Development of an injectable two-phase drug delivery system for sequential release of antiresorptive and osteogenic drugs

Unlike controlled release systems that deliver a single drug, dual or multidrug delivery systems with distinct release profiles are more likely to promote timely and effective tissue regeneration as they provide both temporally and concentration-dependent release of different molecules to mimic natural biological events. In this study, an injectable and biodegradable delivery system was developed to sequentially release an antiresorptive drug (clodronate) followed by an osteogenic agent (simvastatin) to treat bone disease. The injectable delivery system comprised simvastatin-loaded gelatin microspheres suspended in a viscous solution of carboxymethylcellulose (CMC) containing clodronate. Several factors (CMC concentration, glutaraldehyde concentration, simvastatin loading, and gelatin microsphere processing conditions) were investigated for their effects on drug release. Clodronate release was not affected by CMC concentration, with complete delivery within 12 hr, and simvastatin release could be modulated by cross-linking of the gelatin microspheres, loading, and washing conditions. Burst release of simvastatin was reduced from 70% to 6% in conjunction with sustained release for up to 3 weeks. The combined system showed early release of the antiresorptive clodronate sequentially followed by sustained delivery of the osteogenic simvastatin. This robust and flexible two-phase delivery system may prove useful for applications in which multiple drug delivery is desired.     

膜乳化法制备单分散性载羟基喜树碱缓释微球

目的 研究利用微孔膜乳化法制备载抗癌药10-羟基喜树碱（IqCPT）缓释微球的可行性。方法 以HCPT为模型药物,聚乳酸（PEA）为载体,以膜乳化法制备载药微球,并研究制剂的表面形态、载药率、包封率和缓释效果等性质。结果 膜乳化法制备的载HCPT聚乳酸微球,粒径可控制在1-10μm之间。表面圆整,稳定性、单分散性良好,载药率和包封率最高分别可达32．7％和81．7％,24h体外累积释放量为17．3％。结论 膜乳化法制备的载HCPT微球制剂均匀分散,具有明显缓释效果,是制备缓释微球制剂的较好方法。     

Poly (ε-caprolactone) coating delays vancomycin delivery from porous chitosan/β-tricalcium phosphate composites

The orthopedic infection, such as osteomyelitis, especially those caused by Methicillin-resistant Staphylococcus aureus (MRSA), remains a major complication of open fractures. Local vancomycin delivery is considered to provide better methods when avascular zones prevent the delivery of drugs from conventional routes of administration. Chitosan (CS) delivery system has been developed with the disadvantages, such as mechanically weakness, lacking osteoconductivity, and the initial burst of antibiotics into the environment. The aim of this study was to confirm that the prepared CS/β-tricalcium phosphate (β-TCP) composites coated with poly (ε-caprolactone) (PCL), similar to natural bone in components, had a three-dimensional porous structure and could be used as drug carriers to deliver vancomycin in a sustained and controlled manner effectively for 6 weeks at levels to inhibit MRSA proliferation. We prepared porous CS/β-TCP composites by incorporating β-TCP into the system, and coated the composites with PCL of three different concentrations. The morphological structure of composites, including pore size and porosity, was examined. The result showed that CS/β-TCP coated with 2.5w/v% PCL solution had the best coating effect and it retarded the release of vancomycin in a near zero-order mechanism from 0 to 14 days. The drug delivery was significantly delayed after coated with 2.5w/v% PCL. The quantitative release of vancomycin was extended to 42 days. Therefore PCL coating could be used to retard the release of vancomycin from CS/β-TCP composites in a sustained and controlled manner. Porous CS/β-TCP coated with PCL might be one of the candidate vancomycin carriers for treating MRSA-related osteomyelitis. ? 2012 Wiley Periodicals, Inc. J Biomed Mater Res Part B: Appl Biomater, 2012.     

盐酸表阿霉素纳米靶向制剂的缓释效应

背景：盐酸表阿霉素是一种广谱抗生素,目前临床使用的不足多为药物释放快、目标组织药物浓度低,静脉给药后广泛分布于体内各种组织器官,不良反应明显。 目的：针对盐酸表阿霉素临床应用的不足,制备盐酸表阿霉素纳米靶向注射制剂。 方法：以叶酸偶联牛血清白蛋白为载体,采用乳化-高压匀质法,制备盐酸表阿霉素纳米靶向注射制剂,以激光粒度分析仪测定纳米颗粒的粒径大小、粒径分布及Zeta电位,扫描电镜观察纳米颗粒的表面形态,高效液相色谱法分析白蛋白负载盐酸表阿霉素纳米制剂的包封率、载药量和释药性能。 结果与结论：制备的盐酸表阿霉素纳米粒外观呈均匀球型,粒径分布较窄,平均粒径为(157.73±     0.40) nm,平均 Zeta 电位为(-30.85±0.43) mV,载药量 22.78%,包封率可达96.24%。体外模拟释药结果表明药物释放曲线分为两个阶段,突释阶段微球释药量在24 h内达42.6%,缓释阶段纳米粒释药持续时间长,在112 h 时释药量达 84.1%,载药纳米粒的药物释放速率持续稳定。结果表明乳化结合高压匀质法制备的盐酸表阿霉素纳米靶向制剂粒径均匀,粒径范围分布窄,载药量和包封率高,具有一定的缓释作用。     

Sequential antibiotic and growth factor releasing chitosan-PAAm semi-IPN hydrogel as a novel wound dressing

The aim of this study is to prepare a novel wound dressing material which provides burst release of an antibiotic in combination with sustained release of growth factor delivery. This might be beneficial for the prevention of infections and to stimulate wound healing. As a wound dressing material, the semi-interpenetrating network (semi-IPN) hydrogel based on polyacrylamide (PAAm) and chitosan (CS) was synthesized via free radical polymerization. Ethylene glycol dimethacrylate was used for cross-linking of PAAm to form semi-IPN hydrogel. The hydrogel shows high water content (～1800%, in dry basis) and stable swelling characteristics in the pH range of the wound media (～4.0–7.4). The antibiotic, piperacillin–tazobactam, which belongs to the penicillin group was loaded into the hydrogel. The therapeutic serum dose of piperacillin–tazobactam for topic introduction was reached at 1st hour of the release. Additionally, in order to increase the mitogenic activity of hydrogel, epidermal growth factor (EGF) was embedded into the CS–PAAm in different amounts. Cell culture studies were performed with L929 mouse fibroblasts and the simulated cell growth was investigated by 3-(4,5-dimethylthiazol-2-yl)-diphenyltetrazolium bromide assay. The successful sustained release behavior of CS–PAAm hydrogel for EGF maintained the presence of EGF in the culture up to 5?days and the highest mitochondrial activities were recorded for the 0.4?μg EGF-loaded/mg of hydrogel group. In conclusion, CS–PAAm semi-IPN hydrogel loaded with piperacillin–tazobactam and EGF could be proposed for an effective system in wound-healing management.     

Growth factor sequestration and enzyme-mediated release from genipin-crosslinked gelatin microspheres

Controlled release of growth factors allows the efficient, localized, and temporally-optimized delivery of bioactive molecules to potentiate natural physiological processes. This concept has been applied to treatments for pathological states, including chronic degeneration, wound healing, and tissue regeneration. Peptide microspheres are particularly suited for this application because of their low cost, ease of manufacture, and interaction with natural remodeling processes active during healing. The present study characterizes gelatin microspheres for the entrapment and delivery of growth factors, with a focus on tailored protein affinity, loading capacity, and degradation-mediated release. Genipin crosslinking in PBS and CHES buffers produced average microsphere sizes ranging from 15 to 30 microns with population distributions ranging from about 15 to 60 microns. Microsphere formulations were chosen based on properties important for controlled transient and spatial delivery, including size, consistency, and stability. The microsphere charge affinity was found to be dependent on gelatin type, with type A (GelA) carriers consistently having a lower negative charge than equivalent type B (GelB) carriers. A higher degree of crosslinking, representative of primary amine consumption, resulted in a greater negative net charge. Gelatin type was found to be the strongest determinant of degradation, with GelA carriers degrading at higher rates versus similarly crosslinked GelB carriers. Growth factor release was shown to depend upon microsphere degradation by proteolytic enzymes, while microspheres in inert buffers showed long-term retention of growth factors. These studies illuminate fabrication and processing parameters that can be used to control spatial and temporal release of growth factors from gelatin-based microspheres.     

Development and characterization of rifampicin loaded floating microspheres

Gastroretentive floating microspheres have a potential for enhancing the bioavailability and controlled delivery of drugs. The present study involves development of rifampicin floating microspheres in order to increase the gastric retention time. The microspheres were prepared by solvent evaporation technique and characterized for particle size, shape, zeta-potential, entrapment, and release kinetics. The developed systems were almost spherical in shape. The entrapment efficiency was found to be 86.34%. The percentage buoyancy after 8 hours was found to be 61.06. The prepared microspheres exhibited prolonged drug release in gastric medium and hence could be utilized for sustained delivery of anti-tubercular drugs.     

Biodegradable and complexed microspheres used for sustained delivery and activity protection of SOD

To develop a new protein delivery system for superoxide dismutase (SOD), biodegradable materials like poly(DL-lactide-co-glycolide) (PLGA), alginate, and chitosan were used for preparing PLGA microspheres and alginate-chitosan microspheres, which were used for encapsulating protein. Alginate-chitosan microspheres showed much higher entrapment efficiency (91.08% +/- 1.28%) than that of PLGA microspheres (36.42% +/- 1.81%). In vitro release study showed that SOD presented a sustained release character in the preparation of these biodegradable materials. After 15 days, 43.72% +/- 0.43% of protein was released from alginate-chitosan microspheres, while there was 62.96% +/- 3.95% of protein release from PLGA microspheres. However, alginate-chitosan demonstrated that it was a better material to control the burst release of protein from microspheres. Furthermore, SOD activity in microspheres was evaluated, and the results showed that microspheres protected the activity of protein to some extent. Finally, PLGA-alginate-chitosan complex microspheres were constructed and the release character in vitro demonstrated that this preparation could not only prolong the release of drug but also decrease the burst release.     

Development and in vitro characterization of vascular endothelial growth factor (VEGF)-loaded poly(DL-lactic-co-glycolic acid)/poly(ethylene glycol) microspheres using a solid encapsulation/single emulsion/solvent extraction technique

Poly(DL-lactide-co-glycolide) (PLGA)/polyethylene glycol (PEG) microspheres are one modality of controlled delivery of biologically active molecules that would further the development of engineered tissues. As a possible mechanism to stimulate angiogenesis within an engineered tissue, vascular endothelial growth factor (VEGF) and bovine serum albumin (BSA) were coencapsulated into microspheres fabricated from PEG and 50/50 PLGA using a solid-encapsulation/single-emulsion/solvent extraction technique. Two VEGF/BSA ratios were studied: 1:2000 and 1:10,000. Analysis consisted of the loading efficiency, particle size distribution, bright-field microscopy, scanning electron microscopy, release kinetics, and an in vitro human umbilical vein endothelial cell proliferation assay to assess biological activity of the released VEGF. Results show the microspheres could be manufactured, stored, and degraded over 28 days. The burst release rates for 1:2000 and 1:10,000 VEGF/BSA microspheres were 71.87 +/- 8.11 and 27.91 +/- 1.71 ng/mL (mean +/- standard error of the mean), respectively; steady-state release rates were 6.56 +/- 1.10 and 2.21 +/- 0.47 ng/mL, respectively. The microspheres released biologically active VEGF, and the VEGF increased the proliferation of HUVECs in culture (p <.05). The successful development of a novel, cost-effective, scalable technique for producing microspheres loaded with biologically active proteins is presented. Using the data obtained from these studies, a defined concentration of microspheres will deliver a quantifiable level of VEGF at a known release rate.     

Poly(methyl methacrylate)-grafted chitosan microspheres for controlled release of ampicillin

Microspheres of 50-500 microm diameter were prepared from a blend of chitosan and chitosan-g-PMMA. Environmental scanning electron microscopic and SEM studies revealed that the microspheres are porous and the pores extend toward the inner core of the microspheres. The microspheres were also found to be hemocompatible and cytocompatible. A model drug ampicillin was used to evaluate the drug loading capacity and the controlled release properties of the microspheres. The system maintained a sustained release of ampicillin for a period of more than 8 days. The drug-loaded chitosan/chitosan-g-PMMA microspheres exhibited higher antibacterial activity for both the gram positive (ATCC 25923 S. aureus) and gram negative (ATCC 25922 E. coli) bacteria than the drug-loaded virgin chitosan microspheres. The percentage release and bioactivity of ampicillin was found to be higher for the chitosan/chitosan-g-PMMA microspheres than the virgin chitosan microspheres. Potential applications such as oral drug delivery, wound dressings, tissue engineering, and so forth, are envisaged from these microspheres.     

Preparation and characterization of poly(lactic acid)-poly(ethylene glycol)-poly(lactic acid) (PLA-PEG-PLA) microspheres for controlled release of paclitaxel

Microspheres of a new kind of copolymer, poly(lactic acid)-poly(ethylene glycol)-poly(lactic acid) (PLA-PEG-PLA), are proposed in the present work for clinical administration of an antineoplastic drug paclitaxel with hypothesis that incorporation of a hydrophilic PEG segment within the hydrophobic PLA might facilitate the paclitaxel release. Paclitaxel-loaded PLA-PEG-PLA microspheres of various compositions were prepared by the solvent extraction/evaporation method. Characterization of the microspheres was then followed to examine the particle size and size distribution, the drug encapsulation efficiency, the colloidal stability, the surface chemistry, the surface and internal morphology, the drug physical state and its in vitro release behavior. The effects of polymer types, solvents and drug loading were investigated. It was found that in the microspheres the PEG segment was homogeneously distributed and caused porosity. Significantly faster release from PLA-PEG-PLA microspheres resulted in comparison with the PLGA counterpart. Incorporation of water-soluble solvent acetone in the organic solvent phase further increased the porosity of the PLA-PEG-PLA microspheres and facilitated the drug release. A total of 49.6% sustained release of paclitaxel within 1 month was achieved. Potentially, the presence of PEG on the surface of PLA-PEG-PLA microspheres could improve their biocompatibility. PLA-PEG-PLA microspheres could thus be promising for the clinical administration of highly hydrophobic antineoplastic drugs such as paclitaxel.     

Changes in cisplatin delivery due to surface-coated poly (lactic acid)-poly(epsilon-caprolactone) microspheres

Smooth muscle cell proliferation plays a major role in the genesis of restenosis after angioplasty or vascular injury. Local delivery of agents capable of modulating vascular responses, have the potential to prevent restenosis. However, the development of injectable microspheres for sustained drug delivery to the arterial wall is a major challenge. We demonstrated the possibility of entrapping an antiproliferative agent, cisplatin, in a series of surface coated biodegradable microspheres composed of poly(lactic acid)poly(caprolactone) blends, with a mean diameter of 2-10 pm. The microspheres were surface coated with poly ethylene glycol (PEG), chitosan (Chit), or alginate (Alg). A solution of cisplatin and a 50:50 blend of polylactic acid (PLA)-polycaprolactone (PCL) dissolved in acetone-dichloromethane mixture was poured into an aqueous solution of PEG (or polyvinyl alcohol or Chit or Alg) with stirring using a high speed homogenizer, for the formation of microspheres. Cisplatin recovery in microspheres ranged from 25-45% depending on the emulsification system used for the preparations. Scanning electron microscopy revealed that the PLA-PCL microspheres were spherical in shape and had a smooth surface texture. The amount of drug release was much higher initially (20-30%), this was followed by a constant slow-release profile for a 30-day period of study. It has been found that drug release depends on the amount of entrapped drug, on the presence of extra cisplatin in the dispensing phase, and on the polymer coatings. This PEG or Alg-coated PLA/PCL microsphere formulation may have potential for the targeted delivery of antiproliferative agents to treat restenosis.     

Paclitaxel loaded poly(L-lactic acid) microspheres for the prevention of intraperitoneal carcinomatosis after a surgical repair and tumor cell spill

A controlled release delivery system for paclitaxel was developed using poly(L-lactic acid) to provide local delivery to the peritoneal cavity. Microspheres were made in 1-40 and 30-120 microm size ranges. In an in vitro release study, 30-120 microm microspheres loaded with 10, 20 and 30% paclitaxel exhibited a burst phase of release for 3 days followed by an apparently zero-order phase of release. At all loadings, 20-25% of the original load of paclitaxel was released after 30 days. The effect of microsphere size on retention in the peritoneal cavity was assessed. Control 1-40 microm microspheres were injected intraperitoneally in rats. The rats received either insufflation of the peritoneal cavity using 11 mmHg CO2 or no further treatment. After sacrifice, microspheres with diameters less than 24 microm were observed in the lymphatic system after being cleared from the peritoneal cavity through fenestrations in the diaphragm. Insufflation of the peritoneal cavity had no effect on the size of microspheres that were cleared. Efficacy studies were carried out using 30-120 microm microspheres that were of sufficient size to be retained in the peritoneal cavity. In a model of a tumor cell spill after a cecotomy repair, 100 mg of 30-120 microm microspheres containing 30% paclitaxel were effective in preventing growth of tumors in the peritoneal cavity at both 2 and 6 weeks post-surgery. No gross or histologically evident tumor growth was observed on any peritoneal surfaces or in the surgical wound site. Rats receiving control microspheres all showed tumor cell implantation and growth after 2 weeks.     

Hollow quaternized chitosan microspheres increase the therapeutic effect of orally administered insulin

The delivery of insulin by non-parenteral routes has gained significant attention over the last two decades. In the present study, we prepared hollow quaternized chitosan microspheres by the SPG membrane emulsification technique and glutaraldehyde cross-linking method. The structural properties, as well as the uniform size and autofluorescence, enabled us to develop oral delivery of insulin which conserved the bioactivity of the encapsulated insulin, achieving bioadhesion of microspheres, increasing the loading ability and optimizing the release profile. In vivo evaluation also saw an optimal reduction in blood glucose level and powerful therapeutic effects after treatment with the designed microspheres, which further confirmed the feasibility of using hollow quaternized chitosan microspheres as insulin carriers for oral administration.     

Biodegradable polymer-silica xerogel composite microspheres for controlled release of gentamicin

Single and double layered composite microspheres were prepared by encapsulating gentamicin-loaded silica xerogels with biodegradable PLGA polymers (poly(DL-lactide-co-glycolide)). The in vitro drug release properties of both the composite microspheres were investigated. The single layered composite microspheres showed a high initial burst, followed by two sustained release stages lasting for approximately 6 weeks. The two sustained release stages of the single layered composite microspheres could be attributed to the swelling and bulk erosion of the polymer encapsulations, respectively. In comparison with the single layered composite microspheres, the double layered composite microspheres realized a much reduced initial burst together with three sustained release stages. The whole release period of the double layered composite microspheres could last more than 9 weeks. These distinct behaviors make the double layered composite microspheres promising as a new drug release material for localized drug delivery applications.     

载ADM-PLGA纳米微球的ADM-PLGA-NHAC制备及其对人骨肉瘤MG63细胞的抑制作用

目的　研制载阿霉素(ADM)的聚乳酸-羟基乙酸共聚物(PLGA)纳米微球的纳米羟基磷灰石/胶原复合支架（ADM-PLGA-NHAC）,研究其性质及体外释药特点,探讨其体外抑制人骨肉瘤MG63细胞的作用,为骨肉瘤的治疗提供新策略。 方法　以纳米羟基磷灰石及胶原为原料制备纳米羟基磷灰石/胶原支架并在其中加载ADM-PLGA纳米微球, 通过扫描电子显微镜、体外释放行为等手段评价载药支架材料的性能。以CCK8法、活-死染色评价该复合支架的浸提液在体外对人骨肉瘤MG63细胞株的抗肿瘤活性。 结果　复合支架的孔径多在100~200 μm,孔隙率约为82%,微球与支架间结合较为紧密。复合支架具有良好的缓释特性,28 d内能持续缓慢释放阿霉素。复合支架的浸提液对骨肉瘤MG63细胞生长有明显的抑制作用。 结论　制备的ADM-PLGA-NHAC复合支架具有良好的药物缓释特性及抗肿瘤效应,是一种具有良好应用前景的抗骨肉瘤骨修复材料。     

Formulation, characterization and release studies of alginate microspheres encapsulated with tetanus toxoid

Alginate is a safe, non-immunogenic and inexpensive natural polymer with high mucoadhesive properties. Alginate microspheres can be used as a delivery system for antigens to mucosal surfaces. In the present study alginate microspheres were prepared by an emulsification technique. The effects of sonication time, concentration of alginate, emulsifier and calcium chloride, and also the volume of calcium solution, were evaluated on mean size, size range, surface roughness and porosity, sphericity and clumping of microspheres using an optical microscope and particle size analyzer. The most desirable conditions were 90 s sonication, 3% alginate solution, 2% surfactant and 60 ml of 0.33% CaCl2 in octanol. The resulting microspheres had a mean size of 1.34 +/- 0.3 microm and size range of 0.3 +/- 2.0 microm, with no surface roughness and porosity, low clumping and high sphericity. The encapsulation efficiency was about 47.7%. All batches showed nearly the same release profiles with a low burst release. The stability of the model antigen (tetanus toxoid (TT)) extracted from microspheres was confirmed by SDS-PAGE; and the antigenicity of TT was studied by ELISA and found to be 91 +/- 5% of the original TT. It can be concluded that, with regard to the size and morphological characteristics of the prepared microspheres and their ability in preserving the antigenicity of the encapsulated TT, they could be used as a delivery system for mucosal delivery of TT.     

Fabrication and characterizations of a novel drug delivery device liposomes-in-microsphere (LIM)

In the present work, we developed a novel drug delivery system, liposomes-in-microsphere (LIM) of biodegradable polymers, which is conceived from a combination of the polymer- and the lipid-based delivery systems and can thus integrate the advantages and avoid the drawbacks of the two systems. Liposomes were encapsulated into microspheres of biodegradable polymers by the solvent extraction/evaporation process to form LIMs. The integrity of the liposomes was preserved by modifying the microencapsulation process and coating the liposomes with chitosan. We demonstrated by scanning electron microscopy, laser light scattering and fluorescence spectroscopy that the particle size and surface morphology of the polymeric microspheres did not change significantly with the liposomes encapsulated, the liposomes remained intact within the polymeric matrix of the microspheres, and the encapsulated liposomes could be released from the microspheres in a controlled manner at a nearly constant release rate after an initial off-release period. Decreasing the particle size of liposomes and increasing the pore size of the polymeric matrix shortened the initial off-release period and increased the liposome release rate. In conclusion, a novel drug delivery system, liposomes-in-microsphere, was successfully developed and characterized. The liposome release kinetics could be controlled by the composition and fabrication parameters of the liposomes and polymeric microspheres. Such a novel controlled release system may have potential to be applied for drug delivery and gene therapy.     

Multifunctional alginate microspheres for biosensing, drug delivery and magnetic resonance imaging

This research aims to develop and investigate a multifunctional implantable system capable of biosensing, drug delivery and magnetic resonance imaging (MRI) for continuous monitoring, controlled anti-inflammatory drug delivery and imaging, respectively. A glucose biosensor, diclofenac sodium (Diclo) and magnetic nanoparticles (MNP) were used as the biosensor component, anti-inflammatory agent and MRI contrast agent, respectively. MNP were synthesized by the co-precipitation technique and loaded with the sensor and drug components into alginate microspheres using a commercial droplet generator. The multifunctional system was then characterized using optical microscopy, scanning electron microscopy, transmission electron microscopy, X-ray diffraction, vibrating sample magnetometry (VSM) and MRI. The MNP were found to be in the size range of 5-15 nm. The final system, comprising the biosensor, drug and MNP loaded inside alginate microspheres, was found to be in the size range of 10-60 μm. Biosensing studies indicated an excellent glucose response curve, with a regression coefficient of 0.974 (0-10mM of glucose, response time: 4 min). In vitro Diclo release shows that MNP loading in alginate microspheres increases the burst release percentage by 11-12% in both 60 and 10 μm particles. However, the duration of release for 85% drug release decreases with MNP loading by 7 and 6 days for 39 the 60 and 10 μm particles, respectively. Super-paramagnetism was confirmed by VSM, with 2.09 and 1.368 emu g(-1), respectively, for the 60 and 10 μm particles, with no hysteresis. MRI showed significant contrast for both sizes. The particles showed an excellent biocompatibility (>80%) for all combinations of formulations. The system shows a great potential for biosensing with concurrent drug delivery and visualization for biomedical applications.     

bFGF缓释微球的制备及其促雪旺细胞分裂增殖的初步研究

研究碱性成纤维细胞生长因子(bFGF)缓释微球的制备方法及其对雪旺细胞的促分裂增殖作用。以聚乳酸-羟基乙酸共聚物(PLGA)为载体材料,采用复乳包囊法制备bFGF-PLGA缓释微球,并对微球的形态学、粒径分布、载药量和包封率、及体外释药进行研究。将bFGF、bFGF-PLGA微球分别加入不同组的雪旺细胞培养液中,分别测定雪旺细胞的数量、活力和细胞周期。结果显示,复乳包囊法制备的bFGF-PLGA缓释微球表面光滑圆整,球体均匀度好;微球平均粒径为1.552±0.015μm,平均径距为1.310±0.010;载药量和包封率分别为(27.18×10-3)%±(0.51×10-3)%、66.43%±1.24%;微球的体外释药过程较为稳定,11d释药率为72.47%。体外细胞试验中,培养1、2d时,bFGF组的细胞计数、吸光度明显高于bFGF缓释微球组;培养3、4d时,bFGF组和bFGF缓释微球组的细胞计数、吸光度无统计学差异;培养6、8d时,bFGF缓释微球组的细胞计数、吸光度明显高于bFGF组。流式细胞仪检测结果显示,培养2d后,bFGF组的G2/M S期百分数高于bFGF缓释微球组;培养4、8d后,bFGF缓释微球组的G2/M S期百分数高于bFGF组,差异具有统计学意义。说明采用复乳包囊法制备bFGF-PLGA缓释微球的工艺可行,微球中bFGF的生物活性保存良好,能缓慢持续释放活性bFGF,促进雪旺细胞的分裂增殖。