Objective To introduce an injectable andin situ gelling gelatin hydrogel, and to explore the possibility as a carrier for demineralized bone matrix (DBM) powder delivery. Methods First, thiolated gelatin was prepared and the thiol content was determined by Ellman method, and then the injectable andin situ gelling gelatin hydrogel (Gel) was formed by crosslinking of the thiolated gelatin and poly (ethylene oxide) diacrylate and the gelation time was determined by inverted method. Finally, the DBM-Gel composite was prepared by mixing Gel and DBM powder. The cytotoxicity was tested by live/dead staining and Alamar blue assay of the encapsulated cells in the DBM-Gel. Forin vitro cell induction, C2C12 cells were firstly incubated onto the surface of the DBM and then the composite was prepared. The experiment included two groups: DBM-Gel and DBM. The alkaline phosphatase (ALP) activity was determined at 1, 3, 5,and 7 days after culture.In vivo osteoinductivity was evaluated using ectopic bone formation model of nude rats. Histological observation and the ALP activity was measured in DBM-Gel and DBM groups at 4 weeks after implantation. Results The thiol content in the thiolated gelatin was (0.51±0.03) mmol/g determined by Ellman method. The gelation time of the hydrogel was (6±1) minutes. DBM powder can be mixed with the hydrogel and injected into the implantation site within the gelation time. The cells in the DBM-Gel exhibited spreading morphology and connected each other in part with increasing culture time. The viability of the cells was 95.4%±1.9%, 97.3%±1.3%, and 96.1%±1.6% at 1, 3, and 7 days after culture, respectively. The relative proliferation was 1.0±0.0, 1.1±0.1, 1.5±0.1, and 1.6±0.1 at 1, 3, 5, and 7 days after culture respectively.In vitro induction showed that the ALP activity of the DBM-Gel group was similar to that of the DBM group, showing no significant difference (P>0.05). With increasing culture time, the ALP activities in both groups increased gradually and the activity at 5 and 7 days was significantly higher than that at 1 and 3 days (P<0.05), while there was no significant difference between at 1 and 3 days, and between 5 and 7 days (P>0.05). At 4 weeks after implantationin vivo, new bone and cartilage were observed, but no bone marrow formation in DBM-Gel group; in DBM group, new bone, new cartilage, and bone marrow formation were observed. The histological osteoinduction scores of DBM-Gel and DBM groups were 4.0 and 4.5, respectively. The ALP activities of DBM-Gel and DBM groups were respectively (119.4±22.7) and (146.7±13.0) μmol/mg protein/min, showing no significant difference (t=–2.085,P=0.082). Conclusion The injectable andin situ gelling gelatin hydrogel for delivery of DBM is feasible.
ObjectiveTo review the properties of bio-derived hydrogels and their application and research progress in tissue engineering. MethodsThe literature concerning the biol-derived hydrogels was extensively reviewed and analyzed. ResultsBio-derived hydrogels can be divided into single-component hydrogels (collagen,hyaluronic acid,chitosan,alginate,silk fibroin,etc.) and multi-component hydrogels[Matrigel,the extract of extracellular matrix (ECM),and decellularized ECM].They have favorable biocompatibility and bioactivity because they are mostly extracted from the ECM of biological tissue.Among them,hydrogels derived from decellularized ECM,whose composition and structure are more in line with the requirements of bionics,have incomparable advantages and prospects.This kind of scaffold is the closest to the natural environment of the cell growth. ConclusionBio-derived hydrogels have been widely used in tissue engineering research.Although there still exist many problems,such as the poor mechanical properties,rapid degradation,the immunogenicity or safety,vascularization,sterilization methods,and so on,with the deep-going study of optimization mechanism,desirable bio-derived hydrogels could be obtained,and thus be applied to clinical application.
The biocompatible hydrogel was fabricated under suitable conditions with natural dextran and polyethylene glycol (PEG) as the reaction materials. The oligomer (Dex-AI) was firstly synthesized with dextran and allylisocyanate (AI). This Dex-AI was then reacted with poly (ethyleneglycoldiacrylate) (PEGDA) under the mass ratio of 4∶6 to get hydrogel (DP) with the maximum water absorption of 810%. This hydrogel was grafted onto the surface of medical catheter via diphenyl ketone treatment under ultraviolet (UV) initiator. The surface contact angle became lower from (97 ± 6.1)° to (25 ± 4.2)° after the catheter surface was grafted with hydrogel DP, which suggests that the catheter possesses super hydrophilicity with hydrogel grafting. The in vivo evaluation after they were implanted into ICR rats subcutaneously verified that this catheter had less serious inflammation and possessed better histocompatibility comparing with the untreated medical catheter. Therefore, it could be concluded that hydrogel grafting is a good technology for patients to reduce inflammation due to catheter implantation, esp. for the case of retention in body for a relative long time.
Objective To evaluate the effect of endoscopic surgery combined with intraoperative color Doppler ultrasound on removing the injected breast augmentation agents and share our experiences. Methods Sixteen female who accepted the bilateral removal of injected breast augmentation agents through endoscopic surgery combined with intraoperative color Doppler ultrasound between 2008 and 2010 were enrolled in this study. The results, techniques, and advantages of management were analyzed retrospectively. Results One incision was made in 18 breasts, 2 in 4 breasts, 3 in 10 breasts. The length of incision was 0.5 to 1 cm. The mean operative time was 128.70 min per person. The average amount of bleeding was 52.67 ml per person. Complications such as postoperative bleeding, infection, poor drainage, or breast augmentation agents remain did not happened in all cases. No case was turned into normal operation. Female who accepted this operation were all satisfied with the appearance of incisions. During 1-3 months follow up, neither clinically palpable mass nor sensory disturbance in nipple or areola of breast was observed. Color Doppler ultrasound or magnetic resonance showed 16 cases had been cleared free of breast augmentation agents. Conclusion With the advantages of beauty, safe, minimal invasion, and partial resection of lesions at the same time, endoscopic surgery combined with intraoperative color Doppler ultrasound was an effective approach in the removal of injected breast augmentation agents.
Objective To compare the growth and extracellular matrix biosynthesis of nucleus pulposus cells (NPCs)and bone marrow mesenchymal stem cells (BMSCs) in thermo-sensitive chitosan hydrogel and to choose seed cells for injectable tissue engineered nucleus pulposus. Methods NPCs were isolated and cultured from 3-week-old New Zealand rabbits (male or female, weighing 150-200 g). BMSCs were isolated and cultured from bone marrow of 1-month-old New Zealand rabbits (male or female, weighing 1.0-1.5 kg). The thermo-sensitive chitosan hydrogel scaffold was made of chitosan, disodium β glycerophosphate, and hydroxyethyl cellulose. Then, NPCs at the 2nd passage or BMSCs at the 3rd passage were mixed with chitosan hydrogel to prepare NPCs or BMSCs-chitosan hydrogel complex as injectable tissue engineered nucleus pulposus. The viabil ities of NPCs and BMSCs in the chitosan hydrogel were observed 2 days after compound culture. The shapes and distributions of NPCs and BMSCs on the scaffold were observed by scanning electron microscope (SEM) 1 week after compound culture. The histology and immunohistochemistry examination were performed. The expressions of aggrecan and collagen type II mRNA were analyzed by RT-PCR 3 weeks after compound culture. Results The thermo-sensitive chitosan hydrogel was l iquid at room temperature and sol idified into gel at37 (after 15 minutes) due to crossl inking reaction. Acridine orange/propidium iodide staining showed that the viabil ity rates of NPCs and BMSCs in chitosan hydrogel were above 90%. The SEM observation demonstrated that the NPCs and BMSCs distributed in the reticulate scaffold, with extracellular matrix on their surfaces. The results of HE, safranin O histology and immunohistochemistry staining confirmed that the NPCs and BMSCs in chitosan hydrogel were capable of producing extracellular matrix. RT-PCR results showed that the expressions of collagen type II and aggrecan mRNA were 0.564 ± 0.071 and 0.725 ± 0.046 in NPCs culture with chitosan hydrogel, and 0.713 ± 0.058 and 0.852 ± 0.076 in BMSCs culture with chitosan hydrogel; showing significant difference (P lt; 0.05). Conclusion The thermo-sensitive chitosan hydrogel has good cellular compatibil ity. BMSCs culture with chitosan hydrogel maintains better cell shape, prol iferation, and extracellular matrix biosynthesis than NPCs.
Objective To review the research progress of new antibacterial hydrogels in the treatment of infected wounds in the field of biomedicine, in order to provide new methods and ideas for clinical treatment of infected wounds. Methods The research literature on antibacterial hydrogels at home and abroad was extensively reviewed in recent years, and the antibacterial hydrogels for the treatment of infected wounds were classified and summarized. Results Antibacterial hydrogels can be divided into three categories: inherent antibacterial hydrogels, antibacterial agent release hydrogels, and environmental response antibacterial hydrogels. The advantages and disadvantages of antibacterial materials, antibacterial mechanism, antibacterial ability, and biocompatibility were discussed respectively. Inherent antibacterial hydrogels have the characteristics of wide source, low cost, and simple preparation, but their antibacterial ability is relatively weak. New antimicrobial substances are added to antibacterial agent release hydrogels, such as antimicrobial peptides, metal ions, graphene materials, etc., providing a new therapeutic strategy for alternative antibiotic therapy. On the basis of the antibacterial material, environmental promoting factors such as photothermal effect, pH value, and magnetic force are added to the environmental response antibacterial hydrogels, which synergically enhances the antibacterial ability of the hydrogel, improves the precise regulation function and bionic effect of the hydrogel. ConclusionThe selection of a variety of materials, the addition of a variety of antibacterial agents, and the effect of various promoting factors make composite hydrogels show multiple characteristics. The development of antibacterial hydrogels that can effectively address practical clinical applications remains a significant challenge. In the future, expanding the application range of antibacterial hydrogels, constructing drug-loaded hydrogels, and developing intelligent hydrogels are still new areas that need to be explored and studied.
Objective To investigate the therapeutic effect of BMSCs- chitosan hydrogel complex transplantation on intervertebral disc degeneration and to provide experimental basis for its cl inical appl ication. Methods Two mill il iter of bone marrow from 6 healthy one-month-old New Zealand rabbits were selected to isolate and culture BMSCs. Then, BMSCs at passage 3 were labeled by 5-BrdU and mixed with chitosan hydrogel to prepare BMSCs- chitosan hydrogel complex. Six rabbitswere selected to establ ish the model of intervertebral disc degeneration and randomized into 3 groups (n=2 per group): control group in which intervertebral disc was separated and exposed but without further processing; transplantation group in which 30 μL of autogenous BMSCs- chitosan hydrogel complex was injected into the center of defected intervertebral disc; degeneration group in which only 30 μL of 0.01 mol/L PBS solution was injected. Animals were killed 4 weeks later and the repaired discs were obtained. Then cell 5-BrdU label ing detection, HE staining, aggrecan safranin O staining, Col II immunohistochemical staining and gray value detection were conducted. Results Cell label ing detection showed that autogenous BMSCs survived and prol iferated after transplantation, forming cell clone. HE staining showed that in the control and transplantation groups, the intervertebral disc had a clear structure, a distinct boundary between the central nucleus pulposus and the outer anulus fibrosus, and the obviously stained cell nuclear and cytochylema; while the intervertebral disc in the degeneration group had a deranged structure and an indistinct division between the nucleus pulposus and the outer anulus fibrosus. Aggrecan safarine O stainning notified that intervertebral disc in the control and transplantation groups were stained obviously, with a clear structure; while the intervertebral disc in the degeneration group demonstrated a deranged structure with an indistinct division between the nucleus pulposus and the anulus fibrosus. Col II immunohistochemical staining showed that the tawny-stained region in the control group was located primarily in the central nucleus pulposus with a clear structure of intervertebral disc, the central nucleus pulposus in the transplantation group was positive with obvious tawny-stained intercellular substances and a complete gross structure, while the stained color in the degeneration group was l ighter than that of other two groups, with a indistinct structure.Gray value assay of Col II immunohistochemical staining section showed that the gray value of the control, the ransplantation and the degeneration group was 223.84 ± 3.93, 221.03 ± 3.53 and 172.50 ± 3.13, respectively, indicating there was no significant difference between the control and the transplantation group (P gt; 0.05), but a significant difference between the control and transplantation groups and the degeneration group (P lt; 0.05). Conclusion The rabbit BMSCs-chitosan hydrogel complex can repair intervertebral disc degeneration, providing an experimental foundation for the cl inical appl ication of injectable tissue engineered nucleus pulposus complex to treat intervertebral disc degeneration.
ObjectiveTo assess the effect of microfracture and biomimetic hydrogel scaffold on tendon-to-bone healing in a rabbit rotator cuff tear model.MethodsGelatin and methacrylic anhydride were used to synthesize gelatin methacryloyl (GelMA). Then the GelMA were treated with ultraviolet rays and vacuum freeze-drying method to obtain a biomimetic hydrogel scaffold. The morphology of the scaffold was observed by gross observation and scanning electron microscope. Degradation of the scaffold was determined at different time points. Twenty-four adult New Zealand rabbits, weighting 2.8-3.5 kg and male or female, were surgically created the bilateral acute rotator cuff tear models. One shoulder was treated with microfractures on the footprint and transosseous suture (control group, n=24). The other shoulder was treated with the same way, except for putting the scaffold on the footprint before transosseous suture (experimental group, n=24). The general conditions of rabbits were observed postoperatively. Tendon-to-bone healing was evaluated by gross observation, Micro-CT, HE staining, and bio-mechanical testing at 4 and 8 weeks after operation.ResultsThe scaffold was white and has a porous structure with pore size of 31.7-89.9 μm, which degraded slowly in PBS solution. The degradation rate was about 95% at 18 days. All the rabbits survived to the completion of the experiment. Micro-CT showed that there was no obvious defect and re-tear at the tendon-to-bone interface in both groups. No difference was found in bone mineral density (BMD), tissue mineral density (TMD), and bone volume/total volume (BV/TV) between the two groups at 4 and 8 weeks postoperatively (P>0.05). HE staining showed that the fibrous scar tissue was the main component at the tendon-to-bone interface in the control group at 4 and 8 weeks postoperatively; the disorderly arranged mineralized cartilage and fibrocartilage formation were observed at the tendon-to-bone interface in the experimental group at 4 weeks, and the orderly arranged cartilage formation was observed at 8 weeks. Besides, the tendon maturation scores of the experimental group were significantly higher than those of the control group at 4 and 8 weeks (P<0.05). There was no significant difference in the ultimate load to failure and stiffness between the two groups at 4 weeks (P>0.05); the ultimate load to failure at 8 weeks was significantly higher in the experiment group than in the control group (t=4.162, P=0.009), and no significant difference was found in stiffness between the two groups at 8 weeks (t=2.286, P=0.071).ConclusionCompared with microfracture alone, microfracture combined with biomimetic hydrogel scaffold can enhance tendon-to-bone healing and improve the ultimate load to failure in rabbits.
ObjectiveTo review clinical application and research progress of different types of intelligent responsive hydrogels in repairing articular cartilage injury. MethodsThe animal experiments and clinical studies of different types of intelligent responsive hydrogels for repairing articular cartilage injury were summarized by reviewing relevant literature at home and abroad. ResultsThe intrinsic regenerative capacity of articular cartilage following injury is limited. Intelligent responsive hydrogels, including those that are temperature-sensitive, light-sensitive, enzyme-responsive, pH-sensitive, and other stimuli-responsive hydrogels, can undergo phase transitions in response to specific stimuli, thereby achieving optimal functionality. These hydrogels can fill the injured cartilage area, promote the proliferation and differentiation of chondrocytes, and expedite the repair of the damaged site. With advancements in cartilage tissue engineering materials research, intelligent responsive hydrogels offer a novel approach and promising potential for the treatment of cartilage injuries. ConclusionIntelligent responsive hydrogel is a kind of flexible, controllable, efficient, and stable polymer, which has similar structure and functional properties to articular cartilage, and has become one of the important biomaterials for cartilage repair. However, there is still a lack of unified treatment standards and simple and efficient preparation technology.
Objective To investigate the application potential of alginate-strontium (Sr) hydrogel as an injectable scaffold material in bone tissue engineering. Methods The alginate-Sr/-calcium (Ca) hydrogel beads were fabricated by adding 2.0wt% alginate sodium to 0.2 mol/L SrCl2/CaCl2 solution dropwise. Microstructure, modulus of compression, swelling rate, and degradability of alginate-Sr/-Ca hydrogels were tested. Bone marrow mesenchymal stem cells (BMSCs) were isolated from femoral bones of rabbits by flushing of marrow cavity. BMSCs at passage 5 were seeded onto the alginate-Sr hydrogel (experimental group) and alginate-Ca hydrogel (control group), and the viability and proliferation of BMSCs in 2 alginate hydrogels were assessed. The osteogenic differentiation of cells embeded in 2 alginate hydrogels was evaluated by alkaline phosphate (ALP) activity, osteoblast specific gene [Osterix (OSX), collagen type I, and Runx2] expression level and calcium deposition by fluorescent quantitative RT-PCR and alizarin red staining, Von Kossa staining. The BMSCs which were embeded in alginate-Ca hydrogel and cultured with common growth medium were harvested as blank control group. Results The micromorphology of alginate-Sr hydrogel was similar to that of the alginate-Ca hydrogel, with homogeneous pore structure; the modulus of compression of alginate-Sr hydrogel and alginate-Ca hydrogel was (186.53 ± 8.37) and (152.14 ± 7.45) kPa respectively, showing significant difference (t=6.853, P=0.002); there was no significant difference (t=0.737, P=0.502) in swelling rate between alginate-Sr hydrogel (14.32% ± 1.53%) and alginate-Ca hydrogel (15.25% ± 1.64%). The degradabilities of 2 alginate hydrogels were good; the degradation rate of alginate-Sr hydrogel was significantly lower than that of alginate-Ca hydrogel on the 20th, 25th, and 30th days (P lt; 0.05). At 1-4 days, the morphology of cells on 2 alginate hydrogels was spherical and then the shape was spindle or stellate. When three-dimensional cultured for 21 days, the DNA content of BMSCs in experimental group [(4.38 ± 0.24) g] was significantly higher than that in control group [(3.25 ± 0.21) g ] (t=8.108, P=0.001). On the 12th day after osteogenic differentiation, the ALP activity in experimental group was (15.28 ± 1.26) U/L, which was significantly higher than that in control group [(12.07 ± 1.12) U/L] (P lt; 0.05). Likewise, the mRNA expressions of OSX, collagen type I, and Runx2 in experimental group were significantly higher than those in control group (P lt; 0.05). On the 21th day after osteogenic differentiation, alizarin red staining and Von Kossa staining showed calcium deposition in 2 groups; the calcium nodules and phosphate deposition in experimental group were significantly higher than those in control group (P lt; 0.05). Conclusion Alginate-Sr hydrogel has good physicochemical properties and can promote the proliferation and osteogenic differentiation of BMSCs, so it is an excellent injectable scaffold material for bone tissue engineering.