The macroporous calcium phosphate(CPC) cement with oriented pore structure was prepared by freeze casting. SEM observation showed that the macropores in the porous calcium phosphate cement were interconnected aligne...The macroporous calcium phosphate(CPC) cement with oriented pore structure was prepared by freeze casting. SEM observation showed that the macropores in the porous calcium phosphate cement were interconnected aligned along the ice growth direction. The porosity of the as-prepared porous CPC was measured to be 87.6% by Archimede's principle. XRD patterns of specimens showed that poorly crystallized hydroxyapatite was the main phase present in the hydrated porous calcium phosphate cement. To improve the mechanical properties of the CPC scaffold, the 15% gelatine solution was infiltrated into the pores under vacuum and then the samples were freeze dried to form the CPC/gelatine composite scaffolds. After reinforced with gelatine, the compressive strength of CPC/gelatine composite increased to 5.12 MPa, around fifty times greater than that of the unreinforced macroporous CPC scaffold, which was only 0.1 MPa. And the toughness of the scaffold has been greatly improved via the gelatine reinforcement with a much greater fracture strain. SEM examination of the specimens indicated good bonding between the cement and gelatine. Participating the external load by the deformable gelatine, patching the defects of the CPC pores wall, and crack deflection were supposed to be the reinforcement mechanisms. In conclusion, the calcium phosphate cement/gelatine composite with oriented rmre structure nrenared in this work might be a potential scaffold for bone tissue engineerinm展开更多
Controlled release of the functional factors is the key to improve clinical therapeutic efficacy during the tissue repair and regeneration. The thrce-dimensional (3D) scaffold can provide not only physical propertie...Controlled release of the functional factors is the key to improve clinical therapeutic efficacy during the tissue repair and regeneration. The thrce-dimensional (3D) scaffold can provide not only physical properties such as high strength and porosity hut also an optimal environment to enhance tissue regeneration. Sphingosine 1-phosphate (SIP), an angiogenlc factor, was loaded into mesoporous silica nanoparticles (MSNs) and then incorporated into poly ( L-lactic add ) ( PLLA ) nanofibrons scaffold, which was fabricated by thermally induced phase separation (TIPS) method. The prepared scaffolds were examined by attenuated total reflection Fourier transform infrared spectroscopy (ATR-FTIR), scanning electron microscopy ( SEM), and transmission electron microscopy (TEM) and compressive mechanical test. The ATR-FTIR result demonstrated the existence of MSNs in the PLLA nanofibrous scaffold. The SEM images showed that PLLA scaffold had regular pore channel, interconnected pores and nanofibrous structure. The addition of MSNs at appropriate content had no visible effect on the structure of scaffold. The compressive modulus of scaffold containing MSNs was higher than that of the scaffold without MSNs. Furthermore, fluorescein isothiocyanate (FTTC) was used as model molecule to investigate the release behavior of SIP from MSNs- incorporated PLLA (MSNs/PLLA) nanofibrons scaffold. The result showed that the composite scaffold largely reduced the initial burst release and exhibited prolonged release of FITC than MSNs. Thus, these results indicated that SIP-loaded composite uanofibrons scaffold has potential applications for bone tissue engneering.展开更多
In this study,the macroporous calcium phosphate cement with oriented pore structure was prepared by freeze casting.SEM observation showed that the macropores in the porous calcium phosphate cement were interconnected ...In this study,the macroporous calcium phosphate cement with oriented pore structure was prepared by freeze casting.SEM observation showed that the macropores in the porous calcium phosphate cement were interconnected aligned along the ice growth direction.The porosity of the as-prepared porous CPC was measured to be 87.6% by Archimede's principle.XRD patterns of specimens showed that poorly crystallized hydroxyapatite was the main phase present in the hydrated porous calcium phosphate cement.To improve the mechanical properties of the CPC scaffold,the 15% gelatine solution was infiltrated into the pores under vacuum and then the samples were freeze dried to form the CPC/gelatine composite scaffolds.After reinforced with gelatine,the compressive strength of CPC/gelatin composite increased to 5.12 MPa,around 50 times greater than that of the unreinforced macroporous CPC scaffold,which was only 0.1 MPa.And the toughness of the scaffold has been greatly improved via the gelatine reinforcement with a much greater fracture strain.SEM examination of the specimens indicated good bonding between the cement and gelatine.In conclusion,the calcium phosphate cement/gelatine composite with oriented pore structure prepared in this study might be a potential scaffold for bone tissue engineering.展开更多
Porous calcium phosphate ceramics were produced by compression molding using a special mold followed by sintering. The porous calcium phosphate ceramics have three-dimensional and penetrated open pores 380-400μm in...Porous calcium phosphate ceramics were produced by compression molding using a special mold followed by sintering. The porous calcium phosphate ceramics have three-dimensional and penetrated open pores 380-400μm in diacneter spaced at intervals of 200μm. The layers of the linear penetration pores alternately lay perpendicular to pore direction. The porosity was 59%-65% . The Ca/ P molar ratios of the porous calcium phos phate ceramics range from 1.5 to 1.85. A binder cantaining methyl cellulose was most effective for preparing the powder compact among vinyl acetate, polyvinyl alcohol, starch, stearic acid, methyl cellulose and their mixtures . Stainless steel, polystyrene, nylon and bamboo were used as the long columnar dies for the penetrated open pores. When polystyrene, nylon and bamboo were used as the long columnar male dies, the dies were burned oat during the sintering process. Using stainless steel as the male dies with the removal of the dies before heat treatment resulted in a higher level of densification of the calcium phosphate ceramic.展开更多
In a previous study, the authors tried to synthesize dental materials from dental waste, which was accomplished with alginate impression materials and gypsum. A powder was set by mixing it with phosphate solution. Fib...In a previous study, the authors tried to synthesize dental materials from dental waste, which was accomplished with alginate impression materials and gypsum. A powder was set by mixing it with phosphate solution. Fibrous curled crystals were found through SEM observation. The present study shows a detailed analysis of the crystals. XRD analysis indicated the crystals are Brushite. A unique profile of the crystal shows it can be a good apatite precursor or cell scaffold;however, this hypothesis requires further examination.展开更多
With an elemental composition similar to bone mineral,and the ability to release phosphorus and calcium that benefit bone regeneration,Calcium Phosphate Glass(CPG)serves as a promising component of bone tissue enginee...With an elemental composition similar to bone mineral,and the ability to release phosphorus and calcium that benefit bone regeneration,Calcium Phosphate Glass(CPG)serves as a promising component of bone tissue engineering scaffolds.However,the degradation of CPG composites typically results in increased acidity,and its impact on bone-forming activity is less studied.In this work,we prepared 3D-printed composite scaffolds comprising CPG,Poly-ε-caprolactone(PCL),and various Magnesium Oxide(MgO)contents.Increasing the MgO content effectively suppressed the degradation of CPG,maintaining a physiological pH of the degradation media.While the degradation of CPG/PCL scaffolds resulted in upregulated apoptosis of Rat Bone Marrow-derived Stem Cells(rBMSC),scaffolds containing MgO were free from these negative impacts,and an optimal MgO content of 1 wt%led to the most pronounced osteogenic differentiation of rBMSCs.This work demonstrated that the rapid degradation of CPG impaired the renewability of stem cells through the increased acidity of the surrounding media,and MgO effectively modulated the degradation rate of CPG,thus preventing the negative effects of rapid degradation and supporting the proliferation and osteogenic differentiation of the stem cells.展开更多
Bone scaffolds are critical in current implant and periodontal regeneration approaches. In this study, we prepared a novel composite type-I collagen and hydroxyapatite (HA)/β-tricaleium phosphate (TCP) scaffold ...Bone scaffolds are critical in current implant and periodontal regeneration approaches. In this study, we prepared a novel composite type-I collagen and hydroxyapatite (HA)/β-tricaleium phosphate (TCP) scaffold (CHTS) by incorporating type-I collagen and bovine calcined bone granules, prepared as a mixture of 50% HA and 50% TCP, by freeze drying. We then characterized the CHTS and determined its cytotoxic effects. Additionally, ridge preservation experiments were carried out to evaluate the clinical effects of the CHTS. The results demonstrated that the composite scaffolds had good surface morphology and no cytotoxicity. Additionally, an in vivo experiment in an animal model showed that the CHTS performed equally as well as Bio-Oss Collagen, a widely used bone graft in ridge preservation. These findings revealed that the CHTS, which contained natural constituents of bone, could be used as a scaffold for bone regeneration and clinical use.展开更多
Calcium phosphate(CaP)has been widely used for bone defect repair due to good biocompatibility and osteoconductivity.Additive manufacture of calcium phosphate bioceramics with tailored architectures and improved mecha...Calcium phosphate(CaP)has been widely used for bone defect repair due to good biocompatibility and osteoconductivity.Additive manufacture of calcium phosphate bioceramics with tailored architectures and improved mechanical properties has recently attracted great attention.Herein,calcium phosphate nanoparticles with the size of~89-164 nm were synthesized by the hydrothermal treatment of amorphous calcium phosphate(ACP)precursors at 180°C for 24 h.Biofunctional elements including Mg,Sr and Zn have been doped into these calcium phosphate nanoparticles.Our results revealed that Mg^(2+)ions played critical roles in formation of whitlockite-type calcium phosphate(not hydroxyapatite)from ACP precursors.Moreover,gyroid scaffolds with bionic triply periodic minimal surface structures were fabricated using stereolithography printing of these calcium phosphate nanoparticles,which are likely used as biofunctional scaffolds for bone repair.展开更多
基金the National Natural Science Foundation of China (Nos.50772037 and 50732003)the Science and Technology Program of Guangdong Province of China (No. 2008A030102008)the Research Foundation for Doctors of Jiangxi University of Science and Technology
文摘The macroporous calcium phosphate(CPC) cement with oriented pore structure was prepared by freeze casting. SEM observation showed that the macropores in the porous calcium phosphate cement were interconnected aligned along the ice growth direction. The porosity of the as-prepared porous CPC was measured to be 87.6% by Archimede's principle. XRD patterns of specimens showed that poorly crystallized hydroxyapatite was the main phase present in the hydrated porous calcium phosphate cement. To improve the mechanical properties of the CPC scaffold, the 15% gelatine solution was infiltrated into the pores under vacuum and then the samples were freeze dried to form the CPC/gelatine composite scaffolds. After reinforced with gelatine, the compressive strength of CPC/gelatine composite increased to 5.12 MPa, around fifty times greater than that of the unreinforced macroporous CPC scaffold, which was only 0.1 MPa. And the toughness of the scaffold has been greatly improved via the gelatine reinforcement with a much greater fracture strain. SEM examination of the specimens indicated good bonding between the cement and gelatine. Participating the external load by the deformable gelatine, patching the defects of the CPC pores wall, and crack deflection were supposed to be the reinforcement mechanisms. In conclusion, the calcium phosphate cement/gelatine composite with oriented rmre structure nrenared in this work might be a potential scaffold for bone tissue engineerinm
基金National Natural Science Foundations of China(Nos.31271028,31570984)International Cooperation Fund of the Science and Technology Commission of Shanghai Municipality,China(No.15540723400)+2 种基金Open Foundation of State Key Laboratory for Modification of Chemical Fibers,Polymer Materials,China(No.LK1416)the Innovation Funds of Donghua University,China(No.15D310516)“111 Project” Biomedical Textile Materials Science and Technology,China(No.B07024)
文摘Controlled release of the functional factors is the key to improve clinical therapeutic efficacy during the tissue repair and regeneration. The thrce-dimensional (3D) scaffold can provide not only physical properties such as high strength and porosity hut also an optimal environment to enhance tissue regeneration. Sphingosine 1-phosphate (SIP), an angiogenlc factor, was loaded into mesoporous silica nanoparticles (MSNs) and then incorporated into poly ( L-lactic add ) ( PLLA ) nanofibrons scaffold, which was fabricated by thermally induced phase separation (TIPS) method. The prepared scaffolds were examined by attenuated total reflection Fourier transform infrared spectroscopy (ATR-FTIR), scanning electron microscopy ( SEM), and transmission electron microscopy (TEM) and compressive mechanical test. The ATR-FTIR result demonstrated the existence of MSNs in the PLLA nanofibrous scaffold. The SEM images showed that PLLA scaffold had regular pore channel, interconnected pores and nanofibrous structure. The addition of MSNs at appropriate content had no visible effect on the structure of scaffold. The compressive modulus of scaffold containing MSNs was higher than that of the scaffold without MSNs. Furthermore, fluorescein isothiocyanate (FTTC) was used as model molecule to investigate the release behavior of SIP from MSNs- incorporated PLLA (MSNs/PLLA) nanofibrons scaffold. The result showed that the composite scaffold largely reduced the initial burst release and exhibited prolonged release of FITC than MSNs. Thus, these results indicated that SIP-loaded composite uanofibrons scaffold has potential applications for bone tissue engneering.
基金National Natural Science Foundation of Chinagrant number:50772037 and 50732003+1 种基金Science and Technology Program ofGuangdong Province of Chinagrant number:2008A030102008
文摘In this study,the macroporous calcium phosphate cement with oriented pore structure was prepared by freeze casting.SEM observation showed that the macropores in the porous calcium phosphate cement were interconnected aligned along the ice growth direction.The porosity of the as-prepared porous CPC was measured to be 87.6% by Archimede's principle.XRD patterns of specimens showed that poorly crystallized hydroxyapatite was the main phase present in the hydrated porous calcium phosphate cement.To improve the mechanical properties of the CPC scaffold,the 15% gelatine solution was infiltrated into the pores under vacuum and then the samples were freeze dried to form the CPC/gelatine composite scaffolds.After reinforced with gelatine,the compressive strength of CPC/gelatin composite increased to 5.12 MPa,around 50 times greater than that of the unreinforced macroporous CPC scaffold,which was only 0.1 MPa.And the toughness of the scaffold has been greatly improved via the gelatine reinforcement with a much greater fracture strain.SEM examination of the specimens indicated good bonding between the cement and gelatine.In conclusion,the calcium phosphate cement/gelatine composite with oriented pore structure prepared in this study might be a potential scaffold for bone tissue engineering.
文摘Porous calcium phosphate ceramics were produced by compression molding using a special mold followed by sintering. The porous calcium phosphate ceramics have three-dimensional and penetrated open pores 380-400μm in diacneter spaced at intervals of 200μm. The layers of the linear penetration pores alternately lay perpendicular to pore direction. The porosity was 59%-65% . The Ca/ P molar ratios of the porous calcium phos phate ceramics range from 1.5 to 1.85. A binder cantaining methyl cellulose was most effective for preparing the powder compact among vinyl acetate, polyvinyl alcohol, starch, stearic acid, methyl cellulose and their mixtures . Stainless steel, polystyrene, nylon and bamboo were used as the long columnar dies for the penetrated open pores. When polystyrene, nylon and bamboo were used as the long columnar male dies, the dies were burned oat during the sintering process. Using stainless steel as the male dies with the removal of the dies before heat treatment resulted in a higher level of densification of the calcium phosphate ceramic.
文摘In a previous study, the authors tried to synthesize dental materials from dental waste, which was accomplished with alginate impression materials and gypsum. A powder was set by mixing it with phosphate solution. Fibrous curled crystals were found through SEM observation. The present study shows a detailed analysis of the crystals. XRD analysis indicated the crystals are Brushite. A unique profile of the crystal shows it can be a good apatite precursor or cell scaffold;however, this hypothesis requires further examination.
基金support from the National Key Research and Development Program of China(Grant No.2018YFA0703000)the National Natural Science Foundation of China(Grant Nos.52250006,52075482)+1 种基金the Ningbo Top Medical and Health Research Program(Grant No.2022020304)the Ningbo Key Science and Technology Major Project(Grant No.2022Z143).
文摘With an elemental composition similar to bone mineral,and the ability to release phosphorus and calcium that benefit bone regeneration,Calcium Phosphate Glass(CPG)serves as a promising component of bone tissue engineering scaffolds.However,the degradation of CPG composites typically results in increased acidity,and its impact on bone-forming activity is less studied.In this work,we prepared 3D-printed composite scaffolds comprising CPG,Poly-ε-caprolactone(PCL),and various Magnesium Oxide(MgO)contents.Increasing the MgO content effectively suppressed the degradation of CPG,maintaining a physiological pH of the degradation media.While the degradation of CPG/PCL scaffolds resulted in upregulated apoptosis of Rat Bone Marrow-derived Stem Cells(rBMSC),scaffolds containing MgO were free from these negative impacts,and an optimal MgO content of 1 wt%led to the most pronounced osteogenic differentiation of rBMSCs.This work demonstrated that the rapid degradation of CPG impaired the renewability of stem cells through the increased acidity of the surrounding media,and MgO effectively modulated the degradation rate of CPG,thus preventing the negative effects of rapid degradation and supporting the proliferation and osteogenic differentiation of the stem cells.
文摘Bone scaffolds are critical in current implant and periodontal regeneration approaches. In this study, we prepared a novel composite type-I collagen and hydroxyapatite (HA)/β-tricaleium phosphate (TCP) scaffold (CHTS) by incorporating type-I collagen and bovine calcined bone granules, prepared as a mixture of 50% HA and 50% TCP, by freeze drying. We then characterized the CHTS and determined its cytotoxic effects. Additionally, ridge preservation experiments were carried out to evaluate the clinical effects of the CHTS. The results demonstrated that the composite scaffolds had good surface morphology and no cytotoxicity. Additionally, an in vivo experiment in an animal model showed that the CHTS performed equally as well as Bio-Oss Collagen, a widely used bone graft in ridge preservation. These findings revealed that the CHTS, which contained natural constituents of bone, could be used as a scaffold for bone regeneration and clinical use.
基金financially supported by the National Key Research and Development Program of China from Ministry of Science and Technology(No.2016YFC1100502)the Doctoral Research Foundation Program of Liaoning Province(No.2019-BS-256)+2 种基金the Key Research Program of Frontier Sciences(No.QYZDY-SSWJSC031)from Chinese Academy of Sciences(CAS)Key Research and Development Program of Liaoning Province(No.201703031)Shenyang Key R&D and Technology Transfer Program(No.Z17-7023)。
文摘Calcium phosphate(CaP)has been widely used for bone defect repair due to good biocompatibility and osteoconductivity.Additive manufacture of calcium phosphate bioceramics with tailored architectures and improved mechanical properties has recently attracted great attention.Herein,calcium phosphate nanoparticles with the size of~89-164 nm were synthesized by the hydrothermal treatment of amorphous calcium phosphate(ACP)precursors at 180°C for 24 h.Biofunctional elements including Mg,Sr and Zn have been doped into these calcium phosphate nanoparticles.Our results revealed that Mg^(2+)ions played critical roles in formation of whitlockite-type calcium phosphate(not hydroxyapatite)from ACP precursors.Moreover,gyroid scaffolds with bionic triply periodic minimal surface structures were fabricated using stereolithography printing of these calcium phosphate nanoparticles,which are likely used as biofunctional scaffolds for bone repair.
