Mechanistic modeling of drug release from chitosan coated tablets

A mechanistic model for drug release from tablets coated with chitosan was derived, assuming that: (1) core tablets are spherical and the drug dissolution is diffusion dependent. (2) In order for the drug release to occur, dissolution medium penetrates through the coated film and leaches out the drug through the film and the lag-time, t_lag is set for these processes. (3) The coated film itself dissolves and becomes thinner with time. (4) After the film has completely dissipated and the undissolved core tablet becomes naked, drug release proceeds just as the spherical core tablet. Drug release rate was given as a differential equation. Model adaptation was carried out to the release data of propranolol hydrochloride tablets coated with chitosan and kept in different storage conditions. The goodness-of-fit of our model was better than any other conventional equations tested and estimated model parameters were informative.     

Investigation of the release behavior of a covered-rod-type formulation using silicone.

The purpose of this study was to investigate the effects of the properties of a drug on its release behavior in a cylindrical sustained-release formulation having a two-component structure, with a silicone matrix containing drug powder as the inner layer component, and with its lateral side covered with an silicone outer layer (CR silicone formulation). In this study, the release profile of a drug from "the lateral side covered with silicone" and from "the cross-sections where the inner layer is exposed to the surface" was examined using a newly designed bi-directional elution cell. The relationships between the release profile and solubility of the drug and its permeability through silicone were also studied. Bovine serum albumin (BSA), antipyrine (ANP), indometacin (IDM) and ketoprofen (KP) were used as model drugs. Each CR silicone formulation containing drug powder consisting of a drug and sucrose (SUC) was investigated, and a satisfactory relationship was observed between drug release from the cross-sections and drug solubility, and between drug release from the lateral side and permeability of the drug through a silicone membrane. For CR silicone formulations containing IDM, the addition of deoxycholate sodium (DOC) improved the solubility of IDM; however, release from the lateral side of the formulation remained unchanged, and IDM release from the cross-sections of the formulation increased. In this study it was found that, for controlled release of a drug from CR silicone formulations, control of drug solubility is effective.     

Development of mucoadhesive patches for buccal administration of ibuprofen.

A new formulation for topical administration of drugs in the oral cavity has been developed using several film-forming and mucoadhesive polymers. The films have been evaluated in terms of swelling, mucoadhesion and organoleptic characteristics. The best film, containing polyvinylpyrrolidone (PVP) as film-forming polymer and carboxymethylcellulose sodium salt (NaCMC) as mucoadhesive polymer, was loaded with ibuprofen as a model compound and in vitro and in vivo release studies were performed. Statistical investigation of in vitro release revealed that the diffusion process was the main drug release mechanism and the Higuchi's model provided the best fit. In vivo studies showed the presence of ibuprofen in saliva (range 70-210 microg/ml) for 5 h and no irritation was observed. These mucoadhesive formulations offer many advantages in comparison to traditional treatments and can be proposed as a new therapeutic tool against dental and buccal diseases and disturbs.     

Cultured skin loaded with tetracycline HCl and chloramphenicol as dermal delivery system: mathematical evaluation of the cultured skin containing antibiotics.

Dermal patches consisting of cultured human skin with antibiotics, which have a protective effect on wound skin as well as a preventative effect on second infection of the skin, were prepared and mathematically analyzed as a new drug delivery system (DDS) that can be applied to serious skin defects such as severe burns. In the present study, a three-dimensional cultured human skin model (living skin equivalent-high, LSE-high) was used as a cultured skin membrane and tetracycline HCl (TC-HCl) and chloramphenicol (CP) were used as antibiotics. At first, antibiotics were entrapped in the LSE-high from the dermal side through culture medium in order to obtain a drug-loaded LSE-high. The antibiotic release from the drug-loaded LSE-high was then examined and the resulting release data were used to calculate the effective diffusion coefficient of the antibiotics (D(LSE)) and initial loading concentration of the antibiotics (C0) in the LSE-high. The release profile of TC-HCl was represented by general diffusion-limited kinetics, whereas an initial burst effect was found in the release profile of CP. Therefore, the burst effect was taken into account for analyzing the release profile of CP. Stripped skin excised from hairless rats was used as a wound model, and the antibiotic permeation through the skin from aqueous solution was examined and evaluated using differential equations for Fick's second law of diffusion to obtain the effective diffusion coefficient of the antibiotics in the wound skin (D(skin)). Furthermore, the antibiotic permeation profile through the excised stripped skin from the drug-loaded LSE-high was measured and theoretically evaluated by Fick's second law of diffusion with previously obtained parameters (C0, D(LSE), D(skin)) using a newly constructed two- or three-layered diffusion model. The calculated concentrations of TC-HCl and CP in the upper epidermis of the model wound skin were over their minimum inhibitory concentration (MIC) for several hours against various bacteria, suggesting that this dosage system is useful for the treatment of severe burns. In addition, the present analytical method and diffusion model, with the drug-loaded LSE-high and stripped rat skin, are useful tools for evaluating this new DDS.     

Investigation of novel alginate-magnesium aluminum silicate microcomposite films for modified-release tablets.

Physicochemical properties of sodium alginate-magnesium aluminum silicate (SA-MAS) composite films were investigated and a potential as a film former of SA-MAS dispersion for modifying drug release from tablets was evaluated as well. Interaction between SA and MAS in the composite films was revealed using FTIR spectroscopy. Thermal behavior of the composite films was changed due to the complexation of SA and MAS. Powder X-ray diffractometry data suggested that a higher crystallinity of the composite film and a phase-separated microcomposite were formed. The composite films in the ratios of 1:0.5 and 1:1 showed the increases of tensile strength and percentage of elongation when compared with SA films. Water vapor permeability of the composite films tended to increase with increasing ratio of MAS. The decreases in water uptake and drug permeability in 0.1 M HCl were found in the composite films. A positive charge drug, propranolol HCl, provided a higher affinity on the composite films than a weakly acidic nonelectrolyte, acetaminophen, resulting in a longer lag time and a higher partition coefficient depending on the content of MAS in the composite films. This was due to the complex formation of propranolol HCl and MAS. Using SEM, the tablets coated with SA-MAS dispersion had a smooth surface, while those with SA dispersion showed a pinholing on the surface, resulting in a faster drug release. The drug release profiles of the tablets could be modified by coating with the composite film at different coating levels. This finding suggests that MAS could improve physicochemical properties of the SA films, leading to a novel coating material of the SA-MAS dispersion for modifying drug release from tablets.     

The utility of diffusion chambers as models for the description of drug disposition

Tissue cages were employed to explore the diffusion processes of several cephalosporins into extravascular fluids. Concentrations of cefotaxime in serum and in subcutaneous chambers increased proportionally to the amount of the drug injected. Administration of single equal doses of cephalothin, cephaloridine and cefotaxime resulted in different concentration-time courses in the serum and in diffusion chambers. These observations suggest that diffusion chambers are linked to the tissue at the implantation site. None of the classical compartmental approaches can be applied to evaluate the kinetics of drug diffusion into tissue cages. Correlations of total or non-protein bound drug concentrations in tissue cages to those in the peripheral compartment assumed concentration and time dependent diffusion processes. No specific diffusion constant based on the law of Fick could be derived for the diffusion chambers used in this study. Concentration-time courses in serum and interstitial fluid can be simultaneously evaluated according to pharmacokinetic-pharmacodynamic models. Based on the equation describing the effect site this model can be used to simulate drug concentrations in tissue cages by varying the dose size or the dose interval.     

Characterization of the initial burst release of a model peptide from poly(D,L-lactide-co-glycolide) microspheres.

In order to study the mechanism of initial burst release from drug-loaded poly(D,L-lactide-co-glycolide) (PLGA) microspheres, a model peptide, octreotide acetate, was encapsulated in PLGA 50/50 (M(w) approximately 50,000) microspheres using a double emulsion-solvent evaporation method. A simple and accurate continuous monitoring system was developed to obtain a detailed release profile. After different incubation times in the release medium, the morphology and permeability of the microspheres were examined using scanning electron and confocal microscopy (after immersing the microspheres in a fluorescent dye solution for 30 min), respectively. Both the external and internal morphology of the microspheres changed substantially during release of >50% of the peptide over the first 24 h into an acetate buffer, pH 4 at 37 degrees C. After 5 h, a 1-3 microm "skin" layer with decreased porosity was observed forming around the microsphere surface. The density of the "skin" appeared to increase after 24 h with negligible surface pores present, suggesting the formation of a diffusion barrier. Similar morphological changes also occurred at pH 7.4, but more slowly. Correlated with these results, the confocal microscopy studies (at pH 4) showed that the amount of dye penetrated inside the microspheres sharply decreased with time. In summary, over the first 24 h of drug release, a non-porous film forms spontaneously at the surface of octreotide acetate-loaded PLGA microspheres in place of an initially porous surface. These rapid alterations in polymer morphology are correlated with a sharp decline in permeability and the cessation of the initial burst.     

Dynamic rheological measurements and drug release kinetics in swollen scleroglucan matrices

The structure of scleroglucan gel matrices was characterized by dynamic rheological studies. The results were compared with the release kinetics of theophylline in analogous samples using a Franz diffusion cell, fitting the drug release data with a semi-empirical power law. Dynamic rheology gave information about the viscous and elastic components (loss and storage moduli, respectively) of the gel which could influence the drug-release profiles. Scleroglucan gels showed two structural transitions within the gel regime that coincided with changes in the release pattern. It was found that the introduction of 0.4% (w/w) of theophylline decreased the loss and storage moduli in the 2% (w/w) scleroglucan gels by 50%. The influence of the same wt.% theophylline in other gels was strongly dependent on the gel concentration. These results demonstrated the value of rheological studies to detect matrix structural changes produced by the inclusion of drugs which may modify the drug-release profile.     

Effects of crystalline microstructure on drug release behavior of poly(epsilon-caprolactone) microspheres.

This study investigates the release behavior of papaverine from poly(epsilon-caprolactone) (PCL) microparticles prepared by the oil/water solvent evaporation method. Microparticles were characterized in terms of crystalline morphology, size, drug loading, and encapsulation efficiency by using differential scanning calorimetry (DSC), small angle X-ray scattering (SAXS), scanning electron microscopy (SEM), and UV spectrometry. The release behavior of papaverine was governed by the microstructure of PCL microparticles, suggesting that the environment for diffusion changes according to processing conditions such as polymer solution concentration, thermal history, and polymer molecular weight. As the PCL solution concentration increased, the drug release behavior showed a more sustained pattern. This result indicates that the size of the PCL microparticles is a determining factor for drug release. And when higher PCL molecular weight is used for preparation of microparticles, it led to a rapid release. Furthermore, a more delayed pattern of drug release profile was obtained in the sample prepared with higher thermal treatment. These results suggest that the crystalline microstructure of PCL microparticles plays an important role in its drug release behavior.     

Design of a microporous controlled delivery system for theophylline tablets.

The aim of present work was to develop a microporous-controlled delivery system for theophylline via coating a blend of PCL and PEG on the surface of tablets, where PCL was the major component of film coating material and PEG was acted as a leachable pore-forming agent when contacting with an aqueous medium. The influences of the type of solvent, the amount of PEG, and the thickness of films on the mechanical and thermal properties of coating films and drug release performance were investigated. The DSC thermograms and FTIR spectra indicated both PCL and PEG remained independently in the blended films. The mechanical data showed a decrease tendency as increase in the amount of PEG in the blends due to highly crystalline character of PEG. Slower evaporation rate of acetone than dichloromethane enhanced phase separation between PCL and PEG during film formation, and resulted in the pore size in films prepared from acetone larger than from dichloromethane. The release rate of coated tablets were increased by increasing the amount of pore-forming agent, and the corresponding values from tablets coated in dichloromethane were less than in acetone. Much denser structure and smaller pore size of films formed from dichloromethane contributed to this result. The release of drug from tablets coated in acetone showed a profile more close to a zero-order constant release profile. The penetration of water into drug core played an important role in influencing drug release pattern.     

Development of a biodegradable nanoparticle platform for sildenafil: formulation optimization by factorial design analysis combined with application of charge-modified branched polyesters

Biodegradable nanoparticles have gained tremendous attraction as carriers for controlled drug delivery to the lung. Despite numerous advances in the field, e.g. development of suitable methods for pulmonary administration of polymeric nanoparticles, a sufficient association of the therapeutic agent with the carrier system as well as drug release in a controlled fashion remain considerable challenges. Hence, this study examines the optimization of biodegradable sildenafil-loaded nanoparticle formulations intended for aerosol treatment of pulmonary hypertension. A factorial design analysis was employed to identify the important experimental factors involved in the preparation of nanoparticles by the solvent evaporation technique. The effect of tailored charge-modified branched polyesters on drug loading and in vitro drug release from nanoparticles was also evaluated. Moreover, colloidal stability of obtained nanoparticles was assessed, and stabilization of nanoparticles by lyophilization was accomplished without additional excipients. Essential experimental factors were identified and optimized to allow the preparation of nanoparticles composed of linear polyesters with a sildenafil content of ~5 wt.%. The in vitro drug release profile from these nanoparticles demonstrated a sustained release of sildenafil over ~90 min. Application of charge-modified branched polyesters enhanced the drug content in nanoparticles and drug release profile, according to the charge-density present in the employed polymer. Accordingly an increase in drug loading by a factor of ~1.4, a prolonged drug release profile from nanoparticles over ~240 min was achieved. Sildenafil release from nanoparticles made of linear and charge-modified branched polyesters was governed by a diffusion process. The obtained drug diffusion coefficients were decreased as the charge-density present in the applied polymer was increased, which promotes the strategy to improve drug loading and release rates by electrostatic interactions between polymer and drug. In addition, nanoparticles showed high colloidal stability in different media of importance for pulmonary application and were successfully stabilized by lyophilization. In conclusion, optimization of the nanoparticle preparation process together with the application of tailored polymeric materials facilitated the synthesis of promising drug carriers for sildenafil that permit a novel treatment modality for severe pulmonary hypertension.     

Study on drug release behaviour of CDHA/chitosan nanocomposites--effect of CDHA nanoparticles.

To explore the effect of nanofiller-polymer interaction on the drug release behaviour from a monolithic membrane prepared by Ca-deficient hydroxyapatite (CDHA)/chitosan nanocomposite, release kinetics was investigated in terms of different synthetic processes, i.e. in situ and ex situ routes, and various amounts of CDHA. It was found that a higher value of diffusion exponent (n) was obtained for the membranes in situ synthesized compared with those ex situ prepared. In addition, the n value of the membranes in situ synthesized increased with increasing CDHA amount, which remained in the range below 10wt.%. However, as CDHA content exceeded 30%, the n value remained constant. It indicates that the drug diffusion mechanism is altered by the CDHA-chitosan interaction which is strongly influenced by both the synthesis process and the concentration of the CDHA nanofiller in the membrane. On the other hand, a lower permeability (P) value of the membranes was observed for those prepared via the in situ process. Furthermore, P value decreased and increased with increasing CDHA amount in the range below and above 10wt.%, respectively. It demonstrates that CDHA nanofillers act either diffusion barrier or diffusion enhancer for the CDHA/chitosan membranes, which is determined by the concentration of CDHA nanofiller and the synthesis route of nanocomposite.     

Validation protocol of an automated in-line flow-through diffusion equipment for in vitro permeation studies.

Transdermal drug delivery experiments are often tedious and time consuming in terms of sampling, labor, etc. In this way, the automation of such experiments has increased in the last few years. A protocol suitable to validate an automated diffusion equipment with seven in-line flow-through cells is described. The proposed protocol was divided into two parts. First, validation of each component which makes up the whole equipment, including the study of the statistical variability of the internal volumes between the cells, the temperature into the different chambers, the time and sample volumes, etc. In the second part, a series of permeation studies were carried out comparing the performance of the system against a classical Franz-type diffusion cell. Ketoprofen was used as a model drug. It was proved the low variability of the replicates obtained with the automated flow-through diffusion cells. The best work conditions as flow rate into the receptor chamber, temperature, etc., as well as the best mathematical approach for the diffusion data, were determined. The advantages in terms of time saved and easiness of validation of the flow-through cell design in comparison to the Franz-type cell were evidenced.     

Indomethacin release from ion-exchange microspheres: impregnation with alginate reduces release rate.

Ion-exchange microspheres (MS) designed as a drug delivery system for embolization coupling ability to occlude vessels and chemotherapy were used to evaluate a manufacturing process allowing to control the drug release rate through reduction of diffusion rate of the drug within the particle by impregnation of calcium alginate inside the porous MS. Impregnation was performed by diffusion of sodium alginate inside DEAE-Trisacryl(R) MS, dispersion of the MS in deionised water and gelling alginate by adding CaCl(2) to the dispersed MS. Studied parameters were alginate concentration, alginate diffusion time and calcium concentration. Indomethacin was loaded into the MS by eluting an aqueous indomethacin solution through a chromatographic column packed with impregnated MS. Indomethacin loading was reduced by alginate. Swelling studies showed indomethacin loading enhanced the hydrophobicity of MS while impregnation had no effect. This had an incidence on indomethacin release rate, which was assessed using the rapid elution of PBS through loaded impregnated MS packed in a column. Indomethacin loading reduced its own rate of release. MS impregnated with 2% w/v alginate gelled with a 40 mM calcium solution presented the lower release rate. This work indicated the manufacturing conditions to display a calcium alginate matrix effect on indomethacin release from DEAE-Trisacryl MS.     

Interrelation of permeation and penetration parameters obtained from in vitro experiments with human skin and skin equivalents.

In a comparative study, two different in vitro cutaneous test systems were examined: (1) The Franz diffusion cell (FD-C), a test system to study drug permeation through the skin and to obtain data like steady state flux and lag time as well as permeability and diffusion coefficients. (2) The Saarbruecken penetration model (SB-M), a test system to investigate drug penetration into different skin layers and after varying incubation times to acquire values about the quasi steady state drug amounts in the stratum corneum (SC). Three drug concentrations (0.9, 0.45 and 0.225%) of a lipophilic model drug preparation, flufenamic acid in wool alcohols ointment, were applied on the skin's surface using 'infinite dose' conditions. Trypsin-isolated SC, heat-separated epidermis, full-thickness skin and reconstructed human skin (RHS) served as skin membranes in the FD-C, while the SB-M experiments were only carried out using full-thickness skin. Increasing steady state flux data and m(ss) values (steady state drug amount in the SC) were detectable after the application of rising drug amounts. Concerning the permeability of the used skin membranes in establishing barrier properties, the following rank order was observed: RHS>SC> or =epidermis>full skin. The flux data of the FD-C experiments for isolated SC, separated epidermis and RHS were linearly related with the m(ss) values of the SB-M investigations, allowing a direct comparison of permeation with penetration parameters. Concerning the drug amount in the SC, previous investigations succeeded in the establishment of an in vivo/in vitro correlation. Based on the results presented here, the prediction of drug amounts present in the SC after different incubation times in vivo is now possible after penetration as well as permeation experiments using the lipophilic model drug preparation, flufenamic acid in wool alcohols ointment.     

A model for the drug release from a polymer matrix tablet--effects of swelling and dissolution.

A model for simulating the drug release from a swelling and dissolving polymer tablet is presented and verified to data. The model is based on a mechanistic approach, and it can therefore be employed to study the sensitivity of true physical constants, for instance the drug diffusion coefficient or the drug solubility. The model generates the drug and polymer release profiles and the front positions of the total tablet, the solid core, and of the solid-drug-solubilized-drug interface. The convective contribution to mass transfer is shown to be of great importance. This is most markedly noticed for slowly diffusing drugs. In a simulation with a low value of the drug diffusion coefficient, it is shown that the initial drug release rate is faster than the polymer dissolution rate, followed by a second stage with a slower drug release rate. Furthermore, it is shown that polymer dissolution influences the drug release profile significantly, but not the front position of saturated drug in the gel layer. The model is verified against drug release and polymer dissolution data for the slightly soluble drug Methyl paraben and the soluble drug Saligenin in a poly (ethylene oxide) tablet, resulting in good agreement between model and experiments.     

DSIMS characterization of a drug-containing polymer-coated cardiovascular stent.

Dynamic Secondary Ion Mass Spectrometry (DSIMS) was used to study the release behavior of cytochalasin D, an actin polymerase inhibitor effective in the reduction of smooth muscle cell (SMC) proliferation, from a polymer-coated cardiovascular stent. High-performance liquid chromatography (HPLC) was used to determine the percentage of drug released as a function of time and showed the typical behavior of a drug-releasing system that is comprised of a core drug-polymer dispersion surrounded by a drug-free polymeric membrane: an initial burst of the drug followed by a gradual elution over time. DSIMS profiles, as a function of release time, indicated that depletion of the drug initially occurred only in the outer layers of the coating. As release progressed the DSIMS profile showed a gradual decrease of cytochalasin D with increasing depth. This study shows that DSIMS is a powerful tool for the determination of drug distributions in, and the release behavior from, thin polymer layers.     

基于复合多聚体材料的缓释局麻药在慢性痛动物模型中的应用

  目的  对复合多聚体材料组成的局麻药缓释载体的药物释放特征和镇痛效果进行测评。  方法  使用静电纺丝技术制备含盐酸布比卡因的PLGA(聚乳酸-羟基乙酸共聚物)缓释膜(静电纺丝膜, M组), 并以PLGA-PEG(聚乙二醇)-PLGA温敏凝胶包裹纺丝膜制备成含盐酸布比卡因的缓释递送系统(凝胶包裹静电纺丝膜形成的复合缓释载体, G组), 评定两组体外释放特征、体内镇痛效果及安全性。  结果  体外条件下, M组对盐酸布比卡因的累积释放时间可达5 d以上, G组累积释放时间可延长至10 d。体内条件下, M组和G组对坐骨神经慢性压迫损伤大鼠模型的镇痛时间均可达14 d, 两组镇痛效果无显著差异(P＞0.05)。M组盐酸布比卡因血药浓度在术后第1天达峰值[(0.294±0.029)μg/L], G组于术后第3天达峰值[(0.192±0.064)μg/L], 且峰值较M组降低, 两组盐酸布比卡因血药浓度均在安全范围内。HE染色示, M组、G组大鼠的心脏、肝脏、脾脏、肺、肾脏组织均未见明显病理改变。  结论  本研究制备的以盐酸布比卡因纳米纺丝缓释膜为基础, PLGA-PEG-PLGA温敏凝胶包裹为介质的复合缓释材料, 可进一步延长盐酸布比卡因缓释时间, 具有长效镇痛效果且无毒性作用。     

A novel enzymatic technique for limiting drug mobility in a hydrogel matrix.

An oral colon specific drug delivery platform has been developed to facilitate targetted release of therapeutic proteins as well as small molecule drugs. A simple enzymatic procedure is used to modify the molecular architecture of a lightly chemically crosslinked galactomannan hydrogel as well as a model drug-galactomannan oligomer conjugate, fluoroisocynate (FITC) tagged guar oligomer, to entrap the model drug. The enzyme-modified hydrogel retains the drug until it reaches the colonic environment where bacteria secrete enzymes (namely beta-mannanase) to degrade the gel and release the drug molecule. Laser scanning confocal microscopy combined with fluorescence recovery after photobleaching is used to quantify the diffusion of the drug conjugate. The diffusion coefficient of solutes in the lightly crosslinked galactomannan hydrogel is approximately equal to the diffusion coefficient in the guar solution for simple diffusional drug loading. After drug loading, alpha-galactosidase treatment generates additional physical crosslinks in the hydrogel matrix as well as between the drug-oligomer conjugate and the hydrogel, which reduces diffusion of the drug-oligomer conjugate significantly. Degradation of the hydrogel by beta-mannanase results in a slow and controlled rate of FITC-guar oligomer diffusion, which generates an extended release profile for the model drug.