ObjectiveTo prepare of a novel functional self-assembling peptide nanofiber hydrogel scaffold RADKPS designed with linking the short functional motif of bone morphogenetic protein 7 (BMP-7) and to evaluate its biocompatibility so as to provide the experimental basis for in vivo studies on regeneration of degenerated nucleus pulposus tissue.
MethodA functional self-assembling peptide RADA-KPSS was designed by linking the short functional motif of BMP-7 to the self-assembling peptide RADA16-I. And the novel functional self-assembling peptide RADKPS was finally prepared by isometric mixing RADA16-I with RADA-KPSS. The structure characteristic of the functional self-assembling peptide nanofiber hydrogel scaffold RADKPS was evaluated by general observation and atomic force microscopy. Bone marrow mesenchymal stem cells (BMSCs) were isolated from 3-month-old New Zealand white rabbits and cultured. After the 3rd generation BMSCs were seeded on the peptide nanofiber hydrogel scaffold RADKPS for 7 days, the cellular compatibility of RADKPS was evaluated through scanning electron microscopy assay, cellular fluorescein diacetate/propidium iodide staining, and MTT assay. 1%RADKPS was injected into isolated intervertebral disc organs from 6-month-old New Zealand white rabbits, then the organs were cultured and the cellular activity of the intervertebral disc organs was observed. The blood compatibility of RADKPS was evaluated with hemolytic assay. After RADKPS was implanted into subcutaneous part of Kunming mice (aged 6-8 weeks) for 28 days, general observation and HE staining were carried out to evaluate the tissue compatibility.
ResultsThe functional self-assembling peptide solution RADKPS presented a homogeneous transparent hydrogel-like. Atomic force microscopy revealed that the RADKPS could self-assemble into three-dimensional nanofiber hydrogel scaffolds; the fibre diameter was (25.68±4.62) nm, and the fibre length was (512.42±32.22) nm. After BMSCs cultured on RADKPS for 7 days, scanning electron microscopy showed that BMSCs adhered to the scaffolds. And cell viability was maintained over 90%. MTT assay revealed that RADKPS of 0.1%, 0.05%, and 0.025% could increase the proliferation of BMSCs. The result of hemolytic assay revealed that the hemolysis rates of the RADKPS solutions with different concentrations were less than 5%, indicating that it met the requirement of hemolytic assay standard for medical biomaterials. After subcutaneous implantation, no vesicle, erythema, and eschar formation around injection site were observed. Meanwhile, HE staining showed inflammatory cells infiltration (lymphocytes), substitution of hydrogel scaffold by fibrous tissue, and good tissue compatibility.
ConclusionsThe novel functional self-assembling peptide nanofiber hydrogel scaffold RADKPS has good biocompatibility and biological reliability, which would be suitable for tissue engineering repair and regeneration of nucleus pulposus tissue.
In cases where a tracheal injury exceeds half the length of the adult trachea or one-third of the length of the child trachea, it becomes difficult to perform end-to-end anastomosis after tracheal resection due to excessive tension at the anastomosis site. In such cases, tracheal replacement therapy is required. Advances in tissue engineering technology have led to the development of tissue engineering tracheal substitutes, which have promising applications. Hydrogels, which are highly hydrated and possess a good three-dimensional network structure, biocompatibility, low immunogenicity, biodegradability, and modifiability, have had wide applications in the field of tissue engineering. This article provides a review of the characteristics, advantages, disadvantages, and effects of various hydrogels commonly used in tissue engineering trachea in recent years. Additionally, the article discusses and offers prospects for the future application of hydrogels in the field of tissue engineering trachea.
ObjectiveTo summarize the research progress of hydrogels for the regeneration and repair of degenerative intervertebral disc and to investigate the potential of hydrogels in clinical application.MethodsThe related literature about the role of hydrogels in intervertebral disc degeneration especially for nucleus pulposus was reviewed and analyzed.ResultsHydrogels share similar properties with nucleus pulposus, and it plays an important role in the regeneration and repair of degenerative intervertebral disc, which can be mainly applied in nucleus pulposus prosthesis, hydrogel-based cell therapy, non-cellular therapy, and tissue engineering repair.ConclusionHydrogels are widely used in the regeneration and repair of intervertebral disc, which provides a potential treatment for intervertebral disc degeneration.
Heart failure affects quality of life and life expectancy of tens of millions of individuals. There are no available economic and effective treatments for end-stage heart failure. Hydrogels are novel tissue engineering materials, which have the potential to ameliorate myocardium remodeling, increase cardiac output, improve quality of life and prolong life span by implantation into myocardium. The preclinical experiments and clinical trials have greatly explored the function of hydrogels in heart failure. In this review, we summarized the approaches of implantation, mechanism and clinical outcomes of the hydrogels.
Objective To introduce the development of dextran-based hydrogel and its drug delivery system in drug sustained and/or controlled release, and to investigate their application in tissue engineering.Methods Related literature was extensively reviewed and comprehensively analyzed. Results In recent years, great progress was made in the studies of dextran-based hydrogels and study on dextran-based intelligent materials became an investigative hotspot especially in tissue engineering. Conclusion Dextran based hydrogel is considered to be a good potential material in field of drug delivery and tissue engineering. Endowed with new characteristics, a series of intelligent biomaterials can be derived from dextran-based hydrogels, which can be widely used in biomedicine. Further study should be done on the industrialization of its interrelated production.
This research aims to investigate the encapsulation and controlled release effect of the newly developed self-assembling peptide R-LIFE-1 on exosomes. The gelling ability and morphological structure of the chiral self-assembling peptide (CSAP) hydrogel were examined using advanced imaging techniques, including atomic force microscopy, transmission electron microscopy, and cryo-scanning electron microscopy. The biocompatibility of the CSAP hydrogel was assessed through optical microscopy and fluorescent staining. Exosomes were isolated via ultrafiltration, and their quality was evaluated using Western blot analysis, nanoparticle tracking analysis, and transmission electron microscopy. The controlled release effect of the CSAP hydrogel on exosomes was quantitatively analyzed using laser confocal microscopy and a BCA assay kit. The results revealed that the self-assembling peptide R-LIFE-1 exhibited spontaneous assembly in the presence of various ions, leading to the formation of nanofibers. These nanofibers were cross-linked, giving rise to a robust nanofiber network structure, which further underwent cross-linking to generate a laminated membrane structure. The nanofibers possessed a large surface area, allowing them to encapsulate a substantial number of water molecules, thereby forming a hydrogel material with high water content. This hydrogel served as a stable spatial scaffold and loading matrix for the three-dimensional culture of cells, as well as the encapsulation and controlled release of exosomes. Importantly, R-LIFE-1 demonstrated excellent biocompatibility, preserving the growth of cells and the biological activity of exosomes. It rapidly formed a three-dimensional network scaffold, enabling the stable loading of cells and exosomes, while exhibiting favorable biocompatibility and reduced cytotoxicity. In conclusion, the findings of this study support the notion that R-LIFE-1 holds significant promise as an ideal tissue engineering material for tissue repair applications.
OBJECTIVE: To investigate the effect of compound pattern of ceramic bovine bone (CBB) and hydrogel(HG) on attachment, proliferation and differentiation of bone marrow stromal cell (MSC), and to find out the best way of constructing tissue engineered bone. METHODS: CBB, HG and MSC was compounded in different patterns and sequences to form CBB/HG/MSC (group A), HG/MSC/CBB (group B), CBB/MSC/HA (group C) and CBB/MSC (control group). Attachment and morphology of MSC were observed by scanning electronic microscope; the proliferation of MSC was evaluated by cell count; alkaline phosphatase(ALP) activity was examined by histochemistry and type I collagen synthesis was examined by immunohistochemistry staining 5 and 10 days later. RESULTS: In group A, MSC spread better, and ALP activity of group A was significantly higher than that of group B and control group(P lt; 0.01); but there was no significant difference between group A and group C(P gt; 0.05). There was no significant difference in type I collagen synthesis between four groups on the 5th day; but mean gray scale of type I collagen in group B was significantly higher than that in the other groups on the 10th day(P lt; 0.01). CONCLUSION: Different compound patterns of CBB, HG and MSC affect attachment, proliferation, differentiation of MSC. The compound pattern of CBB/HG/MSC is better than the others.
Research on vitreous substitutes has advanced from conventional gases and silicone oils to third-generation biomimetic hydrogels. While existing substitutes provide short-term retinal tamponade, they typically require strict postoperative positioning and carry risks of cataract formation, ocular hypertension, and silicone oil emulsification. These materials therefore fall short of meeting the essential requirements for long-term tissue support, matched physicochemical properties, and high biocompatibility simultaneously. Recently, polymer-based hydrogels have gained prominence as ideal candidates owing to their high water content, optical transparency, adjustable viscoelasticity, and favorable biocompatibility. They have diversified into several forms, including uncrosslinked solutions, preformed hydrogels systems, and in-situ crosslinked systems. Biopolymer hydrogels, such as those derived from hyaluronic acid, collagen, or alginate, demonstrate high safety but often exhibit inadequate mechanical strength and poor stability in vivo. Synthetic polymer hydrogels, including polyethylene glycol, polyvinyl alcohol, and polyvinylpyrrolidone, allow tunable properties yet raise concerns regarding monomer toxicity and degradation-related safety. Future research is shifting from simple material replacement toward functional reconstruction and intelligent regulation. Increasing efforts aim to develop smart hydrogels capable of sustained drug release and cell encapsulation, alongside advanced strategies employing biodegradable scaffolds to promote native vitreous regeneration, with the ultimate goal of achieving full functional restoration.
Objective To investigate the feasibility of a dual-crosslinked injectable hydrogel derived from acellular musclar matrix (AMM) for promoting myoblasts proliferation and myogenic differentiation. Methods Firstly, hyaluronic acid was oxidized with NaIO4 and methylated to prepare methacrylamidated oxidized hyaluronic acid (MOHA). Then, AMM obtained by washing enzymatically treated muscle tissue was aminolyzed to prepare aminated AMM (AAMM). MOHA hydrogel and AAMM were crosslinked using Schiff based reaction and UV radiation to prepare a dual-crosslinked MOHA/AAMM injectable hydrogel. Fourier transform infrared spectroscopy (FTIR) was used to characterize MOHA, AAMM, and MOHA/AAMM hydrogels. The injectability of MOHA/AAMM hydrogel were evaluated by manual injection, and the gelation performance was assessed by UV crosslinking. The rheological properties and Young’s modulus of the hydrogel were examined through mechanical tests. The degradation rate of the hydrogel was assessed by immersing it in PBS. The active components of the hydrogel were verified using immunofluorescence staining and ELISA assay kits. The promotion of cell proliferation by the hydrogel was tested using live/dead staining and cell counting kit 8 (CCK-8) assays after co-culturing with C2C12 myoblasts for 9 days. The effect of the hydrogel on myogenic differentiation was evaluated by immunofluorescence staining and real time quantitative polymerase chain reaction (RT-qPCR). ResultsFTIR spectra confirmed the successful preparation of MOHA/AAMM hydrogel. The hydrogel exhibited good injectability and gelation ability. Compared to MOHA hydrogel, MOHA/AAMM hydrogel exhibited higher viscosity and Young’s modulus, a reduced degradation rate, and contained a higher amount of collagen (including collagen type Ⅰ and collagen type Ⅲ) as well as bioactive factors (including epidermal growth factor, fibroblast growth factor 2, vascular endothelial growth factor, and insulin-like growth factor 1). The live/dead cell staining and CCK-8 assay indicated that with prolonged incubation time, there was a significant increase in viable cells and a decrease in dead cells in the C2C12 myoblasts within the MOHA/AAMM hydrogel. Compared with MOHA hydrogel, the difference was significant at each time point (P<0.05). Immunofluorescence staining and RT-qPCR analysis demonstrated that the deposition of IGF-1 and expression levels of myogenic-related genes (including Myogenin, Troponin T, and myosin heavy chain) in the MOHA/AAMM group were significantly higher than those in the MOHA group (P<0.05). ConclusionThe MOHA/AAMM hydrogel prepared based on AMM can promote myoblasts proliferation and myogenic differentiation, providing a novel dual-crosslinked injectable hydrogel for muscle tissue engineering.
Hydrogel is a kind of degradable hydrophilic polymer, but excessive hydrophilicity leads to larger volume, lower elastic modulus and looser structure, which further affect its use. Especially in the field of biomedical engineering, excessive swelling of the hydrogel can compress the nerves and improve degradation rate resulting in mismatch of tissue growth and released ions. Therefore, anti-swelling hydrogel has been a research hotspot in recent years. This paper reviews the recent research progress on anti-swelling hydrogel, and expounds the application mechanism and preparation method of hydrogel in biomedical engineering, aiming to provide some references for researchers in the field of anti-swelling hydrogel.
