Protein-loaded PLGA-PEG-PLGA microspheres: a tool for cell therapy

A promising strategy to repair injured organs is possible by delivering a growth factor via poly-(d,l lactide-co-glycolide) (PLGA) microspheres; the latter are coated with adhesion molecules that serve as a support for cell delivery. At present, PLGA is not the optimal choice of polymer because of poor or incomplete protein release. The use of a more hydrophilic PLGA-PEG-PLGA (A-B-A) copolymer increases the degree of protein release. In this work, the impact of different combinations of (B) and (A) segments on the protein-release profile has been investigated. Continuous-release profiles, with no lag phases, were observed. The triblock ABA with a low molecular weight of PEG and a high molecular weight of PLGA showed an interesting release pattern with a small burst (<10% in 48 h) followed by sustained, protein release over 36 days. Incomplete protein release was found to be due to various causes: protein adsorption, protein aggregation and protein denaturation under acidic conditions. Interestingly, cell viability and cell adhesion on microspheres coated with fibronectin highlight the interest of these polymers for tissue engineering applications.     

PEGylation of Octreotide: I. Separation of Positional Isomers and Stability Against Acylation by Poly(D,L-lactide-<Emphasis Type="Italic">co</Emphasis>-glycolide)

Purpose. To investigate the mechanism by which polyethylene glycol (PEG) conjugation (PEGylation) prevents the acylation of octreotide by poly(d,l-lactide-co-glycolide) (PLGA).Methods. Octreotide was chemically modified by reaction with succinimidyl propionate-monomethoxy PEG. Each PEGylated octreotide species with different PEG number and modified position was separated by reversed-phase high-performance liquid chromatography (RP-HPLC) and characterized by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) with endoproteinase Lys-C digestion. Acylation of octreotide and PEGylated octreotides was observed with hydrophobic and hydrophilic PLGA.Results. Two mono- and one di-PEGylated octreotides were separated by RP-HPLC. MALDI-TOF MS of the PEGylated products after Lys-C digestion at different pH revealed that the two mono-PEGylated octreotides were modified at the N-terminus and Lys⁵ residue, respectively. The interaction of octreotide with PLGA involved an initial adsorption followed by acylation and the subsequent release of octreotide and acylated octreotide. The initial adsorption of octreotide was dependent on the acidity of PLGA. PEGylation of octreotide significantly inhibited the initial adsorption and acylation by PLGA. In particular, the acylation could be completely prevented by mono-PEGylation at the N-terminus of octreotide.Conclusions. This study shows that the N-terminus of octreotide is the preferred PEGylation site to prevent acylation in degrading PLGA microspheres. The mono-N-terminally PEGylated octreotide may possibly serve as a new source for somatostatin microsphere formulation.     

Surface modification of poly (l-lactic acid) microspheres for site-specific delivery of ketoprofen for chronic inflammatory disease

The purpose of this research was to investigate the potential of surface modified Poly (l-lactic acid) (PLA) microspheres as a carrier for site-specific delivery of anti-inflammatory drug, ketoprofen, for the treatment of rheumatoid arthritis. Microspheres were prepared by solvent evaporation method using 20% w/w PLA in methylene chloride and 100 mL of a 2.5% poly vinyl alcohol (PVA) solution. Formulations were optimized for several processing parameters like drug to polymer ratio, stirring rate and volume of preparation medium etc. The surface of PLA microspheres was modified with gelatin to impart fibronectin recognition. The microspheres were characterized by surface morphology, size distribution, encapsulation efficiency, and by in vitro drug release studies. The prepared microspheres were light yellow, discrete, and spherical. Formulation with optimum drug to polymer ratio exhibited smallest vesicle size (43.02), high drug encapsulation efficiency (81.11) and better process yield (83.45). The release of drug was extended up to 24 h with Higuchi pattern of drug release. The in vivo results showed that the gelatin modified formulation reduced paw edema at greater extent than pure drug and PLA microspheres and it could be a promising carrier system for controlled and site-specific delivery of ketoprofen with possible clinical applications.     

Heparin Immobilized Porous PLGA Microspheres for Angiogenic Growth Factor Delivery

Purpose Heparin immobilized porous poly(d,l-lactic-co-glycolic acid) (PLGA) microspheres were prepared for sustained release of basic fibroblast growth factor (bFGF) to induce angiogenesis.Materials and Methods Porous PLGA microspheres having primary amine groups on the surface were prepared using an oil-in-water (O/W) single emulsion method using Pluronic F-127 as an extractable porogen. Heparin was surface immobilized via covalent conjugation. bFGF was loaded into the heparin functionalized (PLGA-heparin) microspheres by a simple dipping method. The bFGF loaded PLGA-heparin microspheres were tested for in vitro release and in vivo angiogenic activity.Results PLGA microspheres with an open-porous structure were formed. The amount of conjugated amine group onto the microspheres was 1.93 ± 0.01 nmol/mg-microspheres, while the amount of heparin was 95.8 pmol/mg-microspheres. PLGA-heparin microspheres released out bFGF in a more sustained manner with a smaller extent of initial burst than PLGA microspheres, indicating that surface immobilized heparin controlled the release rate of bFGF. Subcutaneous implantation of bFGF loaded PLGA-heparin microspheres in mice significantly induced the formation of new vascular microvessels.Conclusions PLGA microspheres with an open porous structure allowed significant amount of heparin immobilization and bFGF loading. bFGF loaded PLGA-HP microspheres showed sustained release profiles of bFGF in vitro, demonstrating reversible and specific binding of bFGF to immobilized heparin. They also induced local angiogenesis in vivo in an animal model.     

Adsorption of Brain Proteins on the Surface of Poly (D,L-lactide-co-glycolide) (PLGA) Microspheres

Poly(D,L-lactide-co-glycolide) (PLGA) microspheres have been studied for intracerebral delivery of anticancer agents. To explore the biocompatibility nature of the polymer in brain, we have investigated the adsorption of brain proteins on the surfaces of PLGA microspheres. Microspheres were made by the solvent evaporation method using an oil/water (o/w) system. The brain protein adsorption experiment was performed by using a sonication eluting method. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) was used to examine the brain proteins adsorbed. Ethyl cellulose microspheres were used in the study as a reference. The amount of brain proteins adsorbed on PLGA microspheres was also determined using a radiolabeling technique. The extent of brain proteins adsorbed on the PLGA microspheres was found to be lower than that adsorbed on the ethyl cellulose microspheres. The adsorption of brain proteins on PLGA microspheres, however, was significant, as indicated quantitatively by the ¹²⁵I labeling studies. The adsorption of brain proteins on the surface of the PLGA microspheres may be important when considering the use of this polymer as a brain implant delivery system.     

Microspheres made by w/o/o emulsion method with reduced initial burst for long-term delivery of endostar, a novel recombinant human endostatin

The purpose of this work is to design biodegradable Poly(lactide-co-glycolide) (PLGA) microspheres with low initial burst for sustained delivery of Endostar (a novel recombinant human endostatin) and investigate effects of PLGA molecular weight and composition on the release behavior of Endostar microspheres. Endostar microspheres were prepared by using novel w/o/o multiple emulsification-evaporation technique. Effects of polymer molecular weight and copolymer composition on particle properties and release behavior (in vitro and in vivo) have been reported. Drug release in vitro decreased with increase in molecular weight and lactide content of PLGA. Zero order release and low initial burst were obtained with all microsphere formulations. The in vivo performance of Endostar microspheres were also found to be dependent on the polymer molecular weight and copolymer composition. Together, these results suggest that the initial burst release can be reduced by w/o/o emulsion method and the release of Endostar can be changed significantly by varying the polymer molecular weight and copolymer composition.     

Preparation and characterization of poly(D,L-lactic-co-glycolic Acid) microspheres containing flurbiprofen sodium

This study aimed to prepare biodegradable microspheres containing flurbiprofen sodium, a nonsteroidal anti-inflammatory drug (NSAID), as the drug delivery system to the periodontal pocket. Microspheres were prepared from biodegradable copolymers of poly (D,L-lactic-co-glycolic acid) (PLGA) using solvent evaporation method. The effects of the different copolymers and amounts of polyvinyl alcohol (PVA) as a dispersing agent on characteristics of the microspheres were evaluated. Although there was no correlation between microsphere size and amount of PVA, an optimum PVA concentration was essential to achieve narrower size distributions of microspheres. As the concentration of PVA increased, the drug loading of the microspheres increased. The effect of PVA on drug loading was found to be statistically significant for those microspheres prepared from PLGA 50:50 (p < 0.05). Regarding copolymer composition, PLGA 85:15 provided higher drug loading into the microspheres than PLGA 50:50 (p < 0.05). The recoveries of microspheres (60-80%) were affected neither by different PVA concentrations nor by copolymer compositions (p > 0.05). According to the first-order release rate constants of the microspheres, the microspheres of PLGA 50:50 released the drug at the highest rate consistently, with the highest hydrophilicity of this copolymer.     

长春西汀聚乳酸-聚乙醇酸缓释微球的研制

目的:制备长春西汀聚乳酸-聚乙醇酸(PLGA)缓释微球,并研究其药剂学性质。方法:采用改良O/W乳化-溶剂挥发法制备微球,以PLGA浓度、理论载药量、有机相与分散介质的比例和分散介质中明胶的浓度为4因素,每个因素选定3个水平,按L9(34)的正交设计方案,以载药量、包封率和粒径分布为指标,优化处方。用扫描电镜观察微球的形态,用光学显微镜观察并计算微球的粒径分布,用差示扫描量热(DSC)法研究药物在载体中的分散状态,用紫外分光光度法检测微球中长春西汀含量并计算载药量和包封率,用动态透析释药法进行微球的体外释放研究。结果:最佳处方为PLGA浓度16%,理论载药量20%,有机相与分散介质的比例1:10,分散介质中明胶的浓度1%;制备的长春西汀PLGA缓释微球的形态圆整、光滑,粒径分布均匀,平均粒径为(10.0±0.18)μm(n=500),DSC法分析药物确已被包裹于微球中,载药量为(18.46±0.26)%,包封率为(91.30±0.98)%(n=3),24h累积释药率约为18%。结论:长春西汀PLGA缓释微球制备工艺稳定,质量符合药剂学要求,缓释性好。     

Formulation factors in preparing BTM-chitosan microspheres by spray drying method

Chitosan (CTS) microspheres were prepared by a spray drying method using type-A gelatin and ethylene oxide-propylene oxide block copolymer as modifiers. Surface morphological characteristics and surface charges of prepared microspheres were investigated by using scanning electron microscopy (SEM) and microelectrophoresis. The particle shape, size and surface morphology of microspheres were significantly affected by the concentration of gelatin. Betamethasone disodium phosphate (BTM)-loaded microspheres demonstrated good drug stability (less 1% hydrolysis product), high entrapped efficiency (95%) and positive surface charge (37.5 mV). The in vitro drug release from the microspheres was related to gelatin content. Microspheres containing gelatin/CTS 0.4 approximately 0.6(w/w) had a prolong release pattern for 12 h. These formulation factors were correlated to particulate characteristics for optimizing BTM microspheres in pulmonary delivery.     

Reverse Engineering the 1-Month Lupron Depot®

The 1-month Lupron Depot® (LD) encapsulating water-soluble leuprolide in poly(lactic-co-glycolic acid) (PLGA) microspheres is a benchmark product upon which modern long-acting release products are often compared. Despite expiration of patent coverage, no generic product for the LD has been approved in the USA, likely due to the complexity of components and manufacturing processes involved in the product. Here, we describe the reverse engineering of the LD composition and important product attributes. Specific attributes analyzed for microspheres were as follows: leuprolide content by three methods; gelatin content, type, and molecular weight distribution; PLGA content, lactic acid/glycolic acid ratio, and molecular weight distribution; mannitol content; in vitro drug release; residual solvent and moisture content; particle size distribution and morphology; and glass transition temperature. For the diluent, composition, viscosity, and specific gravity were analyzed. Analyzed contents of the formulation and the determined PLGA characteristics matched well with the official numbers stated in the package insert and those found in literature, respectively. The gelatin was identified as type B consistent with ~?300 bloom. The 11-μm volume-median microspheres in the LD slowly released the drug in vitro in a zero-order manner after ~?23% initial burst release. Very low content of residual moisture (<?0.5%) and methylene chloride (<?1 ppm) in the product indicates in-water drying is capable of removing solvents to extremely low levels during manufacturing. The rigorous approach of reverse engineering described here may be useful for development of generic leuprolide-PLGA microspheres as well as other new and generic PLGA microsphere formulations.     

Poly(l-lactide-co-glycolide) nanospheres conjugated with a nuclear localization signal for delivery of plasmid DNA

Polymeric nanospheres fabricated from biodegradable poly(lactide-co-glycolide) (PLGA) have been extensively investigated for applications in gene delivery. In this study, we show that the covalent conjugation of a nuclear localization signal (NLS, SV40 peptide) on PLGA nanospheres enhances the gene transfection efficiency. NLS conjugated PLGA copolymer was prepared by using a coupling reaction between maleimide-terminated PLGA copolymer and NLS in the presence of Imject maleimide conjugation buffer. PLGA nanospheres encapsulating plasmid (pDNA) were prepared by using a double emulsion-solvent evaporation method. The kinetics of in vitro release of pDNA from PLGA nanospheres was determined with UV in phosphate buffered saline (PBS). Gene transfection efficiency in human dermal fibroblasts was tested in vitro using nanospheres encapsulating the luciferase gene. The conjugation of the NLS peptide to the PLGA nanospheres could improve the nuclear localization and/or cellular uptake of PLGA nanosphere/pDNA constructs and thereby improve the transfection efficiency of a PLGA nanosphere gene delivery system. The pDNA was released from PLGA nanospheres over nine days. NLS conjugation enhanced the gene transfection efficiency in vitro by 1.2 ～ 3.2-fold over 13 days. PLGA/pDNA nanospheres appeared to be superior to PEI/pDNA complexes for the long-term expression of pDNA. Furthermore, the level of the sustained gene expression of the PLGA nanospheres was enhanced by the conjugation of NLS to the PLGA nanospheres. This study showed that the NLS conjugation enhanced the gene transfection efficiency of the PLGA nanosphere gene delivery system in vitro and that the enhanced gene expression was sustained for at least 13 days.     

Poly(L-lactide-co-glycolide) nanospheres conjugated with a nuclear localization signal for delivery of plasmid DNA

Polymeric nanospheres fabricated from biodegradable poly(lactide-co-glycolide) (PLGA) have been extensively investigated for applications in gene delivery. In this study, we show that the covalent conjugation of a nuclear localization signal (NLS, SV40 peptide) on PLGA nanospheres enhances the gene transfection efficiency. NLS conjugated PLGA copolymer was prepared by using a coupling reaction between maleimide-terminated PLGA copolymer and NLS in the presence of Imject maleimide conjugation buffer. PLGA nanospheres encapsulating plasmid (pDNA) were prepared by using a double emulsion-solvent evaporation method. The kinetics of in vitro release of pDNA from PLGA nanospheres was determined with UV in phosphate buffered saline (PBS). Gene transfection efficiency in human dermal fibroblasts was tested in vitro using nanospheres encapsulating the luciferase gene. The conjugation of the NLS peptide to the PLGA nanospheres could improve the nuclear localization and/or cellular uptake of PLGA nanosphere/pDNA constructs and thereby improve the transfection efficiency of a PLGA nanosphere gene delivery system. The pDNA was released from PLGA nanospheres over nine days. NLS conjugation enhanced the gene transfection efficiency in vitro by 1.2 approximately 3.2-fold over 13 days. PLGA/pDNA nanospheres appeared to be superior to PEI/pDNA complexes for the long-term expression of pDNA. Furthermore, the level of the sustained gene expression of the PLGA nanospheres was enhanced by the conjugation of NLS to the PLGA nanospheres. This study showed that the NLS conjugation enhanced the gene transfection efficiency of the PLGA nanosphere gene delivery system in vitro and that the enhanced gene expression was sustained for at least 13 days.     

Comparative assessment of in vitro release kinetics of calcitonin polypeptide from biodegradable microspheres

The objective of our study was to compare the in vitro release kinetics of a sustained-release injectable microsphere formulation of the polypeptide drug, calcitonin (CT), to optimize the characteristics of drug release from poly-(lactide-co-glycolide) (PLGA) copolymer biodegradable microspheres. A modified solvent evaporation and double emulsion technique was used to prepare the microspheres. Release kinetic studies were carried out in silanized tubes and dialysis bags, whereby microspheres were suspended and incubated in phosphate buffered saline, sampled at fixed intervals, and analyzed for drug content using a modified Lowry protein assay procedure. An initial burst was observed whereby about 50% of the total dose of the drug was released from the microspheres within 24 hr and 75% within 3 days. This was followed by a period of slow release over a period of 3 weeks in which another 10-15% of drug was released. Drug release from the dialysis bags was more gradual, and 50% CT was released only after 4 days and 75% after 12 days of release. Scanning electron micrographs revealed spherical particles with channel-like structures and a porous surface after being suspended in an aqueous solution for 5 days. Differential scanning calorimetric studies revealed that CT was present as a mix of amorphous and crystalline forms within the microspheres. Overall, these studies demonstrated that sustained release of CT from PLGA microspheres over a 3-week period is feasible and that release of drug from dialysis bags was more predictable than from tubes.     

Comparative Assessment of In Vitro Release Kinetics of Calcitonin Polypeptide from Biodegradable Microspheres

The objective of our study was to compare the in vitro release kinetics of a sustained-release injectable microsphere formulation of the polypeptide drug, calcitonin (CT), to optimize the characteristics of drug release from poly-(lactide-co-glycolide) (PLGA) copolymer biodegradable microspheres. A modified solvent evaporation and double emulsion technique was used to prepare the microspheres. Release kinetic studies were carried out in silanized tubes and dialysis bags, whereby microspheres were suspended and incubated in phosphate buffered saline, sampled at fixed intervals, and analyzed for drug content using a modified Lowry protein assay procedure. An initial burst was observed whereby about 50% of the total dose of the drug was released from the microspheres within 24 hr and 75% within 3 days. This was followed by a period of slow release over a period of 3 weeks in which another 10-15% of drug was released. Drug release from the dialysis bags was more gradual, and 50% CT was released only after 4 days and 75% after 12 days of release. Scanning electron micrographs revealed spherical particles with channel-like structures and a porous surface after being suspended in an aqueous solution for 5 days. Differential scanning calorimetric studies revealed that CT was present as a mix of amorphous and crystalline forms within the microspheres. Overall, these studies demonstrated that sustained release of CT from PLGA microspheres over a 3-week period is feasible and that release of drug from dialysis bags was more predictable than from tubes.     

Insulin-loaded PLGA microspheres for glucose-responsive release

Porous poly(lactic-co-glycolic acid) (PLGA) microspheres were prepared, loaded with insulin, and then coated in poly(vinyl alcohol) (PVA) and a novel boronic acid-containing copolymer [poly(acrylamide phenyl boronic acid-co-N–vinylcaprolactam); p(AAPBA-co-NVCL)]. Multilayer microspheres were generated using a layer-by-layer approach depositing alternating coats of PVA and p(AAPBA-co-NVCL) on the PLGA surface, with the optimal system found to be that with eight alternating layers of each coating. The resultant material comprised spherical particles with a porous PLGA core and the pores covered in the coating layers. Insulin could successfully be loaded into the particles, with loading capacity and encapsulation efficiencies reaching 2.83?±?0.15 and 82.6?±?5.1% respectively, and was found to be present in the amorphous form. The insulin-loaded microspheres could regulate drug release in response to a changing concentration of glucose. In vitro and in vivo toxicology tests demonstrated that they are safe and have high biocompatibility. Using the multilayer microspheres to treat diabetic mice, we found they can effectively control blood sugar levels over at least 18 days, retaining their glucose-sensitive properties during this time. Therefore, the novel multilayer microspheres developed in this work have significant potential as smart drug-delivery systems for the treatment of diabetes.     

The in-vitro and in-vivo characterization of PLGA:L-PLA microspheres containing dexamethasone sodium phosphate

Dexamethasone sodium phosphate (DSP) is a widely used corticosteroid in the treatment of brain oedema associated with brain tumours. DSP has many side effects that limit its usage at an effective concentration. The objective of this study was to minimize these side effects by encapsulating DSP using biodegradable synthetic polymers, to extend the release time from microspheres and to evaluate the effectiveness in the treatment of brain oedema. Microspheres containing 5% DSP were formulated by the solvent evaporation method by using a 1:1 mixture of two synthetic polymers, poly(lactic-co-glycolic acid) and L-polylactic acid (PLGA and L-PLA). The surface morphologies and particle size distribution of the microspheres were investigated. The in-vitro     

Controlled-release injectable containing Terbinafine/PLGA microspheres for Onychomycosis Treatment

Controlled-release drug delivery systems based on biodegradable polymers have been extensively evaluated for use in localized drug delivery. In the present study, intralesionally injectable poly (lactide-co-glycolide) (PLGA) microspheres for controlled release of terbinafine hydrochloride (TH) was developed for treating fungal toe/finger nail infections. TH–PLGA microspheres were formulated using O/W emulsification and modified solvent extraction/evaporation technique. Microspheres were evaluated for particle size and size distribution, encapsulation efficiency, surface, and morphology. The in vitro drug release profile was studied in aqueous media as well as in 1% agar gel. Microspheres system was also evaluated in excised cadaver toe model, and extent of TH accumulation in nail bed, nail plate, and nail matrix was measured at different time points. Microspheres were found to provide consistent and sustained TH release. Intralesional administration of controlled-release microspheres can be a potential alternative mode of treating fungus-infected toe and/or finger nails. © 2014 Wiley Periodicals, Inc. and the American Pharmacists Association J Pharm Sci 103:1178–1183, 2014     

PLGA microspheres encapsulating siRNA anti-TNFalpha: Efficient RNAi-mediated treatment of arthritic joints

The aim of this study was to investigate potentialities of poly(dl-lactide–co-glycolide) (PLGA) microspheres for the delivery of small interfering RNAs (siRNAs) against tumor necrosis factor α (TNF-α) to achieve prolonged and efficient inhibition of TNF-α for the treatment of rheumatoid arthritis (RA). PLGA microspheres were prepared by a modified multiple emulsion–solvent evaporation method. The formulations were characterized in terms of morphology, mean diameter and siRNAs distribution, encapsulation efficiency, and in vitro release kinetics. The efficiency of this system was then evaluated both in vitro and in vivo using the murine monocytic cell line J774 and a pre-clinical model of RA, respectively. siRNA-encapsulating PLGA microspheres were characterized by a high encapsulation efficiency and a slow and prolonged anti-TNF-α siRNAs. Our results provide evidence that, upon intra-articular administration, PLGA microspheres slowly releasing siRNAs effectively inhibited the expression of TNF-α in arthritic joints. Our system might represent an alternative strategy for the design of novel anti-rheumatic therapies based on the use of RNA interference in RA.     

Poly(hydroxybutyrate-hydroxyvalerate) microspheres containing progesterone: preparation, morphology and release properties.

The biodegradable polyesters, poly(hydroxybutyrate) (PHB) and poly(hydroxybutyrate-hydroxyvalerate) (PHBV) were investigated for use as sustained delivery carriers of a model drug, progesterone. Spherical microspheres containing the drug were prepared by an emulsion solvent-evaporation method with gelatin as an emulsifier. Methylene chloride as the polymer solvent yielded smoother microspheres than chloroform. The surface texture was also dependent upon the temperature of the preparation and polymer used. Surface crystals were observed when the drug loading was increased beyond 5 per cent w/w. Thermograms of the microspheres did not show an endotherm corresponding to the melting of the drug because the drug dissolved in the melted polymer while heating. The amount of residual solvent in the microspheres (gas chromatographic assay) ranged from 3.4 to 58.4 ppm and was dependent on the processing temperature, concentration of the polymer in the solvent and the polymer composition. In vitro release of the drug was slowest from microspheres made from copolymer containing 9 per cent hydroxyvalerate. A less porous microsphere matrix was formed by this copolymer.     

Size-Dependency of DL-Lactide/Glycolide Copolymer Particulates for Intra-Articular Delivery System on Phagocytosis in Rat Synovium

Purpose. The present study evaluated the size-dependency of DL-lactide/glycolide copolymer (PLGA) particulates for an intra-articular delivery system on phagocytosis in the rat synovium after administering directly into the joint cavity. We also investigated the biocompatibility of PLGA particulate systems administered directly into the joint cavity of the rat. Methods. Fluoresceinamine bound PLGA (FA-PLGA) nanospheres and microspheres were prepared by the modified emulsion solvent diffusion method. The suspension of these particulate systems was administered into the rat-joint cavity and the biological action of the synovium was evaluated by histological inspection and fluorescence microscopy. Results. A colloidal suspension of the FA-PLGA nanospheres, with a mean diameter of 265 nm, was phagocytosed in the synovium by the macrophages infiltrated through the synovial tissues. The phagocytosed nanospheres were delivered to the deep underlying tissues. An aqueous suspension of the FA-PLGA microspheres, with a mean diameter of 26.5 m, was not phagocytosed in the macrophages. The macrophages slightly proliferated in the epithelial lining synovial-cells and the microspheres were covered with a granulation of multinucleated giant cells. The molecular weights of the polymer in these particulate systems were slowly reduced in the synovium. Localized inflammatory responses were almost undetected. Conclusions. PLGA nanospheres should be more suitable for delivery to inflamed synovial tissue than microspheres due to their ability to penetrate the synovium. PLGA particulate systems with biocompatibility in the joint can provide local-therapy action in joint diseases in a different manner depending on the size of the system.