Preparation and characterization of a novel COL/BC composite for potential tissue engineering scaffolds

This paper describes the biosynthesis of a novel collagen-bacterial cellulose (COL/BC) composite by adding collagen to the culture medium of Acetobacter xylinum. The morphology of COL/BC composite was observed by SEM and TEM and compared with pristine BC. The composite was further characterized by FTIR and XRD. It is found that the structure of BC network changes when collagen is present in the nutrient medium. Further work is underway to gain insights into the mechanisms governing the experimental phenomena.     

Fabrication and characterization of porous hydroxyapatite microspheres by spray-drying method

In the present paper, porous hydroxyapatite (HA) microspheres were fabricated using gelatin as a pore-forming agent by spray-drying method. The mean particle size of the microspheres is about 7 μm and the surface area is about 53.4 m²/g. The experimental results showed that the porosity of the prepared microspheres is higher and the pores are more interconnected compared with the microspheres obtained without any additives.     

羟基磷灰石基多孔复合支架的制备及其表征

研究利用造孔剂法制备高度贯通的多孔羟基磷灰石(HA)支架,孔隙率约为78%,并利用聚己内酯(PCL)分别复合纳米HA(nHA)或微纳米生物玻璃(nBG)粉末对其进行涂覆改性,粉末的添加量均为10%~40%(质量分数)。4种类型支架分别记为HA、PCL/HA、nHA-PCL/HA和nBG-PCL/HA。实验结果发现,nHA-PCL/HA和nBG-PCL/HA复合支架最大抗压强度分别为1.41~1.98 MPa和1.35~1.78MPa。4类支架矿化实验显示,浸泡21d后nBG-PCL/HA表面促进生成较多的磷灰石矿化物;细胞实验结果显示细胞在4类支架上均生长良好,说明支架具有良好的生物相容性。支架在实验犬背部肌肉组织内植入2个月的组织学检测显示,4种支架内均有新骨形成,尤其是nHA-PCL/HA和nBG-PCL/HA孔内有更多的新生骨组织,说明这两种支架表面复合涂层中的生物活性纳米颗粒对诱导新骨生成具有积极的促进作用。     

多孔 n2 HA/ PA26复合材料的制备及性能

采用注塑方法制备了多孔纳米磷灰石/聚酰胺26 (n2 HA/ PA26) 复合材料 , 采用 SEM、XRD、IR、 力学性能测试考察了多孔材料的性能。结果发现 : 多孔纳米磷灰石/聚酰胺26复合材料的孔隙分布均匀 , 贯通性良好 , 孔的尺寸约为 100～700μm , 平均孔径约 300～500μm , 大孔壁上有丰富的微孔 ; 所得多孔复合材料的孔隙率可控 , 总孔隙率最高可达 881 6 %; 多孔材料的总孔隙率降低 , 则开孔率随之降低 ; 多孔纳米磷灰石/聚酰胺26 复合材料的抗压强度为 1. 1～15. 6 MPa , 压缩模量为 0. 4～1. 4 GPa ; 在总孔隙率相近的条件下 , 多孔材料的抗压强度随 n2 HA质量分数增加而升高; 发泡剂和发泡过程对组成纳米磷灰石/聚酰胺26复合材料的两组元材料的性质和结构无影响。这种多孔材料可望作为人体非承重部位的植入骨修复体和组织工程支架使用。     

Fabrication,characterization and in vitro drug release behavior of electrospun PLGA/chitosan nanofibrous scaffold

In this study both aligned and randomly oriented poly(d,l-lactide-co-glycolide) (PLGA)/chitosan nanofibrous scaffold have been prepared by electrospinning. The ratio of PLGA to chitosan was adjusted to get smooth nanofiber surface. Morphological characterization using scanning electron microscopy showed that the aligned nanofiber diameter distribution obtained by electrospinning of polymer blend increased with the increase of chitosan content which was similar to that of randomly oriented nanofibers. The release characteristic of model drug fenbufen (FBF) from the FBF-loaded aligned and randomly oriented PLGA and PLGA/chitosan nanofibrous scaffolds was investigated. The drug release rate increased with the increase of chitosan content because the addition of chitosan enhanced the hydrophilicity of the PLGA/chitosan composite scaffold. Moreover, for the aligned PLGA/chitosan nanofibrous scaffold the release rate was lower than that of randomly oriented PLGA/chitosan nanofibrous scaffold, which indicated that the nanofiber arrangement would influence the release behavior. In addition, crosslinking in glutaraldehyde vapor would decrease the burst release of FBF from FBF-loaded PLGA/chitosan nanofibrous scaffold with a PLGA/chitosan ratio less than 9/1, which would be beneficial for drug release.     

碳纳米管/羟基磷灰石复合材料的制备及表征

以含钴介孔分子筛为催化剂、乙醇为碳源, 采用CVD法制备碳纳米管(CNTs)。通过原位合成法制备一系列不同碳纳米管含量的碳纳米管/羟基磷灰石(CNTs/HA)复合材料。分别采用XRD、FTIR、TEM、N₂吸附-脱附和Raman光谱等分析手段, 对所合成CNTs/HA复合材料的晶相、结构、形貌和比表面积等进行了表征。同时研究了碳纳米管的添加量对所合成CNTs/HA复合材料形貌的影响。XRD与Raman结果表明, 所得CNTs/HA复合粉体中仅有CNTs与HA两种物相, 纯度较高, 结晶度较好; TEM结果显示, CNTs/HA复合材料中CNTs表面均匀包裹着一层纳米级的针状HA晶粒, 两者形成了较强的界面结合, 且当CNTs与HA的质量比为3:17时, CNTs与HA形成最佳结合状态; N₂吸附-脱附表征结果表明, 与HA的比表面积相比, CNTs/HA复合材料具有较高比表面积。     

In vitro cellular response to hydroxyapatite scaffolds with oriented pore architectures

The objective of the present work was to evaluate the in vitro cellular response to hydroxyapatite (HA) scaffolds with oriented pore architectures. Hydroxyapatite scaffolds with approximately the same porosity (65–70%) but two different oriented microstructures, described as ‘columnar’ (pore diameter = 90–110 μm) and ‘lamellar’ (pore width = 20–30 μm), were prepared by unidirectional freezing of suspensions. The response of murine MLO-A5 cells, an osteogenic cell line, to these scaffolds was evaluated using assays of MTT hydrolysis, alkaline phosphatase (ALP) activity, and alizarin red staining. While the cellular response to both groups of scaffolds was better than control wells, the columnar scaffolds with the larger pore width provided the most favorable substrate for cell proliferation and function. These results indicate that HA scaffolds with the columnar microstructure could be used for bone repair applications in vivo.     

Design of tunable protein-releasing nanoapatite/hydrogel scaffolds for hard tissue engineering

Hierarchically structured porous scaffolds based on nanocrystalline carbonated hydroxyapatite reinforced hydrogels (Gellan or Agarose) have been tested as protein release matrices while evaluation their in vitro biocompatibility. The shaping method used develops under mild conditions thus allowing the incorporation of labile substances. The Bovine Serum Albumin (BSA), employed as a model protein, has been included by using two drug-inclusion strategies: during the scaffolds preparation (in situ process) or by injection of an aqueous protein solution within (ex situ process). The release studies showed a more controlled BSA delivery when the protein was incorporated during the scaffold preparation when compared to that where the protein has been loaded in a second step (ex situ process). The release patterns can also be tailored as a function of the scaffold composition (ceramic/polysaccharide ratio and nature) as well as the drying technology employed. Biocompatibility studies demonstrated that these scaffolds, regardless of the composition, allow the culture of osteoblasts on and around the material, thus supporting the potential use of these biomaterials for bone tissue engineering.     

Fabrication of nanofibrous macroporous scaffolds of poly(lactic acid) incorporating bioactive glass nanoparticles by camphene-assisted phase separation

Here we produced macroporous and nanofibrous scaffolds with bioactive nanocomposite composition, poly(lactic acid) (PLA) incorporating bioactive glass nanoparticles (BGnp) up to 30 wt%, targeting bone regeneration. In particular, the nanofibrous structure in the scaffolds was generated by using a bicyclic monoterpene, camphene (C₁₀H₁₆), through a phase-separation process with PLA-BGnp phase in chloroform/1,4-dioxane co-solvent. Furthermore, macropores were produced by the impregnation of salt particles and their subsequent leaching out, followed by freezing and lyophilization processes. The produced PLA-BGnp scaffolds presented highly porous and nanofibrous structure with porosities of 90–95% and pore sizes of over hundreds of micrometers. BGnp with sizes of ∼90 nm were also evenly impregnated within the PLA matrix, featuring a nanocomposite structure. The nanofibrous scaffolds exhibited enhanced hydrophilicity and more rapid hydrolytic degradation as the incorporated BGnp content increased. The bone-bioactivity of the scaffolds was substantially improved with the incorporation of BGnp, exhibiting rapid formation of apatite throughout the scaffolds in a simulated body fluid. The developed macroporous and nanofibrous scaffolds with PLA-BGnp bioactive composition are considered as a novel 3D matrix potentially useful for bone tissue engineering.     

骨组织工程多孔支架材料性质及制备技术

多孔性生物可降解支架的选择和制备是组织工程技术成功运用的关键。从骨架的材料要求、常用的骨架材料、骨架的制备技术等几个方面对组织工程和生物降解支架的研究进行了综述 ,并对该研究的前景进行了展望     

Electrochemistry assisted reacting deposition of hydroxyapatite in porous chitosan scaffolds

Electrochemistry assisted reacting deposition method was employed to prepare porous chitosan/hydroxyapatite (CS/HA) composite scaffold with a new design device using ion exchange membranes to separate calcium salt and phosphate solutions. The results determined from XRD and SEM indicates hydroxyapatite can be electrochemically deposited in the chitosan scaffold using the device. After electrochemistry assisted reacting deposition, the surface of the chitosan scaffold was coated with low crystalline HA, particularly at the frame edge of the scaffold. The pores in the scaffold still kept interconnected well and the deposited hydroxyapatite has a cluster microsphere shape whose size is about 3-5 μm.     

分级多孔壳聚糖/聚乳酸复合支架的制备及骨修复性能

为了仿生莲藕内部的贯穿大孔结构,以生物相容性好的壳聚糖(CS)作为基质材料,利用冰粒致孔、石蜡模具和冰模具成型3种成型方法制备了分级多孔CS支架材料,然后与力学强度较高的聚乳酸(PLLA)复合,制备网络互穿CS/PLLA复合支架。通过SEM、压缩强度测试和兔股骨髁骨缺损模型对CS/PLLA复合材料的形貌、力学强度和骨修复性能进行了表征。结果表明:利用冰模具制备的CS/PLLA复合支架能可控、批量制备,具有微米-毫米分级多孔结构,大孔孔径约为2mm,内部均匀分布着孔径约为60μm的贯穿微孔,并在微孔内形成密集的PLLA絮状网络结构。干态复合材料的压缩强度和模量分别比纯CS支架的提高了6倍和15倍。体内植入实验结果表明,CS/PLLA复合材料能够促进骨缺损的愈合,并随着新骨的形成,复合材料逐渐被降解吸收。     

骨组织工程用多孔HA生物材料的制备

用PVB、NH4HCO3和(NH4)2CO3粒子作造孔剂,制备了骨组织工程用多孔HA生物材料.讨论了烧结工艺和造孔剂含量等对材料结构的影响.研究表明,较佳的烧结工艺为1200℃烧结4h,烧结后样品主要是HA相.造孔剂PVB、(NH4)2CO3、NH4HCO3含量分别为10vol%、15vol%和20vol%时,多孔HA陶瓷拥有大于100μm和5～50 μm的贯通孔,具有较好的孔连通性与孔结构,有利于细胞和组织的生长以及营养输送;其最大孔隙率为50.3%,抗压强度为6.33MPa.     

硅基HA/Al2O3复合生物涂层的制备与表征

通过磁控溅射沉积、阳极氧化与溶胶-凝胶结合的多步技术在Si(100)表面制备了HA/Al2O3复合生物涂层材料.采用TG-DSC测定了复合涂层中HA外层的烧成温度,采用XRD、FT-IR以及EDS分析了Si(100)基HA/Al2O3复合生物涂层的组成,并借助SEM研究了复合涂层的表面与截面的微观形貌.研究表明,凝胶完全转变为HA外层的最低温度约为550℃,凝胶经600℃处理30min后可在Si(100)-Al2O3基上形成具有一定数量纳米细孔且含有少量CO3的HA外层;A外层嵌入Si(100)基阳极氧化Al2O3多孔层的孔洞中构成HA/Al2O3复合生物涂层.     

Fabrication of mesoporous carbonated hydroxyapatite/carbon nanotube composite coatings by microwave irradiation method

Carbonated hydroxyapatite/carbon nanotube composite coatings (MHCs) with mesoporous structures were fabricated by electrophoretic deposition of nacre powders and carbon nanotubes on Ti6Al4V substrates followed by treatment with a phosphate buffer solution (PBS) by microwave irradiation method. The carbon nanotubes are dispersed uniformly on the whole MHCs. The conversion mechanism of the crack-free nacre/carbonate nanotube composite coatings (NCCs) to MHCs is a dissolution-precipitation reaction. After soaking in PBS, calcium ions are released from the nacre powders and react with phosphate ions to form carbonated hydroxyapatite nanoparticles. These nanoparticles aggregate to form mesopores with the pore sizes of ~ 3.9 nm among them. Simulated body fluid (SBF) immersion tests reveal that MHCs have a good in vitro bioactivity.     

聚己内酯/羟基磷灰石晶须复合多孔支架的研究

采用溶液浇铸法,以二氯甲烷作为溶剂,制备了聚己内酯/羟基磷灰石晶须(PCL/HAw)复合多孔支架,并进行了正交试验,综合分析了不同配方量的PCL和HAw对材料机械性能的影响。结果表明,可通过控制PCL的量来控制支架的力学性能,通过加入HAw提高支架的亲水性能,支架的接触角实验显示其接触角为81°;PCL的结晶度会随着HAw含量的增加而增强,复合多孔支架的抗拉强度为1.43M~9.21MPa,并在PCL与HAw的质量比为100∶3时达到最大;细胞毒性实验显示,PCL/HAw复合多孔支架细胞毒性为0,满足生物材料使用要求。     

磁性多孔碳材料的研究进展

磁性多孔碳材料同时具有磁性和多孔性质,其拥有丰富的孔道结构、高的比表面积、高孔容、良好的活性位点和磁性可分离等优异的性能,可以很好的解决多孔碳材料在应用过程中难分离回收等问题,因此,磁性多孔碳材料已经在吸附领域得到广泛的应用.按照孔径大小、磁性强弱以及组合方式的不同将磁性多孔碳材料进行了分类,并综述了近年来磁性多孔碳材...     

Fabrication of 3D chitosan–hydroxyapatite scaffolds using a robotic dispensing system

A new robotic desktop rapid prototyping (RP) system was designed to fabricate scaffolds for tissue engineering applications. The experimental setup consists of a computer-guided desktop robot and a one-component pneumatic dispenser. The dispensing material (chitosan and chitosan–hydroxyapatite (HA) dissolved in acetic acid) was stored in a 30-ml barrel and forced out through a small Teflon-lined nozzle into a dispensing medium (sodium hydroxide–ethanol in ratio of 7:3). Layer-by-layer, the chitosan was fabricated with a preprogramed lay-down pattern. Neutralization of the chitosan forms a gel-like precipitate, and the hydrostatic pressure in the sodium hydroxide (NaOH) solution keeps the cuboid scaffold in shape. Comparison of the freeze-dried scaffold to the wet one showed linear and volumetric shrinkage of about 31% and 62%, respectively. A good attachment between layers allowed the chitosan matrix to form a fully interconnected channel architecture. Results of in vitro cell culture studies revealed the scaffold biocompatibility. The results of this preliminary study using the rapid prototyping robotic dispensing (RPBOD) system demonstrated its potential in fabricating three-dimensional (3D) scaffolds with regular and reproducible macropore architecture.     

Fabrication and characterization of porous calcium polyphosphate scaffolds

Porous calcium polyphosphate (CPP) scaffolds with different polymerization degree and crystalline phases were prepared, and then analyzed by scanning electron microscopy (SEM), Thermmogravimetry (TG) and X-ray diffraction (XRD). Number average polymerization degree was calculated by analyzing the calcining process of raw material Ca(H₂PO₄)₂, as a polycondensation reaction. Amorphous CPP were prepared by the quenching from the melt of Ca(H₂PO₄)₂ after calcining, and CPP with different polymerization degree was prepared by controlling the calcining time. Meanwhile, CPP with the same polymerization degree was prepared to amorphous or different crystalline phases CPP which was made from crystallization of amorphous CPP. In vitro degradation studies using 0.1 M of tris-buffered solution were performed to assess the effect of polymerization degree or crystalline phases on mechanical properties and weight loss of the samples. With the increase of polymerization degree, the weight loss during the degradation decreased, contrarily the strength of CPP increased. The degradation velocity of amorphous CPP, α-CPP, β-CPP and γ-CPP with the same polymerization degree decreased in turn at the same period. The full weight loss period of CPP can be controlled between 17 days and more than 1 year. The results of this study suggest that CPP ceramics have potential applications for bone tissue engineering.     

Fabrication and characterization of novel meso-porous carbon/n-octadecane as form-stable phase change materials for enhancement of phase-change behavior

In this study, series of novel composite phase change materials (PCMs) were prepared through vacuum impregnation by using meso-porous carbon as a supporting matrix and n-octadcane as PCMs. The meso-porous carbon material was prepared through one-pot co-assembly method, using resorcinol and formaldehyde as carbon precursor, tetraethoxysilane as silica sources and triblock copolymer F127 as a template. And the phase behaviors of n-octadcane confined in the nano-porous structure of the meso-porous carbon were further investigated. Fourier transform-infrared spectroscopy spectra show that n-octadecane was effectively encapsulated in the porous structure of mesoporous carbon and the composite PCMs were successfully prepared. Differential scanning calorimetry results confirm that the composite PCMs possess a good phase change behavior, fast thermal-response rate and excellent thermal cycling stability. In addition, the composite PCMs possess expected heat storage and heat release properties. All these results demonstrate that the composite PCMs possess good comprehensive property so that they can be used widely in energy storage systems.