Influence of polymer blends on the characterization of gliclazide--encapsulated into poly (ε-caprolactone) microparticles.

Gliclazide (GLZ)-loaded microparticles made with a polymeric blend were prepared by a solvent evaporation technique. Organic solutions of two polymers, poly(ε-caprolactone) (PCL) and Eudragit RS (E RS) or ethyl cellulose (EC), in different weight ratios, and 33.3% of GLZ were prepared and dropped into aqueous solution of poly vinyl alcohol, in different experimental conditions, achieving drug-loaded microparticles. The obtained microparticles were characterized in terms of yield of production, shape, size, surface properties, drug content, and in vitro drug release behavior. The physical state of the drugs and the polymer was determined by scanning electron microscopy (SEM), Fourier transform infra red and differential scanning calorimetry. Following the in vitro release studies microparticles made from blends of polymer, PCL/E RS or EC showed slower drug release than microparticles made from single PCL polymer. Surface morphology also revealed presence of porous and spherical structure of microparticles. Microparticles showing sustained release of GLZ were examined in rabbits and plasma GLZ concentrations were calculated using HPLC method of assay.

Design and development of gliclazide-loaded chitosan microparticles for oral sustained drug delivery: in-vitro/in-vivo evaluation.

OBJECTIVES: The objective of this study was to prepare gliclazide-chitosan microparticles with tripolyphosphate by ionic crosslinking. METHODS: Chitosan microparticles were produced by emulsification and ionotropic gelation. The effects of process variables including chitosan concentration, pH of tripolyphosphate solution, glutaraldehyde volume and release modifier agent such as pectin added to the tripolyphosphate crosslinking solution were evaluated. The microparticles were examined with scanning electron microscopy, infrared spectroscopy and differential scanning colorimetry. The serum glucose lowering effect of gliclazide microparticles was studied in streptozotocin-diabetic rabbits compared with the effect of pure gliclazide powder and gliclazide commercial tablets. KEY FINDINGS: The particle sizes of tripolyphosphate-chitosan microparticles were over the range 675-887 µm and the loading efficiency of drug was greater than 94.0%. In-vivo testing of the gliclazide-chitosan microparticles in diabetic rabbits demonstrated a significant antidiabetic effect of gliclazide-chitosan microparticles after 8 h that lasted for 18 h compared with gliclazide powder, which produced a maximum hypoglycaemic effect after 4 h. CONCLUSIONS: The results suggests that gliclazide-chitosan microparticles are a valuable system for the sustained delivery of gliclazide.

Design and development of gliclazide-loaded chitosan for oral sustained drug delivery: in vitro/in vivo evaluation.

Gliclazide (GLZ)/Chitosan microparticles were prepared with tripolyphosphate (TPP) by ionic cross-linking. The particle sizes of TPP-chitosan microparticles were in the range 675-887 µm and the loading efficiencies of drug was more than 94.0%. Chitosan concentration, TPP solution pH and glutaraldehyde volume added to the TPP cross-linking solution had an effect on the drug release characteristics. The microparticles were examined with scanning electron microscopy and infrared spectroscopy. Furthermore, pectin can interact with cationic chitosan on the surface of these TPP/chitosan microparticles to form a polyelectrolyte complex film for the improvement of the drug sustained-release performances. In vivo testing of the GLZ-chitosan microparticles in diabetic albino rabbits demonstrated significant antidiabetic effect of GLZ/chitosan microparticles after 8 h which lasts for 18 h, compared with GLZ powder which produced maximum hypoglycaemic effect after 4 h, suggesting that GLZ/chitosan microparticles are a valuable system for the long-term delivery of GLZ.

A new pressure-controlled colon delivery capsule for chronotherapeutic treatment of nocturnal asthma.

The purpose of this study was to prepare a pressure-controlled colon delivery capsule (PCDC) containing theophylline (TPH) dispersion in a lipid matrix as a chronotherapeutic drug delivery system for the treatment of nocturnal asthma. The system was made by film coating using Eudragit S100- based formula over the sealed-hard gelatin capsules containing the drug-lipid dispersion. The lipid formula was composed mainly of Gelucire 33/01 (G33) with different ratios of surfactants (1-10%). The efficiency of the prepared system was evaluated in vitro for its ability to withstand both the gastric and intestinal medium. In addition, the drug plasma concentrations were monitored after single administration to Beagle dogs and compared to that obtained after administration of a reference marketed, generic, sustained-release TPH tablets, Avolen(®) SR. It was found that the optimum lipid formula was GL2 containing 90% G33 and 10% Labrasol. The film-coated capsules showed complete resistance to both the acidic environment (pH 1.2) for 2 hours and phosphate buffer pH 6.8 for 3 hours at 37°C. In vivo evaluation of the TPH-based PCDCs showed longer lag time compared TO the marketed formula followed by sudden increase in TPH blood levels, which recommends the high potential of this system as a chronotherapeutic drug delivery for nocturnal asthma. The prepared PCDCs exhibited a significantly higher C(max) and T(max) and a nonsignificantly different AUC compared with Avolen(®) SR. Higher TPH blood levels from 1 to 8 hours postadministration was detected in the case of the prepared PCDCs.

Enhanced oral bioavailability of etodolac by self-emulsifying systems: in-vitro and in-vivo evaluation.

OBJECTIVES: The objective of this study was to prepare a self-emulsifying drug delivery system (SEDDS) for oral bioavailability enhancement of a poorly water-soluble drug, etodolac. The SEDDS formulations were optimized by evaluating their ability to self-emulsify when introduced to an aqueous medium under gentle agitation, and by determination of the particle size of the resulting emulsion. METHODS: An optimized formulation of SEDDS (composed of 20% etodolac, 30% oil Labrafac WL1349, 10% Lauroglycol 90 and 40% Labrasol) was selected for bioavailability assessment in rabbits. The anti-inflammatory effect was also determined in rats, and compared with powder drug and etodolac suspension in water (50 mg/kg). KEY FINDINGS: The peak plasma concentration of 16.4 +/- 1.1 microg/ml appeared after 1.3 +/- 0.2 h, whereas with powder drug and etodolac suspension the values were 7.5 +/- 0.5 and 10.6 +/- 0.7 microg/ml at 4.2 +/- 0.4 and 2.4 +/- 0.2 h, respectively. The AUC(0-8) of the etodolac SEDDS formulation was 2.3 times that of the pure drug and 1.4 times that of the suspension form. SEDDS formulation exhibits a 21% increase in paw thickness compared with a 39% increase on oral administration of etodolac suspension after 4 h at the same dose of the drug (20 mg/kg). CONCLUSIONS: The result indicates the utility of SEDDS for the oral delivery of etodolac and potentially other lipophilic drugs.

Magnetically modulated nanosystems: a unique drug-delivery platform.

Magnetic nanoparticles are attractive targets owing to their unique characteristics that are not shared by bulk materials. Magnetic particles, ranging from nanometer-sized to 1 microm in size, are being used in an increasing number of medical applications. The important properties of magnetic particles for medical applications are nontoxicity, biocompatiblilty, injectability and high-level accumulation in the target tissue or organ. Magnetic nanoparticles modified with organic molecules have been widely used for biotechnological and biomedical applications as their properties can be magnetically controlled by applying an external magnetic field. They offer high potential for numerous biomedical applications, such as cell separation, automated DNA extraction, gene targeting, drug delivery, MRI and hyperthermia. When coated with, for example, an antibody, they can be applied in highly sensitive immunoassays or small substance recoveries. Furthermore, a novel application of magnetic nanoparticles and magnetic forces for tissue engineering, termed 'magnetic force-based tissue engineering' has been proposed. Particular attention had been paid to the preparation methods that allow the synthesis of particles of nearly uniform size and shape.

Controlled-release carbamazepine matrix granules and tablets comprising lipophilic and hydrophilic components.

The objective of this study was to investigate the effect of lipophilic (Compritol 888 ATO) and hydrophilic components (combination of HPMC and Avicel) on the release of carbamazepine from granules and corresponding tablet. Wet granulation followed by compression was employed for preparation of granules and tablets. The matrix swelling behavior was investigated. The dissolution profiles of each formulation were compared to those of Tegretol CR tablets and the mean dissolution time (MDT), dissolution efficiency (DE%), and similarity factor (f(2) factor) were calculated. It was found that increase in the concentration of HPMC results in reduction in the release rate from granules and achievement of zero-order is difficult from the granules. The amount of HPMC plays a dominant role for the drug release. The release mechanism of CBZ from matrix tablet formulations follows non-Fickian diffusion shifting to Case II by the increase of HPMC content, indicating significant contribution of erosion. Increasing in drug loading resulted in acceleration of the drug release and in anomalous controlled-release mechanism due to delayed hydration of the tablets. These results suggest that wet granulation followed by compression could be a suitable method to formulate sustained release CBZ tablets.

In vitro and in vivo characteristics of a thermogelling rectal delivery system of etodolac.

Rectal etodolac-Poloxamer gel systems composed of Poloxamer and bioadhesive polymers were developed and evaluated. Hydroxypropylmethyl cellulose, poly)vinyl) pyrrolidone, methyl cellulose, hydroxyethylcellulose, and carbopol were examined as mucoadhesive polymers. The characteristics of the rectal gels differed according to the properties of mucoadhesive polymers. The physicochemical properties such as gelation temperature, gel strength, and bioadhesive force of various formulations were investigated. The analysis of release mechanism showed that the release of etodolac was proportional to the square root of time, indicating that etodolac might be released from the suppositories by Fickian diffusion. The anti-inflammatory effect of etodolac-Poloxamer gel system was also studied in rats. Moreover, liquid suppository of etodolac did not cause any morphological damage to the rectal tissues. These results suggested that in situ gelling liquid suppository with etodolac and mucoadhesive polymer was a physically safe, convenient, and effective rectal dosage form for etodolac.

Preparation and characterization of spironolactone-loaded gelucire microparticles using spray-drying technique.

The basic objectives of this study were to prepare and characterize solid dispersions of poorly soluble drug spironolactone (SP) using gelucire carriers by spray-drying technique. The properties of the microparticles produced were studied by differential scanning calorimetry (DSC), scanning electron microscopy, saturation solubility, encapsulation efficiency, and dissolution studies. The absence of SP peaks in DSC profiles of microparticles suggests the transformation of crystalline SP into an amorphous form. The in vitro dissolution test showed a significant increase in the dissolution rate of microparticles as compared with pure SP and physical mixtures (PMs) of drug with gelucire carriers. Therefore, the dissolution rate of poorly water-soluble drug SP can be significantly enhanced by the preparation of solid dispersion using spray-drying technique.

The influence of various amphiphilic excipients on the physicochemical properties of carbamazepine-loaded microparticles.

The objective of the present study was to prepare multiple-unit formulations of carbamazepine (CBZ) using an emulsion congealing technique. CBZ-hydrogenated castor oil (HCO) (Cutina® HR) wax microparticles were prepared without organic solvents as an alternative to polymeric microparticles. The process involved emulsification and solidification of CBZ-HCO melt at a significantly low temperature (5°C). Five amphiphilic excipients (Pluronic F-68 (PL), Labrasol (LB), Gelucire 44/14 (GL 44/14), D-α-tocopheryl PEG 1000 succinate (TPGS) and Docusate sodium (DOSS) were added with the wax melt. The microparticles were characterized with respect to their particle size distribution, drug loading, morphological character, drug-excipient interaction, differential scanning calorimetry, Fourier-transform infra-red (FT-IR) and release properties. An average value for production yield was 83.45%. Evaluation of the release data indicates that the release mechanism from the prepared Cutina® HR microparticles follows both the Higuchi model of diffusion and anomalous release mechanism. Microparticles containing 5% Labrasol, TPGS and GL 44/14 had the highest extent of dissolution.

Controlled-release carbamazepine granules and tablets comprising lipophilic and hydrophilic matrix components.

The objective of this study was to investigate the effect of lipophilic (Compritol 888 ATO) and hydrophilic components (combination of HPMC and Avicel) on the release of carbamazepine from granules and corresponding tablet. Wet granulation followed by compression was employed for preparation of granules and tablets. The matrix swelling behavior was investigated. The dissolution profiles of each formulation were compared to those of Tegretol CR tablets and the mean dissolution time (MDT), dissolution efficiency (DE %) and similarity factor (f(2) factor) were calculated. It was found that increase in the concentration of HPMC results in reduction in the release rate from granules and achievement of zero-order is difficult from the granules. The amount of HPMC plays a dominant role for the drug release. The release mechanism of CBZ from matrix tablet formulations follows non-Fickian diffusion shifting to case II by the increase of HPMC content, indicating significant contribution of erosion. Increasing in drug loading resulted in acceleration of the drug release and in anomalous controlled-release mechanism due to delayed hydration of the tablets. These results suggest that wet granulation followed by compression could be a suitable method to formulate sustained release CBZ tablets.

Formulation, release characteristics and bioavailability study of oral monolithic matrix tablets containing carbamazepine.

This study examined the release of carbamazepine (CBZ) from hydrophobic (Compritol 888 ATO) and hydrophilic-hydrophobic matrix combination (Compritol 888 ATO-hydroxpropyl methylcellulose, HPMC). Hydrophobic matrix tablets were prepared by hot fusion technique, while hydrophilic-hydrophobic matrix tablets were prepared by wet granulation technique. The properties of the compressed matrix tablets were determined according to the US Pharmacopoeia. Both matrix formulations displayed a controlled-release profile when compared to the reference formulation (Tegretol CR 200). The bioavailability of CBZ formulations and Tegretol CR 200 were evaluated in beagle dogs. Carbamazepine presented a significant higher bioavailability from matrix tablets containing hydrophilic polymer (HPMC) than that obtained from Tegretol CR200. The average inter-subject plasma concentration variability CV% was the least with tablet containing hydrophilic polymer (HPMC) and was the highest with Tegretol CR 200 (33.8 and 54.1, respectively). Analysis of variance applied to log AUC(0-alpha) and log C(max) showed statistical significant differences among the three formulations (P < 0.05). Plotting the fraction of CBZ released in vitro and fraction absorbed showed a statistically significant relationship (R(2) = 0.935-0.975) for the three matrix tablets examined.

Diclofenac sodium loaded-cellulose acetate butyrate: effect of processing variables on microparticles properties, drug release kinetics and ulcerogenic activity.

The aim of this study was to develop and characterize diclofenac sodium loaded-cellulose acetate butyrate microparticles in order to obtain a controlled-release system. The influence of the type of polymer, the volume and composition of the internal phase, drug loading, surfactant concentration and additive added on microparticles characteristics (particle size, encapsulation efficiency, surface morphology and in vitro release profiles) was studied to optimize the microparticles system. The resultant microparticles were evaluated for the recovery, average particle size, drug loading and incorporation efficiency. The microparticles exhibited good flowing nature and compressibility index when compared to pure drug. Dissolution rate of diclofenac sodium in phosphate buffer (pH 6.8) increased with increases in initial drug loading, surfactant concentration and addition of alcohol as co-solvent but decreased with increases in the concentration of additives such as Gantrez AN or Eudragit S100 in the internal phase. The dissolution data showed a Higuchi diffusion pattern for most of the formulations. About 56-81% reduction in ulcerogenic activity was observed with microparticles containing Eudragit S100 17-25%, based on total polymer concentration, when compared with pure diclofenac sodium.

In vitro performance of carbamazepine loaded to various molecular weights of poly (D,L-lactide-co-glycolide).

The purpose of this study was to develop and assess the in vitro characteristics of carbamazepine-loaded microspheres. A solvent evaporation method was used to incorporate carbamazepine (CBZ) into poly (D,L-lactide-co-glycolide) (PLGA) with different molecular weights. The optimum conditions for CBZ-PLGA microspheres preparation were considered and the in vitro release of CBZ of PLGA microspheres were followed up to 24 hr in USP dissolution medium. The effect of using different ratios of PLGA microspheres, prepared with different molecular weights, for optimizing CBZ release also was investigated. CBZ encapsulation efficiency was 68 to 82% for all prepared formulations. Thermograms of CBZ-PLGA microspheres suggest that CBZ was totally entrapped with the PLGA polymer. The presence of Pluronic F-68 has improved the encapsulation of CBZ, resulted in better and smoother microspheres surfaces and enhanced its release pattern. CBZ release profiles were biphasic patterns; after an initial burst, a constant CBZ release rate was observed up to 24 hr. The release from these PLGA-based spherical matrices was consistent with the diffusion mechanism. CBZ dissolution T(50%) was significantly affected (> 3-fold) by increasing the lactide percent from 33.3 to 66.6% from different microspheres mixtures. The present study provides evidence that the encapsulation of CBZ to PLGA microspheres, either as a single polymer or mixture of two, was a successful attempt to control the release of CBZ.

In vitro characterization of carbamazepine-loaded precifac lipospheres.

Lipospheres of carbamazepine were prepared by melt dispersion technique using Precifac ATO 5 in the various drug-lipid ratios. The resulting free-flowing lipospheres were evaluated with respect to surface morphology, particle size distribution, encapsulation efficiency, and in vitro release behavior. The effect of druglipid ratio, the surfactant added, emulsion stabilizer, and stirring speed also were identified as the key variables affecting the formation of discrete spherical lipospheres and drug release rate. The preparation conditions were optimized by using 0.4% w/v span 20 (Hydrophilic-Lipophilic Balance, HLB = 8.6) as a surfactant and 1% w/v gelatin solution as a stabilizer in presence of a high level of water. We found that the ratio of drug to lipid affects the size of the spheres. The incorporation efficiency was found to be high at all loadings. Increasing the lipid:drug ratio produced more spherical, smooth, and round lipospheres. All the prepared lipospheres exhibited slow release profiles dictating the Higuchi mode of release. We saw that the higher the sphere size and the ratio of Precifac, the slower is in vitro drug release.