Preparation and Characterization of TAM-Loaded HPMC/PAN Composite Fibers for Improving Drug-Release Profiles

The present paper reports the preparation and characterization of composite hydroxypropyl methylcellulose/polyacrylonitrile (HPMC/PAN)-medicated fibers via a wet spinning technique. Tamoxifen (TAM) was selected as a model drug. Numerous analyses were conducted to characterize the mechanical, structure and morphology properties of the composite fibers. The drug content and in vitro dissolution behavior were also investigated. SEM images showed that the TAM-loaded HPMC/PAN composite fibers had a finger-like outer skin and a porous structure. FT-IR spectra demonstrated that there was a good compatibility between polymer and drug. Results from X-ray diffraction and DSC suggested that most of the incorporated TAM was evenly distributed in the fiber matrix in an amorphous state, except for a minority that aggregated on the surface of fibers. The drug content in the fibers was lower than that in the spinning solution and about 10% of TAM was lost during spinning process. In vitro dissolution results indicated that, compared to TAM–PAN fibers, HPMC/PAN composite systems had weaker initial burst release effects and more drug-loading. The combination of hydrophilic polymer HPMC with PAN could improve the performance of polymer matrix composite fibers in regulating the drug-release profiles.     

Orthogonal experimental preparation of Sanguis Draconis- Polyvinylpyrrolidone microfibers by electrospinning

How to improve the bioavailability of the Sanguis Draconis (SD) is an important problem in the potential clinical applications. The aim of this study was to develop a drug delivery system to achieve high bioavailability of SD, a drug with poor water solubility. It will promote the research about new formulations of the SD and the other insoluble drugs. In this study, a highly biocompatible hydrophilic polymer, polyvinylpyrrolidone (PVP), was selected as a carrier, mixed with different proportions of SD to produce SD-PVP microfibers by solution electrospinning. By orthogonal experiments, the optimal spinning conditions of the preparation of SD-PVP fibers were investigated. The morphology of different proportions of SD-PVP microfibers was observed by scanning electron microscopy, and the phase characteristics were characterized by Fourier transform infrared spectrometry, X-ray diffraction, and differential scanning calorimetry. The hydrophilic properties of SD-PVP fiber membranes with different SD content were analyzed by the water contact angle assay. In vitro dissolution experiments were carried out to observe the dissolution of drugs in SD-PVP fiber membranes. The results showed that the diameter of SD-PVP fibers increased with the enlargement of SD content. A eutectic mixture was formed after blending PVP and SD, and the hydrogen bonds were formed between the SD and PVP with no chemical reaction occurred. The dispersion of SD in the fiber decreased with the increase of SD content. The higher the content of SD in the fiber, the more hydrophobic the fiber membrane. In vitro dissolution studies revealed that the dissolution content of SD from SD-PVP microfibers was significantly higher than that of the pure or original drug SD. However, as the SD content increased from 15% to 30%, the dissolution of the drug in the SD-PVP fibers decreased. The SD-PVP fiber prepared in this study showed much higher solubility than the original drug in vitro, which has great significance for the development of new dosage forms for the clinical application of SD, and it has a useful reference for the study of similar bioavailability of poorly soluble drugs.     

Novel chitosan-based hyaluronan hybrid polymer fibers as a scaffold in ligament tissue engineering

To clarify the feasibility of using novel chitosan-based hyaluronan hybrid polymer fibers as a scaffold in ligament tissue engineering, their mechanical properties and ability to promote cellular adhesion, proliferation, and extracellular matrix production were studied in vitro. Chitosan fibers and chitosan-based 0.05% and 0.1% hyaluronan hybrid fibers were developed by the wet spinning method. Hyaluronan coating significantly increased mechanical properties, compared to the chitosan fibers. Rabbit fibroblasts adhesion onto hybrid fibers was significantly greater than for the control and chitosan fibers. For analysis of cell proliferation and extracellular matrix production, a three-dimensional scaffold was created by simply piling up each fiber. At 1 day after cultivation, the DNA content in the hybrid scaffolds was higher than that in the chitosan scaffold. Scanning electron microscopy showed that the fibroblasts had produced collagen fibers after 14 days of culture. Immunostaining for type I collagen was clearly predominant in the hybrid scaffolds, and the mRNA level of type I collagen in the hybrid scaffolds were significantly greater than that in the chitosan scaffold. The present study revealed that hyaluronan hybridization with chitosan fibers enhanced fiber mechanical properties and in vitro biological effects on the cultured fibroblasts.     

琥珀酸美托洛尔HPMC骨架片释放影响因素研究

以羟丙基甲基纤维素（HPMC）为骨架材料，乙基纤维素（EC）为阻滞剂，采用湿颗粒压片法制备琥珀酸美托洛尔亲水凝胶骨架片，考察HPMC用量、HPMC黏度、EC用量、制备方法、压片压力、释放介质及转速对琥珀酸美托洛尔（MS）骨架片体外释药的影响。结果表明，MS骨架片体外释药符合Higuchi方程，药物释放机制是骨架溶蚀和药物扩散的综合效应；HPMC用量与黏度、阻滞剂用量、制备方法、压片压力对释放速率均有显著性影响；释放介质的pH值及转速对释放速率无显著性影响。     

氟尿嘧啶/左旋聚乳酸生物可降解纤维支架载药体系构建与缓释效应

目的 研发一种可供机体埋植的长效的氟尿嘧啶载药纤维支架.方法 有机相分离法制备纤维,扫描电镜（SEM）观察纤维形态,光学显微镜测定纤维直径,红外光谱分析（FTIR）和差示扫描热分析（DSC）鉴定药物载体结合状态并测定纤维中PLLA的结晶度,紫外分光光度法（UV）测定纤维的载药量以及体外释放.结果 制备出微米级的载药纤维,载药量与载药效率均较高;药物与聚乳酸属于简单物理混合;相对应两种结构模式载药纤维呈现两种释放模式.结论 b型结构纤维适合于开发成长效的在位埋植载药纤维支架.     

静电纺丝聚膦腈/明胶复合纤维支架的生物矿化行为**◆

背景：虽然静电纺丝高分子纤维的生物矿化研究文章已不少见,但国内外尚无关于静电纺丝聚膦腈及其与明胶复合纤维的生物矿化研究报道。 目的：考察聚膦腈/明胶复合纤维支架作为骨组织工程支架的可行性。 方法：静电纺丝法构建生物可降解聚膦腈/明胶复合纤维支架,采用5倍模拟体液,并结合扫描电镜、X射线能谱、X射线光电子能谱、傅里叶变换红外光谱等手段,观察其生物矿化行为。 结果与结论：与纯明胶的纤维膜相比,聚(丙氨酸乙酯-甘氨酸乙酯)膦腈(PAGP)和明胶混合溶液静电纺丝得到的复合纤维膜,经交联处理后仍能够保持良好的纤维形貌和多孔结构。在采用CO2平衡的改进5倍模拟体液中,纯PAGP和PAGP/明胶纤维表面沉积的矿物质都经历了片状二水合磷酸一氢钙前驱体的生成及其向羟基磷灰石转化的过程,但后者由于明胶成分的存在,整个过程发生发展的速度要明显快于前者。而对于纯明胶纤维,其在改进5倍模拟体液中浸泡24 h后,所生成矿物质仍主要为羟基磷灰石的前驱体二水合磷酸一氢钙。说明复合纤维中,疏水性PAGP的引入不仅有利于纤维形貌的保持,还能抑制明胶的溶出,使PAGP /明胶复合纤维的矿化性能明显改善。       

Electrospun biphasic drug release polyvinylpyrrolidone/ethyl cellulose core/sheath nanofibers

The capability of core/sheath nanofibers prepared using coaxial electrospinning to provide adjustable biphasic drug release was investigated. Using ketoprofen (KET) as the model drug, polyvinylpyrrolidone as the sheath polymer, and ethyl cellulose as the core matrix, the coaxial process could be conducted smoothly and continuously without spinneret clogging. Scanning electron microscopy and transmission electron microscopy revealed linear nanofibers with homogeneous and clear core/sheath structures. Differential scanning calorimetry and X-ray diffraction verified that the core/sheath nanofibers were nanocomposites, with the drug present in the polymer matrix in an amorphous state. Attenuated total reflectance–Fourier transform infrared spectra demonstrated that the sheath polymer and core matrix were compatible with KET owing to hydrogen bonding. In vitro dissolution tests showed that the core/sheath nanofibers could provide typical biphasic drug release profiles consisting of an immediate and sustained release. The amount of drug released in the first phase was tailored by adjusting the sheath flow rate, and the remaining drug released in the second phase was controlled by a typical diffusion mechanism. The present study shows a simple and useful approach for the systematic design and fabrication of novel biomaterials with structural characteristics for providing complicated and programmed drug release profiles using coaxial electrospinning.     

Influence of sol and stage of spinnability on in vitro bioactivity and dissolution of sol-gel-derived SiO2 fibers

The ability of the sol-gel-derived green state silica fibers to induce the formation of bone-like calcium phosphate (HCA) on their surfaces has not been studied earlier. Bioactive silica fibers provide alternatives for the design of novel products, e.g., as implants used in tissue guiding or bone repairs. In this study, dry spinning was used to prepare the sol-gel fibers. Different fibers with different bulk structures were prepared by changing the composition and controlling the stage of spinnability. Additionally, the influence of the aging time of the fibers on the bulk structure of the samples was investigated. Furthermore, the ability to form calcium phosphate was investigated in vitro in the simulated body fluid (SBF). Transmission electron microscopy was used to illustrate the bulk structure of the green state fibers and scanning electron microscopy to illustrate the formed calcium phosphate layer on the fibers. The fibers were additionally characterized by measuring the dissolution of the silica in the SBF. In vitro bioactive silica fibers were successfully prepared. The calcium phosphate layer was formed within 1-5 days in the best case. The structural stability and the in vitro bioactivity varied with the aging time expect in one case where practically stable fibers could be prepared. The concentration of silica released in the SBF had no direct connection with the HCA formation. The silica-rich gel layer was not observed on the fibers, but the structure of the fibers was suggested to have an important role in the HCA formation.     

Gentamicin release from modified acrylic bone cements with lactose and hydroxypropylmethylcellulose

Modified polymethylmethacrylate (PMMA) bone cements formulations were prepared by including different proportions of gentamicin and release modulators such as lactose or hydroxypropylmethylcellulose (HPMC). Surface aspect, gentamicin release and porosity of these modified formulations were studied by means of scanning electron microscopy (SEM), a specially designed system for the dissolution studies of the bone cements, and mercury intrusion porosimetry. Lactose modified cements presented an irregular surface with numerous hollows and voids due to the lactose dissolution. HPMC cements presented a characteristic laminated and flaky surface. The drug release of lactose formulations was up to four-fold greater (13%) than the commercial bone cement CMW1 Gentamicin one (3%). The amount of gentamicin eluted at the first withdrawn sample ranged from 30% to 60% of total gentamicin released over the assay. Gentamicin release from lactose formulations increased as lactose percentage was increased which agree with the porosity results. Nevertheless, the use of release modulator HPMC increased porosity, but did not produce an increase in the gentamicin release. HPMC dissolution creates a surrounding sticky and viscous medium similar to a gel that makes the gentamicin release from the cement matrix difficult.     

Artemisinin–Polyvinylpyrrolidone Composites Prepared by Evaporative Precipitation of Nanosuspension for Dissolution Enhancement

Nanoparticles of a poorly water-soluble anti-malarial drug, artemisinin (ART), and its composite particles with a hydrophilic polymer, polyvinylpyrrolidone (PVP), were synthesized using a nanofabrication method called the evaporative precipitation of nanosuspension (EPN). ART nanoparticles and ART/PVP composite particles containing ART nanoparticles coated with PVP were successfully prepared with the aim of improving the dissolution rate of ART. The effect of polymer concentration on the physical and morphological properties, and dissolution rate of the EPN-prepared ART/PVP composite particles was investigated. The crystallinity of ART nanoparticles decreased with increasing polymer concentration, as suggested by the differential scanning calorimetry and X-ray diffraction studies. The phase solubility studies revealed an A_L-type of curve, indicating a linear increase in the drug solubility with PVP concentration. The dissolution of the ART nanoparticles and ART/PVP composite particles markedly increased as compared to that of the original ART powder due to lower particle size and reduced crystallinity of the drug particles. The percent dissolution efficiency (DE), relative dissolution (RD), t _75% and similarity factor (f ₂) were calculated for the statistical analysis. Various mathematical models, viz., zero-order, first-order, Korsemeyer–Peppas and Higuchi, were applied to fit the experimental drug-dissolution data and diffusion was found to be the drug release mechanism.     

Homogeneous chitosan-PLGA composite fibrous scaffolds for tissue regeneration

Novel chitosan-poly(lactide-co-glycolide) (PLGA) composite fibers and nonwoven fibrous scaffolding matrices were designed for cartilage regeneration. A homogenous one-phase mixture of chitosan and PLGA at a ratio of 50:50 (w/w %) was successfully produced using cosolvents of 1,1,1,3,3,3-hexafluoroisopropanol and methylene chloride. A wet spinning technique was employed to fabricate composite fibrous matrices. Physical characterizations of one-phase chitosan-PLGA composite (C/Pc) matrices were performed for their homogeneity, in vitro degradability, mechanical property and wettability in comparison to two-phase chitosan and PLGA composite fibrous matrices in which PLGA was dispersed in a continuous chitosan phase. The one-phase property of C/Pc matrices was confirmed from thermal analysis. Significantly retarded degradation was observed from the composite C/Pc fibrous matrices in contrast to the PLGA-dispersed chitosan (C/Pd) fibrous matrices due to the effective acid-neutralizing effect of chitosan on acid metabolites of PLGA. The composition of chitosan with PLGA resulted in a characteristic soft and strong mechanical property that could not be retained by either PLGA or the chitosan fibers. In addition, the presence of chitosan in the composite matrices provided proper wettability for cell cultivation. The C/Pc matrices were further investigated for their scaffolding function using chondrocytes for cartilage regeneration. Enhanced cell attachment was observed on the composite matrix compared with the PLGA fibrous matrices. The mRNA expression of type II collagen and aggrecan was upregulated in the composite matrix owing to the superior cell compatibility of chitosan. These results suggest an excellent potential for C/Pc one-phase composite fibrous matrices as scaffolding materials for tissue regeneration.     

Paclitaxel-eluting composite fibers: drug release and tensile mechanical properties

New core/shell fiber structures loaded with paclitaxel were developed and studied. These composite fibers are ideal for forming thin, delicate, biomedically important structures for various applications. Possible applications include fiber-based endovascular stents that mechanically support blood vessels while delivering drugs for preventing restenosis directly to the blood vesel wall, or drug delivery systems for treatment of cancer. The core/shell fiber structures were formed by "coating" dense core fibers with porous paclitaxel-containing poly(DL-lactic-co-glycolic acid) (PDLGA) structures. Shell preparation ("coating") was performed by freeze-drying water in oil emulsions. The present study focused on the effects of the emulsion's formulation (composition) and processing conditions on the paclitaxel release profile and on the fibers' tensile mechanical properties. In general, the porous PDLGA shell released approximately 40% of the paclitaxel, with most of the release occurring during the first 30 days. The main release mechanism during the tested period is diffusion, rather than polymer degradation. The release rate and quantity increased with increased drug content or decreased polymer content, whereas the organic:aqueous phase ratio had practically no effect on the release profile. These new composite fibers are strong and flexible enough to be used as basic elements for stents. We demonstrated that proper selection of processing conditions based on kinetic and thermodynamic considerations can yield polymer/drug systems with the desired drug release behavior and good mechanical properties.     

Preparation and properties of ProNectin F-coated biodegradable hollow fibers

ProNectin F-coated biodegradable hollow fibers were newly prepared and their cytocompatibility was evaluated in vitro. Although the coating efficiency onto poly(l-lactic acid) (PLLA) and poly(lactide-co-caprolactone) [p(LA/CL)] matrices was similar, the cell adhesion properties were greatly affected by the nature of the polymer substrate. ProNectin F-coated PLLA showed about seven times higher cytocompatibility than ProNectin F-coated p(LA/CL). The single-extruded melt spinning method and the core–sheath bicomponent melt spinning method were employed to prepare PLLA hollow fibers. The effect of the spinning conditions, such as the melt draw ratio, spinneret temperature, and take-up speed, on the diameter and wall thickness of the spun fibers was studied in detail. For single-extruded melt spinning, a segmented type of spinneret was used, and the effect of the flow rate of nitrogen, which was confined in the hollow part of fibers, was studied. X-ray photographs of the drawn hollow fibers, clarified the significant molecular orientation, which was much higher than that in drawn solid PLLA fiber under identical drawing conditions. The morphology and mechanical properties of hollow fibers demonstrated an increase in the tensile strength and a decrease in the thickness of the PLLA wall with increased nitrogen flow rates and melt draw ratios for single-extruded melt spinning. These results indicate the unique characteristics of ProNectin F-coated PLLA hollow fibers, which can be successfully utilized as a biodegradable substrate.     

盐酸恩丹西酮缓释片的研制及体外释药特性

制备盐酸恩丹西酮缓释片并对影响释药的因素进行考察。以羟丙甲纤维素（HPMC）为骨架材料制备了盐酸恩丹西酮缓释片，通过正交设计试验优选最佳处方和工艺。对影响释药的因素，如HPMC的黏度和用量、填充剂的种类、制片工艺、润湿剂及释放介质pH等进行了考察。盐酸恩丹西酮缓释片体外释药符合Higuchi方程，HPMC的黏度、填充剂的种类及测定释放度的转速对该缓释片的释药几乎无影响，而制片工艺、润湿剂及释放介质pH值对缓释片释药影响较大。盐酸恩丹西酮缓释片在体外12h缓释效果较好。     

Biodegradable polyhydroxyalkanoate implants for osteomyelitis therapy: in vitro antibiotic release

Various random copolyesters of 3-hydroxybutyrate and 3-hydroxyvalerate (PHBV) and 3-hydroxybutyrate and 4-hydroxybutyrate P(3HB-4HB) were used in the construction of biodegradable, implantable rods for the local delivery of antibiotics (Sulperazone and Duocid) in chronic osteomyelitis therapy. Drug loading, type of active agent, and additional coating of the implant surface all have significant contributions to the in vitro release profile. The rate and duration of Sulperazone release from P(3HB-4HB) rods were controlled by the polymer/drug ratio (drug loading). The rate of drug dissolution was substantially higher than that of polymer degradation. Therefore, the release phenomenon was more dependent on drug dissolution rather than on polymer degradation or diffusion. Coating rods with the same type of polymer substantially reduced the initial burst effect observed with the uncoated rods, and significantly decreased the release rate so that the release kinetics became almost zero order. Antibiotic release from coated rods was sustained for over a period of 2 weeks at a constant rate, whereas uncoated rods released their contents in less than a week. Impregnation of Duocid into the hydrophobic polymer matrix yielded a rod with a smoother surface topography. The release from these rods was significantly higher than for rods loaded with Sulperazone and a zero order release could not be obtained with these samples.     

Cotton-wool-like bioactive glasses for bone regeneration

Inorganic sol–gel solutions were electrospun to produce the first bioactive three-dimensional (3-D) scaffolds for bone tissue regeneration with a structure like cotton-wool (or cotton candy). This flexible 3-D fibrous structure is ideal for packing into complex defects. It also has large inter-fiber spaces to promote vascularization, penetration of cells and transport of nutrients throughout the scaffold. The 3-D fibrous structure was obtained by electrospinning, where the applied electric field and the instabilities exert tremendous force on the spinning jet, which is required to be viscoelastic to prevent jet break up. Previously, polymer binding agents were used with inorganic solutions to produce electrospun composite two-dimensional fibermats, requiring calcination to remove the polymer. This study presents novel reaction and processing conditions for producing a viscoelastic inorganic sol–gel solution that results in fibers by the entanglement of the intermolecularly overlapped nanosilica species in the solution, eliminating the need for a binder. Three-dimensional cotton-wool-like structures were only produced when solutions containing calcium nitrate were used, suggesting that the charge of the Ca²⁺ ions had a significant effect. The resulting bioactive silica fibers had a narrow diameter range of 0.5–2 μm and were nanoporous. A hydroxycarbonate apatite layer was formed on the fibers within the first 12 h of soaking in simulated body fluid. MC3T3-E1 preosteoblast cells cultured on the fibers showed no adverse cytotoxic effect and they were observed to attach to and spread in the material.     

Role of polymer matrix on the conductivity of polymers doped with tetracyanoquinodimethane (TCNQ) salts of polycations

The influence of interactions with polymer matrix on the critical concentration and stability of heterogeneous conductive polymer films was investigated. These films were obtained by reticulate doping of polyacrylonitrile (PAN), poly(methyl methacrylate) (PMMA) and polycarbonate (PC) with complex salts of tetracyanoquinodimethane (TCNQ) with polycations having sulfonium groups in the main chain, Ks[4,6]. It was found that the chemical structure of the matrix influences the conductivity of such systems. The PMMA matrix is most suitable for obtaining conducting systems at low concentration of the dopant. In PMMA the absorption spectra of moleculary dispersed Ks[4,6] do not change with time. The strong influence of PAN matrix was confirmed by the study of absorbance changes of Ks[4,6] with time in this matrix and particularly by investigation of absorption of this salt in solutions containing acrylonitrile/methyl methacrylate copolymers of various composition.     

Biocompatibility of novel polymer-apatite nanocomposite fibers

On the basis of the bioactivity of hydroxyapatite (HA) and the excellent mechanical and biocompatible performance of polyethylene terephthalate (PET), composite microfibers made of nanograde HA with PET was designed and fabricated to mimic the structure of biological bone, which exhibits a composite of nanograde apatite crystals and natural polymer. The PET/HA nanocomposite was molded into fibers so that the bulk structures' mechanical properties can be custom tailored by changing the final 3D orientation of the fibbers. This study focused on the in vitro biocompatibility evaluation of the PET/HA composite fibers as potential bone fixation biomaterial for total hip replacement prosthesis surfaces. The MTT assay was performed with the extracts of the composite fibers in order to evaluate the short-term effects of the degradation products. The cell morphology of L929 mouse fibroblast cell line was analyzed after direct contact with the fiber scaffolds for different time periods, and the cell viability was also analyzed by the Alamar Blue assay. The release of the inflammatory cytokine, tumor necrosis factor-alpha (TNF-alpha), from RAW 264.7 macrophages in the presence of fiber extracts and fibers was used as a measure of the inflammatory response. The ability of the fiber matrices to support L929 attachment, spreading, and growth in vitro, combined with the compatible degradation extracts and low inflammation potential of the fibers and extracts, suggests potential use of these fibers as load-baring bone fixation biomaterial structures.     

Effect of water storage of E-glass fiber-reinforced composite on adhesion of Streptococcus mutans

This study investigated the effect of water storage of fiber-reinforced composite on the adhesion of Streptococcus mutans (S. mutans) and its ability to stay adhered and multiply on the FRC. The materials (E-glass fibers and denture base polymer) were stored in water for 14 or 30 days or left dry. Water contact angles of the materials before and after water storage were determined. Test specimens, with or without parotid saliva or serum pellicle, were incubated in a suspension of S. mutans allowing initial adhesion to occur. Bacterial adhesion and multiplication was studied using scanning electron microscopy. Contact angles of both materials were significantly reduced after water storage indicating an increase in surface free energy. When studied without a surface pellicle, water storage significantly increased adhesion of S. mutans to both glass and polymer. Saliva coating of the materials resulted in higher degree of adhesion to glass fibers in comparison with polymer and after 14 days water storage glass bound over twice as much S. mutans cells than the polymer matrix. Bacterial growth and biofilm formation occurred equally on both materials. The results of this in vitro study suggest that in order to avoid the possible increase in S. mutans adhesion, the reinforcing glass fibers should be covered with the matrix polymer of the composite.     

In vitro evaluation of poly(epsilon-caprolactone-co-DL-lactide)/ bioactive glass composites

In vitro bioactivity of composites of poly(epsilon-caprolactone-co-DL-lactide) P(CL/DL-LA) containing different amounts (40, 60 and 70 wt%) of bioactive glass, S53P4, was evaluated. Two ranges of granule size of bioactive glass (< 45 microm and 90-315 microm) were blended with P(CL/DL-LA) copolymer in a batch mixer. The composites were characterised by dynamic mechanical thermal analysis. The molecular weight and the melting temperature of the copolymer matrix were adjusted to enable the application of the composite material by injection below 50 degrees C. Formation of Ca-P deposition on the surface of the composites after dissolution in simulated body fluid at 37 degrees C was recorded by scanning electron microscopy. Degradation of the composite material was measured by water absorption and changes in the average molecular weights as a function of the dissolution time. In vitro bioactivity was found to be dependent on the weight fraction and granule size range of the bioactive glass used. The presence of the bioactive filler also accelerated the degradation compared with the neat polymer sample.