Fibroin Composite Research Articles

Research on silk fibroin composite materials for wet environment applications

Silk fibroin material has good mechanical properties and excellent biocompatibility as a natural biomaterial with broad application prospects. However, by applying regenerated silk fibroin in biomaterials with high mechanical strength requirements, such as bone materials, there are problems, such as insufficient mechanical properties and a significant decline in mechanical properties in the wet state. In this report, a silk fibroin composite that maintains high strength in the wet state was prepared by adding nano-SiO2 as a nano-strengthening filler to the silk protein material and employing an epoxy-based silane coupling agent KH560 as an interfacial reinforcing agent. The results showed that the dry compressive strength of the composite material was substantially increased compared with that of the pure silk protein material; the wet compressive strength was significantly increased compared with that of the pure silk fibroin material, and the decrease of the mechanical properties in the wet state was low. The cytotoxicity test results of the composites showed that the materials were not cytotoxic. Rat bone marrow mesenchymal stem cells were cultured on the surface of the composites, and the results indicated that the composites could support the proliferation of bone marrow mesenchymal stem cells. The silk fibroin nanocomposites developed in this work can be applied as bone repair materials.

Patternable and flexible thermoelectric generators based on Bi2Te3/silk fibroin composites for temperature sensing and wearable applications

Thermoelectric (TE) materials are functional materials that can directly convert heat energy into electrical energy, and have a positive effect on alleviating the energy crisis. Inorganic semiconductor materials have attracted extensive attention due to their excellent TE properties, among which Bi2Te3 is the best and most widely used inorganic TE material at room temperature. However, inorganic TE materials are still restricted by unfavorable factors such as scarcity of raw material resources, heavy metal pollution, high price, high rigidity, and complex processing technology, which greatly limit their development process. Therefore, it is urgent to develop flexible TE materials with high performance, non-polluting, non-toxic and low price. The combination of silk fibroin and inorganic TE materials not only retains the properties of TE materials, but also improves their flexibility. Here, the Bi2Te3/SF TE films are successfully fabricated by the evaporation-assisted self-assembly method with Seebeck coefficient of 199 μV⋅K−1 (p-type) and −240 μV⋅K−1 (n-type). In order to verify the feasibility of collecting and utilizing ambient heat energy in real life, the Bi2Te3/SF TE films are cut into various patterns (such as, flower, rabbit, tree, etc) to collect wasted ambient heat. Further, the Bi2Te3/SF thermoelectric generator (TEG) reaches a maximum power of 21 nW at a temperature difference of 43.5 K. A series of self-power temperature sensing demonstrations from single TE film, TEG, to TEG array are proposed to demonstrate their potential applications in the field of self-power sensors. Finally, by inserting Bi2Te3/SF TEG array into a bracelet, a self-powered smart bracelet can be successfully constructed, demonstrating the feasibility of the Bi2Te3/SF TE film in the development of self-powered wearable electronics.

Degradable Elastomeric Silk Biomaterial for Flexible Bioelectronics.

The integration of degradable and biomimetic approaches in material and device development can facilitate the next generation of sustainable (bio) electronics. The use of functional degradable materials presents exciting opportunities for applications in healthcare, soft robotics, energy, and electronics. These include conformability to curved surfaces, matching of stiffness of tissue, and the ability to withstand mechanical deformations. Nature-derived materials such as silk fibroin (SF) provide excellent biocompatibility, resorbability, and tunable properties toward such goals. However, fibroin alone lacks the required mechanical properties and durability for processing in biointegrated electronics and dry conditions. To overcome these limitations, we report on an elastomeric photocurable composite of silk fibroin and poly(dimethylsiloxane) (PDMS). Photofibroin (containing methacryl functionalities) is doped with photoPDMS (methacryloxypropyl-terminated poly(dimethylsiloxane)) to form an elastomeric photofibroin (ePF) composite. The elastomeric silk is photocurable, allowing for microfabrication using UV photolithography. It is suitable for circuits, strain-sensing devices, and biointegrated systems. The ePF exhibits flexibility in both wet and dry conditions, enhanced mechanical strength and long-term durability, and optical transparency. It is stable at high temperatures, compatible with electronic materials, and cytocompatible while being enzymatically degradable. This work therefore highlights a path toward combining natural and synthetic materials to achieve versatile properties and demonstrates the potential of silk fibroin composites in (bio) electronics, encapsulation, and packaging.

Non-Pore Dependent and MMP-9 Responsive Gelatin/Silk Fibroin Composite Microparticles as Universal Delivery Platform for Inhaled Treatment of Lung Cancer.

Developing a drug delivery platform that possesses universal drug loading capacity to meet various requirements of cancer treatment is a challenging yet interesting task. Herein, a self-assembled gelatin/silk fibroin composite (GSC) particle based drug delivery system is developed via microphase separation followed by desolvation process. Thanks to its preassembled microphase stage, this GSC system is suitable for varying types of drugs. The desolvation process fix drugs inside GSC rapidly and densify the GSC structure, thereby achieving efficient drug loading and providing comprehensive protection for loaded drugs. Actually, the size of this brand-new non-pore dependent drug delivery system can be easily adjusted from 100nm to 20µm to fit different scenarios. This work selects GSC with 3µm diameter as the universal inhaled drug delivery platform, which shows an excellent transmucosal penetration and lung retention ability. Additionally, the MMP-9 sensitive degradation property of GSC enhances the targeted efficiency of drugs and reduces side effects. Intestinally, GSC can self-amplify the regulation of innate immunity to reverse the cancerous microenvironment into an antitumor niche, significantly improving the therapeutic effect of drugs. This study of GSC universal drug platform provides a new direction to develop the next-generation of drug delivery system for lung cancer.

Controlled Drug Release and Antibacterial Properties of Levofloxacin-Loaded Silk/Chitosan Green Composite for Wound Dressing

Antibacterial wound dressings have great importance to reduce wound infections caused by bacteria. In this research work, levofloxacin-loaded silk fibroin and chitosan composite scaffolds were synthesized for effective wound dressing applications. Initially, silk was degummed for extraction of silk fibroin, and it was mixed with chitosan at different ratios. The chitosan and silk fibroin were stirred at room temperature to get soluble and clear gel formation. Afterward, citric acid was poured into the solution and stirred for more 30 min to get a homogeneous solution. The chitosan and silk fibroin composite was dried using a vacuum oven at 40 °C for 48 h. Next, the composite was loaded with levofloxacin HCL for 24 h at room temperature. The prepared composite was characterized by scanning electron microscopy (SEM), energy-dispersive X-ray spectroscopy (EDX), and fourier transform infrared (FTIR) spectroscopy. The antibacterial activity of prepared scaffolds was evaluated by the agar disc diffusion method. The results of FTIR spectroscopy proved that citric acid cross-linked the cross-linked silk fibroin with chitosan. SEM and EDX spectroscopy demonstrated successful loading of levofloxacin onto scaffolds. Moreover, the levofloxacin-loaded scaffold samples confirmed sustained drug release and antibacterial properties. All results demonstrated that the composite scaffolds using silk fibroin and chitosan with an appropriate antibacterial agent could effectively inhibit the growth of bacteria.

Three-Dimensional Printing of Customized Scaffolds with Polycaprolactone-Silk Fibroin Composites and Integration of Gingival Tissue-Derived Stem Cells for Personalized Bone Therapy.

Regenerative biomaterials play a crucial role in the success of maxillofacial reconstructive procedures. Yet today, limited options are available when choosing polymeric biomaterials to treat critical size bony defects. Further, there is a requirement for 3D printable regenerative biomaterials to fabricate customized structures confined to the defect site. We present here a 3D printable composite formulation consisting of polycaprolactone (PCL) and silk fibroin microfibers and have established a robust protocol for fabricating customized 3D structures of complex geometry with the composite. The 3D printed composite scaffolds demonstrated higher compressive modulus than 3D printed scaffolds of PCL alone. Furthermore, the compressive modulus of PCL-Antheraea mylitta (AM) silk scaffolds is higher than that of the PCL-Bombyx mori (BM) silk scaffolds at their respective ratios. Compressive modulus of PCL-25AM silk scaffolds (73.4 MPa) is higher than that of PCL-25BM silk scaffolds (65.1 MPa). Compressive modulus of PCL-40AM silk scaffolds (106.1 MPa) is higher than that of PCL-40BM silk scaffolds (77.7 MPa). Moreover, we have isolated, characterized, and integrated human gingival mesenchymal stem cells (hGMSCs), an effective autologous cell source, onto the 3D printed scaffolds to evaluate their bone regeneration potential. The results demonstrated that PCL-silk microfiber composite scaffolds of Antheraea mylitta origin showed much higher bioactivity than the Bombyx mori ones because of arginine-glycine-aspartic acid (RGD) sequences present in the Antheraea mylitta silk fibroin protein favoring cell attachment and proliferation. By day 14, the metabolic activity of hGMSCs was highest in PCL-40AM (4.5 times higher than that at day 1). In addition, to show the translational potential of this work, we have fabricated a patient defect-specific model (mandible) using the CT scan obtained by the micro-CT imaging to understand the printability of the composite for fabricating complex structures to restore maxillofacial bony defects with precision when applied in a clinical scenario.

Silk Fibroin as Adjuvant in the Fabrication of Mechanically Stable Fibrin Biocomposites.

Fibrin is a very attractive material for the development of tissue-engineered scaffolds due to its exceptional bioactivity, versatility in the fabrication, affinity to cell mediators; and the possibility to isolate it from blood plasma, making it autologous. However, fibrin application is greatly limited due to its low mechanical properties, fast degradation, and strong contraction in the presence of cells. In this study, we present a new strategy to overcome these drawbacks by combining it with another natural polymer: silk fibroin. Specifically, we fabricated biocomposites of fibrin (5 mg/mL) and silk fibroin (0.1, 0.5 and 1% w/w) by using a dual injection system, followed by ethanol annealing. The shear elastic modulus increased from 23 ± 5 Pa from fibrin alone, to 67 ± 22 Pa for fibrin/silk fibroin 0.1%, 241 ± 67 Pa for fibrin/silk fibroin 0.5% and 456 ± 32 Pa for fibrin/silk fibroin 1%. After culturing for 27 days with strong contractile cells (primary human arterial smooth muscle cells), fibrin/silk fibroin 0.5% and fibrin/silk fibroin 1% featured minimal cell-mediated contraction (ca. 15 and 5% respectively) in contrast with the large surface loss of the pure fibrin scaffolds (ca. 95%). Additionally, the composites enabled the formation of a proper endothelial cell layer after culturing with human primary endothelial cells under standard culture conditions. Overall, the fibrin/silk fibroin composites, manufactured within this study by a simple and scalable biofabrication approach, offer a promising avenue to boost the applicability of fibrin in tissue engineering.

Silk fibroin-Yb3+/Er3+:YAG composite films and their thermometric applications based on up-conversion luminescence

Silk Fibroin (SF) is a well-known protein, and has been employed in the development of diverse advanced materials for applications on medical and biological field, drug delivery systems and, also, in the electronic and photonic area. In addition, the up-conversion emission process could be proposed in fibroin-based materials and becomes a challenge for the photonic field based on biocompatible devices obtained from fibroin. To avoid the unwanted upconversion (UC) quenching process, herein, lanthanide ions were used as sensitizer and emitters ions, and them was incorporated into an inorganic particle obtained from spray pyrolysis synthesis. Specifically, we have obtained Yb3+ and Er3+ ions doped YAG (Yttrium Aluminum Garnet, Y3Al5O12) spherical submicrometric particles, without spurious phases. All samples were characterized by X-Ray Diffraction, Scanning Electron Microscopy, and photoluminescence. The spectroscopic studies showed an intense UC emission from Er3+ ions. Furthermore, looking for the development of a new fibroin composite which should be used as sensor or smart ink, we inserted the YAG particles in SF, and a new flexible composite film with controlled amounts of particles and tuned transmittance behavior was obtained. Finally, it was confirmed the characteristic luminescent behavior (as UC emission) of the particles in the composite films. As the emitters levels (2H11/2 and 4S3/2) from Er3+ ions are thermally coupled, all materials (particles and films) were exploited as luminescent thermometer, and data confirmed the thermal sensibility comparable to other systems based on Yb3+/Er3+ ions.

A Review on the Application of Chitosan-Silk Fibroin Composites in the Biomedical Field

A Review on the Application of Chitosan-Silk Fibroin Composites in the Biomedical Field

Tuning surface texture of thermoplastic polyurethane/silk fibroin composites by phase separation method

Silk fibroin powder made from waste silk has gained considerable attention because of its outstanding physicochemical properties. In this study, thermoplastic polyurethane/silk fibroin (TPU/SF) composites were successfully prepared by combining different phase separation methods. The transformation of porous to compact films prepared by vapor/nonsolvent-induced phase separation (V–NIPS) as well as solvent evaporation/nonsolvent-induced phase separation (E-NIPS) using binary solvents. The effect of the film-formation method on the morphology, structure, and performance of the composite films were investigated. Compared with the surface of E-NIPS composite films, that of V–NIPS composite films had many micron-sized craters. Furthermore, SEM and porosity analysis results further supported the proposed film-formation mechanism. Upon the addition of 30 wt% SF, V–NIPS5 showed good mechanical properties with a stress of 16.2 MPa, strain of 1241.2%, and toughness of 118.2 MJ/m3. E-NIPS25 also showed good mechanical properties with a stress of 25.5 MPa, strain of 1089.7%, and toughness of 144.7 MJ/m3. The strengthened interface interaction between SF and TPU was observed through the analysis of the fractured surfaces. Furthermore, the V–NIPS composite films showed good hydrophilicity and biocompatibility. This approach of constructing unique surface structures has potential applications in functional fields, such as development of bionic materials and biological cell adhesion materials.

Immune Response to Silk Sericin-Fibroin Composites: Potential Immunogenic Elements and Alternatives for Immunomodulation.

The unique properties of silk proteins (SPs), particularly silk sericin (SS) and silk fibroin (SF), have attracted attention in the design of scaffolds for tissue engineering over the past decades. Since SF has good mechanical properties, while SS displays bioactivity, scaffolds combining both proteins should exhibit complementary properties enhancing the potential of these materials. Unfortunately, SS-SF composites can generate chronic immune responses and their immunogenic element is not completely clear. The potential of SS-SF composites in tissue engineering, elements which may contribute to their immunogenicity, and alternatives for their preparation and design, to modulate the immune response and take advantage of their useful properties, are discussed in this review. It is known that SS can enhance β-sheet formation in SF, which may act as hydrophobic regions with a strong affinity for adsorption proteins inducing the chronic recruitment of inflammatory cells. Therefore, tailoring the exposure of hydrophobic regions at the scaffold surface should represent a viable strategy to modulate the immune response. This can be achieved by coating SS-SF composites with SS or other hydrophilic polymers, to take advantage of their antibiofouling properties. Research is still needed to realize the full potential of these composites for tissue engineering.

Osteogenic potential and properties of injectable silk fibroin/tetracalcium phosphate/monetite composite powder biocement systems.

The powdered cement tetracalcium phosphate/monetite/silk fibroin composite (CFIB) was prepared by simple mechanical milling of tetracalcium phosphate/monetite powder mixture with fibrous soluble silk fibroin (SF). The powder composite cement mixtures contained 5 and 10wt % of SF and 2% NaH2 PO4 solution with 0.1% genipin was used as a liquid component. The setting time of CFIB cement increased with addition of SF from 5 to 25 min in fully injectable cement with 10wt % of SF. The compressive strength of hardened composites was reduced to 14 MPa which is close to strength of cancellous bone. The 8% of SF from origin amount in CFIB composites was only desorbed from cements after 7 days soaking in simulated body fluid (SBF). It was found almost full transformation of calcium phosphate components in composite to rod-like nanohydroxyapatite after hardening of CFIB cements in SBF. The SF in hardened cements was present in fine globular form after dissolution, actively affected the fluidity of pastes, morphology of hydroxyapatite particles, and microstructure. The excellent cell proliferation and a high over expression of osteogenic gene markers in MSCs were confirmed after the long-time cultivation in CFIB10 cement extract. Injectable CFIB10 cements have appropriate properties for utilization in bone defect treatments with possible positive effect on healing process.

Tendon-bioinspired wavy nanofibrous scaffolds provide tunable anisotropy and promote tenogenesis for tendon tissue engineering

The development of tendon-biomimetic nanofibrous scaffolds with mesenchymal stem cells may represent a promising strategy to improve the unsatisfactory outcomes of traditional treatments in tendon repair. In the present study, the nanofibrous scaffolds comprised of poly(p-dioxanone) (PPDO) and silk fibroin (SF) composites were fabricated by using electrospinning technique and subsequent thermal ethanol treatment. The PPDO/SF composite scaffolds presented parallel fiber arrangement with crimped features and nonlinear mechanical properties, which mimic the structure-function relationship of native tendon tissue mechanics. We demonstrated that the fiber crimp degree and mechanical properties of as-prepared PPDO/SF wavy nanofibrous scaffolds (WNSs) could be tunable by adjusting the mass ratio of PPDO/SF. The biological tests revealed that the addition of SF obviously promoted the cell adhesion, proliferation, and phenotypic maintenance of human tenocytes on the WNSs. A preliminary study on the subcutaneous implantation showed that the PPDO/SF WNSs notably decreased the inflammatory response compared with pure PPDO WNSs. More importantly, a combination of growth factor induction and mechanical stimulation was found to notably enhance the tenogenic differentiation of human adipose derived mesenchymal stem cells on the PPDO/SF WNSs by upregulating the expressions of tendon-associated protein and gene markers. Overall, this study demonstrated that our PPDO/SF WNSs could provide a beneficial microenvironment for various cell activities, making them an attractive candidate for tendon tissue engineering research.

Rheological characterization, compression, and injection molding of hydroxyapatite-silk fibroin composites

Traditional bone fixation devices made from inert metal alloys provide structural strength for bone repair but are limited in their ability to actively promote bone healing. Although several naturally derived bioactive materials have been developed to promote ossification in bone defects, it is difficult to translate small-scale benchtop fabrication of these materials to high-output manufacturing. Standard industrial molding processes, such as injection and compression molding, have typically been limited to use with synthetic polymers since most biopolymers cannot withstand the harsh processing conditions involved in these techniques. Here we demonstrate injection and compression molding of a bioceramic composite comprised of hydroxyapatite (HA) and silk fibroin (SF) from Bombyx mori silkworm cocoons. Both the molding behavior of the HA-SF slurry and final scaffold mechanics can be controlled by modulating SF protein molecular weight, SF content, and powder-to-liquid ratio. HA-SF composites with up to 20 weight percent SF were successfully molded into stable three-dimensional structures using high pressure molding techniques. The unique durability of silk fibroin enables application of common molding techniques to fabricate composite silk-ceramic scaffolds. This work demonstrates the potential to move bone tissue engineering one step closer to large-scale manufacturing of natural protein-based resorbable bone grafts and fixation devices.

Preparation of Hydroxyapatite/Silk Fibroin Composite and Its Adoption in Posterolateral Spinal Fusion of Rats

Hydroxyapatite/silk fibroin (HAp/SF) composite was prepared and applied to the posterolateral spinal fusion model in rats to observe the effect of bone fusion. Method: Calcium chloride, diammonium phosphate, SF, and polyvinyl alcohol were used as raw materials, HAp/SF composites were prepared by chemical precipitation. The microstructure of the composite, crystal phase composition, and chemical structure were analyzed by the scanning electron microscope (SEM) and X-ray diffraction (XRD), and fourier transform infrared spectrometer (FTIR Spectrometer). Through the cultivation of osteoblasts MC3T3-E1 in vitro, the adhesion and proliferation (A&P) of cells on the face of materials were investigated. Thereby, the biocompatibility of the material was characterized. HAp/SF material was applied to the rat posterolateral spinal fusion model. The osteogenesis and spinal fusion were evaluated by the imaging observation, histological observation and manual palpation. The results showed that the rod-shaped HAp with uniform size and high purity was obtained, with a diameter of 20∼40 nm and a length of 200∼500 nm, similar to the apatite crystal in natural bone tissue (BT). In composite materials, a spatial network structure was formed by the interweaving of the SF fibers, and HAp was deposited on the face of the SF or in the middle of its network structure. In the obtained HAp/SF materials, the calcium ions of HAp and the carbonyl groups of SF were used to form thermally stable complexes through strong chemical bonds. Besides, SF was a template for the directional induction of HAp crystal growth, and the growth of HAp crystal along the C axis was regulated by SF. The growth direction was parallel to the long axis of SF fibers, and was consistent with the structure of apatite crystals deposited on the face of collagen fibers in natural BT. The results of cell culture in vitro showed that: after comparison with the control group (CG) with pure Hap, the adhesion ability of cells to HAp/SF material was significantly improved. The proliferation capacity of bone artificial bone (BAM) material and HAp/SF material was also significantly improved. The nuclear and skeletal staining results of MC3T3-E1 cells on the face of three groups of materials (HAp, BAM and HAp/SF) were combined, and the results also indicated that BAM and HAp/SF materials had good ability to promote cell A&P. The results of posterolateral spinal fusion in rats showed that HAp/SF materials group palpated the posterolateral spine for fusion. The formation of new BT on the posterolateral side of the spine was revealed by the Micro-computed tomography (Micro-CT) examination. In conclusion, HAp/SF composite had good osteoblastic compatibility and can achieve good spinal fusion effect.

Progressive trends in heavy metal ions and dyes adsorption using silk fibroin composites.

Thriving industrialization for human lifestyle headway has seeded the roots of water intoxication with harmful and hazardous toxic metal ions and dyes, which may ingress into food chains and become homicidal or mutation causing for creatures. The degummed functionalized silk fibroin composites with different biomaterials and synthetic materials are able to show adsorption efficiencies equivalent to 52.5%, 90%, 81.1%, 93.75%, 84.2%, and 98.9% for chromium, copper, cadmium, lead, thorium, and uranium ions, respectively, and adsorption capacity of 88.5mg/g, 74.63mg/g, 76.34mg/g, and 72mg/L for acid yellow 11, naphthol orange, direct orange S, and methylene blue, respectively, which make them desirable solution for water toxicants removal. This review is intended to describe the ability of silk fibroins to adsorb and abolish toxic heavy metal ions and dyes from water reservoirs, thus, providing a way to step toward water sanitation and wholesome living. Graphical abstract.

Laser patterning and induced reduction of graphene oxide functionalized silk fibroin

This paper presents a one-step method for patterning and reducing graphene oxide functionalized in silk fibroin using femtosecond laser induced forward transfer (LIFT). Such approach renders fibroin, a natural biopolymer with excellent biocompatibility, chemical stability, and mechanical properties, improved electrical conductivity in a controlled and localized way. Composite films based on silk fibroin and graphene oxide/reduced graphene oxide were fabricated by spin coating at room temperature. The films composition was characterized by micro-Raman spectroscopy demonstrating the presence of graphene oxide in the silk fibroin matrix. The influence of pulse energy on the fs laser transfer process was investigated, yielding a threshold energy of 24.0 nJ. Additionally, the laser-induced reduction of graphene oxide attained by LIFT was determined by Raman spectroscopy and further confirmed by an increase in the electrical conductivity. The approach presented here proved to be an efficient route to simultaneously produce micrometric patterns of graphene oxide/silk fibroin composite (with line widths on the order of 1 μm), and reduction of graphene oxide, opening new opportunities for the development of green composites for electronics devices, including for instance microfluidic sensors, capacitors and LEDs.

Characterization of Physical Properties and Tensile Strength of Chitosan/Fibroin Composite via Freeze Drying Method

Chitosan and silk fibroin composite are natural biopolymers widely used in biomedical engineering applications. This work studied the properties of a chitosan and silk fibroin composite were prepared by freeze drying method. The characterizations were operated by fourier-transform infrared spectroscopy, scanning electron microscopy, and x-ray diffraction. In addition, the tensile strength was obtained for various compositions. The results showed that the freeze-dried composite was of high porosity with 3D interconnected pores that are suitable for tissue engineering. In addition, both Fourier-transform infrared spectroscopy and x-ray diffraction indicated that the composite materials were water soluble.

Thermally triggered injectable chitosan/silk fibroin/bioactive glass nanoparticle hydrogels for in-situ bone formation in rat calvarial bone defects

Copper-containing bioactive glass nanoparticles (Cu-BG NPs) with designed compositions and sizes were synthesized and incorporated into chitosan (CH)/silk fibroin (SF)/glycerophosphate (GP) composites to prepare injectable hydrogels for cell-free bone repair. The resulting Cu-BG/CH/SF/GP gels were found to exhibit well-defined injectability and to undergo rapid gelation at physiological temperature and pH. They were highly porous and showed the ability to administer Si, Ca and Cu ions at their respective safe doses in a sustained and controlled manner. In vitro studies revealed that the gels supported the growth of seeded MC3T3-E1 and human umbilical vein endothelial cells, and effectively induced them toward osteogenesis and angiogenesis, respectively. In vivo bone repair based on a critical-size rat calvarial bone defect model demonstrated that the optimal Cu-BG/CH/SF/GP gel was able to fully restore the bone defect with formation of vascularized bone tissue and mineralized collagen deposition during a treatment period of 8 weeks without utilization of any cells and/or growth factors. The results suggest that the presently developed Cu-BG/CH/SF/GP composite hydrogels have great potential and translation ability for bone regeneration owing to their thermo-sensitive properties, cell-free bioactivity, and cost-effectiveness. Statement of SignificanceHydrogels loaded with cells and/or growth factors exhibit potential in bone repair. However, they have been facing obstacles related to the clinic translation. Here, a novel type of hydrogel system consisting of copper-containing bioactive glass nanoparticles and chitosan/silk fibroin composite was developed. These gels showed injectability and thermally triggered in situ gelation properties and were able to administer the release of ions at safe but effective doses in a controlled manner while inducing the seeded cells toward osteogenesis and angiogenesis. The optimal gel showed the ability to fully repair critical-size rat calvarial bone defects without involving time consuming cell processing and/or the use of expensive growth factors, confirming that this novel hydrogel system has great potential for translation to the clinic.

Electrically Conductive Polyaniline/Silk Fibroin Composite for Ammonia and Acetaldehyde Sensing

In this study, camphorsulphonic acid-doped conducting polyaniline/silk fibroin (Pani/SF) composites were prepared by in-situ polymerisation. The Pani/SF composite fibres were characterised by using Attenuated total reflectance-Fourier transform infrared (ATR-FTIR) spectroscopy, thermogravimetric analysis, scanning electron microscopy and digital photographs. Results indicated that the Pani was successfully coated on silk fibroin. The electrical properties of Pani/SF composite fibres were influenced by the extent of loading of aniline monomers. The as-prepared material was studied as a sensing material by observing the change in their electrical conductivity on exposure to ammonia and acetaldehyde, followed by ambient air at room temperature. It was found that the composite fibres showed good reversibility and conductivity decreased on exposure to higher concentration of ammonia and acetaldehyde vapours at room temperature.