Formulation and stability evaluation of ketoprofen sustained-release tablets prepared by fluid bed granulation with Carbopol 971P solution

The objectives of the present study were: (1) to investigate the possibility of using a Carbopol polymeric solution as granulating agent by the fluid bed granulating process; (2) to select a suitable method of tabletting for sustaining the release of ketoprofen for 12 hr; (3) to perform stability studies according to International Committee on Harmonization (ICH) guidelines and photostability on ketoprofen SR tablets; (4) to study the influence of the storage conditions on release kinetics and melting endotherm of ketoprofen; and (5) to predict the shelf-life of the ketoprofen SR tablets. Tabletting ingredients were ketoprofen, anhydrous dicalcium phosphate, Carbopol® 971P, talc, and magnesium stearate. Carbopol® 971P solution (0.8% w/v) was used as a granulating solution in the fluid bed granulator. For comparative evaluation, tablets were also prepared by direct compression and wet granulation, and subjected to dissolution. Tablets prepared by fluid bed granulation technique were stored in incubators maintained at 37, 40, 50, and 60°C, 40°C/75% RH, 30°C/60% RH, and 25°C/60% RH, and in a light chamber with light intensity of 600 ft candle at 25°C. Melting endotherms were obtained for the drug as well as the tablets during stability studies by differential scanning calorimetry. Tablets prepared by fluid bed granulation technique prolonged the release of ketoprofen better than tablets obtained by direct compression and wet granulation. Further, it complied with the requirements of ICH guidelines for stability testing. Higher temperature and humidity (40 ± 2°C/75% RH, 40°C, 50°C, and 60°C) adversely affected the rate and extent of the dissolution. Ketoprofen SR tablets stored in amber-colored bottles demonstrated a good photostability for 6 months at 600 ft candle. The shelf-life of the formulation was predicted as 32 months.     

Acrylate-based transdermal therapeutic system of nitrendipine

The objective of the present research investigation was to fabricate an acrylate-based transdermal therapeutic system (TTS) of nitrendipine, which could deliver drug at maximum input rate so as to deliver drug in minimum patch size. Transdermal patches were fabricated using synthesized acrylate pressure-sensitive adhesives (PSAs): PSA1, PSA2, and commercially available PSA3 and PSA4 using d-limonene as permeation enhancer. Effect of concentration of d-limonene on permeation kinetics of nitrendipine in PSAs was studied. Fabricated TTS in mentioned PSAs were evaluated for in-vitro release and permeation kinetics through guinea-pig skin. Cumulative release of drug in PSA1, PSA2, PSA3, and PSA4 was observed to be 45%, 40%, 25%, and 25%, respectively, upto 24 hr. Flux of drug through guinea-pig skin calculated at 48 hr in PSA1, PSA2, PSA3, and PSA4, with and without d-limonene, was observed to be 0.346 ± 0.10, 0.435 ± 0.17, 0.410 ± 0.17, and 0.162 ± 0.06, and 0.625 ± 0.19, 1.161 ± 0.46, 0.506 ± 0.17, and 0.520 ± 0.18 (µg/cm²/hr), respectively. The TTS in PSA2 showed comparatively high flux and could deliver drug at high input rate through transdermal route. PSA2 was found to have good rate-controlling property and could be successfully employed in transdermal delivery of nitrendipine.     

Design and evaluation of matrix diffusion controlled transdermal patches of verapamil hydrochloride

Transdermal patches of verapamil hydrochloride were prepared using four different polymers (individual and combination): Eudragit RL100 (ERL100), Eudragit RS100 (ERS100), hydroxypropyl methylcellulose 15 cps (HPMC), and ethyl cellulose (EC), of varying degrees of hydrophilicity and hydrophobicity. The effect of the polymers on the technological properties, i.e., drug release, water vapor transmission rate (WVTR), and percentage moisture loss (ML), percentage moisture absorption (MA), folding endurance, and thickness, was investigated. Different formulations were prepared in accordance with the 2³ factorial design, with ERL100 being the parent polymer. The patch containing ERL100 alone showed maximum WVTR, % MA, and % ML, which could be attributed to its hydrophilic nature. As expected, substitution with ERS100, HPMC, and EC decreased all the above values in accordance with their decreasing degree of hydrophilicity. In vitro release studies showed zero-order release of the drug from all the patches, and the mechanism of release was diffusion mediated. Moreover, the release of the drug was sustained and it extended over a period of 24 hr in all formulations. A12 emerged as the most satisfactory formulation insofar as its technological properties were concerned. Further, release and permeation of the drug from the most satisfactory formulation (A12) was evaluated through different biological barriers (shed snake skin, rabbit skin, and rat skin) to get an idea of the drug permeation through human skin. Shed snake's skin was found to be most permeable (82.56% drug release at 24 hr) and rat skin was least permeable (52.38%). Percutaneous absorption studies were carried out in rabbits. The pharmacokinetic parameters calculated from blood levels of the drug revealed a profile typical of a sustained release formulation, with the ability to maintain adequate plasma levels for 24 hr. [AUC: 3.09 mg/mL hr, C_max: 203.95 µg/mL, T_max: 8 hr]. It can therefore be concluded that the patch containing ERL100 and HPMC in the ratio 8:2 has achieved the objectives of transdermal drug delivery system, such as avoidance of first pass effect, extended release, and reduced frequency of administration.     

Effect of heat on characteristics of chitosan film coated on theophylline tablets

The effect of heat on the characteristics of chitosan film coated on theophylline tablets was studied. Chitosan of high viscosity grade with molecular weight in the range of 800,000-1,000,000, 80-85% degree of deacetylation was used as a film former by dissolving in 1% v/v acetic acid solution. The coated tablets had been cured at 40, 60, and 100°C for 6, 12, and 24 hr. The morphology of the film at the edge and surface of coated tablets was investigated using scanning electron microscopy. Film cracking was increased and clearly observed in the coated tablets cured at 100°C for 24 hr. As a result, more water could be absorbed into the tablets, followed by faster disintegration and faster drug release. The evidence of partial conversion of chitosonium acetate to chitin in the ¹³C nuclear magnetic resonance (NMR) spectra of chitosan films cured at 40, 60, and 100°C was observed, but it had no effect on drug release behavior. Theophylline tablets coated with chitosan films gave sustained release behavior in various media, i.e., distilled water, 0.1 N hydrochloric acid, pH 4.5 acetate buffer, and pH 6.8 phosphate buffer. In addition, the film coating temperature at 55-60°C and curing process at 40 and 60°C had no effect on the drug release from theophylline tablets coated with chitosan polymer. Finally, it might be concluded that both the physical and chemical properties of chitosan films were affected by heat.     

Erosion characteristics of an erodible tablet incorporated in a time-delayed capsule device

A time-delayed oral drug delivery device was investigated in which an erodible tablet (ET), sealing the mouth of an insoluble capsule, controlled the lag-time prior to drug release. The time-delayed capsule (TDC) lag-time may be altered by manipulation of the excipients used in the preparation of the ET. Erosion rates and drug release profiles from TDCs were investigated with four different excipient admixtures with lactose: calcium sulphate dihydrate (CSD), dicalcium phosphate (DCP), hydroxypropylmethyl cellulose (HPMC; Methocel® K100LV grade) and silicified microcrystalline cellulose (SMCC; Prosolv® 90 grade). Additionally, the compressibility of different insoluble coated capsules was tested at different moisture levels to determine their overall integrity and suitability for oral delivery. Erosion rates of CSD, DCP, and SMCC displayed a nonlinear relationship to their concentration, while HPMC indicated rapid first-order erosion followed by zero-order erosion, the onset of which was dependent on the HPMC concentration. Capsule integrity was confirmed to be most suitable for oral delivery when the insoluble ethyl cellulose coat was applied to a hard gelatin capsule using an organic spray coating process. T_50% drug release times varied between 245 (± 33.4) and 393 (± 40.8) minutes for 8% and 20% DCP, respectively, T_50% release times of 91 (± 22.1) and 167 (± 34.6) were observed for 8% and 20% CSD; both formulations showed incidence of premature drug release. The SMCC formulations showed high variability due to lamination effects. The HPMC formulations had T_50% release times of 69 (± 13.9), 213 (± 25.4), and 325 (± 30.3) minutes for 15%, 24%, and 30% HPMC concentrations respectively, with no premature drug release. In conclusion, HPMC showed the highest reproducibility for a range of time-delayed drug release from the assembled capsule formulation. The method of capsule coating was confirmed to be important by investigation of the overall capsule integrity at elevated humidity levels. The erosion characteristics of ETs containing HPMC may be described by gravimetric loss. The novel time-delayed capsule device presented in this study may be assembled to include an erodible tablet with a known concentration of HPMC. A variety of suitable drugs for targeted chronopharmaceutical therapy can beincorporated into such a device, ultimately improving drug efficacy and patient compliance, and reducing harmful side effects.     

Preparation, in Vitro and in Vivo Evaluation of Liposomal/Niosomal Gel Delivery Systems for Clotrimazole

Clotrimazole, which is an imidazole derivative antifungal agent, was widely used for the treatment of mycotic infections of the genitourinary tract. To develop alternative formulation for the vaginal administration of clotrimazole to provide sustained and controlled release of appropriate drug for local vaginal therapy, liposomes/niosomes were evaluated as delivery vehicles. To optimize the preparation of liposomes/niosomes with regard to size and entrapment efficiency, multilamellar liposomes/niosomes containing drug were prepared by lipid hydration method. The prepared liposomes/niosomes were incorporated into 2% carbopol gel, and the systems were evaluated for drug stability in phosphate-buffered saline (pH 7.4) and simulated vaginal fluid at 37 ± 1°C. Further, the vesicle gel system was evaluated by antifungal activity and tolerability on tissue level in rat.     

Aqueous preparation and evaluation of albumin-chitosan microspheres containing indomethacin

Controlled-release egg albumin-chitosan microspheres containing indomethacin as a model drug were successfully prepared by coacervation method. The proposed method can offer a simple method for microsphere preparation in an aqueous system with the elimination of the use of organic solvents that are usually needed in conventional techniques of microencapsulation. The interaction between negatively charged egg albumin molecules in phosphate buffer, pH 7.2, or sodium hydroxide solution and positively charged chitosan molecules dissolved in diluted acetic acid to form an insoluble precipitate was the principle for the formation of the microspheres. The effects of many process variables, such as amount of formaldehyde as a cross-linking agent, stirring time, final pH of encapsulation medium, initial drug loading, and albumin concentration or albumin-to-chitosan weight ratio, on the properties of the prepared microspheres were investigated. Incorporation efficiencies of the microspheres to the drug were high in most cases and ranged between 63.3 ± 3.6% and 92.39 ± 3.2%, while particle sizes were 435.2 ± 12.6 up to 693.9 ± 34.6 µm for the different tested batches. On the other hand, the values of angles of repose and compressibility indices were in the range of 23.5 ± 0.4 to 32.0 ± 0.7 degrees and 11.1 ± 0.7% to 23.6 ± 0.7% respectively, which indicate overall good free flowing nature of the microspheres of all batches. The maximum required amount of the cross-linking agent was determined to avoid excessive unnecessary chemicals. It was also noticed that excessive time of stirring and excessive initial drug loading are not recommended as it may lead to microspheres of low properties. The pH of the encapsulation media (pH 3.77 up to pH 4.91) significantly affected the properties of the microspheres. As the pH of the encapsulation media was increased, the incorporation efficiency, particle size, and flowability decreased, along with increase of drug release rate, which could be related to incomplete cross linking of the microspheres matrix. It was also observed that high concentration of albumin solution and accordingly the increase of albumin-to-chitosan weight ratio were accompanied with increases in incorporation efficiency and particle size with improved microsphere flowability and slow indomethacin release. Thus, the proposed microspheres showed the ability to control the release of indomethacin, and their properties were highly affected by many process variables that could be controlled to obtain an optimized system.     

In Vitro Release of Disopyramide from Cellulose Acetate Butyrate Microspheres

Disopyramide was microencapsulated with cellulose acetate butyrate (CAB) using an emulsion-solvent evaporation process. Drug dissolution from microcapsules was studied in both simulated gastric (SGF) and intestinal fluids (SIF) under sink conditions using the USP paddle method. There was no significant difference between drug release into SIF and SGF. As the CAB to drug ratio decreased from 3:1 to 2:1 at constant polymer mass, the drug release rate increased and the T50Y0 decreased from 2.3 hr to 0.3 hr for 303 pm particles. Dissolution T50% increased from 0.4 hr to 2 hr when the mean microcapsule size was increased from 153 to 428 μm (26% drug loading). The addition of acetone to the external phase during preparation shifted the size distribution toward larger particles, but resulted in a higher drug dissolution rate for a given particle size range. A shift to smaller particles was obtained upon increasing the concentration of surfactant. The dissolution profiles were described by the Higuchi and Baker-Lonsdale equations for drug release from spherical matrices up to 90% of the drug release.     

Preparation of amifostine polylactide-co-glycolide microspheres and its irradiation protective to mouse through oral administration

The objectives of this study were to prepare the amifostine polylactide-co-glycolide (PLGA) microsphere and investigate its irradiation protective to mouse through oral administration. Amifostine-loaded PLGA microsphere was formulated using a modified double emulsion-solvent evaporation technique. The microsphere particle was spherical with a mean diameter of 2.8?±?0.1 µm. Release data of amifostine PLGA microsphere was tested in phosphate-buffered saline at 37°C using a dialysis method and its release profiles was biphasic, showing a relatively large burst effect (50%) over the first 6?h, followed by a slower release phase, which sustained with 80% amifostine released in 48?h and almost 100% release till 6 days (144?h). A diffusion-controlled release model (Higuchi equation, R²?=?0.9725) was obtained for amifostine releasing from PLGA microsphere. The radiation experiment was performed by applied cobalt-60 γ-radiation source. One hour before γ-radiation exposure, the mouse was orally given free amifostine and PLGA microsphere, respectively. The irradiation effects, such as blood cell concentration, superoxidase dismutase (SOD) activity and malondialdehyde (MDA) level were monitored. The results indicated that amifostine PLGA microsphere was more irradiation protective to mouse than that of free amifostine under the same oral administration route.     

Enhanced percutaneous permeability of nicardipine hydrochloride by carvone across the rat abdominal skin

The purpose of this study was to investigate the effect of carvone on the permeation of nicardipine hydrochloride across the excised rat abdominal epidermis from 2% w/w hydroxypropyl cellulose (HPC) gel system. The HPC gel formulations containing nicardipine hydrochloride (1% w/w) and selected concentrations of carvone (0 to 12% w/w) were prepared, and evaluated for drug content, stability of the drug, and in vitro permeation of the drug through excised rat abdominal epidermis. The HPC gel was found to contain 99.98 to 101.6% of nicardipine hydrochloride, and the drug was found to be stable in the HPC gels. The permeation flux of nicardipine hydrochloride across rat epidermis was increased markedly by the addition of carvone to the HPC gels. A maximum flux of nicardipine hydrochloride (243.95.70 ± 1.90 µg/cm²/hr) was observed with an enhancement ratio of 7.9 when carvone was incorporated at a concentration of 12% w/w in the HPC reservoir system. The differential scanning calorimetry and Fourier transform-infrared data indicated that carvone increased the permeability of nicardipine hydrochloride across the rat epidermis by partial extraction of lipids in the stratum corneum. The results suggest that carvone may be useful for enhancing the skin permeability of nicardipine hydrochloride from transdermal therapeutic system containing HPC gel as a reservoir.     

In Vitro Release of Disopyramide from Cellulose Acetate Butyrate Microspheres

Abstract

Disopyramide was microencapsulated with cellulose acetate butyrate (CAB) using an emulsion-solvent evaporation process. Drug dissolution from microcapsules was studied in both simulated gastric (SGF) and intestinal fluids (SIF) under sink conditions using the USP paddle method. There was no significant difference between drug release into SIF and SGF. As the CAB to drug ratio decreased from 3:1 to 2:1 at constant polymer mass, the drug release rate increased and the T50Y0 decreased from 2.3 hr to 0.3 hr for 303 pm particles. Dissolution T50% increased from 0.4 hr to 2 hr when the mean microcapsule size was increased from 153 to 428 μm (26% drug loading). The addition of acetone to the external phase during preparation shifted the size distribution toward larger particles, but resulted in a higher drug dissolution rate for a given particle size range. A shift to smaller particles was obtained upon increasing the concentration of surfactant. The dissolution profiles were described by the Higuchi and Baker-Lonsdale equations for drug release from spherical matrices up to 90% of the drug release.     

Differential Thermal Analysis of Polyethylene Glycol and Glycerol Monostearate Suppository Bases Containing Theophylline

Water soluble polyethylene glycol 4000 (PEG4) suppositories were prepared containing 4% (w/w) theophylline. Various concentrations of polyethylene glycol 1000 (PEG1) and glycerol monostearate (GMS) were also added. Differential thermal analysis (DTA) of the PEG4 and PEG1 combination suppositories showed no melting endotherm for theophylline. But when theophylline concentration in the base was 12% (w/w) and above, sharp endothermic peak of theophylline was obtained. In contrast, when GMS was added as a base material above 50% (w/w) with PEG4, the melting endotherm of theophylline (4%, w/w) appeared at 273-274°C. The melting endotherm of the suppository bases increased up to 2 to 4°C due to storage at 4°C for six months.     

Biodegradable microparticulates of beta-estradiol: preparation and in vitro characterization

Beta-estradiol has been recommended for the long-term therapy of osteoporosis and its oral formulations are subjected to intensive first pass metabolism. The present investigation was aimed at preparing and characterizing biodegradable microparticles of beta-estradiol with polymers such as PLA, PLGA 85/15, PLGA 75/25, and their mixtures. The microparticles were prepared by solvent evaporation method using methylene chloride as a solvent and polyvinyl alcohol as a surfactant. The drug-polymer ratios were 1:3, 1:5, and 1:7. The prepared microparticles (twelve formulations) were tested for encapsulation efficiency and in vitro drug release in 50% methyl alcohol/phosphate buffer pH 7.4. The results showed that the encapsulation efficiency varied from 81 to 100% and the formulation fabricated from PLGA 85/15 (1:3) showed less burst and consistent long time release. This formulation when further characterized displayed irregular spherical shape with an average particle size of 72 µm. The crystallinity of the drug was reduced when investigated using X-ray diffractometry. No chemical interaction between the drug and the polymer was observed as evidenced by FT-IR analysis. The results indicated that beta-estradiol biodegradable microparticles with PLGA 85/15 (1:3) could be a suitable approach for long term therapy of osteoporosis.     

Apparent solubility of drugs in partially crystalline systems

Using several griseofulvin samples, representing different solid-state structures, the solubility behavior of drugs in both one-state (totally ordered, semiordered or disordered) and two-state systems was studied. Special attention was directed towards the surface structure of the particles. The partially crystalline samples were obtained by milling the raw material (crystalline standard) or storing the quenched sample (amorphous standard). The solid-state structure of the materials was studied using x-ray diffraction (XRD), differential scanning calorimetry (DSC), isothermal microcalorimetry (IMC), and scanning electron microscopy (SEM). The saturation concentration of the materials was studied in suspensions containing different dispersion concentrations of drug after centrifugation and filtration, using spectrophotometry. In all cases these dispersion concentrations exceeded the solubility of the drug. The solubilities were plotted vs. dispersion concentrations for each sample. Several solubility plateaus were found. The lowest and highest solubility plateaus corresponded to the solubilities of crystalline and amorphous standards. These plateaus were reached at 8 and 44 µg/mL for crystalline and amorphous griseofulvin standards, respectively. An intermediate plateau served as an indication of the existence of a totally semiordered structure. This was reached at 19 µg/mL for griseofulvin. Any deviation from these plateaus was suggested to be indicative of the existence of heterogeneity on the surface structure, which in most cases could be described as a two state system. In such cases, the apparent solubility was a function of dispersion concentration, until at very high dispersion concentrations (4000-20,000 µg/mL) the saturation concentration of the totally disordered (44 µg/mL) or semiordered (19 µg/mL) one-state phase was reached. No reduction in these values was observed during storage for 50 days. It is thus concluded that, in partially crystalline systems, the saturation concentration is an interfacial phenomenon, which depends on the amount, reactivity, and solid-state structure of the exposed solid surfaces in equilibrium with the solution. A simplified solubility model is proposed to qualitatively describe the relationship between established apparent solubilities (saturation concentrations) and different combinations of solid-state structures.     

Matrices of water-soluble drug using natural polymer and direct compression method

The objective of this research was to find an optimum Carrageenan matrix formulation with the desired drug release and physical properties prepared by direct compression. In order to achieve this, matrices containing 10% theophylline, different Carrageenan level, and different excipient were prepared and evaluated. A selected matrix containing 40% Carrageenan and lactose fast flo was tested for dissolution in three different dissolution media (distilled water, 0.1 N HCl, and phosphate buffer pH 7.4). The same formulation was also tested for dissolution at 50 rpm, 100 rpm, and 150 rpm, and using different dissolution apparatus (Apparatus 1 and 2).

All matrices showed a decrease in drug release as the polymer level was increased. Only Avicel PH-101 did not show any significant difference between matrices prepared with 30% and 40% polymer. At 10% polymer level, it appears that the type of diluent used controls the drug release. However, at high polymer level, 30% and 40%, it appears that the polymer level controls the drug release. Phosphate buffer pH 7.4 and 0.1 N HCl increase drug release and appear to increase Carrageenan solubility and decrease gel formation. Also, as the rotational speed of the apparatus was increased, the integrity of the gel layer was decreased, and the release of drug was increased. The drug release from Carrageenan matrices appears to follow the diffusion model for inert matrix up to 90 min. After 90 min, the drug release follows a zero-order model.

This study demonstrated that matrices using Carrageenan can be successfully prepared by direct compression.     

Characterization of poly(ethylene oxide) as a drug carrier in hot-melt extrusion

Poly(ethylene oxide) (PEO) as a drug carrier in hot-melt extrusion was studied by using a model drug, nifedipine, in a twin-screw extruder. Binary mixtures of PEO and nifedipine have been shown to be amenable to hot-melting at a temperature as low as 70°C, well below nifedipine's melting point (172°C). Hot-stage microscopy provided visual evidence that nifedipine can form a miscible dispersion with PEO at 120°C. Complete loss of nifedipine crystallinity when extrudated at and above 120°C with a drug loading of 20% (w/w) was further confirmed by differential scanning calorimetry (DSC) and X-ray diffraction. Cross-sectional imaging of the extrudates using scanning electron microscopy indicated homogeneous drug distribution inside PEO when the processing temperature was above 120°C. Raman spectroscopy confirmed drug-PEO interactions at a molecular level. Cryo-milled extrudates showed significant improvement in dissolution rate compared to either pure nifedipine or the physical mixture of PEO and nifedipine. A state of supersaturation was achieved after 10-minute release in pH 6.8 phosphate buffer. Finally, stability study demonstrated that the solid dispersion system is chemically stable for at least 3 months under the conditions of both 25°C/60% RH and 40°C/75% RH. Overall, PEO appears to be a promising aid/carrier to solublize poorly soluble drugs through the formation of solid dispersion via hot-melt extrusion, thereby improving dissolution and absorption.     

Preparation of amifostine polylactide-co-glycolide microspheres and its irradiation protective to mouse through oral administration

The objectives of this study were to prepare the amifostine polylactide-co-glycolide (PLGA) microsphere and investigate its irradiation protective to mouse through oral administration. Amifostine-loaded PLGA microsphere was formulated using a modified double emulsion-solvent evaporation technique. The microsphere particle was spherical with a mean diameter of 2.8 ± 0.1 μm. Release data of amifostine PLGA microsphere was tested in phosphate-buffered saline at 37°C using a dialysis method and its release profiles was biphasic, showing a relatively large burst effect (50%) over the first 6 h, followed by a slower release phase, which sustained with 80% amifostine released in 48 h and almost 100% release till 6 days (144 h). A diffusion-controlled release model (Higuchi equation, R2 = 0.9725) was obtained for amifostine releasing from PLGA microsphere. The radiation experiment was performed by applied cobalt-60 γ-radiation source. One hour before γ-radiation exposure, the mouse was orally given free amifostine and PLGA microsphere, respectively. The irradiation effects, such as blood cell concentration, superoxidase dismutase (SOD) activity and malondialdehyde (MDA) level were monitored. The results indicated that amifostine PLGA microsphere was more irradiation protective to mouse than that of free amifostine under the same oral administration route.     

Enhanced efficacy of clindamycin hydrochloride encapsulated in PLA/PLGA based nanoparticle system for oral delivery

Clindamycin hydrochloride (CLH) is a clinically important oral antibiotic with wide spectrum of antimicrobial activity that includes gram‐positive aerobes (staphylococci, streptococci etc.), most anaerobic bacteria, Chlamydia and certain protozoa. The current study was focused to develop a stabilised clindamycin encapsulated poly lactic acid (PLA)/poly (D,L‐lactide‐co‐glycolide) (PLGA) nano‐formulation with better drug bioavailability at molecular level. Various nanoparticle (NPs) formulations of PLA and PLGA loaded with CLH were prepared by solvent evaporation method varying drug: polymer concentration (1:20, 1:10 and 1:5) and characterised (size, encapsulation efficiency, drug loading, scanning electron microscope, differential scanning calorimetry [DSC] and Fourier transform infrared [FTIR] studies). The ratio 1:10 was found to be optimal for a monodispersed and stable nano formulation for both the polymers. NP formulations demonstrated a significant controlled release profile extended up to 144 h (both CLH‐PLA and CLH‐PLGA). The thermal behaviour (DSC) studies confirmed the molecular dispersion of the drug within the system. The FTIR studies revealed the intactness as well as unaltered structure of drug. The CLH‐PLA NPs showed enhanced antimicrobial activity against two pathogenic bacteria Streptococcus faecalis and Bacillus cereus. The results notably suggest that encapsulation of CLH into PLA/PLGA significantly increases the bioavailability of the drug and due to this enhanced drug activity; it can be widely applied for number of therapies.Inspec keywords: drug delivery systems, biomedical materials, antibacterial activity, nanoparticles, nanomedicine, microorganisms, polymers, nanofabrication, differential scanning calorimetry, encapsulation, drugs, scanning electron microscopy, Fourier transform infrared spectraOther keywords: Streptococcus faecalis, Bacillus cereus, DSC, stable nanoformulation, monodispersed nanoformulation, pathogenic bacteria, FTIR spectra, molecular dispersion, thermal behaviour, controlled release profile, Fourier transform infrared spectra, differential scanning calorimetry, scanning electron microscopy, drug loading, encapsulation efficiency, polymer concentration, solvent evaporation method, molecular level, drug bioavailability, stabilised clindamycin encapsulated poly lactic acid‐poly (D,L‐lactide‐co‐glycolide) nanoformulation, protozoa, Chlamydia, anaerobic bacteria, gram‐positive aerobes, antimicrobial activity, oral antibiotics, oral delivery, PLA‐PLGA based nanoparticle system, clindamycin hydrochloride     

Development of a novel soft hydrogel for the transdermal delivery of testosterone

A soft hydrogel formulation for the transdermal delivery of testosterone (TS) was developed, and the effect of various skin-permeation enhancers was studied in vitro and in vivo. Testosterone was incorporated into a polyvinyl alcohol (PVA)-based soft hydrogel with polyisobutylene (PIB) and various skin-permeation enhancers (dodecylamine, HPE101, oleic acid, or lauric acid). In vitro rat-skin permeation of TS from the soft hydrogel was investigated using Keshary-Chien diffusion cells for 24 hr at 37°C. In vivo plasma-concentration profiles of TS after applying the soft hydrogel on the dorsal skin of rat were determined using a commercial radioimmunoassay kit. The formulated soft hydrogel formed a thin film on the skin within 2 to 3 min after application and remained in a dried-film state for at least 24 hr. Addition of PIB into the hydrogel to increase the adhesion resulted in a negligible reduction in the skin-permeation rate of TS. However, rat-skin permeation of TS increased with the addition of permeation enhancers both in vitro and in vivo. Dodecylamine at the concentration of 3% was the most effective among tested. Plasma concentration of TS significantly increased for at least 24 hr with the addition of dodecylamine. These results suggest the feasibility of the development of a soft hydrogel formulation for the transdermal delivery of TS.     

Development of extended release dosage forms using non-uniform drug distribution techniques

Development of an extended release oral dosage form for nifedipine using the non-uniform drug distribution matrix method was conducted. The process conducted in a fluid bed processing unit was optimized by controlling the concentration gradient of nifedipine in the coating solution and the spray rate applied to the non-pareil beads. The concentration of nifedipine in the coating was controlled by instantaneous dilutions of coating solution with polymer dispersion transported from another reservoir into the coating solution at a controlled rate. The USP dissolution method equipped with paddles at 100 rpm in 0.1 N hydrochloric acid solution maintained at 37°C was used for the evaluation of release rate characteristics. Results indicated that (1) an increase in the ethyl cellulose content in the coated beads decreased the nifedipine release rate, (2) incorporation of water-soluble sucrose into the formulation increased the release rate of nifedipine, and (3) adjustment of the spray coating solution and the transport rate of polymer dispersion could achieve a dosage form with a zero-order release rate. Since zero-order release rate and constant plasma concentration were achieved in this study using the non-uniform drug distribution technique, further studies to determine in vivo/in vitro correlation with various non-uniform drug distribution dosage forms will be conducted.