Streptomycin sulphate microspheres: dissolution rate studies and release kinetics. I

Targeting of drugs by microspheres, nanoparticles and liposomes is intended to increase the selective targeting to specific organs and to reduce their side effects. Streptomycin sulphate, a tuberculostatic antibiotic, is used as the active principle in this study. The aim is to accumulate the loaded microspheres in the lungs. The release of drugs associated with microsphere carriers has been found to be dependent on a number of factors. The aim of the investigation was to study the influence of the extent and nature of cross-linking, the type and the amount of the matrix material on the release characteristics of streptomycin sulphate microspheres. Human serum albumin and gelatin (Type B) were used as two different matrix materials. The crosslinking agents used were 2,3-butanedione and formaldehyde at different concentrations, and variable duration times. The in vitro release of streptomycin sulphate from microspheres is characteristically biphasic, with an initial fast release (the 'burst effect'), followed by a much slower release. Alteration in the characteristics of drug-loaded microspheres result in significant changes in the second (slow) phase of release. The release profiles of the different formulations has been studied and evaluated kinetically.     

Factors affecting mechanism and kinetics of drug release from matrix-based oral controlled drug delivery systems

Matrix technologies have often proven popular among the oral controlled drug delivery technologies because of their simplicity, ease in manufacturing, high level of reproducibility, stability of the raw materials and dosage form, and ease of scale-up and process validation. Technological advancements in the area of matrix formulation have made controlled-release product development much easier than before, and improved upon the feasibility of delivering a wide variety of drugs with different physicochemical and biopharmaceutical properties. This is reflected by the large number of patents filed each year and by the commercial success of a number of novel drug delivery systems based on matrix technologies. Matrix-based delivery technologies have steadily matured from delivering drugs by first-order or square-root-of-time release kinetics to much more complex and customized release patterns. In order to achieve linear or zero-order release, various strategies that seek to manipulate tablet geometry, polymer variables, and formulation aspects have been applied. Various drug, polymer, and formulation-related factors, which influence the in situ formation of a polymeric gel layer/drug depletion zone and its characteristics as a function of time, determine the drug release from matrix systems. Various mathematical models, ranging from simple empirical or semi-empirical (Higuchi equation, Power law) to more complex mechanistic theories that consider diffusion, swelling, and dissolution processes simultaneously, have been developed to describe the mass transport processes involved in matrix-based drug release. Careful selection of an appropriate model for drug release provides insight to the underlying mass transport mechanisms and helps in predicting the effect of the device design parameters on the resulting drug-release rate. Thus, a basic understanding of release kinetics and appropriate mechanisms of drug release from matrix system and their inter-relationships may minimize the number of trials in final optimization, thereby improving formulation development processes.     

Dynamics of dissolution and diffusion-controlled drug release systems

Analytical expressions were derived to explain the influence of the dissolution/diffusion number (Di) on the time constant and steady-state flux when dispersed drugs are released from a finite matrix. A key novelty of this work is the introduction of a single time-constant that combined the analysis of both dissolution- and diffusion-based systems. Focus is placed on systems with a constant dissolution rate and diffusion coefficient. Solutions, based on the residue theorem, were in agreement with published results describing the transport of estradiol in a polymeric matrix. The experimental cumulative amount of drug released was 0.1 mg/cm2 in 100 hours compared to 0.084 mg/cm2 predicted by the theoretical model. The process time constant, estimated from the first eigenvalue (t0) and a more accurate statistical approach (t(eff)), showed a consistent decrease with increasing Di values. For a dissolution/diffusion number of 0.21, t0 and t(eff) were estimated at 58.44 and 73.02 hrs, respectively. With the presence of a skin layer, t(eff) increased to 575.7 hrs. These results can be used to assess the relative impact of dissolution and diffusion on the time it takes drugs to attain a therapeutic level in the bloodstream.     

Modelling drug dissolution from controlled release products using genetic programming

This study has investigated and compared genetic programming (GP) - a method of automatically generating equations that describe the cause-and-effect relationships in a system - and statistical methods for modelling two controlled release formulations--a matrix tablet and microspheres. With the improved GP models exhibiting comparable predictive power, as well as simpler equations in some cases, the results obtained indicate that GP can be considered as an effective and efficient method for modelling controlled release formulations.     

Modeling microstructure development and release kinetics in controlled drug release coatings

In recent years, controlled release coatings, comprised of drug-polymer composites, have been integrated with medical devices, improving device functionality and performance. However, relationships between material properties, manufacturing environment, composite (micro)structure, and subsequent release kinetics are not well established. We apply a thermodynamically consistent model to probe the influence of drug-polymer chemistry (phobicity), drug loading, and evaporation rate on microstructure development during fabrication. For these structures, we compute release profiles for exposure to polymer-insoluble media and media in which the polymer readily dissolves. We find that with increasing drug-polymer phobicity, structural heterogeneities form at lower loadings and more rapid rates. The heterogeneities remain isolated and compact at low loadings and become interconnected as the drug to polymer ratio approaches 1.0. Release into polymer-insoluble media was dramatically enhanced by heterogeneities, resulting in up to a fourfold increase in drug release. In polymer-soluble media, however, heterogeneities diminished release. Although reductions of only 30% were typically observed, the absolute changes were much larger than observed in polymer-insoluble media. Our results suggest that improved comprehension and quantification of the physico-chemical properties in controlled release systems will enable the microstructure to be tailored to achieve desired responses that are insensitive to manufacturing variations.     

Calcium alginate microparticles for oral administration: I: Effect of sodium alginate type on drug release and drug entrapment efficiency.

The natural polymers alginate and chitosan were used for the preparation of controlled release nicardipine HCl gel microparticles. The effect of the mannuronic/guluronic acid content and the alginate viscosity on the prolonged action of the microparticles, which were prepared with different types of alginates, were investigated. The mean particle sizes and the swelling ratios of the microparticles were also determined. The in vitro release studies were carried out with a flow-through cell apparatus in different media (pH 1.2, 2.5, 4.5, 7 and 7.5 buffer solutions). The release of nicardipine was extended with the alginate gel microparticles prepared with guluronic acid rich alginate. After the determination of the most appropriate alginate type, the effect of alginate-chitosan complex formation was studied on the release pattern of drug incorporated. It was observed that the alginate-chitosan complex formation reduced the erosion of the alginate-chitosan matrix at pH 7-7.5. The release of drug from the chitosan-alginate gel microparticles took place by both diffusion through the swollen matrix and relaxation of the polymer at pH 1.2-4.5.     

Percolation effects in matrix-type controlled drug release systems

From experimental evidence it is well known that the bioavailability of controlled release systems, i.e., the percentage of the dose absorbed by the body, is often reduced compared to a corresponding dosage form with immediate release. In the case of inert matrices, a water-soluble drug is embedded in a finely dispersed state in an insoluble carrier material and released by diffusion. In the present work such systems are described by percolation theory. Based on a Bethe lattice model the amount of drug substance ‘trapped’ in the matrices, which determines the reduction of bioavailability, is calculated in a straight-forward way from the volume-to-volume ratio of drug and matrix material. To check the use of the model, matrix tablets are prepared with caffeine as a model drug and ethyl cellulose or hydrogenated castor oil as carrier materials, and their drug release is determined in vitro. The experimental findings are in good agreement with the values predicted from the percolation model. The most pronounced reductions of bioavailability are observed if the volume-to-volume ratio of drug and matrix substance is below a percolation threshold.     

Calcium pectinate gel beads for controlled release drug delivery: II. Effect of formulation and processing variables on drug release.

The effect of four formulation and processing variables, calcium concentration, drying condition, concentration of hardening agent and hardening time on the bead properties and the release characteristics of a model drug from calcium pectinate gel (CPG) beads were studied. A poorly soluble compound, indomethacin, was used as the model drug. The investigated variables affected the bead size, the entrapment efficiency and the release of indomethacin from CPG beads. Drug release was found to be a function of the formulation and processing variables. The slower drug release was achieved from the formulations with higher calcium concentration, higher concentration of hardening agent and longer hardening time. The drying condition, however, did not influence the drug release. The mechanism of indomethacin release from CPG beads followed the diffusion controlled model for an inert porous matrix. All drug release data fitted well to the Higuchi square root time expression.     

Determination of percolation thresholds in matrix-type controlled release systems: Application of a resistance analysis technique

In this work, matrix tablets have been prepared with binary mixtures of the inert polymer Eudragit ® RS 100 and a soluble, power-conductor model substance, sodium chloride. The sodium chloride content comprised between 20 and 80% w/w. A technique based on the measurement of the resistance of the matrix tablets has been used to achieve easy estimation of the values of the percolation thresholds, as a function of the sodium chloride loadings. The results obtained have been expressed in terms of resistivity and evaluated on the basis of percolation theory. The tablet resistivity has been considered as a critical property of the system. A change in this property and the presence of the percolation threshold were observed to appear simultaneously. From the data obtained, we have determined a first percolation threshold comprising between 30 and 40% (w/w) sodium chloride loading. The tablets made with a sodium chloride charge higher than 70% (w/w) undergo a disintegration process. The results obtained have been corroborated by scanning electron microscopy.     

Calcium pectinate gel beads for controlled release drug delivery: II. Effect of form ulation and processing variables on drug release

The effect of four formulation and processing variables, calcium concentration, drying condition, concentration of hardening agent and hardening time on the bead properties and the release characteristics of a model drug from calcium pectinate gel (CPG) beads were studied. A poorly soluble compound, indomethacin, was used as the model drug. The investigated variables affected the bead size, the entrapment efficiency and the release of indomethacin from CPG beads. Drug release was found to be a function of the formulation and processing variables. The slower drug release was achieved from the formulations with higher calcium concentration, higher concentration of hardening agent and longer hardening time. The drying condition, however, did not influence the drug release. The mechanism of indomethacin release from CPG beads followed the diffusion controlled model for an inert porous matrix. All drug release data fitted well to the Higuchi square root time expression.     

Moulded cross-linked chitosan matrix systems for controlled drug release

Matrix-type drug delivery systems were prepared by moulding and drying cross-linked chitosan gels in 24-well plates and they were evaluated in terms of their physical properties, drug content, surface morphology and swelling. Furthermore, the in vitro drug release profiles were subjected to kinetic modelling at two different pH values. In general, the moulded matrix systems showed statistically significantly slower drug release compared to immediate release tablets as measured by the mean dissolution time. Drug release from the moulded matrix systems prepared from chitosan cross-linked with tripolyphosphate was pH-dependent as can be seen from the release exponent value (n) of 0.75 at pH 5.8 (anomalous transport, erosion), while the n value was only 0.40 at pH 7.4 (Fickian diffusion). The matrix systems obtained from chitosan cross-linked with sodium lauryl sulphate showed higher swelling but mostly Fickian diffusional release (n?=?0.25 at pH 7.4, n?=?0.41 at pH 5.8).     

Matrix embedded microspherules containing indomethacin as controlled drug delivery systems

This work is focused on the development of controlled drug delivery systems using different wax/fat embedded indomethacin (IM). Discrete wax/fat embedded microspherules containing indomethacin were prepared by using cetostearyl alcohol, paraffin wax and stearic acid by employing emulsification-phase separation method. These matrices have been used as barrier coatings due to their hydrophobic nature. Chemically inert and tasteless nature of wax/fats promotes their use as taste masking agents for bitter drugs. Various waxes and fats are available having different physicochemical properties to suit the needs of formulation. Methyl cellulose (MC) 1% w/v, sodium alginate (SA) 0.5% w/v and Tween-80 (TW) 1% w/v were used as emulgents. The resulting microspherules were discrete, large, spherical and also free flowing. It is revealed from the literature that natures of wax/fat emulgents were found to influence the rate of drug release. In the present work the drug content in all the batches of microspherules were found to be uniform. The rate of drug release corresponded best to first order kinetics, followed by Higuchi and zero-order equations. The release of the model drug from these wax/fat microspherules was prolonged over an extended period of time and the drug release mechanism followed anomalous (non-Fickian) diffusion controlled as well as Super Case II transport. Among the three matrix materials used, paraffin wax retarded the drug release more than the other two. Surface characteristics of microspherules have been studied by Scanning Electron Microscope (SEM). A fair degree rank of correlation was found to exist between the size and release retardation in all the three-wax/fat emulgent combinations.     

Calcium pectinate gel beads for controlled release drug delivery:: I. Preparation and in vitro release studies

Calcium pectinate gel (CPG) beads of indomethacin, a poorly soluble drug, were prepared by dispersing indomethacin in a solution of pectin and then dropping the dispersion into calcium chloride solution. The droplets instantaneously formed gelled spheres by ionotropic gelation. The effect of several factors such as pectin type, the presence of a hardening agent and the drug loading were investigated on the percentage of drug entrapped, size distribution and drug release from the CPG beads. The release characteristics were studied using the rotating basket dissolution method. Strong spherical beads with narrow size distributions, high yields and good entrapment efficiencies could be prepared. All factors investigated have significantly affected the release of indomethacin from CPG beads. The mechanism of drug release from CPG beads followed the diffusion controlled model for an inert porous matrix. Therefore, calcium pectinate gel could be a useful carrier for controlled release drug delivery of poorly soluble drugs.     

Nifedipine solid dispersion in microparticles of ammonio methacrylate copolymer and ethylcellulose binary blend for controlled drug delivery. Effect of drug loading on release kinetics

In order to elucidate the controlled-release mechanism of a poorly water-soluble drug from microparticles of ammonio methacrylate copolymer and ethylcellulose binary blend prepared by a phase-separation method, nifedipine-loaded microparticles with different levels of drug loading were evaluated by micromeritic properties, drug physical state, matrix internal structure, drug dissolution, and release modeling. Drug release study indicated that nifedipine release from the microparticles followed the Fickian diffusion mechanism, which supported the study hypothesis that as a result of formation of a nifedipine molecular dispersion, nifedipine dissolution inside the matrix was no longer the rate-limiting step for drug release, and the drug diffusion in matrix became the slowest step instead. Moreover, study results indicated that even though drug loading did not significantly affect the microparticle size distribution and morphology, nifedipine release rate from those microparticles was more or less influenced by the level of drug loading, depending on matrix formulation. At lower levels of drug loading, nifedipine release was well described by the Baker and Lonsdale's matrix diffusion model for microspheres containing dissolved drug and nifedipine had a plasticizing effect on the polymers that caused an increase in drug effective diffusion coefficient with increasing drug loading. However, at higher levels of drug loading, probably due to formation of solid nifedipine domains in microparticles, a change in the release kinetics was observed.     

Investigation of excipient type and level on drug release from controlled release tablets containing HPMC

The purpose of this study was to investigate the influence of excipient type and level on the release of alprazolam formulated in controlled release matrix tablets containing hydroxypropyl methylcellulose (HPMC). Each tablet formulation contained alprazolam, HPMC (Methocel K4MP), excipients, and magnesium stearate. The soluble excipients investigated were lactose monohydrate, sucrose, and dextrose, and the insoluble excipients included dicalcium phosphate dihydrate, dicalcium phosphate anhydrous, and calcium sulfate dihydrate. The similarity factor (f2 factor) was used to compare the dissolution profile of each formulation. The insoluble excipients, especially dicalcium phosphate dihydrate, caused the drug to be released at a slower rate and to a lesser extent than the soluble excipients. Soluble excipients created a more permeable hydrated gel layer for drug release, increased the porosity resulting in faster diffusion of drug, and increased the rate of tablet erosion. Use of binary mixtures of lactose monohydrate and dicalcium phosphate dihydrate produced release profiles of intermediate duration. Rapid drug dissolution was obtained when only 9.1% w/w of lactose monohydrate was present in the tablet formulation. Only when the dicalcium phosphate dihydrate level was sufficiently high (36.5% w/w) was the release rate and extent decreased. It was demonstrated that the type and level of excipient influenced the rate and extent of drug release from controlled release tablets containing HPMC. The release mechanism of alprazolam from each tablet formulation was described by either the Hixson-Crowell cube root kinetics equation or Peppas's equation. However, the different excipient types investigated did not influence the release mechanism of alprazolam from the final tablets.     

尼莫地平控释片释放度试验研究

本文研究了尼莫地平控释片的释放度试验方法——转篮法，释放介质为含有２２％异丙醇的０．１ｍｏｌ·Ｌ－１盐酸液；磷酸盐缓冲液（ｐＨ５．８）和ｐＨ７．２的溶液。含量测定方法：紫外分光光度法，在三种介质中尼莫地平分别在１～３０μｇ·ｍｌ－１，１０～５０μｇ·ｍｌ－１和１０～５０μｇ·ｍｌ－１的范围内，浓度与吸收度有较好的线性关系。回归方程分别为Ａ＝０．６１５Ｃ＋０．０２３（ｒ＝０．９９９９）；Ａ＝０．０６１４Ｃ＋０．０１２（ｒ＝０．９９９５）；Ａ＝０．０６１２Ｃ＋０．００８８（ｒ＝０．９９９９）。平均回收率分别为９９．６３％，９９．９８％及１００．７７％，ＲＳＤ（％）分别为１．３４％，１．５９％及１．４１％。本方法的体外释放百分率与体内吸收分数有较好的相关性（ｒ＝０．９９１）。     

Drug release kinetics and physicochemical characteristics of floating drug delivery systems

Introduction: Absorption of drugs through the gastrointestinal tract poses a variety of limitations, making the in vivo performance of drug delivery systems uncertain. Following on from recent advances, in a time of increased consideration of floating drug delivery systems, it is as important as ever to continue the progress by studying different aspects of these systems. Moreover, it seems imperative to gain a deeper insight into drug release mechanisms, in order to design a more systematic and intellectual floating system.

Areas covered: This paper summarizes current approaches in the research and development of ideal floating drug delivery systems, from recent literature. Also, in order to have predictability and reproducibility in designing an efficient floating dosage form, some kinetic studies are mentioned, and the drug release mechanism from floating drug delivery systems is discussed.

Expert opinion: Developing an efficient floating dosage form is reliant on a better understanding of the relation between formulation variables and performance of the floating systems. Generally, the combination of two buoyancy mechanisms and gas-generating systems with swellable polymers would be beneficial for obtaining an appropriate floating lag time and duration of buoyancy, which in turn guarantees optimum efficiency of the pharmaceutical dosage form.     

Controlled drug release by polymer dissolution. II: Enzyme-mediated delivery device.

A novel, closed-loop drug delivery system was developed where the presence or absence of an external compound controls drug delivery from a bioerodible polymer. In the described delivery system, hydrocortisone was incorporated into a n-hexyl half-ester of a methyl vinyl ehter-maleic anhydride copolymer, and the polymer-drug mixture was fabricated into disks. These disks were then coated with a hydrogel containing immobilized urease. In a medium of constant pH and in the absence of external urea, the hydrocortisone release was that normally expected for that polymer at the given pH. With external urea, ammonium bicarbonate and ammonium hydroxide were generated within the hydrogel, which accelerated polymer erosion and drug release. The drug delivery rate increase was proportional to the amount of external urea and was reversible; that is, when external urea was removed, the drug release rate gradually returned to its original value.