Synthesis,characterization, biodegradation,and drug delivery application of biodegradable lactic/glycolic acid polymers. Part II: Biodegradation

A series of previously-synthesized lactic/glycolic acid polymers (PLGA) with various molar ratios of lactic to glycolic acid and various molecular weights were further studied with regard to their biodegradation behavior, and in particular, the factors affecting the biodegradation rate. The biodegradation of PLGA is affected by many factors including polymer composition, molecular weight, and nature of the incubating media. The biodegradation rate of PLGA containing higher content of lactic acid moiety is lower than those containing a lower content of lactic acid moiety. PLGAs with a higher molecular weight, degrade faster than those with a lower molecular weight, i.e. the molecular weight decreases more rapidly for higher molecular weight PLGAs than their lower molecular weight counterparts. Nature or properties of the hydrolysis/incubating media may have an effect on the biodegradation of PLGAs. A basic medium may slow down the biodegradation of PLGA in comparison with samples in an acidic medium. The rate of pH reduction for the incubating medium can be divided into three deferent phases, giving an inverted S-type pH profile for the non-buffered incubating media.     

Synthesis, characterization, biodegradation, and drug delivery application of biodegradable lactic/glycolic acid polymers. Part II: biodegradation

A series of previously-synthesized lactic/glycolic acid polymers (PLGA) with various molar ratios of lactic to glycolic acid and various molecular weights were further studied with regard to their biodegradation behavior, and in particular, the factors affecting the biodegradation rate. The biodegradation of PLGA is affected by many factors including polymer composition, molecular weight, and nature of the incubating media. The biodegradation rate of PLGA containing higher content of lactic acid moiety is lower than those containing a lower content of lactic acid moiety. PLGAs with a higher molecular weight, degrade faster than those with a lower molecular weight, i.e. the molecular weight decreases more rapidly for higher molecular weight PLGAs than their lower molecular weight counterparts. Nature or properties of the hydrolysis/incubating media may have an effect on the biodegradation of PLGAs. A basic medium may slow down the biodegradation of PLGA in comparison with samples in an acidic medium. The rate of pH reduction for the incubating medium can be divided into three deferent phases, giving an inverted S-type pH profile for the non-buffered incubating media.     

Preparation of biodegradable microspheres of testosterone with poly(D,L-lactide-co-glycolide) and test of drug release in vitro

Biodegradable microspheres formulation of testosterone (T) can be used as a new physiological approach for androgen replacement in hypogonadal men. In this study, poly(D,L-lactide-co-glycolide) (PLGA) microspheres containing T were prepared by a solvent-evaporation/solvent-diffusion process and the drug release tests of the microspheres were carried out in vitro. T/PLGA microspheres with good yield, desired size and satisfied drug loading were obtained. A significant testosterone sustained release was shown in the drug release tests in vitro. Since PLGA microspheres preparations are normally sterilized by colbat-60 irradiation, the effects of 25 kGy colbat-60 irradiation on physicochemical properties and in vitro drug release profile of T/PLGA microsphere were investigated. The results showed that the irradiation didn't have any effects on the physicochemical properties of T. Though about one-third decrease in molecular weight of PLGA was caused by the irradiation, no significant changes were observed on the drug release profile in vitro.     

Biodegradable poly (lactic acid) microspheres for drug delivery systems

In connection with aim of maximizing the bio-availability of conventional drugs with minimum side-effects, new drug delivery systems (DDS) continue to attracted much attention. The controlled or sustained release of drugs represents one such approach, and in this regard report upon a study of DDS using biodegradable polymers which include poly (lactic acid) (PLA), poly (glycolic acid), and their copolymers (PLGA). Much attention is being paid to the controlled release of bio-active agents from microcapsules and microspheres made of biodegradable polymers, such as lactic acid homopolymers, as well as copolymers of glycolic acid. (11-21) Microcapsules or microspheres are injectable and able to provide pre-programmed durations of action, offering several advantages over the conventional dosage forms. This article reviews the results of a work program conducted in collaboration with a medical doctor upon DDS using biodegradable microspheres, such as PLA and PLGA.     

Paclitaxel and etoposide-loaded Poly (lactic-co-glycolic acid) microspheres fabricated by coaxial electrospraying for dual drug delivery

Abstract

In this study, we fabricated paclitaxel (PTX) and etoposide (ETP) loaded Poly (lactic-co-glycolic acid) (PLGA) microspheres with core–shell structures and particle sizes ranging from 1 to 4?µm by coaxial electrospraying. The microspheres were analyzed by scanning electron microscopy (SEM), transmission electron microscopy (TEM). The drug loading rate and entrapment efficiency of the microspheres were detected by high performance liquid chromatograph (HPLC). Moreover, the drug release profiles and degradation of drug-loaded PLGA microspheres in vitro were investigated, respectively. The distinct layered structure that existed in the manufactured core–shell microspheres can be observed by TEM. The in vitro release profiles indicated that the PLGA/PTX?+?ETP (PLGA/PE) microspheres exhibited the controlled release of two drugs in a sequential manner. Cell Counting Kit-8 was used to detect the toxic and side effects of the microspheres on bone tumor cells. PTX and ETP for combination drug therapy loaded microspheres had more cytotoxic effect on saos-2 osteosarcoma cells than the individual drugs. In conclusion, core–shell PLGA microspheres by electrospraying for combination drug therapy is promising for medicine applications, the PLGA/PE microspheres have some potential for osteosarcoma treatment.     

Development of chondroitin sulfate encapsulated PLGA microsphere delivery systems with controllable multiple burst releases for treating osteoarthritis

The purpose of the study was to design and develop unique drug delivery systems with controllable multiple burst releases of drugs for treating osteoarthritis. Chondroitin sulfate (CS) was encapsulated into four types of PLGA materials, that is, PLGA 50:50, PLGA 65:35, PLGA 75:25, and PLGA 85:15. The effects of microsphere size and various combinations of blend PLGA microspheres on CS release were investigated. The cytotoxicity of the CS-encapsulated microspheres was investigated according to the ISO 10993 guideline. Our study showed that the encapsulation efficiency of CS into PLGA 50:50 microspheres varied with the size of microspheres; however, the encapsulation efficiencies of CS into PLGA microspheres were independent of the types of PLGA materials. The size of PLGA microspheres was shown to affect the rate of CS release. With the increase of microsphere size from 75-150 μm to 300-355 μm, the initial CS release decreased. Further increase in microsphere size led to an increase in the initial CS release. In addition, combination of different types of PLGA microspheres was shown to be capable of achieving multiple burst CS releases. Moreover, the CS encapsulated PLGA microspheres were shown to be non-cytotoxic. This study proved the concept of multiple burst drug releases that were achieved by encapsulating CS into different types of PLGA microspheres and delivering CS from systems consisting of mixed types of PLGA microspheres, which may be applied to treat osteoarthritis by mimicking multiple intra-joint injection of therapeutic agents.     

Development of a sustained-release system for perivascular delivery of dipyridamole

Vascular access grafts implanted in dialysis patients are prone to failure in the long-term because of stenosis and occlusion caused by neointimal hyperplasia. Local delivery of antiproliferative drugs may be effective to prevent this consequence while minimizing the systemic side effects they cause. We developed a combination of poly(lactide-co-glycolide) (PLGA) microspheres with ReGel, an injectable copolymer, as a sustained-release system for perivascular delivery of an antiproliferative drug, dipyridamole. Dipyridamole-incorporated PLGA microspheres with various molecular weights (MWs) of PLGA were prepared by oil-in-water emulsion method. Encapsulation efficiency and surface morphology of microspheres were characterized. In vitro release kinetics of dipyridamole from ReGel or from microspheres/ReGel was experimentally determined. Without microspheres, 40% of the dipyridamole was released from ReGel as an initial burst in the first 3 days followed by continuous release in the subsequent 2 weeks. The use of PLGA microspheres decreased the initial burst and extended dipyridamole release from 23 to 35 days with increasing MW of PLGA. The highest MW PLGA showed a lag time of 17 days before consistent drug release occurred. Mixing microspheres and ReGel with two different MW PLGA achieved a continuous release for 35 days with little initial burst. In vivo release of dipyridamole from microspheres/ReGel exhibited a comparable release pattern to that seen in vitro. This injectable platform is a promising technique for sustained perivascular delivery of antiproliferative drugs.     

载羟基喜树碱聚乳酸-羟基乙酸微球的制备及相关性能研究

目的制备一种载羟基喜树碱的聚乳酸-羟基乙酸(PLGA)缓释微球,并考察其相关性能。方法采用乳化-溶剂挥发法制备羟基喜树碱PLGA微球,用扫描电子显微镜观察载药微球表面形态,测定平均粒径及跨距,高效液相色谱检测包封率、载药率及体外释放情况,改良寇氏法计算小鼠半数致死量。结果制备的载药PLGA微球呈圆球形,表面光滑,无粘连,平均粒径30.8μm,跨距0.9,包封率为85.5%、载药率4.28%,在体外28 d累积释放药物81.4%。羟基喜树碱小鼠静脉注射的半数致死量为18.4 mg/kg,肌内注射半数致死量为71.3 mg/kg,而羟基喜树碱PLGA微球肌内注射的半数致死量为138.5 mg/kg。结论乳化-溶剂挥发法制备的羟基喜树碱PLGA微球粒径适宜,包封率、载药率高,缓释效果好,毒性低,具有潜在的临床应用价值。     

Development of biodegradable poly(propylene fumarate)/poly(lactic-co-glycolic acid) blend microspheres. II. Controlled drug release and microsphere degradation

This article describes the effects of six processing parameters on the release kinetics of a model drug Texas red dextran (TRD) from poly(propylene fumarate)/poly(lactic-co-glycolic acid) (PPF/PLGA) blend microspheres as well as the degradation of these microspheres. The microspheres were fabricated using a double emulsion-solvent extraction technique in which the following six parameters were varied: PPF/PLGA ratio, polymer viscosity, vortex speed during emulsification, amount of internal aqueous phase, use of poly(vinyl alcohol) in the internal aqueous phase, and poly(vinyl alcohol) concentration in the external aqueous phase. We have previously characterized these microspheres in terms of microsphere morphology, size distribution, and TRD entrapment efficiency. In this work, the TRD release profiles in phosphate-buffered saline were determined and all formulations showed an initial burst release in the first 2 days followed by a decreased sustained release over a 38-day period. The initial burst release varied from 5.1 (+/-1.1) to 67.7 (+/-3.4)% of the entrapped TRD, and was affected most by the viscosity of the polymer solution used for microsphere fabrication. The sustained release between day 2 and day 38 ranged from 7.9 (+/-0.8) to 27.2 (+/-3.1)% of the entrapped TRD. During 11 weeks of in vitro degradation, the mass of the microspheres remained relatively constant for the first 3 weeks after which it decreased dramatically, whereas the molecular weight of the polymers decreased immediately upon placement in phosphate-buffered saline. Increasing the PPF content in the PPF/PLGA blend resulted in slower microsphere degradation. Overall, this study provides further understanding of the effects of various processing parameters on the release kinetics from PPF/PLGA blend microspheres thus allowing modulation of drug release to achieve a wide spectrum of release profiles.     

BSA-PLGA缓释微球的制备及优化条件的探索

目的以牛血清白蛋白(BSA)为模型蛋白、聚乳酸-聚乙二醇酸(PLGA)为包裹材料,探索微球的制备方法并优化制备工艺。方法采用复乳-溶剂挥发法制备BSA-PLGA微球,显微测量微球粒径,以微量BCA法测定微球的蛋白含量并计算包封率,进行体外释放,测定微球的累积释放量。探索BSA投药量、PLGA用量、PVA浓度、超声功率等因素对微球包封率、突释量的影响。结果通过正交实验设计,优化了微球的制备工艺,其优化条件是BSA投药量为10mg、PLGA用量为250mg、PVA浓度为1.5%、超声乳化功率为60周。结论通过控制不同的因素,可以得到较高包封率、较小突释、适当载药量和粒径的BSA-PLGA微球。     

利福平/聚乳酸-聚羟基乙酸缓释微球的制备及特性

背景：虽然国内外有很多制备利福平/聚乳酸-聚羟基乙酸共聚物(poly lactic acid-glycolic acid copolymer,PLGA)微球的报道,但这些微球粒径多在10 μm左右,不适合与磷酸钙骨水泥复合制备成具有良好降解性的抗结核修复材料。 目的：制备大粒径利福平/PLGA缓释微球,观察其理化特性和体外缓释特性。 方法：以PLGA为载体,将利福平分散于PLGA的有机溶剂中,采用复乳溶剂挥发法制备利福平/ PLGA缓释微球。光镜和扫描电镜下观察微球的形态特征,测定微球平均直径和跨距,高效液相色谱法测定载药量和包封率,以溶出法和高效液相色谱法观察其体外释药特性,并拟合药物体外释放曲线建立曲线方程。 结果与结论：利福平/PLGA微球电镜观察呈圆球形,分散性好,粘连少,粒径分布集中,平均粒径(80.0±9.4) μm。载药量、包封率分别为(33.18±1.36)%,(54.79±1.13)%。体外缓释试验显示突释期内微球释放度为(14.66±0.18)%,前3 d累计释放度(18.09±0.45)%,到42 d体外累积释放度达到(92.17±1.23)%。提示利福平/PLGA微球具有良好的缓释效果,是一种较为理想的抗结核药物的载体材料和释放系统;PLGA是良好的药物缓释载体,可以用来制备载药缓释微球。     

奥曲肽长效生物可降解微球的制备及其分析方法研究

目的运用已正交优化的复乳法制备三批奥曲肽PLGA长效生物可降解微球,并且建立有效的分析方法。方法利用HPLC、激光粒度仪与扫描电镜等仪器对所制备的微球进行综合质量研究。结果在该工艺条件下制得的三批微球包封率均为35%以上,载药量为8.0%以上,平均粒径为60μm左右,微球外观圆整,形态良好。结论该制备工艺稳定可靠,分析方法科学有效。     

Merits of sponge-like PLGA microspheres as long-acting injectables of hydrophobic drug

Abstract

Our study was initiated to challenge the preconception that nonporous PLGA microspheres with compact matrices should be used to develop long-acting depot injectables of hydrophobic drugs. A simple, new oil-in-water emulsion technique was utilized to produce porous PLGA microspheres with a sponge-like skeleton. Then, their applicability to developing sustained-release depots of hydrophobic drugs was explored in this study. As control, nonporous microspheres with a compact matrix were produced following a typical solvent evaporation process. Both microsphere manufacturing processes used non-halogenated isopropyl formate and progesterone as a dispersed solvent and a model hydrophobic drug, respectively. Various attempts were made to evaluate critical quality attributes of the porous microspheres and the nonporous ones. Surprisingly, the former displayed interesting features from the viewpoints of manufacturability and microsphere quality. For example, the spongy microspheres improved drug encapsulation efficiency and particle size uniformity, inhibited drug crystallization during microencapsulation, and minimized the residual solvent content in microspheres. Furthermore, the porous microspheres provided continual drug release kinetics without a lag time and much faster drug release than the non-porous microspheres did. In summary, the porous and sponge-like PLGA microspheres might find lucrative applications in developing sustained release dosage forms of hydrophobic drugs.     

Design and characterisation of new nanoparticulate polymer blends for drug delivery

The aim of the present work was the design of novel nanoparticle compositions based on poly(lactic acid/glycolic acid) (PLGA): poloxamer and PLGA: poloxamine blend matrices. For this purpose, we have applied a modified solvent diffusion technique that allows the preparation of the nanoparticles without the use of high energy sources. Nanoparticles have been prepared with different PLGA: poloxamer and PLGA: poloxamine ratios using PEO-derivatives with different molecular weights (Mw) and hydrophilia-lipophilia balance (HLB) values. Our results show that the physicochemical characteristics of the nanoparticles, such as size and zeta potential, are influenced by the type of PEO-derivative associated to the PLGA matrix. The 1H-NMR analysis of the different nanoparticle compositions showed that the extent of incorporation of the PEO-derivative depends strongly on its HLB and also on the nanoparticles preparation conditions. The capacity of these nanoparticles as drug delivery devices was evaluated using bovine insulin as a model drug. The insulin-encapsulation efficiency was shown to be dependent on the composition of the nanoparticles, those containing hydrophilic PEO-derivatives being the most effective in entrapping the drug molecules. The formation of the blend system displayed positive effects on the release characteristics of the nanoparticles. Nanoparticles exhibited a reduced initial burst and a nearly linear, constant release rate over a time period of two weeks.     

Fabrication and characterization of monodisperse PLGA–alginate core–shell microspheres with monodisperse size and homogeneous shells for controlled drug release

Monodisperse PLGA–alginate core–shell microspheres with controlled size and homogeneous shells were first fabricated using capillary microfluidic devices for the purpose of controlling drug release kinetics. Sizes of PLGA cores were readily controlled by the geometries of microfluidic devices and the fluid flow rates. PLGA microspheres with sizes ranging from 15 to 50 μm were fabricated to investigate the influence of the core size on the release kinetics. Rifampicin was loaded into both monodisperse PLGA microspheres and PLGA–alginate core–shell microspheres as a model drug for the release kinetics studies. The in vitro release of rifampicin showed that the PLGA core of all sizes exhibited sigmoid release patterns, although smaller PLGA cores had a higher release rate and a shorter lag phase. The shell could modulate the drug release kinetics as a buffer layer and a near-zero-order release pattern was observed when the drug release rate of the PLGA core was high enough. The biocompatibility of PLGA–alginate core–shell microspheres was assessed by MTT assay on L929 mouse fibroblasts cell line and no obvious cytotoxicity was found. This technique provides a convenient method to control the drug release kinetics of the PLGA microsphere by delicately controlling the microstructures. The obtained monodisperse PLGA–alginate core–shell microspheres with monodisperse size and homogeneous shells could be a promising device for controlled drug release.     

Synthesis, characterization, biodegradation, and drug delivery application of biodegradable lactic/glycolic acid polymers: I. Synthesis and characterization

A series of lactic/glycolic acid polymers with various molar ratios of lactic to glycolic acid and various molecular weights were synthesized using the ring-opening polymerization method. The polymerization conditions for the lactic/glycolic acid polymer synthesis were as follows: 150 degrees C, 700 microm Hg, 3 h, 0.03 wt% of catalyst (stannous 2-ethyl-hexanoate) concentration. The molecular weight of these polymers was controlled by using a molecular weight controller, lauryl alcohol. The synthesized polymers have been characterized with respect to polymer composition, molecular weight, inherent viscosity, and glass transition temperature. The characterization experiments show a good correlation between the polymer compositions and the feed ratios of lactic to glycolic acid. The molecular weight of the lactic/glycolic polymers, ranging from 10,876 to 166,630 D and the intrinsic viscosity of the polymers, ranging from 0.16 to 0.86 dl g(-1), are controlled by the amount of molecular weight controller used. The effect of the amount of the molecular weight controller on the polymer molecular weight and the polymer inherent viscosity was studied. Results indicate that the molecular weight and inherent viscosity of the polymers have a log-log linear relationship with the amount of molecular weight controller used. The lactic/glycolic acid polymers are amorphous, glassy, and transparent. The glass transition temperature of the polymers range from 21.95 to 51.29 degrees C, depending on the polymer molecular weight and the composition.     

Design and characterisation of new nanoparticulate polymer blends for drug delivery

The aim of the present work was the design of novel nanoparticle compositions based on poly(lactic acid/glycolic acid) (PLGA): poloxamer and PLGA: poloxamine blend matrices. For this purpose, we have applied a modified solvent diffusion technique that allows the preparation of the nanoparticles without the use of high energy sources. Nanoparticles have been prepared with different PLGA: poloxamer and PLGA: poloxamine ratios using PEO-derivatives with different molecular weights (M _w) and hydrophilia–lipophilia balance (HLB) values. Our results show that the physicochemical characteristics of the nanoparticles, such as size and zeta potential, are influenced by the type of PEO-derivative associated to the PLGA matrix. The ¹H-NMR analysis of the different nanoparticle compositions showed that the extent of incorporation of the PEO-derivative depends strongly on its HLB and also on the nanoparticles preparation conditions. The capacity of these nanoparticles as drug delivery devices was evaluated using bovine insulin as a model drug. The insulin-encapsulation efficiency was shown to be dependent on the composition of the nanoparticles, those containing hydrophilic PEO-derivatives being the most effective in entrapping the drug molecules. The formation of the blend system displayed positive effects on the release characteristics of the nanoparticles. Nanoparticles exhibited a reduced initial burst and a nearly linear, constant release rate over a time period of two weeks.     

Physicomechanical properties of sintered scaffolds formed from porous and protein-loaded poly(DL-lactic-co-glycolic acid) microspheres for potential use in bone tissue engineering

An injectable poly(DL-lactic-co-glycolic acid) (PLGA) system comprising both porous and protein-loaded microspheres capable of forming porous scaffolds at body temperature was developed for tissue regeneration purposes. Porous and non-porous (lysozyme loaded) PLGA microspheres were formulated to represent ‘low molecular weight’ 22–34 kDa, ‘intermediate molecular weight’ (IMW) 53 kDa and ‘high molecular weight’ 84–109 kDa PLGA microspheres. The respective average size of the microspheres was directly related to the polymer molecular weight. An initial burst release of lysozyme was observed from both microspheres and scaffolds on day 1. In the case of the lysozyme-loaded microspheres, this burst release was inversely related to the polymer molecular weight. Similarly, scaffolds loaded with 1 mg lysozyme/g of scaffold exhibited an inverse release relationship with polymer molecular weight. The burst release was highest amongst IMW scaffolds loaded with 2 and 3 mg/g. Sustained lysozyme release was observed after day 1 over 50 days (microspheres) and 30 days (scaffolds). The compressive strengths of the scaffolds were found to be inversely proportional to PLGA molecular weight at each lysozyme loading. Surface analysis indicated that some of the loaded lysozyme was distributed on the surfaces of the microspheres and thus responsible for the burst release observed. Overall the data demonstrates the potential of the scaffolds for use in tissue regeneration.     

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.     

乳酸-羟基乙酸共聚物缓控释微球的制备及突释成因与影响因素

背景：乳酸-羟基乙酸共聚物是一种生物可降解高分子材料,以乳酸-羟基乙酸共聚物为原料制备的载药微球和纳米粒既可提高药物的稳定性,又能实现缓释、控释和靶向释放。 目的：分析乳酸-羟基乙酸共聚物缓控释微球的制备方法以及突释的成因、影响因素和改进方法。 方法：应用计算机检索1990/2010中国期刊全文数据库和PubMed数据库与乳酸-羟基乙酸共聚物缓控释微球的制备及突释联系紧密的文章。 结果与结论：目前乳酸-羟基乙酸共聚物缓释微球制备方法主要有单凝聚法、乳化-固化法、喷雾干燥法。造成其突释的原因首先是药物分子和聚合物分子之间的相互作用太弱,导致药物很容易从微球进入释放递质中,其次是在微球释放初期,药物从微球中的孔洞和缝隙中释放出来导致突释。影响突释程度的具体因素有乳酸-羟基乙酸共聚物的相对分子质量、浓度、微球载药量、主药理化性质、微球制备方法及制备参数等。虽然国内外对突释机制以及控制突释措施的研究都还处于初步阶段,通过对各影响因素加以适当优化与控制,可在一定程度上减少微球的突释率,突释问题应该能够得到解决和控制。