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Abstract Tissue engineering suggests different forms to reconstruct tissues and organs. One of the ways is through the use of polymeric biomaterials such as poly(L-lactic acid) (PLLA). PLLA is a recognized material in tissue engineering due to its characteristics as biocompatibility and bioresorbability. In this work PLLA fibrous membranes were produced by a simple technique known as rotary jet spinning. The rotary jet spinning consists of fibrous membranes production, with fibers of scale nano/micrometric, from a polymeric solution through the centrifugal force generated by the equipment. The membranes formed were subjected to preliminary in vitro assays to verify the cytotoxicity of the membranes made in contact with the cells. Direct cytotoxicity assays were performed through the MTT, AlamarBlue® and Live/Dead® tests, with fibroblastic and osteoblastic cells. The results obtained in this study showed that PLLA membranes produced by rotary jet spinning showed promising results in the 24-hours contact period of the cells with the PLLA fibrous membranes. The information presented in this preliminary study provides criteria to be taken in the future procedures that will be performed with the biomaterial produced, aiming at its improvement.
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Biocompatible Materials , Lactic Acid , Tissue Engineering/methods , In Vitro Techniques/instrumentationABSTRACT
Objective: To investigate the effect of poly (L-lactic acid caprolactone) (PLCL) /gelatin electrospinning on the angiogenesis differentiation of endothelial progenitor cells (EPCs). Methods: Rat bone marrow-derived EPCs were isolated and cultured, then identification was performed. After preparation of PLCL/gelatin blend electrospun scaffold, scanning electron microscopy and water contact angle test were carried out. EPCs were grown on PLCL/gelatin electrospinning and CCK8 was used to detect cell proliferation. The expression of vascular endothelial growth factor (Vegf ) and kinases insert region receptor (Kdr) was observed by RT-PCR and the expression of VEGF protein was observed by Western blotting. Results: The density gradient centrifugation combined with differential adherence method could effectively isolate EPCs. PLCL/gelatin electrospun nanofibers were porous, and the hydrophilic properties were favorable for cell adhesion, and EPCs grew well on the scaffold. The expression of Vegf and Kdr gene in PLCL/gelatin group was higher than that in control group (P=0.000), and the expression of VEGF protein was also increased (P=0.000). Conclusion: PLCL/gelatin is an ideal scaffold for tissue engineering, and it can promote the angiogenesis differentiation of EPCs.
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Objective · To investigate the effect of poly (L-lactic acid caprolactone) (PLCL)/gelatin electrospinning on the angiogenesis differentiation of endothelial progenitor cells (EPCs).Methods· Rat bone marrow-derived EPCs were isolated and cultured,then identification was performed.After preparation of PLCL/gelatin blend electrospun scaffold,scanning electron microscopy and water contact angle test were carried out.EPCs were grown on PLCL/gelatin electrospinning and CCK8 was used to detect cell proliferation.The expression of vascular endothelial growth factor (Vegf) and kinases insert region receptor (Kdr) was observed by RT-PCR and the expression of VEGF protein was observed by Western blotting.Results· The density gradient centrifugation combined with differential adherence method could effectively isolate EPCs.PLCL/gelatin electrospun nanofibers were porous,and the hydrophilic properties were favorable for cell adhesion,and EPCs grew well on the scaffold.The expression of Vegfand Kdr gene in PLCL/gelatin group was higher than that in control group (P=0.000),and the expression of VEGF protein was also increased (P=0.000).Conclusion · PLCL/gelatin is an ideal scaffold for tissue engineering,and it can promote the angiogenesis differentiation of EPCs.
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Biodegradable vascular stent, also known as the third generation stent, has recently been widely studied. Finite element models of three stents with the same structure and different specifications were developed. The mechanical behavior under crimping, expanding and fatigue testing were assessed by von Mises yield and Goodman convergence. The maximum stress during crimping, expanding and fatigue testing were all observed in the stent with the largest size. The results indicated that the largest stent had the highest risk of failure and also provided theoretical evidence for the worst case scenario in the fatigue testing.
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Finite Element Analysis , Polyesters , Stents , Stress, MechanicalABSTRACT
Objective: To explore the effect of silk fibroin/poly( L-lactic acid-co-e-caprolactone) [SF/P(LLA-CL)] nanofibrous scaffold on tendon-bone healing of rabbits.
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Some gel types have been reported to prevent left ventricular (LV) remodeling in myocardial infarction (MI) animal models. In this study, we tested biodegradable thermoresponsive gels. Poly(L-lactic acid)-poly(ethylene glycol) (PLLA-PEG) and poly(D-lactic acid)-poly(ethylene glycol) (PDLA-PEG) were synthesized by the polycondensation of Land D-lactic acids in the presence of PEG and succinic acid. Each of these block copolymers was used to prepare particles dispersed in an aqueous medium and mixed together to obtain a PLLA-PEG/PDLA-PEG suspension, which was found to show a sol-to-gel transition around the body temperature by the stereocomplex formation of enantiomeric PLLA and PDLA sequences. In the present study, the G' of the PLLA-PEG/PDLA-PEG suspension in the rheological measurement remained as low as 1 Pa at 20 ℃ and increased 2 kPa at 37 ℃. The sol-gel systems of PLLA-PEG/PDLA-PEG might be applicable to gel therapy. The effect of the PLLA-PEG/PDLA-PEG gel injection was compared with that of a calciumcrosslinked alginate gel and saline in a rat MI model. The percent fractional shortening improved in the PLLA-PEG/ PDLA-PEG (20.8 ± 4.1%) and alginate gel (21.1 ± 4.8%) compared with the saline (14.2 ± 2.8%) with regard to the echocardiograph 4 weeks after the injection (p<0.05). There were reduced infarct sizes in both PLLA-PEG/PDLA-PEG gel and alginate gel compared with the saline injection (p<0.05). Moreover, a greater reduction in LV cavity area was observed with the PLLA-PEG/PDLA-PEG gel than with the alginate gel (p = 0.06). These results suggest that the PLLA- PEG/PDLA-PEG gel should have high therapeutic potential in gel therapy for LV remodeling after MI.
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Animals , Rats , Body Temperature , Gels , Lactic Acid , Models, Animal , Myocardial Infarction , Succinic Acid , Ventricular RemodelingABSTRACT
In this study, an attempt was made to develop bi-functional constructs serving both as scaffolds and potential delivery systems for application in neural tissue engineering. The constructs were prepared in two steps. In the first step, the bulks of poly (L-lactic acid) (PLLA) in 1, 4-dioxane/water (87:13) were fabricated using liquid-liquid thermally induced phase separation technique. In the next step, the prepared bulks were coated with chitosan nanoparticles produced by two different techniques of ultrasonication and ionic gelation by grafting-coating technique. In ultrasonication technique, the chitosan solution (2 mg/mL) in acetic acid/sodium acetate buffer (90:10) was irradiated by an ultrasound generator at 20 kHz and power output of 750 W for 100 s. In ionic gelation technique, the tripolyphosphate in water solution (1 mg/mL) was added to the same chitosan solution. The physicochemical properties of the products were characterized by Scanning Electron Microscopy, Attenuated Total Reflection Fourier Transform-Infrared, liquid displacement technique, contact angle measurement, compressive and tensile tests, as well as zeta potential and particle size analysis using dynamic light scattering. Moreover, the cell proliferation and attachment on the scaffolds were evaluated through human glioblastoma cell line (U-87 MG) and human neuroblastoma cell line [BE (2)-C] culture respectively. The results showed that the samples coated with chitosan nanoparticles prepared by ultrasonication possessed enhanced hydrophilicity, biodegradation and cytocompatibility compared with pure PLLA and PLLA coated with chitosan nanoparticles prepared by ionic gelation. This study suggests successful nanoparticles-scaffold systems which can act simultaneously as potential delivery systems and tissue engineering scaffolds.
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Humans , Cell Line , Cell Proliferation , Chitosan , Dynamic Light Scattering , Glioblastoma , Hydrophobic and Hydrophilic Interactions , Microscopy, Electron, Scanning , Nanoparticles , Neuroblastoma , Particle Size , Tissue Engineering , Ultrasonography , WaterABSTRACT
For successful tissue engineering of articular cartilage, a scaffold with mechanical properties that match those of natural cartilage as closely as possible is needed. In the present study, we prepared a fibrous silk fibroin (SF)/poly(L-lactic acid) (PLLA) scaffold via electrospinning and investigated the morphological, mechanical, and degradation properties of the scaffolds fabricated using different electrospinning conditions, including collection distance, working voltage, and the SF:PLLA mass ratio. In addition, in vitro cell-scaffold interactions were evaluated in terms of chondrocyte adhesion to the scaffolds as well as the cytotoxicity and cytocompatibility of the scaffolds. The optimum electrospinning conditions for generating a fibrous SF/PLLA scaffold with the best surface morphology (ordered alignment and suitable diameter) and tensile strength (~1.5 MPa) were a collection distance of 20 cm, a working voltage of 15 kV, and a SF:PLLA mass ratio of S50P50. The degradation rate of the SF/PLLA scaffolds was found to be determined by the SF:PLLA mass ratio, and it could be increased by reducing the PLLA proportion. Furthermore, chondrocytes spread well on the fibrous SF/PLLA scaffolds and secreted extracellular matrix, indicating good adhesion to the scaffold. The cytotoxicity of SF/PLLA scaffold extract to chondrocytes over 24 and 48 h in culture was low, indicating that the SF/PLLA scaffolds are biocompatible. Chondrocytes grew well on the SF/PLLA scaffold after 1, 3, 5, and 7 days of direct contact, indicating the good cytocompatibility of the scaffold. These results demonstrate that the fibrous SF/PLLA scaffold represents a promising composite material for use in cartilage tissue engineering.
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Cartilage , Cartilage, Articular , Chondrocytes , Extracellular Matrix , Fibroins , In Vitro Techniques , Silk , Tensile Strength , Tissue EngineeringABSTRACT
Injectable poly-L-lactic acid (PLLA) is world-famous filler used in lipoatrophy and facial rejuvenation because of its collagen neogenesis effect which leads to gradual volume restoration. Until recently, quite a number of unwanted adverse events of PLLA have been reported. However, to the best of our knowledge, paraffinoma as a complication of PLLA has never been reported. We herein describe the first case of paraffinoma after Sculptra® injection and propose its possible mechanism.
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Collagen , Dermal Fillers , Eyelids , Granuloma, Foreign-Body , RejuvenationABSTRACT
Background: The incidence of placement of osteosynthetic materials has grown worldwide. Bioabsorbable materials are more commonly used now days in Orthopedic surgeries. Implants modify the risk of infection by bacterial adhesion, tissue integration, and immunomodulation. Bacterial adhesion to implant leads to interaction between bacteria and implant. Aim: To evaluate the incidence of infections associated with use of bioabsorbable implants in Orthopedic surgeries. Materials and methods: The infection rates among 1057 patients were treated with bioabsorbable osteosynthesis devices was investigated. The implant material used was PGA in approximately three fourths of the patients. Results: Depending on the bioabsorbable material used, the infection rates varied from 0.7% (SRPLLA) to 6.5% (SR-PGA and SR-PLLA together). In a comparison with metallic osteosynthesis devices, a total 522 ankle fracture patients were studied. There was no significant difference between the infection rates of the bioabsorbable fixation group (3.2%) and metallic fixation group (4.1%). The effect of bioabsorbable implants volume on wound infections showing a significant positive correlation between the incidence of infection and the implant volume when non-stained SR-PGA or SR-PLLA implants were used. In fracture patients the raising of the implant-bone volume ratio correlated with the rising incidence of infection. Conclusion: Increasing the implant volume causes a higher incidence of wound infection when modern, non-stained implants are used. The increase in the incidence of infection is most prominent when SR-PLLA implants are used. Increasing the implant-bone volume ratio causes a higher incidence of wound infection on the tibial side.
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Objective:To prepare poly-L-lactic acid(PLLA)electrospun nanofibers carrying icariin(ICA)(ICA /PLLA)and to evaluate the effects of the ICA /PLLA on MC3T3-E1 cells.Methods:ICA solution was dispersed into PLLA solution,and electrospun fibers were fabricated by W/O emulsion method.The morphology of ICA /PLLA was observed by SEM.The in vitro release kinetics of ICA /PLLA was examined.The attachment of MC3T3-E1 cells on ICA /PLLA was examined by propidiumiodide(PI)labling and ob-served under fluorescent microscope.The proliferation of the cells was measured by MTT assay.The differentiation of the cells was ob-served by alkaline phosphatase (ALP)assay.Results:In vitro,ICA was effectively released from ICA /PLLA for 22 days,cells were attached well on the surface in all groups,ICA did not affect the proliferation of MC3T3-E1 cells(P >0.05),but increased the ALP activity(P <0.05)of the cells.Conclusion:ICA /PLLA can effectively control the release of ICA and promote the differentiation of MC3T3-E1 cells.
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Objective To study the biocompatibility of silk fibroin/poly L-lactic acid (SF/PLLA) non-woven network,a kind of new composite tissue engineering nanomaterials,and to explore its possibility as the biological implant materials.Methods The PLLA non-woven network was prepared by electrostatic spinning.Physiological saline as control,the leaching solution was prepared and injected into the mice,then the mice were observed for 2 weeks.The materials were implanted into the back of the mice,and 3-0 suture was used as control.Tissues were collected at 1,2,3,and 4 weeks after operation,dyed by HE staining and then the photos were taken.The tissue reactions in experimental group and control group were observed.The rabbit knee joint cartilage cells were cultured,and then subculture cells were seeded to the surface of materials.After cultured invitro,the adhesion and growth of the cells were observed with inverted optical microscope.The bioactivities of the rabbit knee joint cartilage cells in negative control group(DMEM culture media),experimental group(DMEM containing materials) and positive control group(DMEM containing phenol solution)were determined by MTT assay after cocultured for 24 and 48 h.Results After injection,the body status of the mice in experimental group was the same to the control group.There were little fibroblasts was and a little of lymphocytes and macrophage cells in the materials which were implanted into the back of the mice at the beginning.Then the number of the fibroblasts was increased, but the number of the lymphocytes and macrophage cells did not change obviously.The materials degraded slowly, and the material degraded obviously at 4 weeks.The inflammation of tissue around the material reduced gradually from the 2nd week.The inflammation of tissue around the material was the same to the suture,and sometimes was slighter than the suture.After sed for 24 h,there were cells attaching to the fibers of the material.More and more cells attached to the fibers.The reasult of MTT assay showed that the cytotoxicities in experimental groups were all on LevelⅠ at 24 and 48 h.Except for positive control group,the A values were increased in other groups with the extended response time.At the same time,there was no significant difference in cytotoxicity between experimental group and negative control group(P>0.05)and the A value in experimental group was higher than that in positive control group(P<0.01).Conclusion The SF/PLLA non-woven network scaffold material has good biological compatibility and safety,it could be used as implant material in tissue engineering.
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PURPOSE: We report a case of visual loss after the injection of poly-L-lactic acid filler into the right forehead area for cosmetic purposes. CASE SUMMARY: A 46-year-old female patient visited our clinic due to sudden visual disturbance and dysesthesia on the right forehead and cheek. Her best corrected visual acuity was no light perception in the right eye and 20/20 in the left eye. Visual acuity in her right eye was not corrected. An afferent papillary defect in the right eye and paralysis of oculomotor muscles were observed. Fundus exam revealed a pale optic nerve and turbid retina on the posterior pole. The retinal vessels were narrowed. A papule 1 cm to the lateral margin of the right eyebrow due to the needle injection was found and no other visible skin abnormalities were observed. She had a cosmetic poly-L-lactic acid filler injection into the right forehead area immediately before the visual disturbance occurred. Fluorescent angiography showed occlusion of the right retinal artery and blood flow defects on the retina and choroid were present. The patient was followed up for 6 months and visual acuity and dysesthesia in her right forehead and cheek did not improve. CONCLUSIONS: Several cases of visual loss have occurred after injection of filler on the glabella and forehead for cosmetic purposes. However, most of the complications were observed after the use of hyaluronic fillers and not due to poly-L-lactic acid filler. This is the first case report of visual loss caused by poly-L-lactic acid filler in South Korea in a normal patient. Hence, consideration of complications when using this type of fillers is important.
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Female , Humans , Middle Aged , Angiography , Cheek , Choroid , Eyebrows , Forehead , Korea , Needles , Oculomotor Muscles , Optic Nerve , Paralysis , Paresthesia , Retina , Retinal Artery , Retinal Vessels , Skin Abnormalities , Visual AcuityABSTRACT
BACKGROUND:Previous studies have shown that composite scaffold of chitosan and poly-L-lactic acid has good biocompatibility with some cells. OBJECTIVE:To study the biocompatibility of poly-L-lactic acid reinforced by chitosan and olfactory ensheathing cells. METHODS:In experimental group, olfactory ensheathing cells from Sprague-Dawley rats aged 1-3 days were incubated onto chitosan-reinforced poly-L-lactic acid film. And in control group, olfactory ensheathing cells were co-cultured with poly-L-lysine. The proliferative ability of olfactory ensheathing cells was detected and the cells were observed with immunofluorescence histochemical staining at 1, 3, 5, 7 days after culture. RESULTS AND CONCLUSION:Olfactory ensheathing cells could survive on the chitosan-reinforced poly-L-lactic acid film, and the cytotoxic grade wasⅠ. Morphology of the cells in the experimental group was round or oval, with little processes and the cells aggregated into groups. One day after implantation, the periphery cells of the mass extended short projections and gradual y spread outward;3 days after implantation, the cells spread and most of the cells generated projections, most of which were bipolar or tri-polar;5 days after implantation, cel processes significantly extended, most cells were bipolar and tri-polar cells, while some were oval cells and irregular triangular cells;7 days after implantation, the cel density increased, and cel processes extended. Cel morphology of the control group had similar characteristics as the experimental group. There was no obvious difference between the control and the experimental group in number, perimeter or area of the cells (P>0.05). It showed that chitosan-reinforced poly-L-lactic acid had good biocompatibility with olfactory ensheathing cells.
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OBJECTIVE: The aim of this study was to investigate bone repair after the implantation of vancomycin-loaded poly-L-lactic acid/poly-ethylene oxide microspheres compared with vancomycin-unloaded poly-L-lactic acid/poly-ethylene oxide microspheres. METHODS: Poly-L-lactic acid/poly-ethylene oxide microspheres were implanted in rat tibiae and evaluated for periods of 2, 4, 8, and 12 days and 4, 8, 16, and 32 weeks. The groups implanted with vancomycin-loaded and vancomycin-unloaded microspheres were compared. Histopathologic (semi-quantitative) and histomorphometric analyses were performed to evaluate the bone formation process. RESULTS: During the first period (second day), fibrin and hemorrhaging areas were observed to be replaced by granulation tissue around the microspheres. Woven bone formation with progressive maturation was observed. All of the histopathological findings, evaluated by a semi-quantitative assay and a quantitative analysis (percentage of bone formation), were similar between the two groups. CONCLUSION: Vancomycin-loaded poly-L-lactic acid/poly-ethylene oxide microspheres are a good bone substitute candidate for bone repair. Local antibiotic therapy using vancomycin-loaded poly-L-lactic acid/poly-ethylene oxide microspheres should be considered after the microbiological evaluation of its efficacy.
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Animals , Male , Rats , Bone Substitutes/therapeutic use , Lactic Acid/therapeutic use , Osteogenesis/physiology , Polyethylene Glycols/therapeutic use , Polymers/therapeutic use , Tibial Fractures/surgery , Vancomycin/therapeutic use , Biocompatible Materials , Microspheres , Rats, Wistar , Time Factors , Tibial Fractures/pathologyABSTRACT
ObjectiveTo investigate the biomechanical characteristics of different types of fixation with bioactive cervical fusion cage made of hydroxyapatite and poly L-lactic acid in cervical spinal fusion.MethodsIliac crest bone,bioactive cervical fusion cage and bioactive cervical fusion cage with plate fixation were used for anterior interbody implants after anterior discectomy across C5-6 in six fresh human cervical spine specimens respectively,and the range of motion of the cervical vertebrae interbody fusion were measured through the motional stability test.Results After discectomy,Bioactive Cervical Fusion Cage with plate fixation exhibited a significant increase in stability and a decrease of range of motion in angular motion than others in all motional directions ( P < 0.005 ). Bioactive cervical fusion cage exhibited a decrease in stability and an increase of range of motion (6.25 ± 0.29) in angular motion than the intact spine (5.76 ± 0.40) in extension,but the difference was not significantly ( P > 0.05 ).Bioactive cervical fusion cage exhibited a decrease in angular motion than iliac crest bone and a significant increase in stability in all motional directions except extension (P < 0.005).ConclusionsBioactive cervical fusion cage' s biomechanical performance was excellent and bioactive cervical fusion cage with plate fixation was excellent in stability in all motional direction,and could remain initial stability of cervical vertebrae.
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Objective To find a new material for biomedical scaffold.Methods Composite films from poly-L-lactic acid(PLLA)and opal powder were fabricated.Osteoblasts seeded on the composite films and control ones were examined.Cell densities and morphologies on these films were studied by scanning electron microscopy(SEM).Cell growth and differential function were assessed by 3-(4,5-dimethyltyiazol-2-yl)-2,5-diphenyl tetrazolium bromide(MTT)test.Results SEM study showed that the addition of powder could improve the adhesion between osteoblasts and the composite films.MTT test proved that cell proliferation was improved when opal powder was added.This improvement came from the negative ion given off by the opal powder.The negative ions either accumulate at the cell membrane or enter into the cells.Accumulation of negative ions at the cell membrane leads to a change of electric potential difference across the cell membrane which should be in a proper range for the cells to perform their normal physiological function.If the negative ions enter the cells,they may take part in biochemical reactions whenever possible.In this way,the ions also affect the cell normal metabolism.Conclusion Osteoblasts grow well on opal/PLLA composites and the negative ion from opal powder is responsible for the enhancement of cell growth.This study provides a new material for biomedical scaffold.
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[Objective] To evaluate the cellular biocompatibility of the nano poly(L-lactic acid)-block-poly(?-caprolactone)(Nano-PLLA-b-PCL)with canine articular cells and its feasibility as a scaffold for the cartilage tissue engineering.[Methods]Nano-PLLA-b-PCL was made by liquid-liquid phase separation.Canine articular cells were isolated and multiplied in vitro.The passage 3 cells were seeded onto the PLLA-b-PCL films and cultured in the 2-dimensional environment.The cytotoxicity was measured with MTT assay.Cellular Morphological changes were observed by phase-contrast microscopy and Hoechst33342 fluorometric method.Another passage 3 cells were seeded onto the Nano-PLLA-b-PCL scaffolds(experiment group),PLLA-b-PCL scaffolds(control group)and cultured in the 3-dimensional environment for 3 weeks.The ratio of cell adhesion was detected by cell counting method.The morphological changes of cells were observed by scanning electron microscopy.The protein content in seeded cells were determined by bioinchoninic acid assay(BCA).The content of DNA was quantified using Hoechst33258 assay.[Results]MTT assay showed the PLLA-b-PCL had no cytotoxicity.The seeded cells adhered and proliferated well into the Nano-PLLA-b-PCL scaffolds,and they maintained good cell phenotype.After 21-day cell culture within the Nano-PLLA-b-PCL scaffolds,the chondrocyte DNA and protein contents increased with time.Moreover,the content of DNA and protein was higher in the experiment group than that in the control group,respectively(P
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[Objective]To prepare a new porous composite artificial bone substitute and evaluate its properties.[Method]Thermally induced phase separation was adopted to prepare the artificial bone made from oyster shell powder and PLLA which were proportionally mixed and its properties as porosity rate,pore size and mechanical strength were assessed.Meanwhile the related variation parameters were examined every 2 weeks in a course of 14 weeks after the slices of CAB and pure PLLA were immersed in NS of 37℃ in vitro,the results of which were compared in statistics.[Result]The average porosity rate of artifical bone with TIPS method was 85.1% and pore sizes ranged 100-300 ?m under the SEM,with better pore connectivity and regulation shape.The average compressive strength was 2.12 MPa.As the immersion prolonged,the regular variation was observed about the mass loss of CAB and the pH alteration of solution,there was statistically difference in the indexes between the two groups(P﹤0.05).[Conclusion]The porosity rate,pore size,mechanical strength and degradation performance in vitro of the artifical bone made by TIPS method can satisfy the requirement of bone substitute.