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objective:To prepare a composite photocrosslinked hydrogel containing zeolite imidazole framework-8(ZIF-8),and to evaluate its in vitro cytotoxicity,drug release capability,and antimicrobial propertie.Methods:The ZIF-8 particles were synthesized by hydrothermal method,and the microstructure characteristic was observed under scanning electron microscope(SEM).The particles were mixed with the gelatin methacryloyl(GelMA)with the mass fraction of 0.2%to obtain the composite hydrogel GelMA-Z.The atomic absorption spectroscope was used to detect the cumulative zinc ion(Zn2+)release amounts in GelMA-Z at different time points.The NIH-3T3 cells were co-cultured with GelMA-Z for 1,3,and 7 d;the viabilities of the cells in various groups were detected by CCK-8 assay;the GelMA-Z was co-cultured with Escherichia coli(E.coli)and Staphylococcus aureus(S.aureus)for 6,12,and 24 h and divided into control group,GelMA group,and GelMA-Z group.The bacterial activities of the cells in various groups at different time points were detected by microplate reader;the bacterial formation and the presence of live/dead becterial staining condition were detected by plate antibacterial experiment and live/dead bacterial staining method.Results:The SEM observation results showed that the hydrothermally synthesized ZIF-8 particles had the uniform particle sizes.The atomic absorption spectroscope results showed that Zn2+ in GelMA-Z showed an initial burst phase within 1 d,followed by a slow release,and reached the equilibrium around 7 d.Compared with control group,the viabilities the cells in GelMA group and GelMA-Z group were above 90%on the 1st,3rd,and 7th days,but there was no significant difference(P>0.05).The bacterial activity detection results showed that when co-cultured with bacteria for 6,12,and 24 h,compared with control group and GelMA group,the bacterial activities of the E.coli and S.aureus in GelMA-Z group were decreased(P<0.05).The plate antibacterial experiment results showed that the number of bacterial formation in GelMA-Z group was fewer than those in control group and GelMA group.The live/dead bacterial staining results showed that in GelMA-Z group,there was a large number of red fluorescence stained dead bacteria;in control group and GelMA group,there was a large number of green fluorescence stained live bacteria.Conclusion:The GelMA hydrogel loaded with ZIF-8 particles can achieve the in situ photocrosslinking and possesses good Zn2+ release capability and antimicrobial activity,and it is a novel hydrogel dressing for treatment of the infected wounds.
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Objective To discuss the application of gelatin sponge-hemocoagulase plugging agent in patients with pulmonary puncture bleeding.Methods The clinical data of 43 patients with hemorrhage caused by DSA-guided lung puncture biopsy,who received gelatin sponge-hemocoagulase plugging agent treatment at the Jining Municipal First People's Hospital of China between September 2021 and May 2023,were collected,and the hemostatic effect of gelatin sponge-hemocoagulase plugging agent was analyzed.Results Successful lung puncture needle biopsy was achieved in all the 43 patients.The puncture needle channel occlusion was accomplished by using gelatin sponge-hemocoagulase plugging agent.Five minutes after occlusion treatment,in one patient,whose moderate hemoptysis with moderate bleeding shadow before puncture needle biopsy changed to bloody sputum,the intrapulmonary bleeding shadow displayed on image became slightly enlarged when compared the size five minutes ago,while in all the remaining patients successful hemostasis was achieved,the hemoptysis disappeared and the pulmonary hemorrhage shadow was similar to that five minutes ago.No occlusion-related complications occurred in all patients.Conclusion For the treatment of pulmonary hemorrhage caused by DSA-guided lung puncture biopsy,gelatin sponge-hemocoagulase plugging agent is clinically safe and effective.
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BACKGROUND:Cartilage defects are one of the major clinical challenges faced by orthopedic surgeons.Tissue engineering is an interdisciplinary approach that combines knowledge of engineering and cell biology to provide new ideas and approaches for the repair of cartilage defects. OBJECTIVE:To prepare a multi-component composite scaffold based on silk fibroin,gelatin,and chitosan to screen for a three-dimensional porous scaffold suitable for cartilage regeneration by evaluating its physicochemical properties and biological performance. METHODS:Four groups of porous scaffolds were prepared by vacuum freeze-drying method using silk fibroin,gelatin and chitosan as the base materials,namely chitosan/gelatin scaffold,silk fibroin/chitosan scaffold,silk fibroin/gelatin scaffold and silk fibroin/chitosan/gelatin scaffold.The suitable cartilage scaffolds were screened by scanning electron microscopy,X-ray diffractometer,porosity,water absorption and swelling rate,biodegradation rate and mechanical property detection.Then cartilage scaffolds were co-cultured with chondrocytes isolated and extracted from patients with osteoarthritis.The feasibility of porous scaffolds for cartilage injury repair was evaluated in vitro by cell adhesion rate assay,cell live-dead staining and cell activity proliferation assay. RESULTS AND CONCLUSION:(1)All four groups of scaffolds had porous structures.The comprehensive physical performance test results showed that the silk fibroin/gelatin/chitosan scaffold was more in line with the requirements of cartilage defect repair.This scaffold had a pore size of(176.00±53.68)μm,the porosity of(80.15±2.57)%,and water absorption and swelling rate of(3 712±358)%.After immersion in PBS containing lysozyme for 28 days in vitro,the biodegradation rate was(46.87±3.25)%,and it had good mechanical properties.(2)Chondrocytes could adhere well on the silk fibroin/gelatin/chitosan scaffold,and the cell adhesion rate increased with time.CCK8 and live/dead cell double staining results showed that silk fibroin/gelatin/chitosan scaffold had good biocompatibility and low cytotoxicity.(3)The results showed that silk fibroin/gelatin/chitosan scaffold had a highly hydrated 3D structure,suitable pore size and porosity,good biodegradability and superior mechanical properties,which can provide a good reticular skeleton and microenvironment for nutrient transport and chondrocyte attachment and proliferation.
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BACKGROUND:Salvianolic acid B can inhibit cell damage induced by H2O2,effectively remove excess reactive oxygen species,and exert antioxidant properties.It has been used in the treatment of many diseases.However,there are relatively few studies on the role and mechanism of salvianolic acid B in intervertebral disc degeneration. OBJECTIVE:To observe the effect and mechanism of salvianolic acid B on oxidative stress-induced intervertebral disc degeneration by using gelatin methacryloyl hydrogel as a carrier through the in vitro cell experiment and the in vivo animal experiment. METHODS:The gelatin methacryloyl hydrogel(drug-loaded hydrogel)loaded with salvianolic acid B was prepared.(1)In vitro cell experiment:The lumbar nucleus pulposus cells of adult SD rats were isolated and extracted,and passage 3 nucleus pulposus cells were selected and divided into groups:Group A was added complete medium.In group B,a complete medium containing H2O2 was added.Group C was inoculated on methylacrylylated gelatin hydrogel and added with a complete medium containing H2O2.Group D was inoculated on methyl acrylyl gelatin hydrogel loaded with salvianolic acid B and added into a complete medium containing H2O2.The E group was inoculated on the methylacrylyl gelatin hydrogel loaded with salvianolic acid B,and the complete medium containing H2O2 and the complete medium containing TLR4 signaling pathway inhibitor were added.Cell proliferation,oxidative stress,inflammatory response,gene expression of cell matrix-associated proteins and the protein expression of TLR4/nuclear factor-kB signaling pathway were detected.(2)Animal in vivo experiment:Sixty adult SD rats were randomly divided into normal group,acupuncture group,acupuncture + salvianolic acid group,acupuncture + hydrogel group and acupuncture + loading potion gel group,with 12 rats in each group.The last four groups were treated with acupuncture to establish models of intervertebral disc degeneration and then injected with normal saline,salvianolic acid B solution,non-drug loaded gel and drug-loaded gel in turn.Imaging examination and pathological observation were performed 4 weeks after surgery. RESULTS AND CONCLUSION:(1)In vitro cell experiment:Compared with group A,the cell proliferation was decreased;the oxidative stress reaction and inflammation reaction were enhanced;the expression of extracellular matrix degrading enzymes(matrix metalloproteinase 3,matrix metalloproteinase 13,ADAMTS4,ADAMTS5)was increased in group B(P<0.05),and the synthesis of extracellular matrix(type Ⅱ collagen,proteoglycan)was decreased(P<0.05).The protein expression of the TLR4/nuclear factor-kB signaling pathway was increased(P<0.05).Compared with group B,the cell proliferation of groups D and E was increased,the oxidative stress response and inflammatory response were weakened,and the expression of extracellular matrix degrading enzymes(matrix metalloproteinase 3,matrix metalloproteinase 13,ADAMTS4,ADAMTS5)was decreased(P<0.05),and the synthesis of extracellular matrix was increased(P<0.05).The protein expression of TLR4/nuclear factor-kB signaling pathway was decreased(P<0.05),and the effect was more significant in group E.(2)Animal in vivo experiment:4 weeks after surgery,intervertebral disc height index,index of MRI and pathological and histological grading of the intervertebral disc had improved significantly in the acupuncture+drug-loaded hydrogel group,and simply injecting hydrogel or salvianolic acid B solution can to a certain extent improve the intervertebral disc degeneration,but they are not as good as the injection of the drug-loaded hydrogel.(3)It is concluded that gelatin methacryloyl hydrogel loaded with salvianolic acid B can inhibit oxidative stress and inflammation in the degenerated intervertebral disc tissue,inhibit the degradation of extracellular matrix,and alleviate the process of intervertebral disc degeneration,which may be accomplished by inhibiting the TLR4/nuclear factor-kB signaling pathway.
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BACKGROUND:The imbalance of matrix synthesis and degradation is the main cause of nucleus pulposus degeneration.Small molecule drug Kartogenin(KGN)can restore the balance of matrix synthesis and degradation.Sustained release of KGN using an appropriate drug delivery system is essential for the long-term and effective treatment of KGN.OBJECTIVE:To prepare the injectable hydrogel microspheres by encapsulating KGN with gelatin methacryloyl(GelMA)by microfluidic technology and to investigate the biocompatibility and biological function of nucleus pulposus cells.METHODS:β-Cyclodextrins(β-CD)and KGN were mixed firstly and then mixed with 10%GelMA at a volume of 1:9.Injectable hydrogel microspheres GelMA@β-CD@KGN were prepared by microfluidic technology.The micromorphology of the microspheres was characterized using a scanning electron microscope.The drug release of hydrogel microspheres immersed in PBS within one month was measured.Nucleus pulposus cells were isolated from SD rats and passage 1 cells were cultured in three groups.In the control group,nucleus pulposus cells were cultured separately.In the other two groups,GelMA@β-CD microspheres and GelMA@β-CD@KGN microspheres were co-cultured with nucleus pulposus cells.Cell proliferation was detected by CCK-8 assay and cell survival was detected by live/dead cell staining.Cells were cultured by two complete media with and without interleukin-1β with two kinds of microspheres.mRNA expressions of matrix synthesis and decomposing proteins in nucleus pulposus cells were detected by RT-PCR.RESULTS AND CONCLUSION:(1)Under the scanning electron microscope,the GelMA@β-CD@KGN microspheres after lyophilization were regularly spherical,highly dispersed,uniform in size and full in shape.GelMA@β-CD@KGN microspheres sustained drug release in vitro,reaching 62%of the total drug release at 30 days.(2)Live/dead cell staining showed that GelMA@β-CD@KGN could maintain the activity of nucleus pulposus cells.CCK-8 assay showed that GelMA@β-CD@KGN could promote the proliferation of nucleus pulposus cells.(3)In the complete media with and without interleukin-1β,mRNA expression of aggrecan and type Ⅱ collagen was higher in the GelMA@β-CD@KGN microsphere group than that in the GelMA@β-CD microsphere group(P<0.05,P<0.01);mRNA expression of matrix metalloproteinase 13 and platelet reactive protein disintegrin metallopeptidase 5 was lower than that in the GelMA@β-CD microsphere group(P<0.01).(4)These findings indicate that GelMA@β-CD@KGN microspheres have good biocompatibility and sustained drug release ability.As a drug delivery system,it is a kind of biomaterial with broad application prospects.
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BACKGROUND:At present,nanocomposite gelatin methacryloyl hydrogels have been extensively studied in bone tissue engineering. OBJECTIVE:To review the latest research progress of nanocomposite gelatin methacryloyl hydrogels,and introduce the application of nanocomposite gelatin methacryloyl hydrogels in different bone defect environments. METHODS:The computer retrieval was conducted for relevant literature published in CNKI,WanFang,PubMed,and Web of Science databases from 2016 to 2023.The Chinese and English search terms were"gelatin,methacryl*,nano*,bone,bone tissue engineering,bone regeneration,osteogenesis". RESULTS AND CONCLUSION:(1)Up to now,inorganic nanomaterials,organic nanomaterials and organic-inorganic hybrid nanomaterials are the main nanomaterials used as fillers for gelatin methacryloyl.(2)Inorganic nanomaterials enhance the mechanical strength of gelatin methacryloyl,improve its thixotropic properties and degradation rate,and realize the antibacterial,osteogenic,immunoregulatory,angiogenic and other functions of gelatin methacryloyl hydrogel through its surface charge regulation,drug/factor loading,metal ion self-degradation release,etc.(3)Organic nanomaterial and organic-inorganic hybrid nanomaterial composite gelatin methacryloyl hydrogel are two emerging materials.At present,there are relatively few studies,but from the published research,compared with inorganic nanomaterial gelatin methacryloyl hydrogel,organic nanomaterial gelatin methacryloyl hydrogel has better biocompatibility and drug-loading performance.The interaction between nano phase and organic polymer phase is stronger,and the dispersion of nano particles is better.(4)Organic-inorganic hybrid nanomaterial composite gelatin methacryloyl combines the advantages of the previous two,and has better controllability of metal ion release,which proves great research potential.(5)Nanomaterials can enhance the antibacterial,immune regulation,osteogenesis and other biological properties of gelatin methacryloyl,so as to promote bone regeneration in the complex bone defect microenvironment,such as infected bone defect,diabetes,osteosarcoma resection and so on.However,the relevant research of nanocomposite gelatin methacryloyl hydrogel in bone repair is still limited to animal experiments.Further safety testing and clinical studies are still needed.
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BACKGROUND:Gold nanoparticles are of great significance in the development of multifunctional transdermal drug delivery systems.Smaller gold nanoparticles can penetrate the dermis through the intercellular pathway,but are limited to their easy agglomeration and colloidal morphology,which makes it difficult to exert effects on low delivery efficiency. OBJECTIVE:To develop an ultrasound-optimized hydrogel delivery system by combining phase change nanodroplets with bio-adhesive hydrogel for percutaneous delivery of gold nanoparticles. METHODS:The ultrasound-responsive nanodroplets loaded with gold nanoparticles were prepared by the emulsion solvent evaporation method and loaded into the polydopamine-modified methylacryloyl gelatin hydrogel to prepare a composite hydrogel scaffold.The structure and chemical composition of the ultrasound-responsive nanogold carrier were characterized.The microstructure,porosity,permeability,rheology,in vitro hemostasis,and antibacterial properties of the composite hydrogel were characterized.The cell compatibility of the hydrogel scaffold was evaluated by live/dead staining,and the optimization effects of low-intensity pulsed ultrasound on the permeability,porosity,and mechanical properties of hydrogel were evaluated. RESULTS AND CONCLUSION:(1)Transmission electron microscopy and ultraviolet-visible spectroscopy proved the successful construction of nanogold carriers.The particle size and potential results demonstrated that the synthesized nanoscaled ultrasonic responsive carrier had good stability.(2)Live/dead cell staining proved that the prepared composite hydrogel scaffold had certain biocompatibility.(3)Scanning electron microscopy exhibited that the prepared composite hydrogel scaffold had a porous network structure,and numerous pores of about 2 μm appeared inside the macropores after the addition of nanodroplets and ultrasonic irradiation.The permeability experiment displayed that low-intensity pulsed ultrasound could optimize the porosity and permeability of hydrogel materials.The hemostatic performance of the composite hydrogel scaffold was better than that of the hemostatic sponge and polydopamine@methylacrylylated gelatin hydrogel scaffold.Under the irradiation of low-intensity pulsed ultrasound,the composite hydrogel scaffolds had good antioxidant effects and antibacterial properties.(4)Thermal imaging results manifested that gold nanoparticles were encapsulated in ultrasound-responsive nanobubbles,and more uniform dispersion could be obtained under ultrasonic excitation.(5)The results of the mechanical property test demonstrated that the storage modulus of the hydrogel increased before and after loading gold nanoparticles-nanodroplets,which showed stronger mechanical properties.The elongation at break was 122%,and the ductility was better than that without gold nanoparticles-nanodroplets(P<0.05).(6)These findings indicate that the composite hydrogel scaffold has good biocompatibility,antibacterial property,oxidation resistance,and hemostatic effect.
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BACKGROUND:Titanium and its alloys are widely used in orthopedic implants due to their excellent biocompatibility,corrosion resistance,and mechanical properties.However,it has biological inertia itself,cannot provide a good growth environment for osteoblasts,and it is difficult to form good osseointegration. OBJECTIVE:To construct a composite hydrogel material of gelatin methacryloyl and polyacrylamide on the surface of titanium alloy scaffold,and analyze its osteogenic ability in vitro. METHODS:Gelatin methacryloyl was mixed with acrylamide.Crosslinking agent and catalyst were added to synthesize gelatin methacryloyl and acrylamide(Gelma-PAAM)composite hydrogel.The titanium alloy scaffold modified by affinity silane was mixed with the Gelma hydrogel and Gelma-PAAM composite hydrogel to complete the loading(recorded as Ti-Gelma and Ti-Gelma-PAAM,respectively).The swelling ratio and degradation rate of the two hydrogels on the surface of the scaffold were compared.The bonding state between hydrogels and titanium alloy was observed by scanning electron microscope.Rat bone marrow mesenchymal stem cells were inoculated into Ti,Ti-Gelma and Ti-Gelma-PAAM scaffolds,separately.Cell proliferation,adhesion,and osteogenic differentiation were detected. RESULTS AND CONCLUSION:(1)Compared with Gelma hydrogel,Gelma-PAAM hydrogel had higher swelling rate and lower degradation rate.(2)Scanning electron microscope showed that the surface of the two kinds of hydrogels was honeycomb structure.After being combined with porous titanium alloy scaffold,the film was wrapped on the surface of scaffold and filled with pores.Among them,the Gelma-PAAM composite hydrogel coated the scaffold more fully.(3)CCK-8 assay and live/dead fluorescence staining showed that bone marrow mesenchymal stem cells proliferated well after coculture with Ti-Gelma and Ti-Gelma-PAAM scaffolds and maintained high activity.After osteogenic induction culture,alkaline phosphatase activity,calcium deposition,and osteogenic gene expression of cells of titanium alloy scaffold group were the lowest,and alkaline phosphatase activity,calcium deposition,and osteogenic gene expression of cells of Ti-Gelma-PAAM scaffold group were the highest.(4)Phalloidin cytoskeletal staining exhibited that the cells of pure titanium alloy scaffold group and Ti-Gelma scaffold group were sparse and insufficiently extended,while the cells of Ti-Gelatin-PAAM group had the most adequate stretching and the densest filamentous actin.(5)The results show that Gelma-PAAM hydrogel has good biocompatibility and osteogenic ability,and is more suitable for osteogenic modification on the surface of titanium alloy than Gelma hydrogel.
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BACKGROUND:Combining seed cells with 3D bioprinting technology enables the specific construction of various tissues and organs to meet the demands of tissue repair.However,further research is needed on the promotion of angiogenesis in damaged tissues. OBJECTIVE:By cultivating a 3D scaffold structure of methacrylated gelatin loaded with fibroblasts,obtaining the supernatant,and mixing it in different proportions with a complete culture medium to simulate the cellular microenvironment during tissue repair,this study aimed to explore the role of various cellular microenvironments in promoting angiogenesis in endothelial cells. METHODS:A methacrylated gelatin scaffold structure loaded with fibroblasts was prepared using an extrusion-based 3D bioprinting process.Hydrogel scaffold extract was prepared and mixed with a complete culture medium in ratios of 1:1,1:2,and 1:4 to obtain conditioned medium.Mouse embryonic fibroblasts BALB3T3 and human umbilical vein endothelial cells were co-cultured with complete medium(control group)and hydrogel scaffold extract,respectively.Cell proliferation was assessed using the CCK-8 assay and cell viability was analyzed using live/dead staining.Three kinds of conditioned medium and complete medium(control group)were used to co-culture with human umbilical vein endothelial cells for tube formulation assay,vascular genetic testing,and immunofluorescence staining of CD31. RESULTS AND CONCLUSION:(1)Scanning electron microscopy revealed that the methacrylated gelatin scaffold exhibited a porous structure,and rheological results demonstrated excellent mechanical properties of the hydrogel.CCK-8 assay and live/dead cell staining showed that the hydrogel scaffold extract had no obvious cytotoxicity.(2)Tube formulation assay indicated that the hydrogel showed the total length of cell tubules in 1:1 conditioned medium group was smaller than that in the control group(P<0.05).There were no statistical differences among the four groups in the number of vascular branches formed by endothelial cells(P>0.05).(3)qRT-PCR results showed that for vascular endothelial growth factor mRNA expression,the 1:2 conditioned medium group was lower than the 1:1 conditioned medium group on day 1(P<0.01).On day 3,the expression level of vascular endothelial growth factor in the 1:2 conditioned medium group was higher than that in the control group(P<0.01).On day 5,the cytokine expression level in the 1:2 conditioned medium group was significantly higher than that in the other three groups(P<0.01 or P<0.000 1).The expression in the 1:1 conditioned medium group was significantly lower than that in the other three groups(P<0.05 or P<0.01).On day 1,the expression level of basic fibroblast growth factor in the 1:1 conditioned medium group was significantly higher than that in the control group and 1:4 conditioned medium group(P<0.01,P<0.05).The expression was higher in the 1:2 conditioned medium group than that in the control group(P<0.05).On day 3,the expression levels of cytokines in the 1:4 conditioned medium group was higher than that in the control group(P<0.05).(4)On day 3,the expression of CD31 in the 1:2 conditioned medium group was higher than that in the control group and the 1:4 conditioned medium group(P<0.05).(5)The results indicate that the resulting conditioned media can simulate the microenvironment of vascular regeneration after tissue damage,promoting the vascularization process of endothelial cells.The best promotion of vascularization in endothelial cells was observed when the ratio of supernatant to complete culture medium was 1:2.
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BACKGROUND:Pulp regeneration has been a hot and difficult research topic in recent years,and the construction of composite bio-scaffolding materials provides new ideas and methods for pulp regeneration. OBJECTIVE:To observe the effect of freeze-dried gelatin modified by methacrylic anhydride/treated dentin matrix bioactive scaffolds on proliferation,migration,and osteogenic differentiation of human dental pulp stem cells. METHODS:The mass ratios of gelatin modified by methacrylic anhydride and treated dentin matrix at 2:1,1:1 and 1:2 were obtained by dispersing different masses of treated dentin matrix into gelatin modified by methacrylic anhydride solution.The gelatin modified by methacrylic anhydride/treated dentin matrix bioactive scaffolds were prepared by vacuum freeze-drying.The microstructure,water absorption,and mechanical properties of the scaffolds were measured.Human dental pulp stem cells were cultured with different mass ratios of scaffold extract and DMEM(control group)to detect cell proliferation and migration.Human dental pulp stem cells were cultured with different mass ratios of scaffold extract + osteogenic induction solution and DMEM + osteogenic induction solution(control group),and their osteogenic ability was analyzed by alkaline phosphatase staining. RESULTS AND CONCLUSION:(1)Under scanning electron microscopy,the scaffolds of the three groups all had porous structures.The porosity of the scaffolds increased with the increase of treated dentin matrix quality,and there was significant difference between the two groups(P<0.05).The water absorption of scaffolds increased with the increase of treated dentin matrix mass,and there was significant difference between groups(P<0.05).The compressive strength and shear strength of the scaffold increased with the increase of the mass of treated dentin matrix.(2)CCK-8 assay showed that after 3,5,and 7 days of culture,the cell proliferation absorbance values in the 2:1,1:1,and 1:2 scaffold groups were higher than those in the control group(P<0.05).The cell proliferation absorbance values increased with the increase of treated dentin matrix mass in the scaffold(P<0.05).The cell scratch test showed that the cell migration rate in the 2:1,1:1,and 1:2 scaffold groups was higher than that in the control group(P<0.05),and the cell migration rate increased with the increase of treated dentin matrix mass in the scaffold(P<0.05).(3)Alkaline phosphatase staining showed that the osteogenic differentiation ability of cells in the 2:1,1:1,and 1:2 scaffold groups was stronger than that in the control group,and the osteogenic ability of cells was enhanced with the increase of treated dentin matrix mass in the scaffold.(4)The results showed that the scaffold with a mass ratio of 1:2 between gelatin modified by methacrylic anhydride and treated dentin matrix was the most suitable for the proliferation and differentiation of dental pulp stem cells.
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BACKGROUND:The treatment of bone defects has always been a pressing clinical challenge for medical practitioners.The use of gelatin methacryloyl for three-dimensional extracellular cultivation offers a promising direction for the treatment of extensive bone defects. OBJECTIVE:To review the research progress of gelatin methacryloyl as a three-dimensional cell culture scaffold in bone tissue engineering,aiming to provide further references for clinical bone defect repair. METHODS:Computerized searches were conducted on the CNKI and PubMed databases for articles published from January 1986 to August 2023.The search terms in Chinese and English were"bone defect,bone tissue engineering,biomaterial scaffold,hydrogel,photocrosslinked hydrogel,gelatin methacryloyl,three-dimensional culture,cell culture"and"bone defect,bone tissue engineering,biomaterial scaffold,hydrogel,gelatin methacryloyl,three-dimensional culture,cell culture",respectively.Finally,68 articles were included for review and analysis. RESULTS AND CONCLUSION:(1)When compared to two-dimensional culture techniques,three-dimensional culture can construct a three-dimensional space under aseptic conditions,more effectively simulating the in vivo environment.It provides cells with the appropriate temperature,pH,and sufficient nutrients,allowing cells to grow and proliferate normally outside the body while maintaining their regular structure and function,offering unique advantages.(2)In the realm of bone tissue engineering,hydrogels stand out as the preferred choice for biomaterial scaffolds.Their excellent biocompatibility,degradability,and inherent three-dimensional network structure make them invaluable in bone regeneration studies.(3)The physical and biological properties of gelatin methacryloyl are influenced by factors such as concentration,light exposure duration,type of photoinitiator,and the overall reaction system.These properties can affect cell adhesion,growth,and proliferation,and even the morphology and function of cells.(4)Gelatin methacryloyl,recognized for its excellent biocompatibility,tunable physical properties,injectability,and photosensitivity,has been extensively used in three-dimensional cell encapsulation,three-dimensional bioprinting,and stereolithography techniques based on digital light processing in three-dimensional cell culture systems.(5)Utilizing a range of composite gelatin methacryloyl in three-dimensional cell culture can significantly promote vascularization and bone regeneration,paving the way for enhanced clinical solutions to bone defects.(6)At present,there is a noticeable gap in standardized guidelines concerning the sources,synthesis methods,and safety of gelatin methacryloyl.It is crucial to intensify research efforts to optimize gelatin methacryloyl's application in the three-dimensional cell culture field.
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The study aimed to evaluate the therapeutic effect of nilotinib-loaded biocompatible gelatin methacryloyl (GelMA) microneedles patch on cardiac dysfunction after myocardial infarction(MI), and provide a new clinical perspective of myocardial fibrosis therapies. The GelMA microneedles patches were attached to the epicardial surface of the infarct and peri-infarct zone in order to deliver the anti-fibrosis drug nilotinib on the 10th day after MI, when the scar had matured. Cardiac function and left ventricular remodeling were assessed by such as echocardiography, BNP (brain natriuretic peptide) and the heart weight/body weight ratio (HW/BW). Myocardial hypertrophy and fibrosis were examined by WGA (wheat germ agglutinin) staining, HE (hematoxylin-eosin staining) staining and Sirius Red staining. The results showed that the nilotinib-loaded microneedles patch could effectively attenuate fibrosis expansion in the peri-infarct zone and myocardial hypertrophy, prevent adverse ventricular remodeling and finally improve cardiac function. This treatment strategy is a beneficial attempt to correct the cardiac dysfunction after myocardial infarction, which is expected to become a new strategy to correct the cardiac dysfunction after MI. This is of great clinical significance for improving the long-term prognosis of MI patients.
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Humanos , Infarto del Miocardio/tratamiento farmacológico , Cardiomegalia , Péptido Natriurético Encefálico/uso terapéutico , Fibrosis , Miocardio/patologíaRESUMEN
Gelatin microspheres were discussed as a scaffold material for bone tissue engineering, with the advantages of its porosity, biodegradability, biocompatibility, and biosafety highlighted. This review discusses how bone regeneration is aided by the three fundamental components of bone tissue engineering-seed cells, bioactive substances, and scaffold materials-and how gelatin microspheres can be employed for in vitro seed cell cultivation to ensure efficient expansion. This review also points out that gelatin microspheres are advantageous as drug delivery systems because of their multifunctional nature, which slows drug release and improves overall effectiveness. Although gelatin microspheres are useful for bone tissue creation, the scaffolds that take into account their porous structure and mechanical characteristics might be difficult to be created. This review then discusses typical techniques for creating gelatin microspheres, their recent application in bone tissue engineering, as well as possible future research directions.
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Ingeniería de Tejidos/métodos , Andamios del Tejido/química , Gelatina/química , Microesferas , Huesos , PorosidadRESUMEN
Objective To compare the clinical efficacy and safety of gelatin sponge particles,gelatin sponge strips,and spring coil combined with gelatin sponge particles in preoperative interventional embolization for spinal tumors.Methods The clinical data of a total of 92 patients with spinal tumor,who received preoperative interventional embolization before spinal tumor surgery at the Affiliated Zhongshan Hospital and Xiamen Branch of Fudan University of China between June 2012 and June 2022,were collected.According to the different embolization materials used during the interventional embolization,the patients were divided into gelatin sponge particle group(ni=36),gelatin sponge strip group(n=36),and spring coil plus gelatin sponge particle group(n=20).Kruskal-Wallis testing was used to compare the intraoperative bleeding volume among the three groups,and Fisher's exact probability testing was used to compare the incidence of complications among the three groups.Results Successful surgical resection of the spinal tumor was accomplished in all patients.The median intraoperative bleeding volumes in gelatin sponge particle group,gelatin sponge strip group,and spring coil plus gelatin sponge particle group were 400 mL(200-950 mL),1 000 mL(513-2000 mL),and 1000 mL(500-1350 mL)respectively.The intraoperative bleeding volume in the gelatin sponge particle group was significantly smaller than that in the gelatin sponge strip group(P=0.000 8)and in the spring coil plus gelatin sponge particle group(P=0.002 7),the differences were statistically significant.After operation,4 patients in the gelatin sponge particle group developed incision infection or local abscess formation,one patient in the gelatin sponge strip group developed incision dehiscence,and one patient in the spring coil plus gelatin sponge particle group had postoperative local hematoma at the incision site.No statistically significant difference in the incidence of complications existed between each other among the three groups(all P>0.05).Conclusion For interventional embolization of spinal tumor,all of the gelatin sponge particles,gelatin sponge strips,and spring coils are clinically safe and effective.However,in reducing the amount of blood loss during surgery the superselective catheterization with embolization of tumor-feeding arteries using gelatin sponge particles is superior to the non-superselective catheterization with embolization of tumor-feeding arteries using gelatin sponge strips or combination use of gelatin sponge particles and spring coils.(J Intervent Radiol,2023,32:1184-1189)
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Objective:This study aimed to investigate the physical properties, biocompatibility, and 3D printing performance of a novel hybrid bioink composed of gelatin methacrylated (GelMA) and chitin nanocrystal (ChiNC).Methods:The study was conducted from May 2021 to December 2022, four different bioinks were prepared by adding varying amounts of ChiNC to GelMA bioink. The GelMA concentration in all four bioinks was 100 mg/ml, while the ChiNC concentrations were 0 mg/ml (no ChiNC added), 5 mg/ml, 10 mg/ml, and 20 mg/ml, respectively, named as GC0, GC5, GC10, and GC20 bioinks. The cross-sectional morphology of the hydrogels formed after photocuring the four bioinks was observed using scanning electron microscopy, and the porosity was calculated. Weighing the hydrogels before and after swelling, and then calculate the equilibrium swelling rate. HUVECs were seeded on the surfaces of the hydrogels prepared from the four bioinks and cultured in medium. Cell proliferation was assessed using CCK-8 assays at 1d, 3d, and 7d to compare the proliferation rates of cells on the four hydrogels. HUVECs were added to the four bioinks, and grid-like scaffolds were printed and cultured in medium. Live-Dead staining was performed at 1d and 7d to observe cell viability. Compare the printing effect of bioinks by observing its forming continuous threads properties during extrusion. Finally, tissue-engineered bladder patches simulating the mucosal layer, submucosal layer, and muscular layer anatomical structures of the bladder wall were 3D bioprinted using the optimized bioink composition, and the stability and fidelity of the printed structures were observed to further validate the feasibility of printing multi-layered complex structures with the bioink.Results:Scanning electron microscopy revealed that the porosity of the GC0, GC5, GC10, and GC20 hydrogels were (51.43±6.23)%, (51.85±6.47)%, (50.55±4.59)%, and (42.49±2.20)%, respectively. The differences in porosity between the GC0 group and the other three groups were not statistically significant ( P=0.9994, P=0.9948, P=0.1200). The equilibrium swelling ratio of the other three groups [(8.81±0.41), (7.95±0.19), (7.71±0.14)] was significantly lower than that of the GC0 group (9.37 ± 0.49), and the differences were statistically significant ( P=0.0457, P<0.01, P<0.01). CCK-8 assay showed no significant difference in absorbance value between the GC10 group (0.360±0.009) and the GC0 group (0.357±0.007), GC5 group (0.350±0.012), and GC20 group (0.345±0.018) on the first day ( P=0.9332, P=0.5464, P=0.4937). However, on the third day, the absorbance value of the GC10 group (0.755±0.012) was significantly higher than that of the GC0 group (0.634±0.010), GC5 group (0.704±0.009), and GC20 group (0.653±0.015) ( P<0.01, P=0.0033, P=0.0002). On the seventh day, the absorbance value of the GC10 group (1.001±0.031) was significantly higher than that of the GC0 group (0.846±0.026), GC5 group (0.930±0.043), and GC20 group (0.841±0.024)( P=0.0012, P=0.1390, P=0.0010). The addition of human umbilical vein endothelial cells (HUVECs) into the four groups of hydrogels enabled the printing of grid-like scaffolds, and Live-Dead staining was performed on day 1 and day 7. The cell viability of HUVECs in the four groups on day 1 was (90.13±1.63)%, (90.6±2.45)%, (92.58±2.15)%, and (91.40±3.17)%, respectively. There were no statistically significant differences between the GC0 group and the other three groups ( P=0.9869, P=0.3093, P=0.8008). On day 7, the cell viability was (89.97±3.10)%, (92.18±2.21)%, (92.05±2.25)%, and (90.12±1.97)% for the four groups, respectively. There were no statistically significant differences between the GC0 group and the other three groups ( P=0.3965, P=0.4511, P=0.9995). Bioink extrusion test showed that the GC0 hydrogel could be extruded continuously and form threads at temperatures between 24℃ and 25℃, while the GC10 hydrogel could be extruded continuously and form threads at temperatures between 24℃ and 27℃. Printing tissue engineered bladder patches simulating the anatomical structure of the bladder mucosal layer, submucosal layer, and muscular layer using GC10 bioink, and the printed patches were stable, without collapse, and had high fidelity. Conclusions:Adding ChiNC to GelMA promotes cell adhesion, proliferation, and expands the printing window of GelMA bioink. The biocompatibility of the mixed bioink prepared by adding 10 mg/ml ChiNC in GelMA is good, capable of printing tissue-engineered bladder patches that mimic the anatomical structure of natural bladder walls.
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Objective:To prepare chitosan/gelatin hydrogel composite hemostatic materials loaded with Panax notoginseng (PN/CMC/GMs) and evaluate their performance. Methods:PN/CMC/GMs hydrogel composite hemostatic material were prepared by the freeze-drying method, and their morphology was observed by scanning electron microscopy. Their rheological properties were observed by a rheometer. Their water absorption rate was tested by dissolution. Their biocompatibility was detected by a cytotoxicity assay. Their rapid hemostatic effect was tested using a SD rat liver hemorrhage model.Results:PN/CMC/GMs composite hemostatic materials were prepared in a lattice-like structure with certain porosity. With the increase in Panax notoginseng powder content, the modulus of PN/CMC/GMs increased accordingly, and the mechanical strength increased. PN/CMC/GMs have better water absorption and expansion functions, which can form compression hemostasis and concentrated blood to achieve rapid hemostasis, and have good biocompatibility. Hemostasis experiments showed that the hemostatic time and hemostatic effect of PN, CMC/GMs hemostatic materials on liver injury in rats were better than those of the blank control group. Conclusions:PN/CMC/GMs have good hemostatic effect and biocompatibility and have the potential for further research and clinical application.
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Objective@#To prepare an adhesive hemostatic hydrogel and examine its hemostatic performance and biocompatibility.@*Methods@#The precursor components were homogenously dissolved and photo-crosslinked in order to form dual-network hydrogel.The electron microscopy morphology was then analyzed ; mechanical properties were tested ; in vitro hemostatic performances were investigated by whole blood clotting test and simulation trial of cutaneous bleeding.Further,the hemocompatibility was evaluated. @*Results@#A characteristic porous network structure was presented through microscopy observation of the sample.The tensile strength of hydrogel reached 46 kPa,and strong adhesion was achieved between the hydrogel and ex vivo biological tissues.Hydrogel had significant effect on wound closure and clotting time could be shortened to 1 minute.@*Conclusion@#The hydrogel was capable of accelerating coagulation due to its ability to accumulate platelets and red cells after blood contact.The dual-network hydrogel with good hemocompatibility enabled excellent hemostatic performance by the synergistic effects of the chemical activation mechanism and physical hemostatic effect.
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Introduction: Endo-periodontal lesions can lead to the formation of severe intraosseous defects in the periodontium; which can lead to tooth loss. Objective: Demonstrate that surgical periodontal therapy with the help of gelatin sponges, with colloidal silver nanoparticles, restores bone tissue lost in endo-periodontal lesions. Case presentation: 55-year-old male patient without systemic alterations, diagnosed with grade 3 endo-periodontal lesion in patients with periodontitis. It was treated first with ducts and then with periodontal surgery combined with gelatin sponges, which contain colloidal silver nanoparticles, and were placed filling the 2-wall bone defect involving > 80 percent of the root length, with 24 months of radiographic and clinical follow-up. Conclusions: Based on the case report, surgical periodontal therapy and filling of bone defects with gelatin sponges, which contain colloidal silver nanoparticles, were sufficient to restore the lost bone at a 24-month follow-up. However, further studies are needed to assess the clinical benefit of this material for the treatment of intraosseous defects(AU)
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Humanos , Masculino , Persona de Mediana Edad , Periodontitis/diagnóstico , Pérdida de Hueso Alveolar/terapia , Esponja de Gelatina Absorbible/efectos adversosRESUMEN
Background: Management of posterior scleral perforation is commonly done with cryotherapy/laser or scleral patch graft depending on the size of perforation. However, for large perforations, the availability of donor sclera is always an issue. To overcome this problem, we tried using absorbable gelatin sponge to plug the perforation as an alternative. Purpose: To evaluate the efficacy of gelatin foam as an alternative to scleral patch graft in cases with perforation of posterior sclera. Synopsis: Here we report the case of a 27?year?old male, who sustained penetrating injury to right eye with two metallic intraocular foreign bodies with visual acuity of hand movement close to face. Primary wound repair was done, followed by retrieval of the first piece of metallic foreign body that measured 11X3mm in size. The second foreign body visualized at posterior pole adjascent to the disc was removed using Machemar forceps and it measured 10X3 mmin size. Leakage of PFCL at the site confirmed a posterior scleral perforation. Cryotherapy was avoided due to its proximity to optic nerve head, and donor sclera was not readily available at that moment. We managed the case by plugging the defect with absorbable gelatin foam, followed by silicone oil injection into the vitreous cavity. Post operative outcome was good with restoration of anatomical integrity of the globe along with improvement in visual acuity upto 6/18. Highlights: Gelatin foam being absorbable and inciting less reaction aids in sealing the perforation and maintenance of globe contour with the advantage being readily available, cost?effective and it can be left in situ without the need for additional surgery for its removal. This would be of use in situations where the donor sclera is not readily available, and thus can be a potential alternative. However, further studies with larger sample size need to be done to evaluate and compare its effectiveness over donor scleral grafts
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Abstract Introduction Traumatic large tympanic membrane perforations usually fail to heal and require longer healing times. Few studies have compared the healing and hearing outcomes between gelatin sponge patching and ofloxacin otic solution. Objectives To compare the healing outcomes of large traumatic tympanic membrane perforations treated with gelatin sponge, ofloxacin otic solution, and spontaneous healing. Methods Traumatic tympanic membrane perforations >50% of the entire eardrum were randomly divided into three groups: ofloxacin otic solution, gelatin sponge patch and spontaneous healing groups. The healing outcome and hearing gain were compared between the three groups at 6 months. Results A total of 136 patients with large traumatic tympanic membrane perforations were included in analyses. The closure rates were 97.6% (40/41), 87.2% (41/47), and 79.2% (38/48) in the ofloxacin otic solution, gelatin sponge patch, and spontaneous healing groups, respectively (p = 0.041). The mean times to closure were 13.12 ± 4.61, 16.47 ± 6.24, and 49.51 ± 18.22 days in these groups, respectively (p < 0.001). Conclusions Gelatin sponge patch and ofloxacin otic solution may serve as effective and inexpensive treatment strategies for traumatic large tympanic membrane perforations. However, ofloxacin otic solution must be self-applied daily to keep the perforation edge moist, while gelatin sponge patching requires periodic removal and re-patching.
Resumo Introdução As grandes perfurações traumáticas da membrana timpânica geralmente apresentam falha de cicatrização e requerem tempos de cicatrização mais longos; poucos estudos compararam os resultados de cicatrização e a audição dessas perfurações obtidos com curativo de Gelfoam® e solução otológica de ofloxacina. Objetivo Comparar os resultados de cicatrização de grandes perfurações traumáticas da membrana timpânica tratadas com Gelfoam®, solução otológica de ofloxacina e cicatrização espontânea. Método Perfurações traumáticas de > 50% de todo o tímpano foram divididas aleatoriamente em três grupos: tratamento com solução otológica de ofloxacina, com curativo de Gelfoam® e grupo de cicatrização espontânea. O resultado da cicatrização e o ganho auditivo foram comparados entre os três grupos após 6 meses. Resultados Foram incluídos nas análises 136 pacientes com grandes perfurações traumáticas de membrana timpânica. As taxas de cicatrização foram de 97,6% (40/41), 87,2% (41/47) e 79,2% (38/48) com a solução otológica de ofloxacina, curativo de Gelfoam® e grupos de cicatrização espontânea, respectivamente (p = 0,041). O tempo médio de cicatrização foi de 13,12 ± 4,61, 16,47 ± 6,24 e 49,51 ± 18,22 dias nesses grupos, respectivamente (p < 0,001). Conclusões O curativo de Gelfoam® e a solução otológica de ofloxacina podem servir como estratégias de tratamento eficazes e de baixo custo para grandes perfurações traumáticas de membrana timpânica. Entretanto, a solução otológica de ofloxacina deve ser autoaplicada diariamente para manter a borda da perfuração úmida, enquanto o curativo de Gelfoam® requer sua remoção e reaplicação periódicas.