A high molecular weight silk fibroin scaffold that resists degradation and promotes cell proliferation

The regulation of the biodegradation rate of 3D-regenerated silk fibroin scaffolds and the avoidance of premature collapse are important concerns for their effective applications in tissue engineering. In this study, bromelain, which is specific to sericin, was used to remove sericin from silk, and high molecular weight silk fibroin was obtained after the fibroin fibers were dissolved. Afterwards, a 3D scaffold was prepared via freeze-drying. The Sodium dodecyl sulfate–polyacrylamide gel electrophoresis results showed that the average molecular weight of the regenerated silk fibroin prepared by using the bromelain-degumming method was approximately 142.2 kDa, which was significantly higher than that of the control groups prepared by using the urea- and Na₂CO₃-degumming methods. The results of enzyme degradation in vitro showed that the biodegradation rate and internal three-dimensional structure collapse of the bromelain-degumming fibroin scaffolds were significantly slower than those of the two control scaffolds. The proliferation activity of human umbilical vein vascular endothelial cells inoculated in bromelain-degumming fibroin scaffolds was significantly higher than that of the control scaffolds. This study provides a novel preparation method for 3D-regenerated silk fibroin scaffolds that can effectively resist biodegradation, continuously guide cell growth, have good biocompatibility, and have the potential to be used for the regeneration of various connective tissues.     

New silk protein: modification of silk protein by gene engineering for production of biomaterials

The interest in silk fibroin morphology and structure have increased due to its attractiveness for bio-related applications. Silk fibers have been used as sutures for a long time in the surgical field, due to the biocompatibility of silk fibroin fibers with human living tissue. In addition, it has been demonstrated that silk can be used as a substrate for enzyme immobilization in biosensors. A more complete understanding of silk structure would provide the possibility to further exploit silk fibroin for a wide range of new uses, such as the production of oxygen-permeable membranes and biocompatible materials. Silk fibroin-based membranes could be utilized as soft tissue compatible polymers. Baculovirus-mediated transgenesis of the silkworm allows specific alterations in a target sequence. Homologous recombination of a foreign gene downstream from a powerful promoter, such as the fibroin promoter, would allow the constitutive production of a useful protein in the silkworm and the modification of the character of silk protein. A chimeric protein consisted of fibroin and green fluorescent protein was expressed under the control of fibroin in the posterior silk gland and the gene product was spun into the cocoon layer. This technique, gene targeting, will lead to the modification and enhancement of physicochemical properties of silk protein.     

A comparison of Thai silk fibroin-based and chitosan-based materials on in vitro biocompatibility for bone substitutes

The novel hybrid scaffolds fabricated from silk fibroin, gelatin, low deacetylation degree chitosan and hydroxyapatite were investigated for their in vitro biocompatibility and osteoconductivity to mouse pre-osteoblast cell line (MC3T3-E1) and rat bone marrow-derived stem cells (MSC). We found that gelatin-conjugated silk fibroin films and scaffolds dominantly promoted cell adhesion and proliferation. Film and scaffold prepared from gelatin-conjugated silk fibroin with hydroxyapatite grown crystals effectively enhanced osteogenic differentiation of both cell types, as evaluated by alkaline phosphatase activity and calcium content. However the blend of hydroxyapatite/low deacetylation degree chitosan hybrid materials did not support cell growth. Furthermore, the blended hydroxyapatite in the bulk scaffold was found to be less effective for osteogenic differentiation than the scaffold with hydroxyapatite grown crystals. The comparative study between MC3T3-E1 and MSC showed that both cell types had similar trend of proliferation and osteogenic differentiation on the same material. Also, higher proliferative rate of MC3T3-E1 than MSC was observed.     

New silk protein: modification of silk protein by gene engineering for production of biomaterials.

The interest in silk fibroin morphology and structure have increased due to its attractiveness for bio-related applications. Silk fibers have been used as sutures for a long time in the surgical field, due to the biocompatibility of silk fibroin fibers with human living tissue. In addition, it has been demonstrated that silk can be used as a substrate for enzyme immobilization in biosensors. A more complete understanding of silk structure would provide the possibility to further exploit silk fibroin for a wide range of new uses, such as the production of oxygen-permeable membranes and biocompatible materials. Silk fibroin-based membranes could be utilized as soft tissue compatible polymers. Baculovirus-mediated transgenesis of the silkworm allows specific alterations in a target sequence. Homologous recombination of a foreign gene downstream from a powerful promoter, such as the fibroin promoter, would allow the constitutive production of a useful protein in the silkworm and the modification of the character of silk protein. A chimeric protein consisted of fibroin and green fluorescent protein was expressed under the control of fibroin in the posterior silk gland and the gene product was spun into the cocoon layer. This technique, gene targeting, will lead to the modification and enhancement of physicochemical properties of silk protein.     

Surface Modification and Characterisation of Silk Fibroin Fabric Produced by the Layer-by-Layer Self-Assembly of Multilayer Alginate/Regenerated Silk Fibroin

Silk-based medical products have a long history of use as a material for surgical sutures because of their desirable mechanical properties. However, silk fibroin fabric has been reported to be haemolytic when in direct contact with blood. The layer-by-layer self-assembly technique provides a method for surface modification to improve the biocompatibility of silk fibroin fabrics. Regenerated silk fibroin and alginate, which have excellent biocompatibility and low immunogenicity, are outstanding candidates for polyelectrolyte deposition. In this study, silk fabric was degummed and positively charged to create a silk fibroin fabric that could undergo self-assembly. The multilayer self-assembly of the silk fibroin fabric was achieved by alternating the polyelectrolyte deposition of a negatively charged alginate solution (pH = 8) and a positively charged regenerated silk fibroin solution (pH = 2). Finally, the negatively charged regenerated silk fibroin solution (pH = 8) was used to assemble the outermost layer of the fabric so that the surface would be negatively charged. A stable structural transition was induced using 75% ethanol. The thickness and morphology were characterised using atomic force microscopy. The properties of the self-assembled silk fibroin fabric, such as the bursting strength, thermal stability and flushing stability, indicated that the fabric was stable. In addition, the cytocompatibility and haemocompatibility of the self-assembled silk fibroin fabrics were evaluated. The results indicated that the biocompatibility of the self-assembled multilayers was acceptable and that it improved markedly. In particular, after the self-assembly, the fabric was able to prevent platelet adhesion. Furthermore, other non-haemolytic biomaterials can be created through self-assembly of more than 1.5 bilayers, and we propose that self-assembled silk fibroin fabric may be an attractive candidate for anticoagulation applications and for promoting endothelial cell adhesion for vascular prostheses.     

Degradation mechanism and control of silk fibroin

Controlling the degradation process of silk is an important and interesting subject in the field of biomaterials. In the present study, silk fibroin films with different secondary conformations and nanostructures were used to study degradation behavior in buffered protease XIV solution. Different from previous studies, silk fibroin films with highest β-sheet content achieved the highest degradation rate in our research. A new degradation mechanism revealed that degradation behavior of silk fibroin was related to not only crystal content but also hydrophilic interaction and then crystal-noncrystal alternate nanostructures. First, hydrophilic blocks of silk fibroin were degraded. Then, hydrophobic crystal blocks that were formerly surrounded and immobilized by hydrophilic blocks became free particles and moved into solution. Therefore, on the basis of the mechanism, which enables the process to be more controllable and flexible, controlling the degradation behavior of silk fibroin without affecting other performances such as its mechanical or hydrophilic properties becomes feasible, and this would greatly expand the applications of silk as a biomedical material.     

Materials fabrication from Bombyx mori silk fibroin

Silk fibroin, derived from Bombyx mori cocoons, is a widely used and studied protein polymer for biomaterial applications. Silk fibroin has remarkable mechanical properties when formed into different materials, demonstrates biocompatibility, has controllable degradation rates from hours to years and can be chemically modified to alter surface properties or to immobilize growth factors. A variety of aqueous or organic solvent-processing methods can be used to generate silk biomaterials for a range of applications. In this protocol, we include methods to extract silk from B. mori cocoons to fabricate hydrogels, tubes, sponges, composites, fibers, microspheres and thin films. These materials can be used directly as biomaterials for implants, as scaffolding in tissue engineering and in vitro disease models, as well as for drug delivery.     

Unusual protein behavior illustrated with silk fibroin

We investigated the interaction between phospholipid membranes and silk fibroin recovered from the posterior silk gland of the silkworm. Observations of the planar lipid bilayer membrane and electron microscopic observations of liposomes showed that newly constructed silk fibroin, existing in the form of filaments, quickly penetrates phospholipid membranes without bursting them.     

Flexibility regeneration of silk fibroin in vitro

Although natural silk fibers have excellent strength and flexibility, the regenerated silk materials generally become brittle in the dry state. How to reconstruct the flexibility for silk fibroin has bewildered scientists for many years. In the present study, the flexible regenerated silk fibroin films were achieved by simulating the natural forming and spinning process. Silk fibroin films composed of silk I structure were first prepared by slow drying process. Then, the silk fibroin films were stretched in the wet state, following the structural transition from silk I to silk II. The difference between the flexible film and different brittle regenerated films was investigated to reveal the critical factors in regulating the flexibility of regenerated silk materials. Compared with the methanol-treated silk films, although having similar silk II structure and water content, the flexible silk films contained more bound water rather than free water, implying the great influence of bound water on the flexibility. Then, further studies revealed that the distribution of bound water was also a critical factor in improving silk flexibility in the dry state, which could be regulated by the nanoassembly of silk fibroin. Importantly, the results further elucidate the relation between mechanical properties and silk fibroin structures, pointing to a new mode of generating new types of silk materials with enhanced mechanical properties in the dry state, which would facilitate the fabrication and application of regenerated silk fibroin materials in different fields.     

Chitosan-functionalized silk fibroin 3D scaffold for keratocyte culture

The goal of this study was to evaluate the potential suitability of an artificial membrane composed of silk fibroin (SF) functionalized by different ratios of chitosan (CS) as a substrate for the stroma of the cornea. Keratocytes were cultured on translucent membranes made of SF and CS with different ratios. The biophysical properties of the silk fibroin and chitosan (SF/CS) membrane were examined. The SF/CS showed tensile strengths that increased as the CS concentration increased, but the physical and mechanical properties of chitosan-functionalized silk fibroin scaffolds weakened significantly compared with those of native corneas. The resulting cell scaffolds were evaluated using western blot in addition to light and electron microscopy. The cell attachment and proliferation on the scaffold were similar to those on a plastic plate. Keratocytes cultured in serum on SF/CS exhibited stellate morphology along with a marked increase in the expression of keratocan compared with identical cultures on tissue culture plastics. The biocompatibility was tested by transplanting the acellular membrane into rabbit corneal stromal pockets. There was no inflammatory complication detected at any time point on the macroscopic level. Taken together, these results indicate that SF/CS holds promise as a substrate for corneal reconstruction.     

Hydrothermal production and characterization of protein and amino acids from silk waste

Non-catalytic hydrothermal decomposition of sericin and fibroin from silk waste into useful protein and amino acids was examined in a closed batch reactor at various temperatures, reaction times, and silk to water ratios to examine their effects on protein and amino acid yields. For the decomposition of sericin, the highest protein yield was found to be 0.466 mg protein/mg raw silk, obtained after 10 min hydrothermal reaction of silk waste at 1:100 silk to water ratio at 120 degrees C. The highest amino acid yield was found to be 0.203 mg amino acids/mg raw silk, obtained after 60 min of hydrothermal reaction of silk waste at 1:20 silk to water ratio at 160 degrees C. For the hydrothermal decomposition of fibroin, the highest protein yield was 0.455 mg protein/mg silk fibroin (1:100, 220 degrees C, 10 min) and that of amino acids was 0.755 mg amino acids/mg silk fibroin (1:50, 220 degrees C, 60 min). The rate of silk fibroin decomposition could be described by surface reaction kinetics. The soluble reaction products were freeze-dried to obtain sericin and fibroin particles, whose conformation and crystal structure of the particles were shown to differ from the original silk materials, particularly in the case of fibroin, in which the change from beta-sheet conformation to alpha-helix/random coil was observed.     

Proteomic analysis of 3T3-L1 preadipocytes having a higher cell proliferation rate after treatment with low-molecular-weight silk fibroin peptides

Objectives: Previous studies have reported that fibroin peptides can be used in a new strategy for development of anti‐diabetic peptide drugs. In this study, we separated silk fibroin hydrolysates (SFH) containing silk fibroin peptides into four components according to their molecular weight and tested the effects of these together with three synthetic silk fibroin hexapeptides GAGAGS, GAGAGY, GAGAGA on cell proliferation of 3T3‐L1 preadipocytes. The aim of this study was to investigate protein expression profiles of 3T3‐L1 preadipocytes and those treated with SFH component Fraction I and the synthetic silk fibroin hexapeptide GAGAGS to be able to elucidate difference in protein expression between the 3T3‐L1 preadipocytes and those treated with fibroin peptides Fraction I and GAGAGS. Materials and methods: SFH was separated by dialysis. MTT assays were performed to test effects of SFH components and synthetic silk fibroin hexapeptides on 3T3‐L1 preadipocyte proliferation. We generated proteome maps using two‐dimensional gel electrophoresis and analysed them by peptide mass fingerprinting. Results: GAGAGS and peptide mixtures, Fraction I and Fraction II, had significant effect in promoting 3T3‐L1 preadipocyte proliferation. In the proteomic analysis, 73 protein spots were successfully identified, including 15 which were differentially expressed. Conclusions: Our results show that some silk fibroin peptides of low molecular weight SFH and hexapeptide GAGAGS affected 3T3‐L1 preadipocyte proliferation.     

Freeze-gelled silk fibroin protein scaffolds for potential applications in soft tissue engineering

Recently tissue engineering has escalated much interest in biomedical and biotechnological applications. In this regard, exploration of new and suitable biomaterials is needed. Silk fibroin protein is used as one of the most preferable biomaterials for fabrication of scaffolds and several new techniques are being adopted to fabricate silk scaffolds with greater ease, efficiency and perfection. In this study, a freeze gelation technique is used for fabrication of silk fibroin protein 3D scaffolds, which is both time and energy efficient as compared to the conventional freeze drying technique. The fabricated silk fibroin freeze-gelled scaffolds are evaluated micro structurally for morphology with scanning electron microscopy which reveals relatively homogeneous pore structure and good interconnectivity. The pore sizes and porosity of these scaffolds ranges between 60-110 μm and 90-95%, respectively. Mechanical test shows that the compressive strength of the scaffolds is in the range of 20-40 kPa. The applicability to cell culture of the freeze gelled scaffolds has been examined with human keratinocytes HaCat cells which show the good cell viability and proliferation of cells after 5 days of culture suggesting the cytocompatibility. The freeze-gelled 3D scaffolds show comparable results with the conventionally prepared freeze dried 3D scaffolds. Thus, this technique may be used as an alternative method for 3D scaffolds preparation and may also be utilized for tissue engineering applications.     

丝素蛋白在电纺丝法构建组织工程支架中的应用进展

丝素蛋白是天然高分子纤维蛋白,具有良好的物理和机械力学性能及生物相容性,因而在组织工程领域有着广阔的应用前景。文中对丝素蛋白的化学组成、分子结构特点、提取方法以及利用静电纺丝技术在组织工程化支架构建中的应用作了概述。总结了丝素蛋白在用于组织工程材料上的性能和优势以及在人工血管、皮肤、骨组织等工程化支架方面的应用情况,探讨了丝素蛋白支架对细胞在其上生长、增殖和功能的影响,同时对丝素蛋白在组织工程化食道支架及其他再生医学上的应用前景进行了展望。     

Conformation transition kinetics of Bombyx mori silk protein

Time-resolved FTIR analysis was used to monitor the conformation transition induced by treating regenerated Bombyx mori silk fibroin films and solutions with different concentrations of ethanol. The resulting curves showing the kinetics of the transition for both films and fibroin solutions were influenced by the ethanol concentration. In addition, for silk fibroin solutions the protein concentration also had an effect on the kinetics. At low ethanol concentrations (for example, less than 40% v/v in the case of film), films and fibroin solutions showed a phase in which beta-sheets slowly formed at a rate dependent on the ethanol concentration. Reducing the concentration of the fibroin in solutions also slowed the formation of beta-sheets. These observations suggest that this phase represents a nucleation step. Such a nucleation phase was not seen in the conformation transition at ethanol concentrations > 40% in films or > 50% in silk fibroin solutions. Our results indicate that the ethanol-induced conformation transition of silk fibroin in films and solutions is a three-phase process. The first phase is the initiation of beta-sheet structure (nucleation), the second is a fast phase of beta-sheet growth while the third phase represents a slow perfection of previously formed beta-sheet structure. The nucleation step can be very fast or relatively slow, depending on factors that influence protein chain mobility and intermolecular hydrogen bond formation. The findings give support to the previous evidence that natural silk spinning in silkworms is nucleation-dependent, and that silkworms (like spiders) use concentrated silk protein solutions, and careful control of the pH value and metallic ion content of the processing environment to speed up the nucleation step to produce a rapid conformation transition to convert the water soluble spinning dope to a tough solid silk fiber.     

Structure and properties of regenerated Antheraea pernyi silk fibroin in aqueous solution

Antheraea pernyi silk fibroin fibers were dissolved by aqueous lithium thiocyanate to obtain regenerated A. pernyi silk fibroin solution. By means of circular dichroism, ¹³C NMR and Raman spectroscopy, the molecular conformation of regenerated A. pernyi silk fibroin in aqueous solution was investigated. The relationship of environmental factors and sol–gel transformation behavior of regenerated A. pernyi silk fibroin was also studied. The molecular conformations of regenerated A. pernyi silk fibroin mainly were -helix and random coil in solution. There also existed a little β-sheet conformation. It was obviously different with Bombyx mori silk fibroin, whose molecular conformation in solution was only random coil but no -helix existence. With the increase of temperature and solution concentration and with the decrease of solution pH value, the gelation velocity of regenerated A. pernyi silk fibroin solution increased. Especially, it showed that A. pernyi silk fibroin was more sensitive to temperature than B. mori silk fibroin during the sol–gel transformation. The velocity increased obviously when the temperature was above 30 °C. During the sol–gel transformation, the molecular conformation of regenerated A. pernyi silk fibroin changed from random coil to β-sheet structure. The results of these studies provided important insight into the preparation of new biomaterials by silk fibroin protein.     

Effect of shearing on formation of silk fibers from regenerated Bombyx mori silk fibroin aqueous solution

In this paper, the spinnable regenerated silk fibroin aqueous solution with high concentration was prepared and the regenerated silk fibers were obtained from the aqueous solution by two different spinning processes at ambient temperature. The orientation of these fibers was characterized by polarizing microscope. Their secondary structure was investigated by Raman spectroscopy and related mechanical properties were also measured. These data showed that shearing is an important step for increasing orientation and silk II (β-sheet) structure, and the mechanical properties of the regenerated silk fibers can also be improved by shearing.     

Modification of Bombyx mori silk fabrics by tyrosinase‐catalyzed grafting of chitosan

Tyrosinase could oxidize tyrosyl residues in silk fibroin and result in the production of activated o‐quinone residues, which could facilitate the grafting of the functional amino‐compounds onto silk fibers. In this study, the enzymatic modifications of Bombyx mori silk fibroin with tyrosinase and chitosan were investigated, aiming at improving the properties of silk fabrics, including dyeability, crinkling resistance, and antibacterial activity. The grafting grades of chitosan were evaluated by a color‐development method using bromocresol green. The result indicated that chitosan molecules were not only adsorbed on silk fibers via electrostatic interactions, they also could react with the oxidized silk fibers with tyrosinase. For the silk fabric combinedly treated with tyrosinase and chitosan, tensile strength and crinkling resistance were noticeably increased as compared to that of the chitosan‐treated. The antibacterial activity and its durability measurements revealed the actions of the tyrosinase‐catalyzed grafting of chitosan. The efficacy of the graft reaction might be further enhanced by increasing the accessibility of reactive sites in silk fibers.