Increase in the vascular residence time of propranolol-loaded nanoparticles coated with heparin.

Propranolol-HCI incorporated nanoparticles prepared with a blend of a polyester and a polycationic polymer and coated or not with a low molecular weight heparin by electrostatic interactions were prepared by emulsification followed by solvent evaporation. The mean diameter was 388 and 357 nm for coated and uncoated nanoparticles, respectively, and the entrapment efficiency ranged from 20 to 32%. Coated nanoparticles were negatively-charged, whereas uncoated nanoparticles displayed a positive zeta potential (+30 mV). After intravenous administration to rabbits of propranolol-HCI solution and propranolol-loaded nanoparticles coated or not with heparin, pharmacokinetic data revealed that coated nanoparticles exhibited a prolonged blood residence time. It can be concluded that the hydrophilic layer of heparin at the surface of nanoparticles conferred stealth properties which probably reduce the phagocytosis process and avoid immediate uptake by the mononuclear phagocytic system.

Simple and sensitive HPLC method with fluorescence detection for the measurement of ibuprofen in rat plasma: application to a long-lasting dosage form.

A simple and sensitive high-performance liquid chromatography (HPLC) assay applied to the measurement of ibuprofen in rat plasma has been developed. Two parameters have been investigated to improve ibuprofen detectability using fluorescence detection: variation of mobile phase pH and the use of beta-cyclodextrin (beta-CD). Increasing the pH value from 2.5 to 6.5 and adding 5 mM beta-CD enhanced the fluorescence signal (lambda(exc) = 224 nm; lambda(em) = 290 nm) by 2.5 and 1.3-fold, respectively, when using standards. In the case of plasma samples, only pH variation significantly lowered detection and quantification limits, down to 10 and 35 ng/mL, respectively. Full selectivity was obtained with a single step for plasma treatment, that is, protein precipitation with acidified acetonitrile. The validated method was applied to a pharmacokinetic study of ibuprofen encapsulated in microspheres and subcutaneously administered to rats.

Oral delivery of insulin associated to polymeric nanoparticles in diabetic rats.

Nanoparticles prepared with a blend of a biodegradable polyester (poly(-epsilon-caprolactone)) and a polycationic non-biodegradable acrylic polymer (Eudragit RS) have been used as a drug carrier for oral administration of insulin. The rate of encapsulation of insulin was around 96%. The therapeutic efficiency of oral insulin nanoparticles (25, 50 and 100 IU/kg) in diabetic rats and the intestinal uptake of fluorescein isothiocyanate (FITC) labelled insulin were studied. When administered orally by force-feeding to diabetic rats, insulin nanoparticles decreased fasted glycemia in a dose dependant manner with a maximal effect observed with 100 IU/kg. These insulin nanoparticles also increased serum insulin levels and improved the glycemic response to an oral glucose challenge for a prolonged period of time. FITC-Insulin-loaded nanoparticles strongly adhered to the intestinal mucosa and labeled insulin, either released and/or still inside nanoparticles, was mainly taken up by the Peyer's patches. It is concluded that polymeric nanoparticles allows the preservation of insulin's biological activity. In addition, the antidiabetic effect can be explained by the mucoadhesive properties of the polycationic polymer (Eudragit) RS) allowing the intestinal uptake of insulin.

Oral low molecular weight heparin delivery by microparticles from complex coacervation.

As low molecular weight heparins exhibit limited oral absorption they usually have to be administered parenterally. Their strong negative charge appears to be one of the biggest hurdles to overcome in order to increase oral absorption. Complex coacervation has been proposed as a microencapsulation technique for increased oral drug absorption on the basis of charge compensation. Optimized tinzaparin/acacia gum mixture were coacervated with either gelatin A or B leading to microparticles with monodispersed size distribution, good fluidity and high encapsulation rates (>90%), while mean particle size varied between 5 and 20 microm, respectively, depending on the gelatin type. Tinzaparin was homogeneously distributed throughout the particle matrix and anti-Xa activity was maintained during preparation and storage. Drug release occurred in dependency of the pH triggering the dissociation between tinzaparin/acacia and gelatin. Cell binding experiments on Caco-2 led to slightly increased adhesion of gelatin A microparticles compared to gelatin B (A: 3.5+/-0.3%; B: 2.5+/-0.3%; solution: 1.9+/-0.1%), while drug transport did not differ from free tinzaparin solution. In-vivo results demonstrated an oral bioavailability of about 4.2+/-2.9% with gelatin B particles while gelatin A led to no absorption of tinzaparin. In conclusion, tinzaparin microparticles exhibited excellent particle properties in vitro and demonstrate potential for a formulation increasing the oral bioavailability of low molecular weight heparins.

Low molecular weight heparin loaded pH-sensitive microparticles.

Low molecular weight heparins (LMWH) have shown efficacy in the treatment of inflammatory bowel disease after parenteral administration however risking severe hemorrhagic adverse effects. Therefore, an oral colonic targeted heparin dosage form allowing the release of LMWH directly in the inflamed tissue would be of major interest. Enoxaparin was entrapped into pH-sensitive microspheres using Eudragit P4135F that dissolves at pH>7.2. Particle preparation was based on a double emulsion technique with either solvent extraction or evaporation. In order to increase the entrapment efficacy several preparation parameters were optimized, such as inner phase volume, polymer concentration, stabilization of the internal interface by surfactants. Solvent evaporation led to higher entrapment rates (evaporation: 70.1+/-9.9%; extraction: 46.5+/-6.4%). When increasing the volume of the inner aqueous heparin phase, lower encapsulation rates and larger microspheres ( approximately 100-400 microm) were obtained. Sorbitan monostearate (1.75-28% of the total particle mass) had a stabilizing effect on the primary water/oil emulsion. Indeed, higher encapsulation rates (7%: 78.2+/-3.5%; 14%: 76.4+/-10.1%) and smaller particles ( approximately 120-160 microm) were obtained whereas hexadecyltrimethylammonium bromide destabilized the primary emulsion. Interfacial tension studies at a simulated internal water/oil interface confirmed these results. As expected, in vitro drug release was found to be strongly pH-dependent; LMWH was retained in microspheres at pH<6 (<20% release within 4h) whereas a fast drug release was obtained at pH 7.4. The developed microspheres exhibited a particle size adapted to the needs of inflammatory bowel disease therapy, an efficient LMWH encapsulation, and a pH-controlled drug release. These microspheres represent a promising tool for the selective oral delivery of heparin to the colon, especially interesting in the treatment of inflammatory bowel disease.

Impact of bulk and surface properties of some biocompatible hydrophobic polymers on the stability of methylene chloride-in-water mini-emulsions used to prepare nanoparticles by emulsification-solvent evaporation.

The emulsifying and stabilizing ability of several hydrophobic (insoluble in water and soluble in volatile organic solvents) polymers, such as Eudragit RL, Eudragit RS, PLGA, PCL, and their mixtures, with regard to the methylene chloride (MC)-in-water mini-emulsions, has been compared to the viscosity of MC solutions and to the properties of adsorption and spread monolayers of these polymers. Eudragits RS and RL contain approximately 2.5 and approximately 5 mol% of pendent cationic trimethylammonium (TMA) groups per approximately 164 g/mol segments, whereas PLGA and PCL contain 1 and 2 polar carbonyl groups per 130 and 114 g/mol, respectively. The electrostatic attraction between the dipoles, formed by TMA groups and the condensed counter ions in the MC solutions, leads to the contraction of macromolecular coils of Eudragits, whereas the PLGA and PCL macromolecules, interacting by low polar carbonyl groups (with dipole moment mu = 2.7 D) retain more extended conformation in MC. This explains why the characteristic viscosities [eta] of MC solutions are much lower for the former polymers ( approximately 0.1 dL/g) with regard to PLGA and PCL solutions whose [eta] is equal to 0.3 and 0.6 dL/g, respectively. The ionization of TMA groups in contact with the water phase leads to the irreversible adsorption of Eudragits at the MC/water interface and to high decrease of the interfacial tension gamma (down to 4 mN/m for the 5% MC solutions). Whereas PLGA and PCL possessing low polar carbonyl groups adsorb poorly at the MC/water interface exhibiting gamma congruent with 28 mN/m. Higher stability of spread monolayers of Eudragits (pi* approximately 40 mN/m) with regard to PLGA and PCL (pi* < 20 mN/m) correlates well with higher interfacial activity of the former with regard to the later. The higher surface potential DeltaV of Eudragits (0.9 V) with regard to PLGA (0.3 V) and PCL (0.4V) is explained by the formation of electric double layer (DL) by the former, whereas the later contribute to the DeltaV only by cumulative dipole moments of carbonyl groups. The experimental values of surface potentials correlate well with the Gouy-Chapman model of the DL and the Helmholtz model of the monolayer. The ensemble of experimental results leads to the conclusion that higher emulsifying and stabilizing ability of Eudragits with regard to PLGA and PCL is due to higher adsorption activity of the former which form the corona of polymeric chains with ionized TMA groups around the droplets. It can be postulated that Eudragit polymers have good surface active properties which may allow manufacturing of biocompatible nanoparticles by emulsification-solvent evaporation method without surfactants.

Oral bioavailability of a low molecular weight heparin using a polymeric delivery system.

Low molecular weight heparins (LMWHs) are the standards of anticoagulant for the prevention of deep vein thrombosis (DVT) in patients undergoing arthroplasty and abdominal surgery. However, LMWHs are so far only administered by parenteral route. Thus, they are usually replaced by oral warfarin for outpatient therapy. Since warfarin has a slow onset and high incidence of drug-drug interaction, there is a great need for the development of an oral LMWH formulation. LMWH (tinzaparin)-loaded nanoparticles prepared with a blend of a polyester and a polycationic polymethacrylate by the double emulsion method were administered orally in fasted rabbits. The plasma tinzaparin concentration was measured by a chromogenic anti-factor Xa assay. After oral administration of two doses of tinzaparin-loaded nanoparticles (200 and 600 anti-Xa U/kg), the oral absorption was observed between 4 and 10 or 12 h, with a delayed onset of action ranging from 3 to 4 h. Mean absolute bioavailabilities were 51% and 59% for the two tested doses. We now report that the encapsulation of tinzaparin into nanoparticles is likely to contribute to its oral efficacy with an anticoagulant effect prolonged up to 8 h.

In vitro and in vivo evaluation of oral heparin-loaded polymeric nanoparticles in rabbits.

BACKGROUND: Owing to its short half-life and lack of oral absorption, heparin has to be administered by the parenteral route. An oral heparin formulation, however, would avoid the disadvantages of parenteral injections and would consequently be highly desirable for patients. Polymeric nanoparticles (NPs) prepared with biodegradable poly-epsilon-caprolactone (PCL) and poly(lactic-co-glycolic acid) (PLGA) and nonbiodegradable positively charged polymers (Eudragit RS and RL), used alone or in combination, were evaluated in vitro and in vivo after a single oral administration of heparin-loaded NPs in rabbits. METHODS AND RESULTS: After oral administration of heparin-loaded NPs in rabbits (600 IU/kg), increases in both anti-factor Xa activity and activated partial thromboplastin time (aPTT) were detected with each formulation. Moreover, the anti-Xa activity was detected for a longer period than when a heparin solution was administered intravenously. A peak concentration of 0.16+/-0.01 IU/mL and an average aPTT of 24 seconds (2-fold increase) were obtained 7 hours after oral dosing of Eudragit RL/PCL NPs containing heparin, exhibiting an absolute bioavailability of 23%. CONCLUSIONS: The significant increases in anti-factor Xa activity and aPTT confirmed the oral absorption in rabbits of heparin released from polymeric NPs.

Preparation and characterization of propranolol hydrochloride nanoparticles: a comparative study.

The water-in-oil-in-water (w/o/w) emulsification process is the method of choice for the encapsulation inside polymeric particles of hydrophilic drugs such as proteins and peptides which are high molecular weight macromolecules. Our objective was to apply this technique in order to formulate nanoparticles loaded with both a hydrophilic and a low molecular weight drug such as propranolol-HCl. Nanoparticles were prepared using a pressure homogenization device with various polymers (poly--caprolactone, poly(lactide-co-glycolide), ethylcellulose) and different amounts of drug and were compared in terms of particle size, encapsulation efficiency and drug release. Higher encapsulation efficiencies were obtained with both PCL (77.3%) and PLGA (83.3%) compared to ethylcellulose (66.8%). The in vitro drug release was characterized by an initial burst and an incomplete dissolution of the drug. When decreasing the polymer/drug ratio, the release appeared more controlled and prolonged up to 8 h. It can be concluded that nanoparticles prepared by w/o/w emulsification followed by solvent evaporation might be potential drug carriers for low molecular weight and hydrophilic drugs.

Anticoagulant activity of heparin following oral administration of heparin-loaded microparticles in rabbits.

Heparin-loaded microparticles, prepared according to the double emulsion method with biodegradable (PCL and PLGA) and nonbiodegradable (Eudragit RS and RL) polymers used alone or in combination, with or without gelatin, were characterized in vitro and in vivo after oral administration in rabbits. The entrapment efficiency and the release of heparin were determined by a colorimetric method with Azure II. The antifactor Xa activity of heparin released in vitro after 24 h was assessed. After oral administration of heparin-loaded microparticles in rabbits, the time course of modification of the clotting time estimated by the activated partial thromboplastin time (APTT) was followed over 24 h. Microparticles with a size ranging from 80 to 280 microm were obtained. Heparin entrapment efficiency as well as heparin release depended on both the nature of the polymers and the presence of gelatin. The Eudragit polymers increased the drug loading but slowed down the heparin release, whereas gelatin accelerated the release. No change in clotting time was observed after oral administration of gelatin microparticles. Heparin-loaded microparticles prepared with blends of PLGA and Eudragit displayed a prolonged duration of action characterized by a twofold increase in APTT and a enhancement of absorption. This study demonstrated the feasibility of encapsulating heparin within polymeric particles, and the significant increase in APTT confirmed the oral absorption of heparin released from polymeric microparticles.

Poly(epsilon-caprolactone)/eudragit nanoparticles for oral delivery of aspart-insulin in the treatment of diabetes.

Nanoparticles prepared with a blend of a biodegradable polyester (poly(epsilon-caprolactone)) and a polycationic nonbiodegradable acrylic polymer (Eudragit RS) have been used as a drug carrier for oral administration of a short-acting insulin analogue, aspart-insulin. Insulin-loaded nanoparticles, about 700 nm in diameter, encapsulated 97.5% of insulin and were able to release about 70% of their content in vitro in a neutral medium over 24 h. When administered orally to diabetic rats, insulin-loaded nanoparticles (50 IU/kg) decreased fasted glycemia for a prolonged period of time and improved the glycemic response to glucose in a time-dependent manner, with a maximal effect between 12 and 24 h after their administration. In parallel, plasma insulin levels increased. However, higher (100 IU/kg) and lower (25 IU/kg) doses of insulin did not exert any biological effect. It is concluded that polymeric nanoparticles composed of poly(epsilon-caprolactone)/Eudragit RS are able to preserve the biological activity of the insulin analogue aspart-insulin; however, the postprandial peak suppression was prolonged more than 24 h by comparison with regular insulin working only 6-8 h. This effect may be explained by the monomeric configuration of aspart-insulin, which is probably better taken up by the intestinal mucosa than regular insulin.

Epithelial heparin delivery via microspheres mitigates experimental colitis in mice.

Low-molecular-weight heparins (LMWH) have been shown to be efficient in the treatment of inflammatory bowel disease (IBD). Parenteral heparin therapy, however, may cause hemorrhagic adverse effects. To reduce this risk, epithelial LMWH delivery in combination with a system ensuring selective drug release to the inflamed tissue was tested here. Enoxaparin loaded microspheres (MS) were administered orally to male BALB mice suffering from a pre-existing experimental colitis, whereas control groups received subcutaneous or rectal LMWH solution. Colon weight/length index and alkaline phosphatase and myeloperoxidase activities were assessed to determine the inflammation. Tissue penetration experiments elucidated the processes involved in the proposed new therapeutic approach. Oral LMWH-MS proved to be equally efficient in mitigating experimental colitis as rectally administered LMWH solution when quantified by myeloperoxidase activity (MS, 10.2+/-1.5 U/mg tissue; rectal, 9.2+/-1.6 U/mg) and to be superior to subcutaneous LMWH (s.c., 21.6+/-5.6 U/mg; untreated colitis control, 30.0+/-3.8 U/mg). Pharmacokinetic studies found a notably low systemic availability of oral LMWH delivered from MS (<5%) indicating a low potential for adverse effects. The tissue permeability was selectively enhanced in the inflamed regions where a 9-fold higher LMWH penetration was found compared with healthy tissue. Epithelial LMWH delivery has been found a promising anti-inflammatory therapeutic approach. The use of LMWH-MS in this context offers a promising tool for IBD therapy by enhancing specifically drug availability at inflamed tissue sites while reducing the risk for systemic adverse effects to a negligibly low level.

Influence of polymers on the bioavailability of microencapsulated celecoxib.

Celecoxib, a selective COX-2 inhibitor, primarily used in treatment of osteoarthritis, rheumatoid arthritis and acute pain was encapsulated in microparticles composed of various polyesters, polymethacrylates or cellulose derivatives used alone or blended. The influence of polymers on microparticle mean diameter, encapsulation efficiency and in vitro and in vivo celecoxib release was investigated. Microparticles were in the size range 11-37 microm. Encapsulation efficiency was optimal due to poor aqueous solubility of celecoxib. Considering in vitro release, microparticles could be divided into drug delivery systems with fast and slow release profiles. Microparticles prepared with poly-epsilon-caprolactone, Eudragit RS and low viscosity ethylcellulose, together with physical mixture of celecoxib with lactose and Celebrex, were tested in vivo. Relative bioavailability of celecoxib was below 20% in all cases and was probably the consequence of a slow in vivo release of celecoxib from microparticles or low wettability in the case of Celebrex and physical mixture.

Immunoadsorption of alloantibodies onto erythroid membrane antigens encapsulated into polymeric microparticles.

PURPOSE: Classical immunoadsorbents used for the removal of deleterious molecules in blood such as auto-antibodies are prepared by covalent coupling of antigens onto previously chemically activated supports. Such a chemical treatment may induce a potential toxicity which can be reduced if new immunoadsorbents are prepared by encapsulating erythrocytes-ghosts carrying antigens inside polymeric and porous microparticles. MATERIALS AND METHODS: Erythrocyte-ghosts obtained by hemolysis in hypotonic buffer were encapsulated into ethylcellulose microparticles by w/o/w emulsification. The porosity of microparticles was evaluated by mercury porosimetry. The adsorption ability of encapsulated antigens was evaluated by hemagglutination after contact in tube or elution in column with polyclonal antibody solutions or human blood-plasma. RESULTS: The encapsulation process did not significantly alter the evaluated antigens since a significant decrease in anti-A (from 256 to 4) as well as anti-Kell (from 64 to 2) antibody titer has been observed in column after eight chromatographic runs (2 h). The higher the ghost concentration (total protein content of 6 mg/ml), the higher the adsorption capacity. CONCLUSION: Encapsulation, currently used for drug delivery purposes, may consequently also be applied to the design of new immunoadsorbents as biomaterials.

Enhanced cellular uptake of a glutathione selective fluorogenic probe encapsulated in nanoparticles.

Selective fluorogenic probes for the labelling of intracellular reduced glutathione (GSH), i.e. ortho-phthaldialdehyde (OPA) and naphthalene-2,3-dicarboxaldehyde (NDA), have been encapsulated in polymeric nanoparticles (NPs) and the ability of the NPs to enhance uptake of the probe by microbial cells has been evaluated. Preparation of the probe-loaded NPs composed of Eudragit(®) E was based on an oil-in-water emulsification solvent evaporation method using an ultrasonic probe and polyvinyl alcohol as the surfactant. The encapsulation efficiency of the probes in lyophilized NPs was determined using high performance liquid chromatography (HPLC). A higher encapsulation rate of NDA than OPA was found: 47.6 ± 9.9 (n = 6) and 2.1 ± 0.2% (n = 3), respectively. The NDA-loaded particle diameter and zeta potential were 224.6 ± 14.7 nm and +40.9 ± 6.5 mV, respectively. After 20 min incubation of cultured Candida albicans yeast cells with either free NDA or NDA-loaded NPs (final NDA concentration 100 µM), cells were harvested and corresponding lysates were analysed using HPLC coupled with spectrofluorimetric detection. Incubation of cells with NDA-loaded NPs increased intracellular levels of NDA-GSH adduct by about nine-fold in comparison with the free probe. Adhesion on the cells and the penetration behaviour of NPs loaded with either NDA or fluorescent label (Nile Red) were characterized qualitatively by confocal laser scanning microscopy.

FK506 microparticles mitigate experimental colitis with minor renal calcineurin suppression.

PURPOSE: FK506 microparticles providing selective colonic drug delivery were tested for their efficiency in a local treatment to the inflamed gut tissue in inflammatory bowel disease (IBD). Because FK506 proved its distinct mitigating potential in the treatment of IBD, risking, however, severe adverse effects, a more selective delivery to the site of inflammation may further improve efficiency and tolerability. METHODS: A model colitis was induced to male Wistar rats by trinitrobenzenesulfonic acid. FK506 was entrapped into microspheres (MS) prepared with the pH-sensitive polymer Eudragit P-4135F in order to allow drug delivery to the colon. Clinical activity score, colon/body weight index, and myeloperoxidase activity were determined to assess the inflammation, and adverse effects of FK506 resulting from its systemic absorption were quantified as well. RESULTS: The clinical activity score and myeloperoxidase activity decreased after the administration of all FK506-containing formulations. The MS formulations proved to be as efficient in mitigating the experimental colitis as the subcutaneous drug solution (myeloperoxidase activity, MS: 9.64+/-6.6 U/mg tissue; subcutaneous: 7.48+/-6.96 U/mg) and to be superior to drug solution given by oral route (oral: 12.66+/-5.46 U/mg; untreated colitis control: 21.88+/-4.12 U/mg). The FK506 subcutaneous group exhibited increased levels of adverse effects, whereas the FK506-MS group proved its potential to retain the drug from systemic absorption as evidenced by reduced nephrotoxicity. CONCLUSIONS: The development of this selective delivery system for FK506 should be given particular consideration in the treatment of IBD, as it allows therapy that profits from FK506's high immune suppressive effect with a simultaneously reduced nephrotoxicity.