Sustained Release Matrix of Mebeverine Hydrochloride Using Polyacrylate Resin “Eudragit Retard” Kinetic of Drug Release and Evaluation of a Kinetic Model

Abstract

In this study Eudragit RS PM and RL PM were evaluated as carriers for the preparation of prolonged release solid dispersions of mebeverine hydrochloride by solvent and melting methods. The prepared tablets were examined for dissolution at pH 1.2 and 7.4, Eudragit RS PM and RL PM were found satisfactory as potential slow release carriers. The solid dispersion prepared by the solvent method showed a slow release pattern. Drug release appeared to fit both, first order and Higuchi matrix model kinetics. However, on application of the differential rate treatments, the evidence supported the Higuchi matrix model. Effect of temperatures on dissolution rate was studied for thermodynamic consideration.

The drug release was pH-independent until pH 7.4.As the pH increased, the release was significantly reduced due to solubility problem.     

Use of Proteins to Minimize the Physical Aging of EUDRAGIT® Sustained Release Films

ABSTRACT

The objective of this study was to investigate the influence of two proteins, albumin and type B gelatin, on the physical aging of EUDRAGIT® RS 30 D and RL 30 D coated theophylline pellets. The physicomechanical properties of sprayed films, thermal properties of cast films, influence of proteins on the zeta potential and particle size of the dispersion, and the release of proteins from cast films under simulated dissolution conditions were investigated. The release rate of theophylline decreased significantly over time from pellets coated with an acrylic dispersion containing 10% albumin when there was no acidification of the acrylic dispersion; however, when pellets were coated with an acidified EUDRAGIT®/albumin dispersion, the theophylline release rate was stable for dosage forms stored in the absence of humidity. The drug release rate was faster for pellets coated with acrylic dispersions containing 10% gelatin compared to the albumin–containing formulations. When sprayed films were stored at 40°C/75% RH, the water vapor permeability decreased significantly for both EUDRAGIT® films and those containing EUDRAGIT® and albumin; however, there was no significant change in this parameter when 10% gelatin was present. Albumin was released from the acrylic films when the pH of the dissolution media was below the isoelectric point of the protein while no quantitative release of gelatin was observed in pH 1.2 or 7.4 media. The effect of gelatin to prevent the decrease in drug release rate was due to stabilization in water vapor permeability of the film. Acidification of the polymeric dispersion resulted in electrostatic repulsive forces between albumin and the acrylic polymer, which stabilized the drug release rate when the dosage forms were stored in aluminum induction sealed containers at both 40°C/75% RH and 25°C/60% RH.     

The Use of Precirol® to Prepare Sustained Release Tablets of Theophylline and Quinidine Gluconate

Abstract

Tablets were made using theophylline, lactose and Precirol by a granulation technique, resulting in more than 12 hours release. Granulation and hot fusion methods were used to prepare admixtures of quinidine gluconate and Precirol at different ratios of Precirol: drug, 1:9, 3:7 and 1:1. Dissolution studies in 0.1N HCl showed drastic differences in the release of quinidine gluconate from tablets made by the two different methods; granulation method gave a faster release while the hot fusion method gave slower and incomplete release at higher Precirol content. The release rate decreases with higher Precirol content.     

The Preparation and Stability of Fast Release Furosemide – PVP Solid Dispersion

Abstract

Furosemide-PVP solid dispersion systems were prepared by co-evaporation and freeze-drying methods. The X-ray diffraction patterns indicated that furosemide in the coprecipitates was in amorphous form. The dissolution rate of furosemide was markedly increased in these solid dispersion systems. The increase in dissolution was a function of the ratio of drug to PVP used. With 1:7 ratio the best result was obtained. The 49000 mol. wt. PVP yielded the most rapid furosemide dissolution. Dissolution studies have shown that coprecipitate of furosemide-PVP (1:7) is the best combination. Factors contributing to the enhancement of furosemide' dissolution from the dispersion in PVP were discussed. The increase in release rates was attributed to the increased wettability, coacervate formation and the complexation.

The effect of aging on furosemide-PVP solid dispersions has been investigated. After storage, under the different humidities (55%, 70% and 85% RH) coprecipitates showed no change in either dissolution rate or X-ray diffraction patterns.     

Stability and In Vitro Drug Release of Flurbiprofen-Loaded Poly-ε-Caprolactone Nanospheres

The effects of temperature and two different initial pH (2.67 and 7.00) on poly-ε-caprolactone (PεCL) nanospheres loaded with flurbiprofen (FB) (aqueous suspensions) were studied to investigate their influence on the stability and physicochemical characteristics of these drug delivery systems. The drug release behavior was also studied. Release of the associated FB occurred very fast on high dilution in a buffered medium. The stability of the polymeric system depends on the temperature and the initial pH value; it is more degradable with the particles stored at 40°C with an initial pH value of 2.67.     

Influence of a Long Stay of the Heat‐Release Surface in Kerosene on the Critical Heat Flux in Boiling in It under Steady‐State and Step Conditions of Heat Release

Results of experimental investigations of the influence of a long stay of the heatrelease surface in kerosene on the first critical density of the heat flux in boiling under the steadystate and step conditions of heat release are given.     

Temperature/Humidity Sensitivity of Sustained‐Release Formulations Containing Kollidon® SR

The effects of temperature and humidity on tablets containing Kollidon® SR have been evaluated using diphenhydramine HCl as a model drug. Exposure of tablets to ICH accelerated stability condition (40°C/75%RH) in an open dish resulted in rapid increases in tablet hardness, accompanied by step‐wise decreases in dissolution rate. Such a change can be observed as fast as an hour upon exposure. The tablet matrix appears to rapidly absorb atmospheric moisture, as demonstrated by tablet weight gain and moisture adsorption isotherms. Exposure to 25°C/60%RH similarly resulted in increases in tablet hardness, although with minimal impact on dissolution. Potential implications of such rapid moisture uptake during aqueous film‐coating were further evaluated by spraying either water or an Opadry solution in a coating pan. Exposure of Kollidon SR tablets to the aqueous coating process indeed resulted in noticeable changes in both hardness and dissolution. Application of the Opadry solution appears to affect tablet behavior to a lesser degree, compared to water, most likely due to protection via formed barrier film. Attention needs to be paid to the extreme sensitivity of Kollidon SR matrix tablets to temperature and moisture during product development.     

The Effect of 2-Hydroxypropyl-β-cyclodextrin on In Vitro Drug Release of Steroids from Suppository Bases

The effects of 2-hydroxypropyl-β-cyclodextrin (HPCD) on drug solubility and drug release from suppository bases were studied for dexamethasone (DX), dexamethasone acetate (DXA), hydrocortisone (HC), hydrocortisone acetate (HCA), and prednisolone acetate (PNA). It was found that HPCD significantly increased the aqueous solubility of all five steroids, and the increased drug solubility significantly influenced the drug release from the polyethylene glycol (PEG) base but not from the cocoa butter base.     

Preparation and Evaluation of pH‐Dependent Gradient‐Release Pellets for TCM

This paper is designed to investigate a novel sustained release system for Traditional Chinese Medicinal Compound Recipe (TCMCR) by incorporating three kinds of pH‐dependent gradient‐release coated pellets into capsules. In our study, dosage reform was conducted on the TCMCR model drug–Guanxin Suhe Wan (GSW), which is in the traditional form of honey bolus, comprising Styrax, Borneolumsyntheticum, Olbanum, Radix aristolochiae and Lignum santali albi. In this study, the β‐CD inclusion complexes were prepared separately for Styrax, Borneolumsyntheticum and the volatile oil extracted from the mixture of Olbanum, Radix aristolochiae and Lignum santali albi. Pellets were prepared in a centrifugal granulator using the powder layering technique and then divided into 3 equal weight portions and coated with HPMC, HPMCP HP‐55 and Eudragit L100/S100 to obtain gradient release in stomach, duodenum and jejunum or ileum respectively. On this basis, a pH‐dependent sustained‐release pellets system, “Guanxin Suhe Sustained‐release Capsules”(GSSC), was prepared by mixing the above three kinds of coated pellets at the weight ratio of 1:1:1. Pharmacokinetic (PK) studies between GSW and GSSC were made on male volunteers and isolated guinea pig hearts by plasma drug concentration method and serum pharmacology method respectively. In plasma drug concentration method, T_max was 0.42 h and 1.08 h for GSW and GSSC respectively, while in the serum pharmacology method, T_max was 0.56 h and 0.52 h respectively. The relative bioavailability of GSSC to GSW was 95.62% and 121.82% separately in the above two methods, indicating a similarity between the two methods in predicting the PK behavior of GSSC.     

Evaluation of the Tablet Core Factors Influencing the Release Kinetics and the Loadability of Push–Pull Osmotic Systems

Push–pull osmotic systems have been developed to deliver poorly soluble drugs in a modified-release fashion. The aim of this study was to investigate the influence of the tablet core factors on the drug release kinetics and loadability. The release kinetics was efficiently modulated by varying either the proportion of osmotic agent or the drug layer polymer grade as an alternative to change the membrane characteristics. High osmotic agent proportions and viscous-grade polymers were recommended to formulate high drug loads up to 20%?without losing both the release completeness and the zero-order drug release kinetics.     

Evaluation of pH-Sensitivity and Drug Release Characteristics of (Polyacrylamide-Grafted-Xanthan)–Carboxymethyl Cellulose-Based pH-Sensitive Interpenetrating Network Hydrogel Beads

Novel pH-sensitive interpenetrating network hydrogel beads of polyacrylamide-grafted-xanthan (PAAm-g-XG) and sodium carboxymethyl cellulose (NaCMC) loaded with ketoprofen were prepared and evaluated for pH sensitivity and drug release characteristics. The pH-sensitive PAAm-g-XG copolymer was synthesized by free radical polymerization under the nitrogen atmosphere followed by alkaline hydrolysis. The grafting and alkaline hydrolysis reactions were confirmed by Fourier transform infrared spectroscopy. Differential scanning calorimetry and X-ray diffraction studies were carried out to know the crystalline nature of encapsulated drug. Scanning electron microscopic study revealed that the interpenetrating polymer network (IPN) beads possess porous matrix structure in alkaline pH whereas nonporous matrix structure was observed in acidic pH. The swelling of the beads and drug release was significantly increased when pH of the medium was changed from acidic to alkaline. The results of pulsatile swelling study indicated that the IPN beads changed their swelling behavior when pH of the external medium was altered. As pH of the medium was changed from 1.2 to 7.4, a considerable increase in swelling was observed for all the beads. However, swelling process was slower than the deswelling. At higher pH values, the carboxyl functional groups of hydrogels undergo ionization and the osmotic pressure inside the beads increases resulting in higher swelling. Drug release followed case II transport mechanism in acidic medium whereas anomalous/non-Fickian transport mechanism was observed in alkaline medium.     

Eudragit NE40–Drug Mixed Coating System for Controlling Drug Release of Core Pellets

This study was aimed at developing a controlled-release coating system around core pellets with aqueous dispersion, along with some water channeling agents. Core pellets of diltiazem were prepared using the extrusion-spheronization technique and subsequently coated with aqueous dispersion of Eudragit NE40 alone, or drug–polymer mixtures using bottom-spray fluidized bed coater. The lag time in drug release profiles increased as the coating levels of Eudragit NE40 were increased, whereas no lag time was observed in core pellets coated with drug–polymer mixtures. Mixed coating at the 7% level exhibited comparatively better release profiles and provided desirable release rates during the 12-hour testing interval. Diltiazem HCl release from mixed coating was fairly independent of pH and drug loading. Curing of coated pellets was found to be an essential step for stable drug release profiles. The selection of core size range had remarkable effect on drug release rate and was considerably reduced by using greater core size.     

Formulation and Characterization of a Compacted Multiparticulate System for Modified Release of Water-Soluble Drugs—Part II Theophylline and Cimetidine

The purpose was to investigate the effectiveness of an ethylcellulose (EC) bead matrix and different film-coating polymers in delaying drug release from compacted multiparticulate systems. Formulations containing theophylline or cimetidine granulated with Eudragit^® RS 30D were developed and beads were produced by extrusion–spheronization. Drug beads were coated using 15% wt/wt Surelease^® or Eudragit^® NE 30D and were evaluated for true density, particle size, and sphericity. Lipid-based placebo beads and drug beads were blended together and compacted on an instrumented Stokes B2 rotary tablet press. Although placebo beads were significantly less spherical, their true density of 1.21 g/cm³ and size of 855 μm were quite close to Surelease^®-coated drug beads. Curing improved the crushing strength and friability values for theophylline tablets containing Surelease^®-coated beads; 5.7 ± 1.0 kP and 0.26 ± 0.07%, respectively. Dissolution profiles showed that the EC matrix only provided 3 h of drug release. Although tablets containing Surelease^®-coated theophylline beads released drug fastest overall (t_44.2% = 8 h), profiles showed that coating damage was still minimal. Size and density differences indicated a minimal segregation potential during tableting for blends containing Surelease^®-coated drug beads. Although modified release profiles >8 h were achievable in tablets for both drugs using either coating polymer, Surelease^®-coated theophylline beads released drug fastest overall. This is likely because of the increased solubility of theophylline and the intrinsic properties of the Surelease^® films. Furthermore, the lipid-based placebos served as effective cushioning agents by protecting coating integrity of drug beads under a number of different conditions while tableting.     

An In-Vivo Bioequivalence Study of a New Nifedipine Extended Release Dosage Form, ‘Opticaps’

Abstract

A single dose fasting cross over study was carried out in human volunteers comparing Nifedipin-Mepha 20 retard Opticaps® capsules to Adalat® retard tablets. Opticaps® is a newly developed release formulation containing an active ingredient in a “semi solid” matrix within a hard gelatin capsule. Pharmacokinetic variables were calculated from the nifedipine plasma concentration data and evaluated statistically. The results showed Nifedipin-Mepha 20 retard Opticaps® capsules to be bioequivalent to Adalat® retard in all respect. Primary parameters were calculated by fitting the mean plasma concentration data for a two compartment open first order absorption model with lagtime using the computer PCNONLIN program. The parameter's obtained were used to simulate blood levels for a multiple dose administration of 20 mg nifedipine every 12 hours.     

Light or Heat? The Origin of Cargo Release from Nanoimpeller Particles Containing Upconversion Nanocrystals under IR Irradiation

Nanoimpellers are mesoporous silica nanoparticles that contain azobenzene derivatives bonded inside the pores and rely on the continuous photoisomerization of multiple azobenzenes to release cargo under near UV irradiation. A recent study employs upconversion nanocrystal embedded particles to replace UV light with IR light to stimulate nanoimpellers. However, the photothermal effect of IR irradiation and its likely contribution to the observed release behavior are not examined. It is found that, in the absence of upconversion nanocrystals, the azobenzene co‐condensed silica particles still respond to 980 nm illumination, which increases the nanoparticle temperature by 25 °C in 15 min, experimentally measured by an encapsulated nanothermometer. After suppressing the heating, the IR irradiation does not initiate the release, indicating that optical heating, not upconverted light, is responsible for the triggered cargo release. The results are explained by numerical analyses.     

Polyelectrolyte–Drug Complexes of Lambda Carrageenan and Basic Drugs: Relevance of Particle Size and Moisture Content on Compaction and Drug Release Behavior

The interaction between polyelectrolytes (PE) and oppositely charged drugs (D) results in complexes (PE–D) that can be exploited in controlled release drug delivery systems. The aim of this work is to better understand the relevance of some preparative parameters such as moisture content and particle size on the performance of two PE–D complexes to be used in oral controlled release tablets. PE–D complexes containing diltiazem HCL (DTZ) or metoprolol tartrate (MTP) and lambda carrageenan were obtained at two particle size levels (<45 μm and 75–105 μm), maintained at different values of relative humidity (RH) (11, 52, 75, and 93%), and compressed. The tablets were characterized for porosity, hardness, moisture content, and contact angle. Drug release profiles were fitted to the Weibull equation, and a factorial design was used to understand the relevance of particle size and RH% on release rate as a function of medium pH. The results indicated that the hydrophobic character of the complex between PE and D depended on the drug and in the present case was more pronounced for DTZ than for MTP. This in turn affected the possible release mechanism and therefore the importance of particle size and RH%.     

Release of Theophylline from Ethyl Cellulose Mecrocapsues Alone and in Conjuction with Fat Embedded (Precirol®) Granules and Hydroxypropyl Methycellulose

Abstract

Microcapsules of theophylline with ethyl cellulose were prepared by coacervation technique using cabosil® (silicon dioxide) as separant. Tablets were prepared from microcapsules, microcapsules + theophylline fat embedded granules, and microcapsules and hydroxypropyl methylcellulose 4000 (HPMC). Release was studied in vitro by the rotating basket method. Prolonged release of theophylline was observed from microcapsules with no drug dumping. The release from microcapsules was of first-order whereas that from all the tablet formulation was diffusion controlled according to the Higuchi model. Good correlation was found between release rate and core:wall ratio for all the systems. Decrease in hardness of tablets made from microcapsules alone decreased the release rate, indicating damage of microcapsules during compression. The tablets compressed from fat embedded granules, microcapsules with fat embedded granules, and microcapsules with HPMC gave a desired release for a 74 hour sustained release preparation.     

Investigation of the Dynamics of Evaporation of Condensed Bodies on the Basis of the Law of Spectral‐Radiation Intensity of Particles

The fundamentals of radiation theory and the mechanism of evaporation of condensed bodies are presented. The distribution functions of particles of a body by energies and by the intensity of their transition from one energy level to another in the process of evaporation have been obtained based on the law of spectralradiation intensity of the body particles. The temperature dependence of the resulting vapor flow on the outer surface of a massive condensed body and a thin layer in equilibrium and nonequilibrium states, which, in the limit, transforms to the known Hertz–Knudsen formula, has been found.