Release Rate of Drugs from Ethyl Cellulose Coated Granules Containing Caffeine and Salicylic Acid

Abstract

Fluidized bed coating with ethyl cellulose., polyethylene glycol mixtures has been utilized for prolongation of drug release from granules containing salicylic acid and caffeine as model drugs. Drug release from the coated granules followed first order kinetics.

Particle size of the active material, granule composition and extraction medium pH did not affect the rate and kinetics of drug release. Increase in coat thickness decreased the release rate whereas elevation of the ratio of polyethylene glycol to ethyl cellulose enhanced the release rate to a degree related to the polyethylene glycol concentration. The permeability constants of salicylic acid and caffeine for the ethyl cellulose-polyethylene glycol coatings were of a similar order to those measured previously using solutions of the drugs with planar barrier films.     

Valuation of a Cellulose Acetate (CA) latex as coating material for controlled release products

Abstract

Cellulose acetate (CA) latex plasticized with 150% triacetin (TA) and 120% triethylcitrate (TEC), based on polymer weight, provided dense and homogeneous films when deposited onto propranolol HCl tablets using conventional fluid bed technology. Film permeability to the drug was low and flux/permeability enhancers were added to the CA structure during its manufacture. Films containing 40% surcrose and 10% PEG 8000 were found to provide the best release characteristics in terms of small lagtime (1 hour) and drug release profile (over 12 hours). When sucrose was added to TA or TEC plasticized fimls, a macroporous membrane was created during exposure to the dissolution fluid due to sucrose release from the film. These observations are consistent with the controlled porosity walls previously described for CA films deposited from organic solvents. It was postulated that drug mass transport occurs mainly within the porous CA structure and the mechanism responsible for its is a combination of molecular diffusion/osmotic pressure via water transport into the porous cellulose acetate membrane. Plasticizer loss during drying had also been demonstrated and related to the change in release profile seen with drying time.     

Effect of Formulation Variables on Dissolution Profile of Diclofenac Sodium from Ethyl- and Hydroxypropylmethyl Cellulose Tablets

Abstract

The effects of formulation variables on the release profile of diclofenac sodium from ethyl cellulose (EC) and hydroxypropylmethyl cellulose (HPMC) matrix tablets were investigated. With increase in viscosity of ethyl cellulose used in nonaqueous granulation, a decrease in drug release from the tablets was observed, while the percentage of fines articles passed through 60 mesh) in the granulation had a significant effect on the dissolution profile. Granules containing 15% fines exhibited slow release of the drug in comparison to those containing 30% fines with EC matrices. An analysis of kinetics of drug release from hydrophobic EC matrix showed Fickian diffusion regulated dissolution. Drug release from HPMC tablets followed an apparent zero-order kinetics.     

Release Studies of Neomycin From Different Ophthalmic Ointment Bases

Abstract

The release of neomycin from ten different ointment bases for possible ophthalmic use was monitored using a microbiological agar plate method. An obvious difference in antibiotic release from the various bases was observed. The effect of benzalkonium chloride, as preservative, on the antimicrobial activity of neomycin was studied and found to be dependent on the base used. From the whole set of results for release and stability, after shelf storage for 24 months, Bases No. 9 (containing castor oil, hydrogenated castor oil and cetyl alcohol) and No. 10 (containing liquid paraffin, hard paraffin, glyceryl monostearate and wool fat) were found to be the bases of choice for neomycin ophthalmic ointments.     

The MiniWiD-Coater. III. Effect of Application Temperature on the Dissolution Profile of Sustained-Release Theophylline Pellets Coated with Eudragit Rs 30 D

Abstract

Theophylline pellets were coated with Eudragit RS 30 D in a miniature fluid-bed pan coater called MiniWiD developed recently. The dispersions were plasticized with varying amounts of triethyl citrate (TEC), dibutyl phthalate (DBP), and polyethylene glycol 6000 (PEG) and applied at different temperatures ranging from 25 to 45 °C. Theophylline release was tested by dissolution using the USP Apparatus 2 (paddle) in 0.1 N hydrochloric acid under sink conditions over 6 hours.

At a coating level of 4 % (0.7 mg/cm²) sustained-release profiles were obtained from dispersions plasticized with TEC or DBP. By reducing the amount of plasticizer from 20 to 10%, films with higher permeabilities were obtained. This effect was compensated by tempering the pellets at 50 deg;C for 24 hours. The coating temperature had little effect on the dissolution profiles of TEC-plasticized films and no effect on films with DBP.

Coatings plasticized with 20% PEG were applied at temperatures ranging from 25 to 45 °C. These films required a coating level of about 18 % (3.3 mg/cm²) to provide comparable sustained-release properties. In contrast to DBP and TEC, a strong influence of the coating temperature on the release rates was observed in which higher temperatures led to slower release rates. This behavior can be explained by the minimum film-forming temperature (MFT). Since PEG does not lower the MFT of Eudragit RS 30 D, the application of these films below the MFT of 45 °C is associated with a lower degree of film formation.     

Evaluation of hydroxypropyl methylcellulose phthalate 50 as film forming polymer from aqueous dispersion systems

Abstract

Hydroxypropyl methylcelluose phthalate 50 (HPMCP 50) was evaluated as a film forming polymer from aqueous dispersion systems. The influence of plasticizer type and level on the elasticity of HPMCP 50 free films prepared by the casting method was studied by measuring Young's modulus using an Instron Material Testing System. The release of a water soluble drug in various dissolution media from pellets coated with HPMCP 50 with 30% plasticizer containing various levels of hydroxypropyl cellulose (HPC) or hydroxypropyl methylcellulose (HPMC) was also studied. The influence of coating level on drug release from pellets was also investigated. Results showed that HPMCP 50 alone without a plasticizer does not form a film. However, when a plasticizer was added HPMCP 50 did form a film. Also, as the concentration of the plasticizer triethyl citrate was increased the elasticity of HPMCP 50 films was increased. Similar results were obtained with the plasticizer diethyl phthalate. For pellets a high coating level was required to achieve adequate protection in 0.06 N HCl. Drug release from coated pellets was found to be dependent upon the type and the level of the water soluble polymer incorporated with HPMCP 50. Drug release was increased as the percentage of HPC was increased. Higher release rates were obtained with HPMC compared to HPC. Coating level significantly influenced drug release in 0.06 N HCl; however, less of an effect was observed at pH 5.5.     

Leaching of water-soluble plasticizers from polymeric films prepared from aqueous colloidal polymer dispersions

Abstract

The leaching of water-soluble plasticizers from polymeric films prepared by casting and drying of plasticized colloidal polymer dispersions was investigated with respect to the type and concentration of plasticizer (triethyl citrate or triacetin), film thickness, type of colloidal polymer dispersions (acrylic: Eudragit RS30D, RL30D, or L30D; cellulosic: Aquacoat), Eudragit RS30D/RL30D ratio, and method of film preparation (solvent- or pseudolatex-casting). The leaching increased with increasing level of plasticizer as indicated by an increase in the release rate constant while the release rate constant was independent of the film thickness. The leaching was more rapid from Aquacoat films than from Eudragit RS30D films at all plasticizer concentrations. Increasing the amount of the more hydrophilic polymer dispersion, Eudragit RL30D, in mixed Eudragit RS/RL films increased the rate of leaching. The incorporation of propranolol HCl into the polymeric films significantly increased the leaching rate constant when compared to drug-free films. The leaching from pseudolatex-cast films was faster when compared to the leaching from solvent-cast films due to the denser structure of the solvent-cast films.     

An Investigation Into the Formation of Plasticizer Channels in Plasticized Polymer Films

Abstract

The effects of plasticizer, polyethylene glycol (PEG-600), on the sucrose permeability, void volume and morphology of cellulose acetate free films were investigated. The sucrose permeability of cellulose acetate free films was found to decrease with increasing PEG-600 to a minimum and increase dramatically when they were plasticized by over 30% (w/w) PEG-600. The decrease in sucrose permeability of cellulose acetate free films with increasing plasticizer at low plasticizer concentrations could be interpreted by the antiplasticization effect, and the dramatic increase of sucrose permeability of cellulose acetate free films at high plasticizer level could be explained by the formation of plasticizer channels. The void volume of cellulose acetate free films were calculated by determining the water content in the films, and the effect of PEG-600 on the morphology of cellulose acetate free films was studied by using the scanning electron microscopy (SEM). Both the void volume and SEM studies supported the assumption that the plasticizer channels would be formed in the polymer films which contain high concentration of plasticizer.     

The Influence of Different Plasticizers and Polymers on the Mechanical and Thermal Properties,Porosity and Drug Permeability of Free Shellac Films

ABSTRACT

The effect of triethyl citrate (TEC) and different molecular weights and concentrations of polyethylene glycol (PEG), in addition to the effect of different water-soluble polymers and dispersions at different levels, hydroxypropyl methylcellulose (HPMC), methylcellulose (MC), carbomer 940, polyvinyl alcohol (PVA), ethyl cellulose (EC), on the mechanical and thermal properties, drug permeability, and porosity of free shellac films were investigated. Shellac films were cast from aqueous solutions, and their mechanical properties were studied by tensile test. Thermal analyses were performed using differential scanning calorimetry (DSC).

The results showed that the addition of plasticizer caused a decrease in both elastic modulus and glass transition temperature (T_g) and an increase in elongation at break of free shellac films. This effect was related to the concentrations of plasticizers. Different molecular weights of PEGs have different plasticization mechanisms.

Moreover, the incorporation of different amounts of HPMC, MC, or carbomer in free shellac films caused an increase in the flexibility, decrease in T_g, and a marked increase in drug permeability of free shellac films, whereas the addition of PVA caused a decrease in flexibility and drug permeability and an increase in T_g. Addition of EC resulted in a slight decrease of the elasticity and a small decrease in drug permeability. However it does not show a considerable effect on the T_g. In addition, it was found that the drug permeability is directly related to the mechanical properties and T_g of shellac films.     

In Vitro Dissolution Profile of Theophvlline Lorded Ethvl Cellulose Microspheres Preprred by Emulsificrtion Soluent Eurporrtion

Abstract

Theophylline was entrapped in ethyl cellulose microspheres by a water/oil/water emulsification-solvent evaporation method. Aqueous solution of drug was emulsified into a solution of ethyl cellulose in toluene, containing polyisobutylene as protective colloid, followed by emulsification of this primary emulsion into an external aqueous phase to form a water/oil/water emulsion. Microspheres was formed after solvent evaporation and precipitation of ethyl cellulose. In vitro dissolution profile and effect of polyisobutylene on it were studied.     

A Study on the Manufacture and in Vitro Dissolution of Terbutaline Sulfate Microcapsules and their Tablets

Abstract

Microcapsules of terbutaline sulfate with cellulose acetate butyrate and ethylcellulose were prepared using an emulsion-solvent evaporation technique. The in vitro dissolution of terbutaline sulfate was studied using the USP rotating basket method. As the polymer to drug ratio increased, the microcapsule size distribution shifted to the smaller size and the release of terbutaline sulfate decreased. The release of terbutaline sulfate was independent of the dissolution medium pH for both polymers. The release kinetics from the microcapsules was dependent on the polymer type and polymer to drug ratio. The release of terbutaline sulfate from cellulose acetate butyrate and ethylcellulose microcapsules formulated with a 1:1 polymer to drug ratio was complex and could not be differentiated between the square-root of time and first-order release models. However, the square-root of time model was followed by microcapsules formulated with a 2:1 or a 3:1 cellulose acetate butyrate to drug ratio. When the ethylcellulose to drug ratio was increased to 2:1 the square-root of time model was followed. At an ethylcellulose to drug ratio of 3:1 the release kinetics could not be differentiated between the Hixon-Crowell and first-order release models. The T50% from ethylcellulose microcapsules was decreased when the microcapsules were compressed into tablets with the addition of Avicel^R/Emcompress^R (2:1) or Avicel^R.     

Release and permeation studies of propranolol hydrochloride from hydrophilic polymeric matrices

Abstract

In-vitro release of propranolol hydrochloride, from various hydrophilic polymeric bases was studied. These included: methocel®, avicel® CL-611/ methylcellulose, polyvinyl alcohol/gelatin based systems. Several additives, such as, ethyl alcohol, dimethylsulfoxide (DMSO) and polyethylene glycol-400 were included in the formulations for possible enhancement of the drug release. The release studies were carried out using the cellulose membrane and the hairless mouse skin as the diffusion barriers. The general rank order for the drug release through these membranes was observed to be: the methocel® matrix > the avicel® CL-611 matrix > the polyvinyl alcohol/gelatin matrix > and the emulsion base. The additives in the formulations had little or no effect in enhancing the drug release. However, when the hairless mouse skin was soaked in (DMSO) for one hour prior to its use in the diffusion studies, the drug release was found to increase by 40% from the methocel® matrix formulation.

The drug release data were treated with various kinetic principles to assess the relevant parameters, such as the diffusion, partition and permeability coefficients. Using these information, the formulations were screened for their suitability to deliver propranolol hydrochloride via the diadermatic dosage form.     

Medicament Release from Ointment Bases: II. Testosterone: in vitro Release and Effects of Additives on its Release

Abstract

The in vitro release of testosterone from three different ointment bases including, the water washable, the modified Beller and the modified hydrophyllic ointment base, U.S.P. were studied. Among the bases evaluated, the water washable ointment base provided the better release of the drug. In addition, the effects of various additives (3, 5 and 10% urea, 5% ethyl alcohol, 5% DMSO, 3, 5 and 10% PEG-400, and a combination of 5% ethyl alcohol and 5% DMSO) on the release of testosterone from the water washable base were investigated. The additive ingredients at 3 and 5% level had little or no effect on the release of drug when compared to the control water washable base. However, the release was significantly higher from the sane ointment base containing 10% by weight of PEG-400 and 10% by weight of urea respectively. In addition, the values for the release rate constant, the diffusion coefficient, the permeability coefficient and the partition coefficient were calculated to develop the meaningful kinetic parameters to assess the release of this hydrophobic drug from a topical dosage form.     

The MiniWiD-COATER: II. Comparison of acid resistance of enteric-coated bisacodyl pellets coated with different polymers

Abstract

Neutral pellets were loaded with bisacodyl and enteric-coated with hydroxypropyl methylcellulose acetate succinate (HPMCAS), carboxymethyl ethylcellulose (CMEC), cellulose acetate trimellitate (CAT), and poly(ethylacrylate, methacrylic acid) (Eudragit L 30 D) in a miniature fluid-bed pan coater called MiniWiD. Gastric juice resistance was tested by dissolution using USP Apparatus 2 (paddle) in 0.1 N hydrochloric acid under sink conditions over 6 hours. As a measure of enteric coating quality the USP specifications were used meaning that no more than 10 % of the drug should be released within 2 hours.

Organic-solvent based films of HPMCAS, CMEC and CAT at a coating level of 18 to 25 % provided gastroresistance for more than 6 hours. Aqueous suspensions of HPMCAS and CMEC as well as the ammonium salt aqueous solutions of CAT produced films with a short gastroresistance of below 0.6 hours. By doubling the coating level of water-based HPMCSD films the protection was prolonged to 3.4 h.

Enteric coatings were obtained from all aqueous latex dispersions of Eudragit L 30 D at a coating level of 24 %. The alteration of coating temperature between 25 and 45 °C had no significant effect on the release rates, whereas the variation of type and amount of plasticizer led to a different release rate after 2 hours. Best protection was obtained using films plasticized with 20 % of dibutyl phthalate (DBP) allowing a release of only 4 % of the drug in 6 hours although the application temperature was 15 °C below the minimum film-forming temperature (MFT). All coatings dissolved in artificial intestinal fluid within 15 minutes.     

Properties of Aqueous, Plastic Izer-Containing Ethyl Cellulose Dispersions and Prepared Films in Respect to the Production of oral Extended Release Formulations

Plasticized aqueous ethyl cellulose (EC) dispersions (Aquacoat^R ECD-30) are incompatible with concentrated electrolytes but stable with nonelectrolytes. The minimum film formation temperature (MFT) decreases with increasing plasticizer content, from 81°C to about 30°C with 20% dibutyl sebacate (DBS) in the resulting film. The plasticiser has to penetrate completely into the EC particles before film formation to obtain optimal plastification, the lowest film formation temperature and high permeability of the resulting film. This takes more than 5 hours with 20% DBS. Films prepared from plasticized dispersion with short standing times show craters of former plasticizer droplets. With increasing plasticizer content the sticking point of the films decreases. The plasticizer induce a high water absorption of the films: more than 30% with 23-26% DBS or diethyl phthalate (DEP). DBS is hardly released from the films within 5 hours, in contrast to DEP. Thus, the absorbed water is completely swelling water in case of DBS and partially also substitution water in case of DEP. The films squeeze out cetylalcohol (CA) and also sodium lauryl sulfate (NaLS) during storage, this may change the permeability of the films. EC contains a small amount of carboxylic groups which explains the pH dependent release of drugs from pellets coated with aqueous EC dispersions.     

The Effect of Plasticizers on the Properties of Polyvinyl Alcohol Films

Abstract

The effect of water-soluble plasticizers viz propylene glycol (PG), glycerol and polyethylene glycol 600 (PEG) on the morphology and water resistance of polyvinyl alcohol (PVA) films was investigated. Polyvinyl alcohol films were cast from aqueous solutions, and their morphology studied using differential scanning calorimetry (DSC) and scanning electron microscopy (SEM). Water resistance was characterized by the extent of film dissolution and the water uptake capacity of remnant films after immersion of the films in distilled water for 3 days at 37° C. DSC thermograms showed that crystallite formation in the PVA films was affected to different extent by addition of the three plasticizers. The plasticizers not only reduced the degree of crystallinity in the films, but also lowered the crystalline melting temperatures probably by introducing defects into the crystal lattice. This factor, coupled with leaching of the water-soluble plasticizers from the films when immersed in distilled water, lowered the water resistance of the plasticized PVA films. The influence of plasticizers on the properties of PVA films was further related to the degree of compatibility between the plasticizers and PVA.     

Coated pelletized dosage form: Effect of compaction on drug release

Abstract

The goal of this study was to investigate the effect of compaction of a coated pelletized dosage form on drug release. Three sizes of microcrystalline cellulose and hydrous lactose pellets containing 4% chlorpheniramine maleate (CPM) were manufactured using a rotogranulator (Glatt GPCG-1). Pellets having mesh cuts of: 590–840 μm (20/30 mesh); 420–590 μm (30/40 mesh); and 250–420 μm (40/60 mesh) were then coated with an aqueous ethylcellulose pseudolatex dispersion plasticized with 24% dibutyl sebacate (DBS). Percent weight gains were 25, 30 and 35% for the 20/30, 30/40 and 40/60 mesh pellets, respectively. Coated pellets were blended with 39.3% by weight excipients, then mixtures lubricated and compacted using a Korsch PH106 instrumented rotary press set at 5 kN and 20 rpm (0.30 s contact time). Magnesium stearate was used as the lubricant at a 0.7% level. Excipients used were microcrystalline cellulose, spray dried lactose, pregelatinized starch, dicalcium phosphate, spray dried sorbitol, polyethylene glycol 8000 powder and compressible sugar. Results indicated this coating to be suitable for the controlled release of CPM from small pellets (250–840 μm). However, films did not have the appropriate mechanical properties to withstand compaction stress without rupturing, regardless of the pellets particle size and excipients used. After compaction, depending on pellet size, between 65–100% CPM was released after one hour as opposed to 10–30% for the non-compacted material. The controlled release properties of the pellets were therefore lost during the process.     

Valuation of a Cellulose Acetate (CA) latex as coating material for controlled release products

Cellulose acetate (CA) latex plasticized with 150% triacetin (TA) and 120% triethylcitrate (TEC), based on polymer weight, provided dense and homogeneous films when deposited onto propranolol HCl tablets using conventional fluid bed technology. Film permeability to the drug was low and flux/permeability enhancers were added to the CA structure during its manufacture. Films containing 40% surcrose and 10% PEG 8000 were found to provide the best release characteristics in terms of small lagtime (1 hour) and drug release profile (over 12 hours). When sucrose was added to TA or TEC plasticized fimls, a macroporous membrane was created during exposure to the dissolution fluid due to sucrose release from the film. These observations are consistent with the controlled porosity walls previously described for CA films deposited from organic solvents. It was postulated that drug mass transport occurs mainly within the porous CA structure and the mechanism responsible for its is a combination of molecular diffusion/osmotic pressure via water transport into the porous cellulose acetate membrane. Plasticizer loss during drying had also been demonstrated and related to the change in release profile seen with drying time.     

Release Rate of Drugs from Ethyl Cellulose Coated Granules Containing Caffeine and Salicylic Acid

Fluidized bed coating with ethyl cellulose., polyethylene glycol mixtures has been utilized for prolongation of drug release from granules containing salicylic acid and caffeine as model drugs. Drug release from the coated granules followed first order kinetics.

Particle size of the active material, granule composition and extraction medium pH did not affect the rate and kinetics of drug release. Increase in coat thickness decreased the release rate whereas elevation of the ratio of polyethylene glycol to ethyl cellulose enhanced the release rate to a degree related to the polyethylene glycol concentration. The permeability constants of salicylic acid and caffeine for the ethyl cellulose-polyethylene glycol coatings were of a similar order to those measured previously using solutions of the drugs with planar barrier films.     

Plasticized polylactic acid nanocomposite films with cellulose and chitin nanocrystals prepared using extrusion and compression molding with two cooling rates: Effects on mechanical,thermal and optical properties

Triacetate citrate plasticized poly lactic acid and its nanocomposites based on cellulose nanocrystals (CNC) and chitin nanocrystals (ChNC) were prepared using a twin-screw extruder. The materials were compression molded to films using two different cooling rates. The cooling rates and the addition of nanocrystals (1 wt%) had an impact on the crystallinity as well as the optical, thermal and mechanical properties of the films. The fast cooling resulted in more amorphous materials, increased transparency and elongation to break, (approx. 300%) when compared with slow cooling. Chitin nanocomposites were more transparent than cellulose nanocomposites; however, microscopy study showed presence of agglomerations in both materials. The mechanical properties of the plasticized PLA were improved with the addition of a small amount of nanocrystals resulting in PLA nanocomposites, which will be further evaluated for film blowing and thus packaging applications.