The pharmacokinetics of recombinant human interferon-alpha-2b poly(lactic-co-glycolic acid) microspheres in rats

Interferon-alpha2b (IFN α-2b) microspheres were prepared at various concentrations (5%, 10%, 15%, 20% and 25%) and viscosities (0.39, 0.6, 0.89 and 1.13?dL/g) of poly(lactic-co-glycolic acid) (PLGA) using double emulsion solvent evaporation. The optimal formulation of IFN α-2b microspheres was determined to be 0.89?dL/g PLGA, as assessed by the in vitro release test. The pharmacokinetics of IFN α-2b microspheres was investigated. Nine groups of rats were injected intramuscularly with three doses (0.5, 1 and 2?MIU) of commercial lyophilized IFNα-2b injection or IFN α-2b microspheres. At a dose of 0.5?MIU, the IFN α-2b microsphere released significantly longer than that of the IFN α-2b injection. At a dose of 2?MIU, each pharmacokinetics parameter of microspheres prepared with the IFNa-2b stock solution was manifestly greater than those of the injection. Our study indicated that the IFN α-2b microspheres prepared in 15% of 0.89?dL/g PLGA provided a sustained drug effect for up to 21 days in rats.     

The pharmacokinetics of recombinant human interferon-alpha-2b poly(lactic-co-glycolic acid) microspheres in rats

Interferon-alpha2b (IFN α-2b) microspheres were prepared at various concentrations (5%, 10%, 15%, 20% and 25%) and viscosities (0.39, 0.6, 0.89 and 1.13?dL/g) of poly(lactic-co-glycolic acid) (PLGA) using double emulsion solvent evaporation. The optimal formulation of IFN α-2b microspheres was determined to be 0.89?dL/g PLGA, as assessed by the in?vitro release test. The pharmacokinetics of IFN α-2b microspheres was investigated. Nine groups of rats were injected intramuscularly with three doses (0.5, 1 and 2?MIU) of commercial lyophilized IFNα-2b injection or IFN α-2b microspheres. At a dose of 0.5?MIU, the IFN α-2b microsphere released significantly longer than that of the IFN α-2b injection. At a dose of 2?MIU, each pharmacokinetics parameter of microspheres prepared with the IFNa-2b stock solution was manifestly greater than those of the injection. Our study indicated that the IFN α-2b microspheres prepared in 15% of 0.89?dL/g PLGA provided a sustained drug effect for up to 21 days in rats.     

Controlled release chitosan microspheres of mirtazapine: In vitro and in vivo evaluation

The purpose of the study was to formulate and evaluate controlled release chitosan microspheres of mirtazapine (MTZ) to improve the bioavailability by altering the pharmacokinetic profiles of the drug. Chitosan microspheres were prepared to prolong the release of the drug into the systemic circulation. Microspheres were prepared by a single water in oil (w/o) emulsion technique varying the chitosan/drug ratio, stirring speed and concentration of the crosslinking agent (glutaraldehyde). Drug-polymer compatibility studies were carried out using fourier transform infrared spectroscopy (FT-IR) and differential scanning calorimetry (DSC). The microspheres were evaluated for encapsulation efficiency, particle size, surface morphology, swelling index, in vitro release, as well as erosion and in vivo studies in rats. The FT-IR and DSC studies revealed no interaction between drug and polymer. The encapsulation efficiency of different formulation varied from 53 ± 1.2% to 78 ± 1.5%. The mean particle size of the optimized formulation F-14 was 106.4 ± 0.5 μm. Surface morphology revealed that chitosan microspheres were discrete and spherical in shape with a porous surface. The release of MTZ from chitosan microspheres was rapid up to 4 h, and then it was continuously and slowly released up to 48 h. Optimized formulation (F-14) was found to be stable under accelerated storage conditions based on International Conference on Harmonisation guidelines. Pharmacokinetic studies revealed that the optimized formulation showed significant increases in systemic exposure (AUC = 177.70 ± 7.39 μg·h/mL), half-life (4.72 ± 0.46 h) and reduced clearance (0.009 ± 0.0001 L/h) compared to pure drug administration. Hence, the present study demonstrates that controlled release formulation of MTZ microspheres using chitosan can improve pharmacokinetic profiles of MTZ.     

Preparation and in vitro characterization of vascular endothelial growth factor (VEGF)-loaded poly(D,L-lactic-co-glycolic acid) microspheres using a double emulsion/solvent evaporation technique

Biodegradable Poly(lactic-co-glycolic acid; PLGA), microspheres encapsulating the angiogenic protein recombinant human vascular endothelial growth factor (rhVEGF) were formed to achieve VEGF release in a sustained manner. These microspheres are a promising delivery system which can be used for therapeutic angiogenesis. The PLGA microspheres incorporating two different initial loading amounts of rhVEGF have been prepared by a modified water-in-oil-in-water (w/o/w) double emulsion/solvent evaporation technique. The microspheres have been characterized by particle size distribution, environmental scanning electron microscopy (ESEM), light microscopy, encapsulation efficiency and their degradation was studied in?vitro. The rhVEGF released from microspheres was quantified by the competitive enzyme-linked immunosorbent assay (ELISA) and human umbilical vein endothelial cell (HUVEC) proliferation assay was used to assess biological activity of the released VEGF. The microspheres were spherical with diameters of 10-60?μm and the encapsulation efficiency was between 46% and 60%. The release kinetics of rhVEGF was studied for two different amounts: 5?μg VEGF (V5) and 50?μg VEGF (V50) per 500?mg starting polymer. The total protein (VEGF:BSA) release increased up to 4 weeks for two rhVEGF concentrations. The ELISA results showed that the burst release for V5 and V50 microspheres were 4 and 27?ng/mL, respectively. For V5, the microspheres showed an initial burst release, followed by a higher steady-state release until 14 days. VEGF release increased up to 2 weeks for V50 microsphere. HUVEC proliferation assay showed that endothelial cells responded to bioactive VEGF by proliferating and migrating.     

替莫唑胺乳酸-羟基乙酸共聚物微球的制备及表征

采用乳化-溶剂挥发法制备替莫唑胺微球,考察了制备工艺中影响微球粒径、载药量和包封率的主要因素,筛选处方工艺.按优化工艺制得的微球形态圆整,表面光滑,平均粒径62.2μm,载药量7.5%,包封率83.5%,体外试验表明该载药微球有明显的缓释效果.     

Multivesicular liposome formulations for the sustained delivery of interferon α-2b

AIM: To develop and optimize a sustained release multivesicular liposome (MVL) formulation of interferon (IFN) alpha-2b. METHODS: IFN alpha-2b MVL were prepared using a typical double-emulsion procedure. The sustained release effects of IFN alpha-2b MVL were investigated by monitoring the blood IFN alpha-2b concentration using an enzyme-linked immunosorbent assay test after subcutaneous administration to healthy mice. RESULTS: IFN alpha-2b was successfully encapsulated in MVL with high efficiency, and the integrity of encapsulated protein was maintained. After subcutaneous injection, the MVL slowly released IFN alpha-2b into systemic circulation in a sustained manner. The estimated serum half-life of IFN alpha-2b was approximately 30 h. In addition, varying the size of the MVL preparations could further modify the in vivo release profile. CONCLUSION: IFN alpha-2b MVL may be a useful sustained release formulation in the clinical treatment of viral diseases.     

Preparation and characterization of D, L-PLA loaded 17-β-Estradiol valerate by emulsion/evaporation methods

PLA microparticles containing 17-β-estradiol valerate were prepared by an emulsion/evaporation method in order to sustain drug release. This system was characterized concerning particle size, particle morphology and the influence of formulation and processing parameters on drug encapsulation and in vitro drug release. The biodegradation of the microparticles was observed by tissue histological analysis. Scanning electron microscopy and particle size analysis showed that the microparticles were spherical, presenting non-aggregated homogeneous surface and had diameters in the range of 718-880 nm (inert micro-particles) and 3-4 μm (drug loaded microparticles). The encapsulation efficiency was ～80%. Hormone released from microparticles was sustained. An in vivo degradation experiment confirmed that microparticles are biodegradable. The preparation method was shown to be suitable, since the morphological characteristics and efficiency yield were satisfactory. Thus, the method of developed microparticles seems to be a promising system for sustained release of 17-β-estradiol.     

Prevention of structural perturbations and aggregation upon encapsulation of bovine serum albumin into poly(lactide-co-glycolide) micropheres using the solid-in-oil-in water technique

Bovine serum albumin (BSA) was encapsulated into poly(lactide-co-glycolide) (PLG) microspheres by a solid-in-oil-in-water (s/o/w) technique. We tested whether perturbations in BSA secondary structure could be minimized during encapsulation by using trehalose and how this would influence BSA aggregation and release. BSA secondary structure was monitored noninvasively by Fourier-transform infrared spectroscopy. When BSA was co-lyophilized with trehalose, lyophilization-induced structural perturbations were significantly reduced. The formulation obtained (BSA-Tre) was encapsulated into PLG microspheres and, by optimizing critical encapsulation parameters, a loading efficiency of 85% was achieved. However, due to the loss of the excipient in the o/w emulsion step, the structure of BSA-Tre was more perturbed than before encapsulation. Excipient-loss and encapsulation-induced structural perturbations could be prevented by saturating the aqueous phase in the o/w step with trehalose and by using the organic solvent chloroform. This in turn reduced the formation of soluble BSA aggregates. BSA was released from PLG microspheres using the improved formulations with an initial release in 24 h of not more than 22%, followed by a sustained release over at least 2 weeks. In summary, optimization of the encapsulation conditions in the s/o/w procedure resulted in the encapsulation of BSA without procedure-induced structural perturbations and minimized the release of aggregated protein. This demonstrates that the s/o/w technique is an excellent alternative to the most common encapsulation procedure, namely the water-in-oil-in-water technique.     

重组人干扰素α2b聚乳酸乙醇酸共聚物微球在大鼠体内的药动学研究

目的:考察重组人干扰素α2b聚乳酸乙醇酸共聚物(PLGA)微球在大鼠体内的药动学特征。方法:首先对双抗体夹心酶联免疫吸附法用于大鼠血清中干扰素α2b浓度测定进行了方法学考察,然后给2组大鼠分别肌内注射1MIU重组人干扰素α2b的市售注射用灭菌粉末和PLGA微球,按不同时间点取全血,分离血清,测定血清中的干扰素α2b浓度,用3p97软件计算药动学参数。结果:所建立的浓度测定方法可满足药动学研究的方法学要求;大鼠肌内注射2种制剂后,药动学特征均符合二室模型,tmax、t1/2β、AUC分别为0·72h和1·39h、22·71h和33·32h、21668·72和38655·87pg·mL·h-1。与注射用灭菌粉末相比,微球组的tmax、t1/2β明显延长,AUC值增加。结论:所制干扰素α2bPLGA微球在大鼠体内具有较明显的缓释特征。     

紫杉醇微球的处方工艺优化及其体外释放性研究

目的:优化紫杉醇聚[1,3-双(对羧基苯氧基)丙烷-癸二酸](P(CPP∶SA))微球处方工艺并评价其体外释放行为。方法:采用单乳化法制备药物缓释微球,以正交试验研究制备时搅拌速度(A)、处方中P(CPP∶SA)浓度(B)和乳化剂聚乙烯醇(PVA)的浓度(C)对微球包封率的影响;观察优化条件后制备的微球的外观形态,评价其体外释放行为。结果:当A为4000r.min-1、B为80mg.mL-1、C为1%时,所得微球形态完整,紫杉醇的包封率达到90%以上,体外持续释放30d,累积释药率达80%以上。结论:用优化条件制备的微球中紫杉醇的包封率高,并具有良好的体外缓释性。     

Optimisation of aciclovir poly(D,L-lactide-co-glycolide) microspheres for intravitreal administration using a factorial design study

The purpose of this work was to obtain an optimised long-term aciclovir PLGA microspheres formulation for intravitreal administration to minimise, as much as possible, the dose of microspheres to be administered with a suitable particle size for its injection through a 27G needle in a single dose. Microspheres were prepared by the solvent evaporation method. To obtain the optimum formulation a two-factor five-level central rotatable composite 2(2) + star design was employed. The independent variables were aciclovir and gelatin (added to the external phase of the emulsion). The dependent variables were the yield of production (%), the encapsulation efficiency (%), the initial burst release (%), the cumulative amount released from 1 to 14 days and the amount of aciclovir at the end of the release assay (microg aciclovir/mg microspheres). The best formulation according to the studied variables was (0,0), prepared with 80 mg of aciclovir and 80 mg of gelatin. This formulation showed good yield of production (70.14 +/- 3.72 %) and encapsulation efficiency ( 70.77 +/- 2.62 %), and released the drug at a constant rate for 63 days with a mean release constant of 1.73 +/- 0.08 microg/day per mg microspheres. The selected formulation reduces a 40% the dose of microspheres to be administered through a 27G needle with respect to previous studies.     

Formulation,development, and performance evaluation of metoclopramide HCl oro-dispersible sustained release tablet

The present study was undertaken to develop and evaluate an oro-dispersible, sustained release tablet of metoclopramide HCl. The technology was comprised of developing sustained release microparticles, and compression of resultant microspheres into a fast dispersible tablet by direct compression. The microspheres of metoclopramide HCl were prepared by an emulsification-solvent evaporation method using ethylcellulose as the matrix polymer. The prepared microspheres were evaluated for morphology, particle size, entrapment efficiency, and in vitro drug release characteristics. Scanning electron microscopy demonstrated spherical particles with a mean diameter of 81.27 ± 5.87 μm and the drug encapsulation efficiency was found to be 70.15 ± 3.06%. The process and formulation variables such as rotation speed, polymer concentration, and drug concentration influenced the drug encapsulation efficiency and in vitro drug release. Optimized microspheres were compressed into tablets which were comprised of metoclopramide HCl microspheres, 53% (w/v) of D-mannitol granules, 7% (w/w) of Polyplasdone XL 10, and 0.5% (w/w) of calcium stearate. The tablets demonstrated a hardness of 59 ± 3 N, friability of 0.21% and disintegration time of 27 ± 3 sec. The formulations were subjected to stability studies as per ICH guidelines and were found to be stable after a 6 month study. In vivo experiments conducted in rats demonstrated that a constant level of metoclopramide HCl in plasma could be maintained for up to 20 h at a suitable concentration for antiemetic activity. An appropriate combination of excipients made it possible to obtain orally disintegrating sustained release tablets of metoclopramide HCl using simple and conventional techniques.     

Preparation and characterization of spray-dried mucoadhesive microspheres of ketorolac for nasal administration

The objective of this investigation was to prepare mucoadhesive microspheres of ketorolac for nasal delivery to avoid gastrointestinal side effects of conventional dosage form. Mucoadhesive microspheres were prepared using carbopol, polycarbophil and chitosan as polymer by spray drying method. The process and formulation parameters were varied to study the effect on the yield and particle size. Microspheres were characterized for surface morphology, encapsulation efficiency, swelling behavior, mucoahesion properties, interaction studies using FTIR and DSC, in vitro drug release, ex vivo nasal cilio toxicity studies and in vivo anti-inflammatory and analgesic activity. Prepared microspheres were discrete, bulky, free flowing and showed an average encapsulation efficiency ranging from 79-92%. The results showed that the process parameters significantly affect the particle size (10.29-16.75 μm) and yield of microspheres (36.53-56.69%). Interaction studies revealed that there were no drug to polymer interactions. Prepared microspheres exhibited good swelling and mucoadhesion strength which confined the strong mucoadhesive property of microspheres. Ketorolac release from the microspheres was extended up to 8 h and exhibited fickian drug release kinetics with best fit to higuchi model. The drug loaded microspheres were found to be nontoxic to nasal mucosa. The anti-inflammatory and analgesic effects of formulation showed a significant increase (p < 0.05) in percent inhibition value of up to 8 h when compared with ketorolac. In conclusion, spray dried microspheres based on chitosan could be suitable nasal delivery system for the administration of ketorolac.     

β-methasone-containing biodegradable poly(lactide-co-glycolide) acid microspheres for intraarticular injection: effect of formulation parameters on characteristics and in vitro release

A sustained drug release system based on the injectable poly(lactic-co-glycolic acid) (PLGA) microspheres loaded with β-methasone was prepared for localized treatment of rheumatic arthritis. The microscopy and structure of microspheres were characterized by scanning electron microscope (SEM) and Fourier transform infrared (FTIR). The effects of various formulation parameters on the properties of microspheres and in vitro release pattern of β-methasone were also investigated. The results demonstrated that increase in drug/polymer ratio led to increased particle size as well as drug release rate. Increase in PLGA concentration led to increased particle size, but decreased burst release. The drug encapsulation efficiency increased sharply by increasing polyvinyl alcohol (PVA) concentration in the aqueous phase from 1.5 to 2.0%. β-methasone release rate decreased considerately with decreasing OP (organic phase)/AP (aqueous phase) volume ratio. Stirring rate had significantly influence on the particle size and encapsulation efficiency. Independent of formulation parameters, β-methasone was slowly released from the PLGA microspheres over 11 days. The drug release profile of high drug loaded microspheres agree with Higuchi equation with a release mechanism of diffusion and erosion, that of middle drug loaded microspheres best agreed with Hixcon-Crowell equation and controlled by diffusion and erosion as well. The low drug loaded microspheres well fitted to logarithm normal distribution equation with mechanism of purely Fickian diffusion.     

Chitosan microspheres of aceclofenac: In vitro and in vivo evaluation

The objective of this investigation was to achieve controlled drug release of Aceclofenac (ACE) microspheres and to minimize local side-effects in the gastrointestinal tract (GIT). Sustained release chitosan microspheres containing ACE were prepared using double-emulsion solvent evaporation method (O/W/O). Chitosan microspheres were prepared by varying drug to polymer ratio (1:3, 1:4, 1:5 and 1:6). Microspheres were characterized for morphology, swelling behavior, mucoadhesive properties, FTIR and DSC study, drug loading efficiency, in vitro release, release kinetics, and in vivo study was performed on rat model. ACE-loaded microspheres were successfully prepared having production yield, 57–70% w/w. Drug encapsulation efficiency was ranging from 53–72% w/w, Scanning electron microscopy (SEM) revealed particle size of microspheres was between 39 and 55 μm. FTIR spectra and DSC thermograms demonstrated no interaction between drug and polymer. The in vitro release profiles of drug from chitosan microspheres showed sustained-release pattern of the drug in phosphate buffer, pH 6.8. In vitro release data showed correlation (r² > 0.98), good fit with Higuchi/Korsmeyer-Peppas models, and exhibited Fickian diffusion. ACE microspheres demonstrated controlled delivery of aceclofenac and apparently, no G.I.T. erosion was noticed.     

Biodegradable bromocryptine mesylate microspheres prepared by a solvent evaporation technique. I: Evaluation of formulation variables on microspheres characteristics for brain delivery

The aim of this study was to formulate biodegradable microspheres containing an anti-parkinsonian agent, bromocryptine mesylate, for brain delivery. The effect of formulation parameters (e.g. polymer, emulsifying agent type and concentration) on the characteristics of the microspheres produced, the efficiency of drug encapsulation, the particle size distribution and in vitro drug release rates from the bromocryptine mesylate microspheres were investigated using a 3 2 factorial design. Bromocryptine mesylate was encapsulated into biodegradable polymers using the following three different polymers; poly(L-lactide), poly(D,L-lactide) and poly(D,L-lactide-co-glycolide). The SEM photomicrographs showed that the morphology of the microspheres greatly depended on the polymer and emulsifying agent. The results indicate that, regardless of the polymer type, increase in emulsifying agent concentration from 0.25-0.75% w/v markedly decreases the particle size of the microspheres. Determination of particle size revealed that the use of 0.75% w/v of emulsifying agent concentration and a polymer solution concentration of 10% w/v resulted in optimum particle size. In order to prepare biodegradable microspheres with high drug content and small particle size, selection of polymer concentration as well as emulsifying agent concentration is critical. Polymer type has a less pronounced effect on the percentage encapsulation efficiency and particle size of microspheres than on the t 50% . The microspheres prepared by all three polymers, at a polymer concentration of 10% w/v and an emulsifying agent concentration of 0.75% w/v with NaCMC:SO (4:1, w/v) mixture was as the optimum formulation.     

Biodegradable bromocryptine mesylate microspheres prepared by a solvent evaporation technique. I: Evaluation of formulation variables on microspheres characteristics for brain delivery

The aim of this study was to formulate biodegradable microspheres containing an anti-parkinsonian agent, bromocryptine mesylate, for brain delivery. The effect of formulation parameters (e.g. polymer, emulsifying agent type and concentration) on the characteristics of the microspheres produced, the efficiency of drug encapsulation, the particle size distribution and in vitro drug release rates from the bromocryptine mesylate microspheres were investigated using a 3(2) factorial design. Bromocryptine mesylate was encapsulated into biodegradable polymers using the following three different polymers; poly(L-lactide), poly(D,L-lactide) and poly(D,L-lactide-co-glycolide). The SEM photomicrographs showed that the morphology of the microspheres greatly depended on the polymer and emulsifying agent. The results indicate that, regardless of the polymer type, increase in emulsifying agent concentration from 0.25-0.75% w/v markedly decreases the particle size of the microspheres. Determination of particle size revealed that the use of 0.75% w/v of emulsifying agent concentration and a polymer solution concentration of 10% w/v resulted in optimum particle size. In order to prepare biodegradable microspheres with high drug content and small particle size, selection of polymer concentration as well as emulsifying agent concentration is critical. Polymer type has a less pronounced effect on the percentage encapsulation efficiency and particle size of microspheres than on the t(50%). The microspheres prepared by all three polymers, at a polymer concentration of 10% w/v and an emulsifying agent concentration of 0.75% w/v with NaCMC:SO (4:1, w/v) mixture was as the optimum formulation.     

PLGA微球的制备及其用于脉冲给药的初步研究

目的：制备聚乳酸-羟基乙酸共聚物（PLGA）微球,并考察其用于脉冲式释药系统的可行性。方法：以牛血清白蛋白（BSA）为模型药物,用S/O/W（Solid-in-oil-in-water）法和S/O/O（Solid-in-oil-in-oil）法制备PLGA（75：25）和PLGA（50：50）微球,比较2种方法制备的微球的表面形态、包封率及载药量等,并考察2种微球的体外释放行为。结果：S/O/W法和S/O/O法制备的微球均圆整、无粘连、形态良好,但S/O/W法制备的微球表面较为平整,而S/O/O法表面均匀分布有较大的凹陷。S/O/W法制备的PLGA（75：25）和PLGA（50：50）微球包封率分别为（60.15±5.95）%、（49.50±3.69）%,载药量分别为（2.56±0.25）%、（2.10±0.16）%,10h内药物释放均为10%左右,而后随着聚合物的降解药物的释放量突然增加;S/O/O法所制微球包封率分别为（84.36±1.11）%、（77.94±1.42）%,载药量分别为（3.58±0.05）%、（3.31±0.06）%,24h内药物释放均可达50%左右,而后呈现较为平稳的释放行为。S/O/O法制备的微球包封率及载药量均较S/O/W法高;S/O/W法制备的PLGA微球药物释放呈现一定的脉冲行为,其中PLGA（75：25）微球体外释放行为受微球粒径的影响较大。结论：S/O/W法制备的PLGA微球具有一定的脉冲式释药效果,微球的粒径最好控制在120μm以下。     

丙氨瑞林微球制备工艺优化和体外释放研究

目的:制备包封率高、可持续释药35 d的丙氨瑞林微球.方法:以生物可降解聚合物聚乳酸-聚羟基乙酸(PLGA)为载体,采用W/O/W复乳溶剂挥发法制备缓释丙氨瑞林微球,以包封率为观察指标,用正交设计L9(34)对微球制备工艺进行优化.在pH=7.0的磷酸盐缓冲溶液中考察微球的体外释放.结果:经优化工艺制备的丙氨瑞林微球包封率为(93.2±1.6)％,90％的微球粒径分布范围为55～65 μm.在选择的释放条件下,至35 d时,药物累积释放92.3％,突释为9.7％.结论:该制备工艺简单、稳定.优化条件下制备的丙氨瑞林微球包封率高、粒径适宜、突释少.     

In vitro modified release of acyclovir from ethyl cellulose microspheres

The aim of this study was to demonstrate a sustained-release microparticulate dosage form for acyclovir via an in vitro study. Ethyl cellulose was selected as a model encapsulation material. All of the microspheres were prepared by an oil-in-water solvent evaporation technique. A 2(3) full factorial experiment was applied to study the effects of the viscosity of polymer, polymer/drug ratio, and polymer concentration on the drug encapsulation efficiency and the dissolution characteristics. The encapsulation efficiency of acyclovir in microspheres was in the range of 20.0-56.6%. Increase in the viscosity of ethyl cellulose and the ratio of CH2Cl2/ethyl cellulose increased drug encapsulation efficiency. The drug continuously released from microspheres for at least 12 h, and the release rate depended on the pH of the release medium. The sustained release characteristic was more prominent in the simulated intestine fluid than in the simulated gastric fluid. A faster release of drug was observed when a high viscosity polymer was used. The decomposition of acyclovir significantly decreased when encapsulated by ethyl cellulose, especially when stored at 37 and 50 degrees C.