An Anti-Inflammatory Drug (Mefenamic Acid) Incorporated in Biodegradable Alginate Beads: Development and Optimization of the Process Using Factorial Design

The objective of this study was to prepare and evaluate biodegradable alginate beads as a controlled-release system for a water-insoluble drug, mefenamic acid (MA), using 3 × 2² factorial design by ionotropic gelation method. Therefore, the mefenamic acid dispersion in a solution of alginate was dropped into the cross-linking CaCl₂ solution and a fairly high yield (71–89%) of MA-alginate beads were obtained. Their encapsulation efficiencies were in the range of 79.3–98.99%. The effect of drug:polymer ratio, CaCl₂ concentration, and curing time on the time for 50% of the drug to be released (t_50%), and the drug entrapment efficiency were evaluated with factorial design method. It was found that drug:polymer ratio and interaction of drug:polymer ratio and curing time had an important effect on the drug to be released (t_50%). The effect of CaCl₂ concentration is also important on the drug release. On the other hand, all factors except CaCl₂ concentration were effective on the drug entrapment efficiency. The swelling properties of beads were also studied. The release mechanism was described and found to be non-Fickian, Case II, and Super Case II transport for the formulations. This study suggested a new mefenamic acid alginate bead formulation for oral delivery of nonsteroidal anti-inflammatory drugs, which cause gastric irritation.     

Calcium alginate microparticles for oral administration: II. Effect of formulation factors on drug release and drug entrapment efficiency.

The release rate of nicardipine HCl from various alginate microparticles was investigated. Manugel A7B618 which has a high guluronic acid content of 70% and a low polymerization degree of 60-400 was used as alginate. A 2(3) factorial design was utilized for the preparation of the alginate microparticles. The effect of drug:polymer weight ratio, CaCl2 concentration and curing time on parameters such as the time for 50% of the drug to be released (t50%) and the drug entrapment efficiency were evaluated with analysis of variance. The mean particle sizes and the swelling ratios of the microparticles were determined. The in vitro release studies were carried out with a flow-through cell apparatus at different media (pH 1.2, 2.5, 4.5, 7, 7.5 buffer solutions). Drug:polymer weight ratio and the concentration of the crosslinking agent were the influential factors on the release of NC from the alginate microparticles. The release of nicardipine was extended with alginate microparticles prepared in a ratio of 1:1 (drug:polymer weight ratio). The release of drug from alginate microparticles took place by both diffusion through the swollen matrix and relaxation of the polymer at pH: 1.2-4.5. However, the release was due to diffusion and erosion mechanisms at pH 7-7.5.     

Calcium alginate microparticles for oral administration: II effect of form ulation factors on drug release and drug entrapment efficiency

The release rate of nicardipine HCl from various alginate microparticles was investigated. Manugel A7B618 which has a high guluronic acid content of 70% and a low polymerization degree of 60-400 was used as alginate. A 23 factorial design was utilized for the preparation of the alginate microparticles. The effect of drug:polymer weight ratio, CaCl2 concentration and curing time on parameters such as the time for 50% of the drug to be released (t50%) and the drug entrapment efficiency were evaluated with analysis of variance. The mean particle sizes and the swelling ratios of the microparticles were determined. The in vitro release studies were carried out with a flow-through cell apparatus at different media (pH 1.2, 2.5, 4.5, 7, 7.5 buffer solutions). Drug:polymer weight ratio and the concentration of the crosslinking agent were the influential factors on the release of NC from the alginate microparticles. The release of nicardipine was extended with alginate microparticles prepared in aratio of 1:1 (drug:polymer weight ratio). The release of drug from alginate microparticles took place by both diffusion through the swollen matrix and relaxation of the polymer at pH: 1.2-4.5. However, the release was due to diffusion and erosion mechanisms at pH 7-7.5.     

A Comparative Histological Study of Alginate Beads as a Promising Controlled Release Delivery for Mefenamic Acid

The new mefenamic acid-alginate bead formulation prepared by ionotropic gelation method using 3 × 2² factorial design has shown adequate controlled release properties in vitro. In the present study, the irritation effects of mefenamic acid (MA), a prominent non-steroidal anti-inflammatory (NSAI) drug, were evaluated on rat gastric and duodenal mucosa when suspended in 0.5% (w/v) sodiumcarboxymethylcellulose (NaCMC) solution and loaded in alginate beads. Wistar albino rats weighing 200 ± 50 g were used during in vivo animal studies. In this work, biodegradable controlled release MA beads and free MA were evaluated according to the degree of gastric or duodenal damage following oral administration in rats. The gastric and duodenal mucosa was examined for any haemorrhagic changes. Formulation code A10 showing both Case II transport and zero order drug release and t₅₀ % value of 5.22 h was chosen for in vivo animal studies. For in vivo trials, free MA (100 mgkg^?1), blank and MA (100 mgkg^?1) loaded alginate beads (formulation code A10) were suspended in 0.5% (w/v) NaCMC solution and each group was given to six rats orally by gavage. NaCMC solution was used as a control in experimental studies. In vivo data showed that the administration of MA in alginate beads prevented the gastric lesions.     

A comparative histological study of alginate beads as a promising controlled release delivery for mefenamic acid

The new mefenamic acid-alginate bead formulation prepared by ionotropic gelation method using 3 x 2(2) factorial design has shown adequate controlled release properties in vitro. In the present study, the irritation effects of mefenamic acid (MA), a prominent non-steroidal anti-inflammatory (NSAI) drug, were evaluated on rat gastric and duodenal mucosa when suspended in 0.5% (w/v) sodiumcarboxymethylcellulose (NaCMC) solution and loaded in alginate beads. Wistar albino rats weighing 200 +/- 50 g were used during in vivo animal studies. In this work, biodegradable controlled release MA beads and free MA were evaluated according to the degree of gastric or duodenal damage following oral administration in rats. The gastric and duodenal mucosa was examined for any haemorrhagic changes. Formulation code A10 showing both Case II transport and zero order drug release and t(50) % value of 5.22 h was chosen for in vivo animal studies. For in vivo trials, free MA (100 mgkg(-1)), blank and MA (100 mgkg(-1)) loaded alginate beads (formulation code A10) were suspended in 0.5% (w/v) NaCMC solution and each group was given to six rats orally by gavage. NaCMC solution was used as a control in experimental studies. In vivo data showed that the administration of MA in alginate beads prevented the gastric lesions.     

Reversed chitosan-alginate polyelectrolyte complex for stability improvement of alpha-amylase: optimization and physicochemical characterization.

The present work explores, using response surface methodology, the main and interaction effects of some process variables on the preparation of a reversed chitosan-alginate polyelectrolyte complex (PEC) with entrapped alpha-amylase for stability improvement. A 3(3) full factorial design was used to investigate the effect of the chitosan and alginate concentrations and hardening time on the percent entrapment, time required for 50% (T(50)) and 90% (T(90)) enzyme release, and particle size. The beads were prepared by dropping chitosan containing alpha-amylase into a sodium alginate solution without any salt. The in vitro enzyme release profile of the beads was fitted to various release kinetics models to study the release mechanism. A topographical characterization was carried out using scanning electron microscopy (SEM), and the entrapment was confirmed using Fourier transform infrared (FTIR) spectroscopy and differential scanning calorimetry (DSC). Stability testing was carried out according to the International Conference on Harmonization (ICH) guidelines for zones III and IV. Beads prepared using 2.5%w/v chitosan and 3%w/v sodium alginate with a hardening time of 60 min had more than 90% entrapment and a T(90) value greater than 48 min. Moreover, the shelf-life of the enzyme-loaded beads was found to increase to 3.68 years, compared with 0.99 years for the conventional formulation. It can be inferred that the proposed methodology can be used to prepare a reversed PEC of chitosan and alginate with good mechanical strength, provided both the reactants are in a completely ionized form at the time of the reaction. Proper selection of the reaction pH, polymer concentration and hence charge density, and hardening time is important and determines the characteristics of the PEC.     

Adipic acid dihydrazide treated partially oxidized alginate beads for sustained oral delivery of flurbiprofen

In this study, periodate oxidation of sodium alginate was controlled such that the oxidized alginate could form isolatable beads with Ca⁺² ions. The beads of oxidized alginate having a degree of oxidation 1 mol%, entrapped 89% flurbiprofen and released almost all of its content within 1.5 h in pH 7.2 phosphate buffer solution. The beads were covalently crosslinked with adipic dihydrazide (ADH) in addition to ionic crosslinks and were characterized. Scanning electron microscopy revealed that the beads were spherical having smooth surfaces. The drug entrapment efficiency decreased (90–86%) with increasing concentration of ADH (2–6% w/v) in the gelation medium. However, the beads prolonged the drug release in alkaline dissolution medium up to 8 h depending upon the concentration of ADH. The beads prepared with 2% ADH swelled more rapidly and led to faster drug release in either pH 1.2 HCl solution or pH 7.2 phosphate buffer solution. The swelling tendencies were reduced and the drug release became slower with higher concentrations in either fluid. The drug diffusion from the beads followed super case II transport mechanism. FTIR spectroscopy indicated stable nature of flurbiprofen in the beads and therefore had potential as sustained oral delivery system for the drug.     

Alginate-diltiazem hydrochloride beads: optimization of formulation factors,in vitro and in vivo availability

Alginate beads containing diltiazem hydrochloride (DTZ) were prepared by the ionotropic gelation method. The effects of various factors (alginate concentration, additives type, calcium chloride concentration and curing time) on the efficiency of drug loading were investigated. The formulation containing a mixture of 0.8% methylcellulose (MC) and 4% alginate cured in 2% calcium chloride for 6 h was chosen as the best formula regarding the loading efficiency. The release rate of DTZ from various beads formulations was investigated. The release of drug from alginate beads followed two mechanisms; by diffusion and relaxation of the polymer at pH 1.2, whilst diffusion and erosion are at pH 6.8. The in vitro release of DTZ from MC-alginate beads showed an extended release pattern which was compared with that from commercially available sustained-release (Dilzem SR) and fast release tablets (Dilzem). Thermal analysis revealed that the drug was molecularly dispersed in the beads matrix. Although the release characteristics of DTZ from Dilzem SR and MC-alginate beads were completely different, the bioavailability of DTZ in dogs was comparable as measured by AUC, MRT and relative bioavailability. The absolute bioavailability of MC-alginate beads and Dilzem SR was 88 and 93%, respectively.     

Low density multiparticulate system for pulsatile release of meloxicam

A blend of floating and pulsatile principles of drug delivery system would have the advantage that a drug can be released in the upper GI tract after a definite time period of no drug release. A multiparticulate floating-pulsatile drug delivery system was developed using porous calcium silicate (Florite RE) and sodium alginate, for time and site specific drug release of meloxicam. Meloxicam was adsorbed on the Florite RE (FLR) by fast evaporation of solvent from drug solution containing dispersed FLR. Drug adsorbed FLR powder was used to prepare calcium alginate beads by ionotropic gelation method, using 3(2) factorial design. Developed formulations were evaluated for yield, entrapment efficiency, image analysis, surface topography, mechanical strength, apparent density, buoyancy studies and dissolution studies. Entrapment efficiency of different formulations varied from 70% to 94%. Formulations show a lag period ranging from 1.9 to 7.8 h in acidic medium followed by rapid release of meloxicam in simulated intestinal fluid USP, without enzymes (SIF). Complete drug release in SIF occurred in less than 1h from the formulations. The size of beads varied from 2.0 to 2.7 mm for different batches. Prepared beads were spherical with crushing strength ranging from 182 to 1,073 g. Floating time was controlled by density of beads and hydrophobic character of drug. A pulsatile release of meloxicam was demonstrated by a simple drug delivery system which could be useful in chronopharmacotherapy of rheumatoid arthritis.     

Microencapsulation of a recombinant aminopeptidase (PepN) from Lactobacillus rhamnosus S93 in chitosan-coated alginate beads

A recombinant aminopeptidase (90 kDa) of Lactobacillus rhamnosus S93 produced by E. coli was encapsulated in alginate or chitosan-treated alginate beads prepared by an extrusion method. This study investigated the effects of alginate, CaCl2, chitosan concentrations, hardening time, pH and alginate/enzyme ratios on the encapsulation efficiency (EE) and the enzyme release (ER). Chitosan in the gelling solution significantly increased the EE from 30.2% (control) to 88.6% (coated). This polycationic polymer retarded the ER from beads during their dissolution in release buffer. An increase in alginate and chitosan concentrations led to greater EE and lesser ER from the beads. The greatest EE was observed in a pH 5.4 solution (chitosan-CaCl2) during bead formation. Increasing the CaCl2 concentration over 0.1 M neither affected the EE nor the ER. Increasing hardening time beyond 10 min led to a decrease in EE and the alginate:enzyme ratio (3 : 1) was optimal to prevent the ER.     

海藻酸钙凝胶微丸作为口服缓释给药载体的研究

将海藻酸钠溶液滴入胶凝剂氯化钙溶液中制备了海藻酸钙凝胶微丸。以胶凝过程中凝胶微丸重量变化 (失水量 )研究了胶凝速率及不同浓度海藻酸钠溶液 ( 1 %～ 4 % )与氯化钙溶液 ( 0 0 5～0 2 0mol/L)对胶凝速率的影响 ,结果是 6h前胶凝速率快 ,随后减慢 ,约 70h胶凝完全 ,氯化钙溶液的浓度≥ 0 1mol/L对胶凝速率无明显影响。干燥的凝胶微丸在不同水性介质中溶胀试验结果表明 :在温度约 37℃时 ,微丸在蒸馏水和 0 1mol/L盐酸 ( pH1 0 )中几乎不溶胀 ,而在磷酸盐缓冲溶液( pH6 8)中1h溶胀 ,溶胀后的微丸直径是干燥前湿微丸直径的 1 80 %。海藻酸钙凝胶微丸这种溶胀的 pH敏感性 ,使它能成为口服药物缓释制剂的载体。以硝苯地平为模型药物制备的海藻酸钙凝胶微丸 ,其体外释放试验结果 ,2h累积释放量为 2 0 %～ 30 % ,6h为 6 0 %～ 80 % ,1 2h时大于85 %。药物从微丸中的释放是以扩散和骨架溶蚀相结合的方式。由此可见 ,硝苯地平的海藻酸钙凝胶微丸具有缓释作用     

Biphasic release characteristics of dual drug-loaded alginate beads

The dual drug-loaded alginate beads simultaneously containing drug in inner and outer layers were prepared by dropping plain (single-layered) alginate beads into CaCl₂ solution. The release characteristics were evaluated in simulated gastric fluid for 2 h followed by intestinal fluids thereafter for 12 h. The surface morphology and cross section of dual drug-loaded alginate beads was also investigated using scanning electron microscope (SEM). The poorly water-soluble ibuprofen was chosen as a model drug. The surface of single-layered and dual drug-loaded alginate beads showed very crude and roughness, showing aggregated particles, surface cracks and rough crystals. The thickness of dual drug-loaded alginate beads surrounded by outer layer was ranged from about 57 to 329μm. The distinct chasm between inner and outer layers was also observed. In case of single-layered alginate beads, the drug was not released in gastric fluid but was largely released in intestinal fluid. However, the release rate decreased as the reinforcing Eudragit^® polymer contents increased. When the plasticizers were added into polymer, the release rate largely decreased. The release rate of dual drug-loaded alginate beads was stable in gastric fluid for 2 h but largely increased when switched in intestinal fluid. The drug linearly released for 4 h followed by another linear release thereafter, showing a distinct biphasic release characteristics. There was a difference in the release profiles between single-layered and dual drug-loaded alginate beads due to their structural shape. However, this biphasic release profiles were modified by varying formulation compositions of inner and outer layer of alginate beads. The release rate of dual drug-loaded alginate beads slightly decreased when the outer layer was reinforced with Eudragit^® RS100 polymers. In case of dual drug-loaded alginate beads with polymer-reinforced outer layer only, the initial amount of drug released was low but the initial release rate (slope) was higher due to more swellable inner cores when compared to polymer-reinforced inner cores. The current dual drug-loaded alginate beads may be used to deliver the drugs in a time dependent manner.     

Release characteristics of brilliant blue from calcium-alginate beads coated with quaternized chitosan

Calcium-alginate beads coated with quaternized chitosan were prepared in a neutral environment, and morphologies were observed by SEM. Optimum conditions for the encapsulation and retention of a model drug (brilliant blue, BB) in acid were obtained from studies of preparation conditions, including alginate and quaternized chitosan concentration, calcium chloride (CaCl2) concentration in the gelling medium and by comparing one-step and two-step preparation methods. Results showed that very high BB encapsulation efficiency (99%, w/w) and low leakage in acid (8%, w/w) was achieved from dry beads when 2.0% (w/v) alginate was dropped into 1.0% (w/v) CaCl2 containing 0.3% (w/v) quaternized chitosan by a one-step method. The release of BB in 0.9% (w/v) NaCl was modulated by coating calcium-alginate with different weight average molecule weight (Mw) and degree of substitution (DS) of quaternized chitosan. A decreased of Mw accelerated the release of BB and a high DS value significantly decreased the release in 0.9% (w/v) NaCl.     

5-Fluorouracil encapsulated alginate beads for the treatment of breast cancer

Alginate beads containing 5-fluorouracil (5-FU) were prepared by the gelation of alginate with calcium cations. Alginate beads loaded with 5-FU were prepared at 1.0 and 2.0% (w/v) polymers. The effect of polymer concentration and the drug loading (1.0, 5.0 and 10%) on the release profile of 5-FU was investigated. As the drug load increased, larger beads were obtained in which the resultant beads contained higher 5-FU content. The encapsulation efficiencies obtained for 5-FU loads of 1.0, 5.0 and 10% (w/v) were 3.5, 7.4 and 10%, respectively. Scanning electron microscopy (SEM) and particle size analysis revealed differences between the formulations as to their appearance and size distribution. The amount of 5-FU released from the alginate beads increased with decreasing alginate concentrations.     

Preparation andin vitro release of melatonin-loaded multivalent cationic alginate beads

The sustained release dosage form which delivers melatonin (MT) in a circadian fashion over 8 h is of clinical value for those who have disordered circadian rhythms because of its short half-life. The purpose of this study was to evaluate the gelling properties and release characteristics of alginate beads varying multivalent cationic species (Al⁺⁺⁺, Ba⁺⁺, Ca⁺⁺, Mg⁺⁺, Fe⁺⁺⁺, Zn⁺⁺). The surface morphologies of Ca- and Ba-alginate beads were also studied using scanning electron microscope (SEM). MT, an indole amide pineal hormone was used as a model drug. The Ca⁺⁺, Ba⁺⁺, Zn⁺⁺, Al⁺⁺⁺, and Fe⁺⁺⁺ ions except Mg⁺⁺ induced gelling of sodium alginate. The strength of multivalent cationic alginate beads was as follows: Al⁺⁺⁺?Fe⁺⁺⁺<Zn⁺⁺<Ca⁺⁺?Ba⁺⁺. In case of Al⁺⁺⁺, the induced hydrogel beads were very fragile and less spherical. Fe-alginate beads were also fragile but stronger compared to Al-alginate beads. Ba-alginate beads, had a similar gelling strength but was less spherical when compared to Ca-alginate beads. Zn-alginate beads were weaker than Ca- and Ba-alginate beads. Very crude and rough crystals of Ba- and Ca-alginate beads at higher magnifications were observed. However, the type and shape of rough crystals of Ba- and Ca-alginate beads were quite different. No significant differences in release profiles from MT-loaded multivalent cationic alginate beads were observed in the gastric fluid. Most drugs were continuously released upto 80% for 5 h, mainly governed by the passive diffusion without swelling and disintegrating the alginate beads. In the intestinal fluid, there was a significant difference in the release profiles of MT-loaded multivalent cationic alginate beads. The release rate of Ca-alginate beads was faster when compared to other multivalent cationic alginate beads and was completed for 3 h. Ba-alginate beads had a very long lag time (7 h) and then rapidly released thereafter. MT was continuously released from Fe-and Zn-alginate beads with initial burstout release. It is assumed that the different release profiles of multivalent cationic alginate beads resulted from forces of swelling and disintegration of alginate beads in addition to passive diffusion, depending on types of multivalent ions, gelling strength and drug solubility. It was estimated that 0.2 M CaCl₂ concentration was optimal in terms of trapping efficiency of MT and gelling strength of Ca-alginate beads. In the gastric fluid, Ca-alginate beads gelled at 0.2 M CaCl₂ concentration had higher bead strength, resulting in the most retarded release when compared to other concentrations. In the intestinal fluid, the decreased release of Ca-alginate beads prepared at 0.2 M CaCl₂ concentration was also observed. However, release profiles of Ca-alginate beads were quite similar regardless of CaCl₂ concentration. Either too low or high CaCl₂ concentrations may not be useful for gelling and curing of alginate beads. Optimal CaCl₂, concentrations must be decided in terms of trapping efficiency and release profiles of drug followed by curing time and gelling strength of alginate beads.     

Release characteristics of diclofenac sodium from poly(vinyl alcohol)/sodium alginate and poly(vinyl alcohol)-grafted-poly(acrylamide)/sodium alginate blend beads.

In this study, acrylamide (AAm) was grafted onto poly(vinyl alcohol) (PVA) with UV radiation at ambient temperature. The graft copolymer (PVA-g-PAAm) was characterized by using Fourier transform infrared spectroscopy (FTIR), elemental analysis and differential scanning calorimetry (DSC). Polymeric blend beads of PVA-g-PAAm and PVA with sodium alginate (NaAlg) were prepared by cross-linking with glutaraldehyde (GA) and used to deliver a model anti-inflammatory drug, diclofenac sodium (DS). Preparation condition of the beads was optimized by considering the percentage entrapment efficiency, particle size, swelling capacity of beads and their release data. Effects of variables such as PVA/NaAlg ratio, acrylamide content, exposure time to GA and drug/polymer ratio on the release of DS were discussed at three different pH values (1.2, 6.8, 7.4). It was observed that, DS release from the beads decreased with increasing PVA/NaAlg (m/m) ratio, drug/polymer ratio (d/p) and extent of cross-linking. However, DS release increased with increasing acrylamide content of the PVA-g-PAAm polymer. The highest DS release was obtained to be 92% for 1/1 PVA-g-PAAm/NaAlg ratio beads. It was also observed from release results that DS release from the beads through the external medium is much higher at high pH (6.8 and 7.4) than that at low pH (1.2). The drug release from the beads mostly followed Case II transport.     

In vitro and in vivo investigation of low molecular weight heparin–alginate beads for oral administration

Abstract

Low molecular weight heparin (LMWH) and standard heparin are widely used anticoagulants. However, they have very poor oral bioavailability and have to be administered by the parenteral route. Alginates are biodegradable, biocompatible and mucoadhesive polymers which can be used for advantage for the oral administration of LMWH. The aim of the study was to develop LMWH–alginate beads for oral delivery. Alginate beads were prepared based on the 2³ factorial design. In vitro characterization studies of the beads were carried out. In vivo studies were performed on rabbits. The LMWH solutions (5000?IU/kg, with and without 5% dimethyl-β-cyclodextrin), as well as the LMWH–alginate beads were administered to rabbits. The IV solution was also administered (100?IU/kg). The anti-Xa activity was measured in plasma. Area under curve (AUC) and C_max values were determined. Histological investigations were also carried out. The formulation consisting of a 1:2 drug/alginate ratio and cured using 0.5?M CaCl₂ for 15?min gave the best result in terms of encapsulation efficiency and the time for 50% of the drug to be released (t_50%). A significantly higher bioavailability was observed for LMWH–alginate beads than for LMWH solutions. It was concluded that, anticoagulant effectiveness was achieved using alginate beads containing LMWH after oral administration to the rabbits.     

Preparation and release characteristics of polymer-reinforced and coated alginate beads

Polymeric reinforcement and coatings of alginate beads were carried out to control the release rate of drug from alginate beads. A poorly water-soluble ibuprofen (IPF) was selected as a model drug. A commercially available Eudragit^® RS100 was also used as a polymer. Effects of polymeric contents, the presence of plasticizers and amount of drug loading on the release rate of drug were investigated. The release rate of drug from alginate beads in the simulated gastric fluid did not occur within 2 h but released immediately when dissolution media were switched to the simulated intestinal fluid. No significant difference of release rate from polymer-reinforced alginate bead without plasticizers was observed when compared to plain (simple) beads. However, the release rate of drug from polymer-reinforced alginate beads was further sustained and retarded when aluminium tristearate (AT) as a plasticizer was added to polymer. However, polyethylene glycol 400 (PEG400) did not change the release rate of drug from alginate beads although PEG400 was used to improve dispersion of polymer and sodium alginate, and plasticize Eudragit^® RS100 polymer. The presence of plasticizer was crucial to reinforce alginate gel matrices using a polymer. As the amount of drug loading increased, the release rate of drug increased as a result of decreasing effects of polymer contents in matrices. The significantly sustained release of drug from polymer-coated alginate beads occurred as the amount of polymer increased because the thickness of coated membrane increased so that cracks and pores of the outer surface of alginate beads could be reduced. The sustained and retarded action of polymer-reinforced and coated beads may result from the disturbance of swelling and erosion (disintegration) of alginate beads. From these findings, polymeric-rein-forcement and coatings of alginate gel beads can provide an advanced delivery system by retarding the release rate of various drugs.     

酮洛芬果胶钙凝胶小球和海藻酸钙凝胶小球的制备及性能比较

目的酮洛芬果胶钙凝胶小球和酮洛芬海藻酸钙凝胶小球的制备及性能比较。方法利用果胶、海藻酸钠及二者不同比例,以酮洛芬为模型药物采用滴制法制备凝胶小球,考察2种多糖物质对药物包封率和释放行为的影响。利用大鼠肠囊外翻实验对凝胶小球的生物黏附性能进行比较,通过对释放机理的探讨和凝胶小球溶胀性的测定进一步证明2种凝胶小球释药行为的不同。结果酮洛芬果胶钙凝胶小球和酮洛芬海藻酸钙凝胶小球均具有良好的生物黏附性能,果胶钙凝胶小球主要通过溶胀作用缓慢释药,而海藻酸钙凝胶小球的释药与凝胶小球慢慢吸水后骨架溶蚀有关。结论酮洛芬果胶钙凝胶小球和酮洛芬海藻酸钙凝胶小球通过与生物黏膜的紧密结合缓慢释药,而二者的释放行为有所不同。     

Formulation optimization and <Emphasis Type="Italic">in vivo</Emphasis> evaluation of mucoadhesive xyloglucan microspheres

Mucoadhesive microspheres of the novel polymer, xyloglucan, have been formulated and their performance characteristics have been systematically evaluated in vitro and in vivo. The mucoadhesive microspheres were obtained by incorporating glipizide as model drug in xyloglucan as a mucoadhesive polymer and sodium alginate as a gel-forming polymer by the orifice-ionic gelation method. A3² factorial design was employed to study the effect of independent variables, xyloglucan concentration (X ₁ ) and calcium chloride (CaCl₂) concentration (X ₂ ), on the dependent variables including drug entrapment efficiency, release time (t ₈₀), and percentage mucoadhesion in 1h. The best batch exhibited high drug entrapment efficiency (92.98%) and percentage mucoadhesion (78% after 1h). The drug release was also controlled for more than 8 hours. In vivo testing of the mucoadhesive microspheres revealed significant hypoglycemic effect of glipizide.