Tofu as excellent scaffolds for potential bone regeneration

Biomimetic scaffolds present the promising potential for bone regeneration. As a natural gel-like traditional food, tofu with porous architecture and proved biological safety indicated a good potential to be a natural scaffold and easy to be improved by surface modification. Hereon, we fabricated the tofu-based scaffolds and systematically explored the potential for bone tissue engineering. In addition, the collagen has been introduced by simple coating to further enhance the surface compatibility of the tofu-based scaffold in bone regeneration. The results showed that the tofu-based scaffolds possessed good porous structure and cytocompatibility. Notably, the tofu-based scaffolds could improve the expression of osteogenesis-related genes and proteins, leading to better bone regeneration after 2 months of implantation. All the results indicated that tofu would become an outstanding sustainable natural porous scaffold for bone regeneration with excellent bioactivities.     

Magnesium-containing silk fibroin/polycaprolactone electrospun nanofibrous scaffolds for accelerating bone regeneration

Bone tissue engineering has become one of the most effective methods for treating bone defects. In this study, an electrospun tissue engineering membrane containing magnesium was successfully fabricated by incorporating magnesium oxide (MgO) nanoparticles into silk fibroin and polycaprolactone (SF/PCL)-blend scaffolds. The release kinetics of Mg²⁺ and the effects of magnesium on scaffold morphology, and cellular behavior were investigated. The obtained Mg-functionalized nanofibrous scaffolds displayed controlled release of Mg²⁺, satisfactory biocompatibility and osteogenic capability. The in vivo implantation of magnesium-containing electrospun nanofibrous membrane in a rat calvarial defect resulted in the significant enhancement of bone regeneration twelve weeks post-surgery. This work represents a valuable strategy for fabricating functional magnesium-containing electrospun scaffolds that show potential in craniofacial and orthopedic applications.     

Microanalysis of hybrid characterization of PLA/cHA polymer scaffolds for bone regeneration

Tissue engineering uses some engineering strategies for the reconstruction and repair of the compromised tissues, among which the use of biomaterials as an alternative to conventional transplants is significant. However, not many research has been developed on the use of biopolymer nanostructure microanalysis and calcium phosphate composites of carbon apatite in PLA as scaffolds for tissue regeneration. In this work, poly (lactic acid) filaments with 5% and 20%, carbon apatite (cHA) were microanalysis to produce a 3D printing scaffold. The scaffolds were characterised by the Scanning Electron Microscope (SEM) and Energy Dispersive X-Ray (EDX) techniques, thereby making it possible to notice a good load dispersion. The microstructural analysis of the scaffolds was carried out by computerised micro-tomography to determine the roughness, morphological parameters of pore size distribution, porosity, as well as better visualisation of the distribution of particles. A computational in vitro and microanalysis tests to assess the biocompatibility viability of the PLA/cHA structure with a variation of scaffold geometry to evaluate their effects on morphological, physicochemical and mechanical properties were also carried out. The characterisation of Ca and P release assays were observed for longer incubation times and the dynamic condition control to simulate the stresses suffered by the biomaterial exerted by the flow of fluids was achieved. The results obtained indicated that the micrographs of the cross-sections of the scaffolds showed a flatness in the loaded material when compared to the 100/0 PLA. Furthermore, the apparent porosity of 5% and 20% of cHA scaffolds gave a porosity percentage of approximately 62% and 41% respectively. The reduced summit height, reduced valley depth and the percentage upper and lower bearing area difference of the samples are 16.33 nm, 9.62 nm and 75.07% respectively. The morphological characterisation surface roughness analysis and tolerance insertion gave a favourable reduced porosity result for the composite scaffolds with 5% of cHA. Hence, this work will assist biomaterial industries in the development of biomaterials which have been engineered with biological systems to meet medical purposes.     

Innovative methodology for developing a bone grafting composite biomaterial starting from the seashell of Rapana thomasiana

Bone grafts are used in a wide array of clinical settings to augment bone repair and regeneration. This article reports a new method for the elaboration of a hybrid biomaterial in the form of sponge based on collagen gel, CaCO₃ from recycled Rapana thomasiana seashell, and Na₂HPO₄·2H₂O. Practically, collagen acts as a matrix through which calcium and phosphate ions are diffusing during in situ hydroxyapatite synthesis. The organic–inorganic interactions among biomaterial components have been studied by infrared spectroscopy, and the surface morphology was investigated by scanning electron microscopy technique. Moreover, the developed biomaterials were studied for in vitro biocompatibility with MG63 human osteoblasts. The results obtained demonstrated that the developed hybrid material does not exhibit a significant cytotoxicity and supports cell proliferation. Consequently, it holds great promise for applications in bone tissue engineering.     

Natural lotus root-based scaffolds for bone regeneration

A high incidence of bone defects and the limitation of autologous bone grafting require 3 D scaffolds for bone repair. Compared with synthetic materials, natural edible materials possess outstanding advantages in terms of biocompatibility, bioactivities and low manufacturing cost for bone tissue engineering. In this work, attracted by the natural porous/fabric structure, good biocompatibility and bioactivities of the lotus root, the lotus root-based scaffolds were fabricated and investigated the...     

Development of nano-tricalcium phosphate/polycaprolactone/platelet-rich plasma biocomposite for bone defect regeneration

Nano-tricalcium phosphate (n-TCP) is an osteoconductive substance which, like polycaprolactone (PCL), has been used for clinical purposes for many years; It has now been licensed for a range of products for clinical and medication distribution. This research aimed to examine the effects of platelet-rich plasma on mesenchymal stem cell proliferation and osteogenic differentiation. Thus, we decided to examine the in vitro and in vivo actions of PRP-treated porous biocomposite scaffolds based on nano-tricalcium phosphate- polycaprolactone (n-TCP-PCL/PRP). The prepared samples were described utilizing FTIR, XRD, and SEM. MTT has measured the cytotoxicity of the biocomposite scaffolds. After two weeks of cell seeding, Alizarin red staining confirmed bone mineral formation by MSCs cells. Moreover, from day 4 to day 7, n-TCP-PCL/PRP biocomposite scaffold improved the expresses of bone marker genes. Platelet-rich plasma (PRP) in conjunction with nano-tricalcium phosphate- polycaprolactone (n-TCP-PCL) biocomposite scaffold is beneficial for the regeneration and stability of the freshly developed bone tissue.     

Collagen-based scaffolds enriched with glycosaminoglycans isolated from skin of Salmo salar fish

In this study both collagen and glycosaminoglycans were isolated from biodegradable waste. Namely collagen was isolated from rat tail tendons and glycosaminoglycans (GAGs) from fish skin. Porous materials were then obtained based on the isolated collagen with 1 or 5% addition of GAGs by freeze-drying process. The scaffolds were studied by infrared spectroscopy, mechanical testing and examined for the porosity and density. The scaffolds structure was observed by scanning electron microscope. The adhesion and proliferation of human osteosarcoma SaOS-2 cells was examined on prepared scaffolds to assess their biocompability.The results showed that the addition of glycosaminoglycans improves the properties of collagen-based scaffolds. Mechanical strength was increased by GAGs addition as well as the porosity of studied materials. Each scaffold with and without GAGs displayed porous structure with interconnected regular shaped pores. The attachment of cells was better for pure collagen scaffold, however, GAGs additive promoted the cells proliferation on the scaffold.     

复合凝胶途径制备胶原-海藻酸钠-羟基磷灰石支架材料

羟基磷灰石和胶原是人体骨的主要成分,近年来,制备纳米羟基磷灰石/ 胶原复合材料已成为目前生物材料研究的热点之一[1-3].海藻酸钠是一种酸性的多聚糖,具有良好的生物相容性,目前已经被广泛应用于化学、生物、医药、食品等领域;海藻酸钠能与钙离子交联,可进一步获得具有良好弹性性能的网状结构[4,5].     

L-Arginine/nanofish bone nanocomplex enhances bone regeneration via antioxidant activities and osteoimmunomodulatory properties

In this study,a promising strategy has been developed to promote bone regeneration by combining antioxidant activities and osteoimmunomodulatory properties.Herein,an L-arginine/nanofish bone(Arg/NFB) nanocomplex has been prepared and evaluated in vitro and in vivo.The Arg/NFB nanocomplex possesses good antioxidant activities and could modulate the polarization of non-activated macrophage into different types and induce the secretion of pre-inflammato ry,anti-inflammatory,osteogenic as well as angiogenic cytokines.Additionally,the regulated immune microenvironment can enhance the osteogenic differentiation of mouse embryo osteoblast precursor cells(MC3 T3-E1) and angiogenic capacity of human umbilical vein endothelial cells(HUVECs),leading to the improved formation of mineralized nodules,alkaline phosphatase activity and angiogenic effects.In vivo results with cranial defect models reveal that the treatment of Arg/NFB nanocomplex exhibited significant improvement of new bone formation and angiogenesis.All the results demonstrate Arg/NFB nanocomplex with antioxidant activities and osteoimmunomodulatory properties could be a new idea for developing the next generation of bone regeneration biomaterials.     

Synthesis and applications of graphene oxide aerogels in bone tissue regeneration: a review

Development of biocompatible porous supports is a promising strategy in the field of tissue engineering for the repair and regeneration of bone tissues with severe damage. Graphene oxide aerogels (GOAs) are excellent candidates for the manufacture of these systems due to their porosity, ability to imitate bone structure, and mechanical resistance, and according to their surface chemical reactivity, they can facilitate osseointegration, osteogenesis, osteoinduction and osteoconduction. In this review, synthesis of GOAs from the most primary source is described, and recent studies on the use of these functionalized carbonaceous foams as scaffolding for bone tissue regeneration are presented.     

HPMC crosslinked chitosan/hydroxyapatite scaffolds containing Lemongrass oil for potential bone tissue engineering applications

The chitosan (CS), hydroxypropyl methyl cellulose (HPMC), hydroxyapatite (HAp and Lemon grass oil (LGO) based scaffolds was prepared by freeze gelation method. The composite formation was confirmed by FTIR (Fourier-transform infrared spectroscopy) analysis and surface morphology was evaluated by SEM (Scanning Electron Microscopy) analysis. The mechanical strength, biodegradation, swelling, porosity and antibacterial activity were evaluated on the basis of LGO contents. The scaffold structure was porous and the mechanical strength was enhanced as a function of LGO contents. The scaffold properties analysis revealed the biodegradation nature and swelling behavior of CS-HPMC-HAp-LGO was also affected significantly as a function of LGO contents. The cytotoxicity of CS-HPMC-HAp-LGO was studied against MC3T3-E1 cells and based on cell viability, no toxic sign was observed. The antimicrobial activity was evaluated against S. aureus and CS-HPMC-HAp-LGO scaffolds showed promising activity, which was varied as a function of LGO contents. The findings revealed that the CS-HPMC-HAp-LGO are biocompatible and have potential for bone tissue engineering.     

Magnesium-zinc-graphene oxide nanocomposite scaffolds for bone tissue engineering

The aim of this study was to fabricate and evaluate magnesium-zinc-graphene oxide nanocomposite scaffolds for bone tissue engineering. For this reason, Mg-6Zn, Mg-6Zn-1GO, and Mg-6Zn-2GO scaffolds were fabricated by the powder metallurgy method. The porosity level and also the pore size of the scaffolds were evaluated by SEM which varied from 40 to 46% and 200 to 500 μm, respectively. The chemical composition and microstructure of the scaffolds were characterized by XRD and SEM equipped with EDS; the presence of Mg, Zn, C, and O elements in the structure of the scaffolds was shown. Also, the elemental map confirmed the existence of magnesium, zinc, carbon, and oxygen in the structure of the scaffold. The mechanical properties of the scaffolds were investigated by the compression test; the results showed that by the addition of graphene oxide to the structure, the compressive strength of the samples increased from 5 to 8 MPa. Electrochemical corrosion polarization tests were conducted to evaluate the corrosion resistance of the samples immersed in simulated body fluid (SBF). Furthermore, the biodegradability of the scaffolds was determined by immersion of the samples in phosphate-buffered saline (PBS). The results demonstrated that the polarization resistance value and the corrosion rate for different formulations including Mg-6Zn, Mg-6Zn-1GO, and Mg-6Zn-2GO were 41.58, 35.48, and 55.40 Ω.cm² followed by 10.60, 14.83, and 9.06 mm.year^?1, respectively. Based on the results, the Mg-6Zn-2GO formulation presented the best corrosion resistance among the samples were investigated, which confirmed the results of the immersion test. Moreover, the MTT assay proved that the extract of Mg-6Zn-2GO scaffolds was not cytotoxic in contact with L-929 cells which validated the studied scaffolds for bone tissue applications.     

Sodium alginate/magnesium oxide nanocomposite scaffolds for bone tissue engineering

A simple 2‐step method, consisting of film casting and polyvinyl alcohol leaching, is proposed to prepare magnesium oxide (MO) nanoparticle‐reinforced sodium alginate scaffolds with right properties for bone tissue engineering. The cytocompatibility of the as‐prepared scaffolds was also evaluated using the 3‐(4,5‐dimethylthiazol‐2‐yl)‐2,5‐diphenyltetrazolium‐bromide yellow tetrazole assay test, wherein chondrocyte cells had been considered as target cells. According to the results, the ensuing sodium alginate nanocomposites, containing 4‐wt% MO nanoparticles, demonstrated the highest physical and mechanical properties after leaching step. The Young modulus of sodium alginate/4‐wt% MO was improved about 44%, in comparison with that of the pure alginate sample. Furthermore, incorporating MO nanoparticles up to 4 wt% controlled the liquid uptake capacity of scaffolds vis‐à‐vis the resultant pure sodium alginate sample. Moreover, with increasing the nanoparticle content, the antibacterial properties of scaffolds enhanced, but their degradation rates under in vitro conditions tapered off. With the introduction of 3‐ and 4‐wt% MO, the average diameter of the bacterial zone of the scaffold samples reduced to less than 10 mm², suggesting an insensitive antimicrobial performance, compared with the pure sodium alginate and the samples with 1‐ and 2‐wt% MO content, which exhibit antimicrobial sensitivity. 3‐(4,5‐Dimethylthiazol‐2‐yl)‐2,5‐diphenyltetrazolium‐bromide assay test also revealed the cultivated chondrocyte cells on the 4‐wt% MO nanoparticle‐reinforced scaffold possessed better interaction as well as appropriate cell attachment and proliferation than the pristine sodium alginate sample.     

Nanofibrous poly(lactic acid)/hydroxyapatite composite scaffolds for guided tissue regeneration

The production of nanofibrous PLA/HA composite scaffolds is described. The morphological, mechanical, surface, and thermal properties of the composites were extensively investigated. The results show that the mixture of PLA and HA formed smooth nanofibers without lumps. The incorporation of HA increased the mechanical strength of the nanofibers and changed the morphology, increasing the mean fiber diameter and pore size. Surface and internal properties confirmed that HA was homogeneously distributed inside the nanofibers and oriented towards their surface. The nanofiber composites allowed the adhesion and proliferation of pre-osteoblasts for up to 3 weeks.     

Viscoelasticity,mechanical properties,and in vivo biocompatibility of injectable polyvinyl alcohol/bioactive glass composite hydrogels as potential bone tissue scaffolds

Abstract

An injectable composite hydrogel composed of polyvinyl alcohol (PVA) and bioactive glass (BG) particles were synthesized by a physical crosslinking approach. The morphology, mechanical properties, and viscoelasticity of the PVA/BG composite hydrogel were characterized. Scanning electronic microscopy (SEM) showed uniform and homogeneous distribution of BG particles throughout the composite hydrogel. The incorporation of 2.5?wt% of BG particles in the composite hydrogel formulations, enhanced the static compressive strength and static elastic modulus by 325% and 150%, respectively. The storage molds (G′) was greater than the loss modules (G′′) at all the frequency range studied, which revealed a self-standing elastic composite hydrogel with a smooth injectability. The PVA/BG composite hydrogel was also implanted subcutaneously in the dorsal region of adult male rats. After 4?weeks of implantation, no inflammatory cells were seen within and around the implant, which indicated that the composite hydrogel was biocompatible. The properties of the synthesized injectable PVA/BG composite hydrogel demonstrate its capability toward bone regeneration.     

Chemotactic ion-releasing hydrogel for synergistic antibacterial and bone regeneration

The repair of critical-sized bone defects remains a major concern in clinical care. Herein, a multifunctional hydrogel is rationally designed to synergistically photothermal antibacterial and potentiate bone regeneration via adding magnesium oxide nanoparticle and black phosphorus nanosheet (BPNS) into poly(vinyl alcohol)/chitosan hydrogel (PVA/CS-MgO-BPNS). Under the dual effect of near-infrared irradiation and CS intrinsic antibacterial properties, PVA/CS-MgO-BPNS hydrogel can kill more than 99.9% of Staphylococcus aureus and Escherichia coli. The released Mg ions stimulate the migration of mesenchymal stem cells (MSCs) to hydrogels and synergize with released phosphate to promote osteogenic differentiation. The PVA/CS-MgO-BPNS hydrogel also promotes calcium phosphate particle formation and therefore improves the biomineralization ability. Furthermore, the potential molecular mechanism of PVA/CS-MgO-BPNS to regulate MSCs migration and differentiation is through activating phosphoinositide 3-kinase (PI3K)-Akt signaling pathways through RNA-seq analysis. Finally, the PVA/CS-MgO-BPNS hydrogel could significantly promote endogenous bone tissue regeneration in the rat skull defect model. Taken together, this easy fabricated multifunctional hydrogel has good clinical applicability for the repair of large-scale bone defects.     

Development and evaluation of osteogenic PMMA bone cement composite incorporating curcumin for bone repairing

Acrylic resin (PMMA - polymethylmethacrylate) is a material widely used in orthopedics to fill gaps or cavities in the bone marrow, bone defects, and implants fixation. However, even if it possesses high mechanical strength and is considered bioinert, its use has various limitations related to the lack of positive additional bioactive effects, such as osteogenesis stimulation. This work reports a preliminary assessment of the effects of curcumin incorporated in PMMA bone cements at different concentrations (4, 5, 7.5, and 10 wt%), and in particular, its osteoinductivity and osteoconductivity in vitro, tested with KUSA-A1 cells. The different samples were characterized using a combination of microscopic and spectroscopic techniques before and after in vitro testing. Results showed that curcumin and PMMA can produce a homogeneous composite material in a wide range of concentrations, up to at least 10 wt%. By increasing the percentage of curcumin both cellular adhesion and bone production are improved, without sacrificing the quality of the bone tissue formed. Addition of curcumin over a threshold of about 5% results in a sudden loss of ultimate strength with an increase of the elongation to failure. Samples containing about 5% of curcumin proved to have good in vitro performances without compromising the mechanical properties. This suggests how curcumin can be considered as a low-cost additive useful not only for its well-known antimicrobial activity but also in the bone regeneration improving the bioactive properties of the PMMA.     

Organometallic manganese complexes as scaffolds for potential molecular wires

This article reviews recent work in the area of organomanganese chemistry designing organometallic based molecular wires for potential applications in molecular electronics utilising the bottom-up approach. The field of molecular electronics has recently received much attention in the pursuit of continued miniaturization of electronics. Molecular wires that can allow a through-bridge exchange of an electron/electron hole between its remote ends/terminal groups are the basic motifs of single electron devices. Our recent work in this field has been the design and development of transition-metal complexes with a special emphasis on the half sandwich dinuclear manganese complexes and the bis dmpe dinuclear Mn(II)/Mn(II). In this review, we would like to highlight the importance of the nature of the transition metal and their significant effect on the redox process, which is of paramount importance for the design of systems that could be ultimately wired into circuits for various applications.     

Modular,synthetic, thiol-ene mediated hydrogel networks as potential scaffolds for 3D cell cultures and tissue regeneration

Natural polymers such as collagen are popular materials for tissue engineering scaffolds due to their innate bioactivity and biocompatibility. Being derived from animal sources, however, means that batch-to-batch consistency is often low and the extraction of collagen is costly. This conundrum facilitates the need for synthetic alternatives as scaffolding materials. In this study, a system of poly(ethylene glycol) (PEG)-based thiol-ene coupled (TEC) hydrogel scaffolds is presented for tissue engineering purposes. The platform includes several necessary features, namely cytocompatibility, high swelling ability, biodegradability, tunable stiffness, and fast, straightforward fabrication. The swelling ability is provided by the hydrophilicity of the ether-links of PEG, which facilitated the formation of high water content hydrogels that match the water content of soft tissues for the proper diffusion of nutrients and waste compounds. TEC ensures fast and facile fabrication, with cross-linking moieties that allow for the biodegradation of the hydrogel network through hydrolytic cleavage. The mechanical properties of the scaffolds are made tunable in the range of storage moduli spanning <1 kPa to >100 kPa. It is also shown that despite the synthetic nature of the hydrogels, human dermal fibroblasts and murine macrophages, Raw 264.7, were able to survive and produce extracellular protein excretions while embedded in the 3D hydrogels.     

Mesoporous porphyrinic metal-organic framework nanoparticles/3D nanofibrous scaffold as a versatile platform for bone tumor therapy

Removal of residual tumor cells and regeneration of large bone defects are urgently required after surgical resection of bone tumors. To address these issues, a bifunctional scaffold with high photothermal effect and osteogenesis was developed for bone tumor therapy. Sintered mesoporous imidazolate framework 8 (ZIF8) nanoparticles with porphyrin-like macrocycles were synthesized by calcination of ZIF8 precursors under an N₂ atmosphere. The prepared ZIF8 possesses good photothermal efficacy and drug loading capability. Phenamil (Phe), an activator of bone morphogenetic protein pathways, was encapsulated into ZIF8 before loading onto gelatin nanofibrous (GF) scaffolds. The loaded Phe exhibited sustained and near-infrared triggered release profiles, which is capable of promoting bone morphogenetic protein 2 induced osteogenic differentiation even under near-infrared treatment. Moreover, our studies revealed that the photothermal effect of GF/ZIF8-Phe scaffolds can kill MG-63 cells in vitro and inhibit subcutaneous tumor growth in vivo. Therefore, the GF/ZIF8-Phe scaffold represents a novel bifunctional platform for tumor therapy and bone regeneration.