staining. 100% CuBG scaffolds significantly enhanced angiogenesis by increased tubule formation (p≤0.01) and VEGF protein production (p≤0.001) (all ≥n=3). In summary, this single-stage, off-the-shelf treatment for osteomyelitis shows potential to minimise bone grafting and antibiotic dependence, while reducing hospital stays and costs

Introduction. Articular cartilage has a low self-regeneration capacity. Cartilage defects have to be treated to minimize the risk of the onset of osteoarthritis. Bioactive glass (BG) is a promising source for cartilage tissue engineering. Until now, conventional BGs (like BG1393) have been used, mostly for bone regeneration, as they are able to form a hydroxyapatite layer and are therefore, less suited for cartilage reconstruction. The aim of this study is to study the effect of 3D printed hydrogel scaffolds supplemented with spheres of the BG CAR12N to improve the chondrogenesis of mesenchymal stem cells (MSCs). Method. Based on our new glass composition (CAR12N), small BG spheres (25-40 µm) were produced and mixed with hydrogel and primary human (h) MSCs. Grid printed scaffolds were cultivated up to 21 days in expansion or chondrogenic differentiation medium. Macroscopical images of the scaffolds were taken to observe surface changes. Vitality, DNA and sulfated glycosaminoglycan (GAG) content was semiquantitatively measured as well as extracellular matrix gene transcription. Result. It was possible to print grid shaped hydrogel scaffolds with BG spheres and hMSCs. No significant changes in scaffold shape, surface or pore size were detected after 21 days in culture. The BG spheres were homogeneously distributed inside the grids. Vitality was significantly higher in grids with CAR12N spheres in comparison to those without. The DNA content remained constant over three weeks, but was higher in the sphere containing scaffolds than in those without BG spheres. GAG content in the grids increased not only with additional cultivation time but especially in grids with BG spheres in chondrogenic medium. Aggrecan and type II collagen gene expression was significantly higher grids cultured in the chondrogenic differentiation medium. Conclusion. This developed 3D model, is very interesting to study the effect of BG on hMSCs and to understand the influence of leaking ions on chondrogenesis

The regenerative capacity of hyaline cartilage is greatly limited. To prevent the onset of osteoarthritis, cartilage defects have to be properly treated. Cartilage, tissue engineered by mean of bioactive glass (BG) scaffolds presents a promising approach. Until now, conventional BGs have been used mostly for bone regeneration, as they are able to form a hydroxyapatite (HA) layer and are therefore, less suited for cartilage reconstruction. The aim of this study is to compare two BGs based on a novel BG composition tailored specifically for cartilage (CAR12N) and patented by us with conventional BG (BG1393) with a similar topology. The highly porous scaffolds consisting of 100% BG (CAR12N, CAR12N with low Ca2+/Mg2+ and BG1393) were characterized and dynamically seeded with primary porcine articular chondrocytes (pACs) or primary human mesenchymal stem cells (hMSCs) for up to 21 days. Subsequently, cell viability, DNA and glycosaminoglycan contents, cartilage-specific gene and protein expression were evaluated. The manufacturing process led to a comparable high (over 80%) porosity in all scaffold variants. Ion release and pH profiles confirmed bioactivity for them. After both, 7 and 21 days, more than 60% of the total surfaces of all three glass scaffold variants was densely colonized by cells with a vitality rate of more than 80%. The GAG content was significantly higher in BG1393 colonized with pACs. In general, the GAG content was higher in pAC colonized scaffolds in comparison to those seeded with hMSCs. The gene expression of cartilage-specific collagen type II, aggrecan, SOX9 and FOXO1 could be detected in all scaffold variants, irrespectively whether seeded with pACs or hMSCs. Cartilage-specific ECM components could also be detected at the protein level. In conclusion, all three BGs allow the maintenance of the chondrogenic phenotype or chondrogenic differentiation of hMSCs and thus, they present a high potential for cartilage regeneration

The treatment of chronic osteomyelitis often includes surgical debridement and filling the resultant void with antibiotic-loaded polymethylmethacrylate cement, bone grafts or bone substitutes. Recently, the use of bioactive glass to treat bone defects in infections has been reported in a limited series of patients. However, no direct comparison between this biomaterial and antibiotic-loaded bone substitute has been performed. . In this retrospective study, we compared the safety and efficacy of surgical debridement and local application of the bioactive glass S53P4 in a series of 27 patients affected by chronic osteomyelitis of the long bones (Group A) with two other series, treated respectively with an antibiotic-loaded hydroxyapatite and calcium sulphate compound (Group B; n = 27) or a mixture of tricalcium phosphate and an antibiotic-loaded demineralised bone matrix (Group C; n = 22). Systemic antibiotics were also used in all groups. After comparable periods of follow-up, the control of infection was similar in the three groups. In particular, 25 out of 27 (92.6%) patients of Group A, 24 out of 27 (88.9%) in Group B and 19 out of 22 (86.3%) in Group C showed no infection recurrence at means of 21.8 (12 to 36), 22.1 (12 to 36) and 21.5 (12 to 36) months follow-up, respectively, while Group A showed a reduced wound complication rate. Our results show that patients treated with a bioactive glass without local antibiotics achieved similar eradication of infection and less drainage than those treated with two different antibiotic-loaded calcium-based bone substitutes. Cite this article: Bone Joint J 2014; 96-B:845–50

Introduction and Objective. Regeneration of cartilage injuries is greatly limited. Therefore, cartilage injuries are often the starting point for later osteoarthritis. In the past, various bioactive glass (BG) scaffolds have been developed to promote bone healing. Due to the fact that they induce the deposition of hydroxyapatite (HA) -the main component of bone matrix, these BG types are not suitable for chondrogenesis. Hence, a novel BG (Car12N) lacking HA formation, was established. Since BG are generally brittle the combination with polymers is helpful to achieve suitable biomechanic stability. The aim of this interdisciplinary project was to investigate the effects of biodegradable polymer Poly(D,L-lactide-co-glycolide) (PLLA) infiltration into a Car12N scaffold for cartilage tissue engineering. Materials and Methods. BG scaffolds were infiltrated with PLLA using phase separation within a solvent. Pure BG Car12N scaffolds served as control. To assess whether the polymer was homogeneously distributed the polymer to glass ratio and pore contents in the upper, middle and lower third of the scaffolds were examined by light microscopy. For a more precise characterization of the scaffold topology, the glass strut length, the glass strut diameter and the pore circumference were also measured. Leaching tests in 0.1M HCl solution over 8 days were used to allow a gel layer formation on the scaffolds surface. Non-leached and leached scaffolds were subjected to strength testing. Cytotoxicity of the scaffolds with and without polymer was tested according to standards. Scaffolds were colonized with 27.777.8 per cm. 3. primary porcine articular chondrocytes (pACs) or primary human mesenchymal stromal cells (hMSCs), respectively. After cultivation for up to 35 days, the vitality, quantitative DNA and sulfated glycosaminoglycan (sGAG) contents per scaffold were determined. Results. The polymer distribution was not homogeneous in the scaffolds. There were significant differences in glass strut length and pore size. Leaching increased the biomechanical strength. All scaffolds were not cytotoxic. pACs and hMSCs were able to adhere to the scaffold with and without polymer and remained viable during the whole culturing period of 35 d. The DNA content was higher in the pAC colonized scaffolds with polymer than without polymer. The sGAG content was higher in hMSCs seeded scaffolds with polymer than in pACs seeded ones with polymer. Conclusions. Polymer infiltration leads to an increase in mechanical stability of Car12N scaffolds and chondrogenic cells are able to colonize these composites suggesting them as a promising

Hydrogels as scaffolds provide a suitable environment for the cells (biocompatibility, biodegradability). Their biomechanical properties are very important to provide not only direct support to the surrounding tissue but also provide a local microenvironment. There is an interest in composite hydrogels with hydroxylapatite or bioactive glass (BAG) for tuning of their bioactivity and biomechanical properties [1]. Hydrogels were prepared from a polysaccharide gellan gum (GG), dissolved in ultrapure water at 90°C under constant stirring to a final concentration of 2 wt.% GG. Sodium-free BAG (70 wt.% SiO. 2. , 30 wt.% CaO) was synthesized using a sol-gel technique with particles of ∼100 nm, clustered to ∼10 µm large agglomerates [1]. The hydrogel composites were prepared by admixing up to 2–8 wt.% of BAG powder into a solution of GG during sonication, and pouring the hot BAG-GG suspension with following cooling to room temperature. Mechanical properties were evaluated using different protocols in creep (0.1 to 1.2 N), strain sweep (1 to 20 µm) and frequency scan (100 to 0.1 Hz) modes, with specimens immersed in water at 25°C. Maximum load (or deformation) before breaking of scaffold materials is a very important material property but is rarely measured. Here creep experiments at different applied stresses were carried out first. These loads exert more proper stress on the scaffold material that results in deformation, which is not the same as during deformation in relaxation or stress-strain tests [2]. The second set of experiments was made at physiologically relevant conditions (1 Hz frequency and small amplitude-controlled deformation) [3]. Amount of 2% BAG was found to be sufficient to get nearly linear deformation in the whole measured strains region, but at higher concentration stress deviated from linearity at strains exceeding ∼0.5% at 1 Hz. Storage modulus (E') did not significantly change and the loss tangent was found nearly constant (∼0.1) for the whole frequency range, indicating a strong network structure of BAG-doped hydrogel. Additions of 2% BAG give a ten-fold increase in both storage and loss moduli, whereas further increase of BAG content does not show further stiffening. The application of tailored protocols [3] allowed analysis of dynamic, creep and relaxation tests in the same device with same specimens, which might be not possible for other techniques. Creep data would provide valuable information in addition to dynamic modes to predict long-term behaviour of the composite hydrogels. Properly tailored protocols could mimic, for example, articular cartilage or other tissue working conditions and allow evaluation of the side effects like swelling at early stage, which measurements are usually rather cumbersome

Introduction

Bioactive glasses (BGs) promote osteogenic differentiation of bone progenitor cells by releasing therapeutically active ions. The well-described 45S5-BG (in mol%: SiO₂ 46.13; P₂O₅ 2.60; CaO 26.91; Na₂O 24.35) was supplemented with CaF₂ and NaF being added to the batch at nominal 5 (F5-BG) and 25 mol% (F25-BG), respectively. While the effect on physical and chemical properties has already been characterized, the biological properties require further studies. This study investigates the effects of fluoride-supplemented BGs on the osteogenic and angiogenic properties of human bone marrow mesenchymal stromal cells (BMSCs) in vitro.

Background

Bio-Active Glass (BAG) is a promising bone graft substitute for large bone defect reconstruction because of its favourable osteoconductive, antibacterial and angiogenic properties. Potentially, it could also mechanically reinforce the defect, thus making it suitable for load-bearing defects. However, the mechanical properties of the reconstructive layer consisting of BAG/bone allograft mixtures are unknown. The goals of this study therefore were, first, to measure the mechanical properties of different BAG/bone graft mixtures and, second, to investigate to what extent such mixtures could reinforce distal tibial defects using micro-FE analysis and high-resolution CT scans.

Osteomyelitis is an infection of bone or bone marrow with a concomitant inflammation involving the bone marrow and the surrounding tissues. Chronic osteomyelitis is historically treated in a two-stage fashion with antibiotic-loaded polymethylmethacrylate as local antibacterial therapy. Two-stage surgeries are associated with high morbidity, long hospitalization and high treatment costs. Next to antibiotic releasing biomaterials, S53P4 bioactive glass is a biomaterial that enables one-stage surgery in local treatment of chronic osteomyelitis. S53P4 bioactive glass is gaining interests in recent years in clinical treatment of chronic osteomyelitis in a one-stage fashion due to its antibacterial and bone regenerating capacities. By changing local pH and osmotic pressure S53P4 bioactive glass attack bacteria in a different way as compared to antibiotics. In this presentation, we will present current clinical treatment options for osteomyelitis, clinical results and level of evidence of various biomaterials used in osteomyelitis treatment. In addition, the clinical results and health-economic results of S53P4 bioactive glass will be detailed. Thereafter a summary of the current standing across the board in osteomyelitis treatment will be provided

The discussion will focus on new approaches to reduce bacterial adhesion on the surface of polymethylmethacrylate (PMMA) in contact with bone, comparing the clinical and engineering point of view. One possibility is to encourage and speed up direct interaction with the bone, for example by adding a bioactive phase in the cement (hydroxyapatite, glass and bioactive glass ceramic). A widespread strategy is also the addition of different types of antibiotics (gentamicin, tobramycin vancomycin, etc.), although they are known to have some drawbacks: not complete release, resistant strain development. Another strategy could be represented by the PMMA-based composite cements loaded with a completely inorganic filler consisting of a bioactive glass doped with ions whose bioactivity mechanism is well-known and encompasses a chemical and biological interaction with tissues promoting osteoinduction. Bioactive glasses can be doped with antibacterial ions (silver, copper, etc.) preserving their biocompatibility and bioactivity and, at the same time, acquiring antibacterial properties. Thus, it is possible to produce composite cements that combine the properties of the polymer matrix with those of the inorganic filler, overcoming the main problems associated with the use of antibiotics. An additional possibility is the addition of essential oils, vegetable oils with remarkable antibacterial properties

The optimal treatment strategy for post-traumatic long bone non-unions is subject of an ongoing discussion. At the Maastricht University Medical Center (MUMC+) the induced membrane technique is used to treat post-traumatic long bone non-unions. This technique uses a multimodal treatment algorithm involving bone marrow aspirate concentrate (BMAC), the reamer-irrigator-aspirator (RIA) and P-15 bioactive peptide (iFactor, Cerapedics). Bioactive glass (S53P4 BAG, Bonalive) is added when infection is suspected. This study aims to objectify the effect of this treatment algorithm on the health-related quality of life (HRQoL) of patients with post-traumatic long bone non-unions. We hypothesized that HRQoL would improve after treatment. From January 2020 to March 2023, consecutive patients who were referred to a multidisciplinary (trauma, orthopaedic and plastic surgery) non-union clinic at the MUMC+, The Netherlands, were evaluated using the Non-Union Scoring System (NUSS). The EQ-5D-5L questionnaire and the Lower Extremity Functional Scale (LEFS) were employed to obtain HRQoL outcomes both prior to and subsequent to surgery, with a follow-up at 6, 18 and 35 weeks. Seventy-six patients were assessed at baseline (T0), with a mean NUSS of 40 (± 13 SD). Thirty-eight patients had their first follow-up, six weeks after surgery (T1). Thirty-one patients had a second follow-up at 18 weeks (T2), and twenty patients had the third follow-up at 35 weeks (T3). The EQ-5D index mean at baseline was 0.480, followed by an index of 0.618 at T1, 0.636 at T2, and 0.702 at T3. A significant difference was found in the HRQoL score between T0 and T1, as well as T2 and T3 (p<0.001; p=0.011). The mean LEFS significantly increased from 26 before intervention to 34, 39, and 43 after treatment (p<0.001; p=0.033; p=0.016). This study demonstrated a significant improvement in the health-related quality of life of patients with post-traumatic long bone non-unions after the standardized treatment algorithm following the induced membrane technique

Synthetic bone grafts are used in several major dental and orthopaedic procedures. Strontium, in the form of strontium ranelate, has been shown to reduce fracture risk when used to treat osteoporosis. The aim of the study was to compare bone repair in femoral condyle defects filled with either a 10% strontium substituted bioactive glass (StronBoneTM) or a TCP-CaSO4 graft. We hypothesise that strontium substituted bioactive glass increases the rate of bone ingrowth into a bone defect when compared to a TCP-CaSO4 ceramic graft. A critical size defect was created in the medial femoral condyle of 24 sheep; half were treated with a Sr-bioactive glass (StronBoneTM), and in the other animals defects were filled TCP-CaSO4. Two time points of 90 and 180 days were selected. The samples were examined with regard to: bone mineral density (BMD) from peripheral quantitative CT (pQCT), mechanical properties through indentation testing, and bony ingrowth and graft resorption through histomorphometry. The radiological density of Sr-bioactive glass in the defect is significantly higher than that of the TCP-CaSO4-filled defect at 90 and 180 days, (p=0.035 and p=0.000). At 90 days, the stiffness of the defect containing Sr-bioactive glass and is higher than that of the TCP-CaSO4 filled defect, (p=0.023). At 6 months there is no significant difference between the two materials. Histomorphometry showed no significant difference in bone ingrowth at any time point, however significantly more of the graft is retained for the StronBoneTM treatment group than the TCP-CaSO4 group at both 0 days (p=0.004) and 180 days (p=0.000). The amount of soft tissue within the defect was significantly less in the StronBoneTM group than for the TCP-CaSO4 group at 90 days (p=0.006) and 180 days (p=0.000). The data shows the mechanical stability of the defect site is regained at a faster rate with the strontium substituted bioglass than the TCP-CaSO4 alternative. Histomorphmetry shows this is not due to increased bone ingrowth but may be due to the incorporation of stiff graft particles into the trabeculae. Sr-bioactive glass produces a stronger repair of a femoral condyle defect at 3 months compared with TCP-CaSO4

Novel biomaterials are being developed and studied, intended to be applied as bone graft substitute materials. Typically, these materials are being tested in in vitro setups, where among others their cytotoxicity and alkaline phosphatase activity (as a marker for osteoblastic differentiation) are being evaluated. However, it has been reported that in vitro tests correlate poorly with in vivo results and therefore many promising biomaterials may not reach the clinic as a bone graft substitute product. One of the reasons for the poor correlation, may be the minimal complexity of the in vitro tests, as compared to the in vivo environment. Ex vivo models, mimicking the natural tissue environment whilst maintaining control of culture parameters, may be a promising alternative to assess biomaterials for bone formation. Assess the possibility of an ex vivo culture platform to test biomaterials on their potential to stimulate new bone formation. Osteochondral plugs (cylinders n=10, Ø 10 mm, height 15 mm) were drilled from fresh porcine knees, from the slaughterhouse. A bone defect (Ø 6 mm) was created and which was filled with a biomaterial graft (S53P4 bioactive glass (n=3); collagen sponges loaded with BMP-2 (n=3, as positive control)) or kept empty (n=4). The explants were cultured in custom-made two-chamber bioreactors for six weeks (LifeTec Group BV). Cartilage and bone were physically separated, similar to the in vivo situation, by a sealing ring. The two tissues were cultured in separate compartments, allowing for specific culture medium for each tissue. Medium was changed every 2–3 days and weekly micro computed tomography (µCT) images were obtained to longitudinally monitor the formation of new bone. An MTT assay was performed on half of the samples after six weeks of culture. The other samples were fixed for histology, to determine which cells were present after six weeks. The MTT metabolic assay showed that a number of cells in the bone were viable after six weeks. The further away from the border, the fewer living cells were observed. The cells in the cartilage also survived. No significant bone formation was observed with µCT in either of groups, even though abundant bone formation was expected in the BMP-2 group. Explanations of the negative results of the positive group might be that too few viable cells remain after six weeks, or that the cells that are still present are not able to form bone. No significant bone formation was observed in the bone defects in osteochondral explants that were cultured with, or without, biomaterials for six weeks. However, the platform showed that it is capable to successfully culture osteochondral explants for six weeks. Histology needs to be performed to evaluate which cells were present at the end of the culture and this will be compared to the cells present directly after drilling the explants

Osteoporosis is a worldwide spread, silent disease steadily increasing due to demographic shift; it results in bone loss and increased porosity that lead to an increase in bone fragility and to low-energy fractures. In such a contest, we worked on the development of 3D scaffolds engineered to mimic the features of human healthy bone. Healthy and osteoporotic bone microCT scans were obtained from tissues discarded during surgical interventions (Istituto Ortopedico Rizzoli-Italy). The obtained .STL file was used to 3D print a type I collagen solution to mimic bone matrix whereas mesoporous bioactive glass/nano-hydroxyapatite were embedded within the collagen fibers to mimic the inorganic phase of human bone. The rheological properties of the Type I collagen/mesoporous glass suspensions were investigated at different collagen concentration and temperatures. The possibility of incorporating growth factors (IGF and β-TGF) in the scaffold struts was investigated proposing several approaches and their retained activity was assessed. Different co-culture of osteoblasts and osteoclasts set-ups were explored in order to define the influence of both chemical and topographical stimuli on the osteoblast-osteoclast coupling

Post-surgical infections are still one of the most frequent adverse events in the prosthetic surgery. PMMA-based cements are widely employed in orthopaedic surgery as filler or prosthetic fixing device. The main problems associated with this material are poor bone integration and infection development. Aiming to avoid bacterial adhesion and to extend the longevity of implants, different solutions were proposed, both in terms of operative procedures and new materials development. Regarding the materials advancement, innovative PMMA-based composite bone cements, contemporaneously bioactive and antibacterial (without the use of antibiotics), were developed. The composites are based on a PMMA matrix containing a bioactive glass, doped with antibacterial ions (Ag+ or Cu++); so, the same filler shows at the same time the ability of promoting bone ingrowth and an antibacterial effect. Composite cements were characterized in terms of morphology and composition, curing parameters and mechanical properties; in vitro tests were performed to verify the material ability to release antibacterial ions and to promote the precipitation of hydroxyapatite. Moreover, cytotoxicity and antimicrobial properties were verified. The cements characteristics were tested using different commercial matrix and different viscosities; therefore, the proposed formulations represent an innovative solution for a new family of antibiotic-free, bioactive and antibacterial cements

Among plant derived molecules, polyphenols have antioxidant, anticancer and antibacterial ability [1,2]. Moreover, they can stimulate osteoblast differentiation and promote apoptosis of tumoral cells [3–4]. It's thus possible combine the properties of these molecules with those of bioactive materials trough surface functionalization. A silica-based bioactive glass and chemically treated bioactive Ti6Al4V were used as substrates while gallic acid and polyphenols extracted from green tea or red grape skin as biomolecules for functionalization. The surface functionalization procedure was optimized in order to maximize the grafting and investigated by means of the Folin&Ciocalteu method and X-Ray Photoelectron Spectroscopy (XPS) analyses. The in vitrobioactivity was studied by means of Field Emission Scanning Electron Microscopy (FESEM) and Fourier Transform Infrared Spectroscopy (FTIR) after soaking in simulated body fluid (SBF). Surface charge and isoelectric point were investigated by means of zeta potential measurements. Free radical scavenging activity evaluation was performed in order to investigate the antioxidant ability of glass samples. Finally, the functionalization selective killing activity towards osteosarcoma cells was in vitroassayed by the metabolic 3-(4,5-Dimethylthiazol-2-Yl)-2,5-Diphenyltetrazolium Bromide (MTT) test and compared with non-tumoral control bone cells. The presence of polyphenols on the surfaces was confirmed by XPS analyses by the appearance of characteristic peaks (C-O and C=O bonds) in the carbon and oxygen regions. The Folin&Ciocalteu test demonstrated the presence and activity of polyphenols on all the substrates and evidenced a clear relation between surface reactivity and grafting ability. The bioactivity tests showed the deposition of hydroxyapatite on the functionalized samples and an influence of biomolecules on its amount and shape for glasses. Zeta potential measurements evidenced a shift of the isoelectric point of glass samples after functionalization. A certain antioxidant activity of bare glass has been evidenced and it is improved by the grafting of tea polyphenols. Accordingly, MTT results confirmed polyphenols selective killer activity towards osteosarcoma cells whose viability was significantly decreased in comparison with safe bone cells. XPS analyses, zeta potential measurements and Folin&Ciocalteu tests showed the presence and the activity of the polyphenols on the surfaces. Bioactivity tests highlighted an improvement of the deposition of hydroxyapatite on the surface of the functionalized glass samples. Certain antioxidant ability has been evidenced for glass samples and was further improved by tea polyphenols. Moreover, a selective toxic activity towards tumor cells was in vitropreliminary confirmed. In conclusions polyphenols were successfully grafted to the surface of glass and Ti6Al4V samples maintaining their activity. Polyphenols improve in vitro bioactivity, antioxidant and anticancer ability of glass. The surface functionalization seems to be a good way to combine the properties of bioactive materials for bone contact applications with those of polyphenols

Introduction. Millions of bone graft surgeries have improved the quality of the life of millions, which cost about £ 2.5 billion annually worldwide. Current focus of the researcher is to synthesis of a bioactive bone scaffold which will reduce the cost and number of the bone graft surgeries. Hypothesis To synthesis novel, bioactive, porous, mechanical stable bone scaffold using bio glass and alginate. Methods. Sr releasing glass was made using by melt derived technique. Composite bone scaffold was made using bio-glass and alginate. Freeze dry technique was used to make the porous bone scaffold. Bone scaffold was characterized using XRD, DSC, FTIR, Particle size analyser, SEM, ICP, Mechanical testing, Cell culture with osteoblast and fibroblast and NMR techniques. RESULTS. Fig: Graph showing the FTIR spectra of bone scaffold. Discussion and conclusion. FTIR shows the Si-o-Si bonds of the glass and shifting of the bonding after adding the alginate and during cross linked with Cacl2 and Srcl2. Scanning electron microscopy result shows the average pore size of around 100µm which is desirable for the growth of the cell. Release of desirable Calcium and phosphate ions can be seen from the ICP-OES measurement. Compression test allows deciding that the composite material with alginate and bioactive glass shows much better result than the simple alginate scaffolds. Cell culture showed round cells on the surface of the scaffold. And the NMR shows the interaction between bio glass and alginate. Significance We were able to produce a new novel bone scaffold which can reduce the economical burden of bone grafting