Engineering red-emitting multi-functional nanocapsules for magnetic tumour targeting and imaging.

In this work we describe the formulation and characterisation of red-emitting polymeric nanocapsules (NCs) incorporating superparamagnetic iron oxide nanoparticles (SPIONs) for magnetic tumour targeting. The self-fluorescent oligomers were synthesised and chemically conjugated to PLGA which was confirmed by NMR spectroscopy, FT-IR spectroscopy and mass spectrometry. Hydrophobic SPIONs were synthesised through thermal decomposition and their magnetic and heating properties were assessed by SQUID magnetometry and calorimetric measurements, respectively. Magnetic nanocapsules (m-NCs) were prepared by a single emulsification/solvent evaporation method. Their in vitro cytotoxicity was examined in CT26 colon cancer cells. The formulated fluorescent m-NCs showed good stability and biocompatibility both in vitro and in vivo in CT 26 colon cancer models. Following intravenous injection, accumulation of m-NCs in tumours was observed by optical imaging. A higher iron content in the tumours exposed to a magnetic field, compared to the contralateral tumours without magnetic exposure in the same animal, further confirmed the magnetic tumour targeting in vivo. The overall results show that the engineered red-emitting m-NCs have great potential as multifunctional nanocarriers for multi-model bioimaging and magnetic-targeted drug delivery.

A thermo-responsive and self-healing liposome-in-hydrogel system as an antitubercular drug carrier for localized bone tuberculosis therapy.

Isoniazid (INH) is a first-line therapy for bone tuberculosis (TB), but its clinic benefits are limited by severe side-effects after long-time administration. While nano-drug delivery systems present as promising strategies for INH delivery, the therapeutic efficacies are usually suboptimal due to ineffective drug accumulation at diseased sites. Local delivery system can achieve high drug concentration at focus sites with minimal systemic exposure, and herein we aimed to employ this strategy to develop a novel liposome-in-hydrogel system for localized treatment of bone TB. To achieve sustainable drug release, a derivative of INH called DINH was loaded because of its hydrophobicity, as well as its better activity and higher biosafety than INH. The hybrid system was demonstrated for thermo-responsive and self-healing properties via phase transition test and rheological studies, which were particularly useful for intra-articular administration. In vivo microdialysis studies revealed that the system can rapidly release drug into synovial fluid to reach effective inhibitory concentrations after localized injection, followed by a steady-state drug release. The optical image studies were performed to study its long-term behavior in vivo, which suggested a sustained drug release profile for several days. This work provides a promising drug delivery system for bone TB therapy.

In situ low-immunogenic albumin-conjugating-corona guiding nanoparticles for tumor-targeting chemotherapy.

Nanoparticles (NPs) are unavoidably covered by a layer of immunogenic proteins upon injection into blood, such as immunoglobins and complements, which buries the active-targeting ligands and triggers the rapid clearance of NPs by the mononuclear phagocytic system. Low antifouling polyethylene glycol is used to inhibit the formation of the immunogenic corona but it leads to poor cellular uptake and the immunogen-related accelerated blood clearance (ABC) phenomenon in multiple administrations. Here, we develop surface maleimide-modified NPs that covalently conjugate in vivo plasma albumin in its corona upon exposure to blood. The in situ recruited low-immunogenic albumin-enriching corona is capable of protecting maleimide-decorated NPs from phagocytosis in the bloodstream, preventing the ABC phenomenon in the second administration, facilitating NP accumulation in the tumor site/cells by the passive EPR effect and albumin receptor-mediated active targeting, and finally improving the antitumor activity. Such findings suggest that the facile strategy, based on the in situ anchored albumin-enriching corona, is efficient at enabling maleimide-decorated NPs to acquire stealth and tumor-targeting ability.

Comparative study of polyglactin 910 and simple catgut in the formation of intraperitoneal adhesions.

PURPOSE: To compare polyglactin 910 and simple catgut sutures for the incidence of intraperitoneal adhesions. METHODS: Twenty female Wistar rats were placed into two groups. Group 1 received ischemic sutures and Group 2 received polyglactin 910. Five sutures inductive of adhesions in each rat were made. After 14 days, the rats were euthanized with an assessment of the presence of adhesions, the number of sutures involved and classification according to the Granat et al. scale described by Ozel et al17. RESULTS: In total, 19 of the 20 rats presented adhesions, with nine from Group 1 and ten from Group 2. There was a smaller number of affected sutures in Group 1, while in Group 2 the majority of the sutures formed adhesions (p=0.0197). According to the Granat et al. scale, Group 1 predominately developed fine, filamentous adhesions or thickening in a restricted area. Group 2 mainly presented extensive, thick adhesions with the involvement of the viscera (p=0.0055). CONCLUSION: Polyglactin 910 sutures formed more adhesions that were more extensive and thicker than the simple catgut sutures.

Comparative study of polyglactin 910 and simple catgut in the formation of intraperitoneal adhesions

Abstract Purpose: To compare polyglactin 910 and simple catgut sutures for the incidence of intraperitoneal adhesions. Methods: Twenty female Wistar rats were placed into two groups. Group 1 received ischemic sutures and Group 2 received polyglactin 910. Five sutures inductive of adhesions in each rat were made. After 14 days, the rats were euthanized with an assessment of the presence of adhesions, the number of sutures involved and classification according to the Granat et al. scale described by Ozel et al17. Results: In total, 19 of the 20 rats presented adhesions, with nine from Group 1 and ten from Group 2. There was a smaller number of affected sutures in Group 1, while in Group 2 the majority of the sutures formed adhesions (p=0.0197). According to the Granat et al. scale, Group 1 predominately developed fine, filamentous adhesions or thickening in a restricted area. Group 2 mainly presented extensive, thick adhesions with the involvement of the viscera (p=0.0055). Conclusion: Polyglactin 910 sutures formed more adhesions that were more extensive and thicker than the simple catgut sutures.

Development of a non-toxic and non-denaturing formulation process for encapsulation of SDF-1α into PLGA/PEG-PLGA nanoparticles to achieve sustained release.

Chemokines are known to stimulate directed migration of cancer cells. Therefore, the strategy involving gradual chemokine release from polymeric vehicles for trapping cancer cells is of interest. In this work, the chemokine stromal cell-derived factor-1α (SDF-1α) was encapsulated into nanoparticles composed of poly-(lactic-co-glycolic acid) (PLGA) and a polyethylene glycol (PEG)-PLGA co-polymer to achieve sustained release. SDF-1α, and lysozyme as a model protein, were firstly precipitated to promote their stability upon encapsulation. A novel phase separation method utilising a non-toxic solvent in the form of isosorbide dimethyl ether was developed for the individual encapsulation of SDF-1α and lysozyme precipitates. Uniform nanoparticles of 200-250 nm in size with spherical morphologies were successfully synthesised under mild formulation conditions and conveniently freeze-dried in the presence of hydroxypropyl-ß-cyclodextrin as a stabiliser. The effect of PLGA carboxylic acid terminal capping on protein encapsulation efficiency and release rate was also explored. Following optimisation, sustained release of SDF-1α was achieved over a period of 72 h. Importantly, the novel encapsulation process was found to induce negligible protein denaturation. The obtained SDF-1α nanocarriers may be subsequently incorporated within a hydrogel or other scaffolds to establish a chemokine concentration gradient for the trapping of glioblastoma cells.

Physicochemical stability and transfection efficiency of cationic amphiphilic copolymer/pDNA polyplexes for spinal cord injury repair.

Multiple age-related and injury-induced characteristics of the adult central nervous system (CNS) pose barriers to axonal regeneration and functional recovery following injury. In situ gene therapy is a promising approach to address the limited availability of growth-promoting biomolecules at CNS injury sites. The ultimate goal of our work is to develop, a cationic amphiphilic copolymer for simultaneous delivery of drug and therapeutic nucleic acids to promote axonal regeneration and plasticity after spinal cord injury. Previously, we reported the synthesis and characterization of a cationic amphiphilic copolymer, poly (lactide-co-glycolide)-graft-polyethylenimine (PgP) and its ability to efficiently transfect cells with pDNA in the presence of serum. We also demonstrated the efficacy of PgP as a therapeutic siRhoA carrier in a rat compression spinal cord injury model. In this work, we show that PgP/pDNA polyplexes provide improved stability in the presence of competing polyanions and nuclease protection in serum relative to conventional branched polyethylenimine control. PgP/pDNA polyplexes maintain bioactivity for transfection after lyophilization/reconstitution and during storage at 4 °C for up to 5 months, important features for commercial and clinical application. We also demonstrate that PgP/pDNA polyplexes loaded with a hydrophobic fluorescent dye are retained in local neural tissue for up to 5 days and that PgP can efficiently deliver pß-Gal in a rat compression SCI model.

Ultrasound-induced mild hyperthermia improves the anticancer efficacy of both Taxol® and paclitaxel-loaded nanocapsules.

We study the influence of ultrasound on paclitaxel-loaded nanocapsules in vitro and in vivo. These nanocapsules possess a shell of poly(dl-lactide-co-glycolide)-poly(ethylene glycol) (PLGA-PEG) and a liquid core of perfluorooctyl bromide (PFOB). In vitro experiments show that mechanical effects such as cavitation are negligible for nanocapsules due to their small size and thick and rigid shell. As the mechanical effects were unable to increase paclitaxel delivery, we focused on the thermal effects of ultrasound in the in vivo studies. A focused ultrasound sequence was therefore optimized in vivo under magnetic resonance imaging guidance to obtain localized mild hyperthermia with high acoustic pressure. Ultrasound-induced mild hyperthermia (41-43°C) was then tested in vivo in a subcutaneous CT-26 colon cancer murine model. As hyperthermia is applied, an inhibition of tumor growth for both paclitaxel-loaded nanocapsules and the commercial formulation of paclitaxel, namely Taxol® have been observed (p<0.05). Ultrasound-induced mild hyperthermia at high acoustic pressure appears as an interesting strategy to enhance cytotoxic efficacy locally.

Efficacy assessment of self-assembled PLGA-PEG-PLGA nanoparticles: Correlation of nano-bio interface interactions, biodistribution, internalization and gene expression studies.

The aim of our study was to develop and compare the biological performance of two types of biodegradable SN-38 loaded nanoparticles (NPs) with various surface properties, composed of low and high Mw triblock PLGA-PEG-PLGA copolymers, applying rational quality and safety by design approach. Therefore, along with the optimization of crucial physico-chemical properties and in order to evaluate the therapeutical potential and biocompatibility of prepared polymeric nanoparticles, analysis of nano-bio interactions, cell internalization, gene expression and biodistribution studies were performed. The optimized formulations, one of low Mw and one composed of high Mw PLGA-PEG-PLGA copolymer, exhibited different characteristics in terms of surface properties, particle size, zeta potential, drug loading, protein adsorption and biodistribution, which may be attributed to the variations in nano-bio interface interactions due to different NP building blocks length and Mw. On the contrary to protein adsorption and biodistribution studies, both types of NPs exhibited similar results during cell internalization and gene expression studies performed in cell culture medium containing serum proteins. This pool of useful data for internalization and efficacy as well as the notable advance in the circulation time of low Mw NPs may be further employed for shaping the potential of the designed nanocarriers.

Formulation of venlafaxine for once daily administration using polymeric material hybrids.

OBJECTIVE: Controlled release venlafaxine for once daily administration. METHODS: Drug resin complexation followed by polymer encapsulation. A 4(1).2(1) factorial design was used to study the effect of polymer type and core: coat ratio on the release profile and kinetics. Polymer combinations were tried for optimisation adapting the desIMNCility function. The optimised formula was tested in rabbits against commercial extended release capsules. RESULTS: Poly-epsilon-caprolactone, poly(d, l-lactide-co-glycolide) ester and poly(d, l-lactide) ester polymers were more efficient in lowering the release rate and the initial burst release than Eudragit(®)RS100. Encapsulation at 1:1 ratio ensured complete coats and drug release sustainment. Formula prepared using 50:50 PLA/Eudragit at 1:1 ratio sustained the drug release up to 24 h with low burst release. This formula had higher venlafaxine absorption in rabbits compared to the commercial capsules. CONCLUSIONS: The optimised formula is superior to the available once-daily trials regarding enhanced bioavailability, dosage form versatility and ease of scaling up.

Fluorescence imaging enabled poly(lactide-co-glycolide).

Fluorescent biomaterials have attracted significant research efforts in the past decades. Herein, we report a new series of biodegradable, fluorescence imaging-enabled copolymers, biodegradable photoluminescent poly(lactide-co-glycolide) (BPLP-co-PLGA). Photoluminescence characterization shows that BPLP-co-PLGA solutions, films and nanoparticles all exhibit strong, tunable and stable photoluminescence. By adjusting the molar ratios of L-lactide (LA)/glycolide (GA) and (LA+GA)/BPLP, full degradation of BPLP-co-PLGA can be achieved in 8-16 weeks. The fluorescence decay behavior of BPLP-co-PLGA can be used for non-invasive monitoring of material degradation. In vitro cytotoxicity and in vivo foreign body response evaluations demonstrate that BPLP-co-PLGA exhibits similar biocompatibility to poly(lactide-co-glycolide) (PLGA). The imaging-enabled BPLP-co-PLGA was fabricated into porous scaffolds whose degradation can be monitored through non-invasive imaging and nanoparticles that show theranostic potential demonstrated by fluorescent cellular labeling, imaging and sustained 5-fluorouracil delivery. The development of inherently fluorescent PLGA copolymers is expected to impact the use of already widely accepted PLGA polymers for applications where fluorescent properties are highly desired but limited by the conventional use of cytotoxic quantum dots and photobleaching organic dyes. STATEMENT OF SIGNIFICANCE: This manuscript describes a novel strategy of conferring intrinsic photoluminescence to the widely used biodegradable polymers, poly(lactide-co-glycolide) without introducing any cytotoxic quantum dots or photo-bleaching organic dyes, which may greatly expand the applications of these polymers in where fluorescent properties are highly desired. Given the already significant impact generated by the use of PLGA and alike, this work contributes to fluorescence chemistry and new functional biomaterial design and will potentially generate significant impact on many fields of applications such as tissue engineering, molecular imaging and labeling, and drug delivery.

Enteric-coated capsules filled with mono-disperse micro-particles containing PLGA-lipid-PEG nanoparticles for oral delivery of insulin.

The success of the oral delivery of insulin (INS) as a therapeutic protein drug would significantly improve the quality of life of diabetic patients who would otherwise receive multiple daily INS injections. The oral delivery of INS, however, is still limited in its delivery efficiency, which could be due to the chemical, enzymatic, and adsorption barriers. In this work, in an attempt to improve the delivery efficiency, the INS-loaded polymer-lipid hybrid nanoparticles (INS-PLGA-lipid-PEG NPs) were designed and constructed through a double-emulsion solvent evaporation technique, followed by formulation of the spherical micro-particles using a spray freeze dryer (SFD). This kind of dryers has a uniquely designed microfluidic aerosol nozzle (MFAN), ensuring the formation of uniform particles. The resulted particles of ∼212 µm could easily be reverted to discrete INS-PLGA-lipid-PEG NPs in an aqueous solution. The INS-PLGA-lipid-PEG NPs created in this work showed a highly negative surface charge, excellent entrapment efficiency (92.3%) and a sustained drug release (∼24 h). Confocal laser scanning microscopy and flow cytometer were used to show that the cellular uptake efficiency for the INS-PLGA-lipid-PEG NPs was more effective than the INS in Caco-2 cells. More importantly, the in vivo pharmacodynamics demonstrated that the orally delivered system induced a prolonged decrease in blood glucose levels among diabetic rats. The relative bioavailability of INS compared with subcutaneous injection in diabetic rats was found to be approximately 12%. These results suggested that the encapsulated INS-PLGA-lipid-PEG NPs are promising and should be investigated further in the near future as an effective INS oral delivery system.

Improved corneal bioavailability of ofloxacin: biodegradable microsphere-loaded ion-activated in situ gel delivery system.

The aim of the study was to improve corneal penetration and bioavailability of ofloxacin (OFX) eye preparations. OFX was incorporated in poly (lactide-co-glycolide) as biodegradable microspheres using oil in oil emulsion solvent evaporation technique. The prepared OFX microspheres were then incorporated in Gelrite(®) in situ gel preparation. In addition, OFX Gelrite-based in situ gel formulations were prepared. OFX formulations were characterized for gelling capacity, viscosity, and rheological properties. Release studies for OFX microspheres, OFX in situ gel, and OFX-loaded microspheres in situ gel formulations were carried out to investigate release characteristics of the drug. The prepared OFX formulations were then investigated in vivo compared with commercially available OFX eyedrops. Results showed that the optimum Gelrite concentration was at 0.4%-0.7% w/v; the prepared formulations were viscous liquid transformed into a pourable gel immediately after the addition of simulated tear fluid with a gelling factor of 27-35. Incorporation of OFX-loaded microspheres in Gelrite solution (0.4% w/v) significantly altered the release profiles of OFX-loaded microspheres in situ gel formula compared with the corresponding OFX gels and OFX microspheres. In vivo results in rabbits showed that OFX-loaded microspheres in situ gel formula improved the relative bioavailability by 11.7-fold compared with the commercially available OFX eyedrops. In addition, the longer duration of action of OFX-loaded microspheres in situ gel formula preparations is thought to avoid frequent instillations, which improves patient tolerability and compliance.

pH-sensitive nanoparticles of poly(L-histidine)-poly(lactide-co-glycolide)-tocopheryl polyethylene glycol succinate for anti-tumor drug delivery.

A novel pH-sensitive polymer, poly(L-histidine)-poly(lactide-co-glycolide)-tocopheryl polyethylene glycol succinate (PLH-PLGA-TPGS), was synthesized to design a biocompatible drug delivery system for cancer chemotherapy. The structure of the PLH-PLGA-TPGS copolymer was confirmed by (1)H-NMR, FTIR and GPC. The apparent pKa of the PLH-PLGA-TPGS copolymer was calculated to be 6.33 according to the acid-base titration curve. The doxorubicin (DOX)-loaded nanoparticles (PLH-PLGA-TPGS nanoparticles and PLGA-TPGS nanoparticles) and corresponding blank nanoparticles were prepared by a co-solvent evaporation method. The blank PLH-PLGA-TPGS nanoparticles showed an acidic pH-induced increase in particle size. The DOX-loaded nanoparticles based on PLH-PLGA-TPGS showed a pH-triggered drug-release behavior under acidic conditions. The results of in vitro cytotoxicity experiment on MCF-7 and MCF-7/ADR cells showed that the DOX-loaded PLH-PLGA-TPGS nanoparticles resulted in lower cell viability versus the PLGA-TPGS nanoparticles and free DOX solution. Confocal laser scanning microscopy images showed that DOX-loaded PLH-PLGA-TPGS nanoparticles were internalized by MCF-7/ADR cells after 1 and 4h incubation and most of them accumulated in lysosomes to accelerate DOX release under acidic conditions. In summary, the PLH-PLGA-TPGS nanoparticles have great potential to be used as carriers for anti-tumor drug delivery.

Non-aggregated protamine-coated poly(lactide-co-glycolide) nanoparticles of cisplatin crossed blood-brain barrier, enhanced drug delivery and improved therapeutic index in glioblastoma cells: in vitro studies.

BACKGROUND AND OBJECTIVES: Non-aggregated protamine impregnated poly(lactide-co-glycolide) nanoparticles of cisplatin (Pt-PLGA NPs) were synthesized to augment brain delivery. METHODS AND RESULTS: The mean particle size of Pt-PLGA NPs and PLGA NPs were observed to be 173.2 ± 7.9 nm and 140 ± 10.2 nm, respectively. The Pt-PLGA NPs significantly (p < 0.05, one-way analysis of variance; ANOVA) delivered higher amount (172.41 ± 15.04 µg) of cisplatin in comparison to 110.48 ± 4.71 µg by PLGA NPs and 20.83 ± 1.65 µg by cisplatin solution across in vitro bovine brain microvessel endothelial cells. Cisplatin bearing Pt-PLGA NPs was found to be highly cytotoxic to U87 glioblastoma cells with an IC50 of 2.1 µM as compared (one-way ANOVA, p < 0.05) to PLGA NPs (3.9 µM) and cisplatin alone (13.33 µM). Impregnation with Pt enhanced the uptake of PLGA NPs in U87 glioblastoma cells as compared to PLGA NPs by following endocytosis mechanism. CONCLUSION: Cisplatin-loaded Pt-PLGA NPs compel preclinical tumour regression study to further improve its utility against glioblastoma.

Preparation and in vitro evaluation of surface-modified poly (lactide-co-glycolide) microparticles as biodegradable drug carriers for pulmonary peptide and protein delivery.

The present study reports the preparation and physicochemical characterization of surface-modified poly(lactide-co-glycolide) (PLGA) microparticles containing interleukin-2 (rhIL-2) for pulmonary delivery. The surface of the microparticles was modified with mucoadhesive polymers such as chitosan and Carbopol 971P. The feasibility of this surface modification was confirmed by measuring the zeta potential. Chitosan-modified PLGA microparticles showed a positive zeta potential, while Carbopol-modified PLGA microparticles were negatively charged. The mucin binding efficiency values have shown that the positively charged chitosan coated microparticles showed a higher adhesive percent to the mucin than the negatively charged un-coated or Carbopol 971P coated microparticles. Furthermore, surface modification of microparticles with chitosan and Carbopol 971P has yielded a slight decrease in the amount of protein initially released. These findings suggest the suitability of surface-modified PLGA microparticles as an efficient carrier system for delivery peptides and proteins to the respiratory tract.

Synthesis, characterisation and drug release properties of microspheres of polystyrene with aliphatic polyester side-chains.

A series of graft copolymers consisting of polystyrene backbone with biocompatible side chains based on (co)polymers of l-lactic acid and glycolic acid were synthesised by combination two controlled polymerisations, namely, nitroxide mediated radical polymerisation (NMRP) and ring opening polymerisation (ROP) with "Click" chemistry. The main goal of this work was to design new biodegradable microspheres using obtained graft copolymers for long-term sustained release of imatinib mesylate (IMM) as a model drug. The IMM loaded microspheres of the graft copolymers, polystyrene-g-poly(lactide-co-glycolide) (PS-g-PLLGA), polystyrene-g-poly(lactic acid) (PS-g-PLLA) and poly(lactic-coglycolic acid) (PLLGA) were then prepared by a modified water-in-oil-in-water (w1/o/w2) double emulsion/solvent evaporation technique. The optimised microspheres were characterised by particle size, encapsulation efficiency, and surface morphology also; their degradation and release properties were studied in vitro. The degradation studies of three different types of microspheres showed that the PS backbone of the graft copolymers slows down the degradation rate compared to PLLGA.

Treating colon cancer with injectable PLGA-PEG-PLGA as a carrier for iodine-125.

PURPOSE OF WORK: Provide a safer way for treating various cancers with PLGA-PEG-PLGA (PPP)-embedded iodine-125. To improve the safety of iodine treatment for colon cancer, iodine-125 solution was embedded into PLGA-PEG-PLGA (PPP) (synthesized by bulk co-polymerization of DL-polylactide glycolide and PEG). Xenograft-carrying nude mice were then treated with iodine-125-PPP. Proliferating cell nuclear antigen and Terminal Transferase dUTP Nick-End Labeling were used to measure proliferation and apoptosis in the tumors, respectively. Simultaneously, immunohistochemistry SP was used to detect the expression levels of p53. In addition, the microvessel density (MVD) of the tumors was recorded. PPP-embedded iodine-125 induced apoptosis by increasing the expression of p53, and by decreasing the levels of VEGF and MVD in the colon cancer tumors (P < 0.01). Significant inhibition of tumor growth is seen with iodine-125 from 0.4 to 0.8 mCi. PPP-embedded iodine-125 has a similar inhibitory efficiency to using the iodine-125 seeds for the treatment of colon tumors (P > 0.05). The findings therefore provide a potentially safer method for treating various tumors with radioactive iodine.

Long-circulating poly(ethylene glycol)-coated poly(lactid-co-glycolid) microcapsules as potential carriers for intravenously administered drugs.

The intrinsic advantages of microcapsules with regard to nanocapsules as intravenous drug carrier systems are still not fully exploited. Especially, in clinical situations where a long-term drug release within the vascular system is desired, if large amounts of drug have to be administered or if capillary leakage occurs, long-circulating microparticles may display a superior alternative to nanoparticles. Here, microcapsules were synthesised and parameters such as in vitro tendency of agglomeration, protein adsorption and in vivo performance were investigated. Biocompatible poly(ethylene glycol) (PEG)-coated poly(DL-lactide-co-glycolide) (PLGA) as wall material, solid and perfluorodecalin (PFD)-filled PEG-PLGA microcapsules (1.5 µm diameter) were manufactured by using a modified solvent evaporation method with either 1% poly(vinyl alcohol) (PVA) or 1.5% cholate as emulsifying agents. Compared to microcapsules manufactured with cholate, the protein adsorption (albumin and IgG) was clearly decreased and agglomeration of capsules was prevented, when PVA was used. The intravenous administration of these microcapsules, both solid and PFD-filled, in rats was successful and exhibited a circulatory half-life of about 1 h. Our data clearly demonstrate that PEG-PLGA microcapsules, manufactured by using PVA, are suitable biocompatible, long-circulating drug carriers, applicable for intravenous administration.

PEG-PLGA based large porous particles for pulmonary delivery of a highly soluble drug, low molecular weight heparin.

This study was designed to evaluate the feasibility of PEG-PLGA copolymers as carriers for pulmonary delivery of a highly soluble drug. We attempt to address the limitations of low entrapment efficiencies and poor release profiles that are associated with the use of conventional PLGAs. We have used low molecular weight heparin (LMWH) as a model for highly soluble and ionizable drugs and a 3 × 3 full factorial design to prepare nine formulations. We considered polymer type and percent NaCl in external phase as two independent variables at three different levels; the levels for polymer type were PLGA, PEG-PLGA and PLGA-PEG-PLGA and that for percent NaCl were 0%, 5% and 8%. Formulations were characterized for various physical properties, respirability, drug release, and evaluated for in vivo absorption, alveolar uptake, and safety. Statistical analyses suggest that both polymer type and salt concentration influenced the morphology and micromeritic properties of the particles. Compared with PLGA, PEG-PLGA copolymers produced inherently larger porous particles with high drug entrapment and a greater extent of drug release. Moreover, addition of NaCl in the external phase maximized drug entrapment but minimized burst release and produced smaller and denser particles. Fluorescent PEG-PLGA particles showed reduced uptake by alveolar macrophages, and exhibited a uniform distribution in the lungs compared with PLGA particles. Further, ~85% of the particles were cleared off the lungs within 6 days. Intratracheally administered PEG-PLGA based optimized formulation exhibited a biological half-life of 18.64 h, which was ~4.5 times longer than plain LMWH. No cytotoxic effect was observed when bronchial epithelial cells were incubated with PEG-PLGA based formulations. Similarly, no increase in the injury markers was observed in the bronchoalveolar lavage fluids collected from rats treated with PEG-PLGA particles of LMWH. Overall, this study suggests that PEG-PLGA block copolymers have the potential to be developed as efficient and biocompatible carriers for pulmonary delivery of highly water-soluble drugs.