Sustained release of hydrophobic and hydrophilic drugs from a floating dosage form

Floating dosage forms enable the sustained delivery of drugs in the gastro-intestinal tract. In this study, a type of multi-unit floating gel bead was synthesized with calcium alginate, sunflower oil, and a drug of interest through an emulsification/gelation process. The alginate beads with oil addition were able to continuously float over the medium for 24h under constant agitation while the non-oily beads could not. Three kinds of drugs with different hydrophilicities, ibuprofen, niacinamide and metoclopramide HCl, were tested in the study. The hydrophobic drug ibuprofen was released in a sustained manner for 24h, due to the oil partitioning. With suitable modification, the beads were able to also release the hydrophilic drugs, niacinamide and metoclopramide HCl, for a similar duration. Therefore a floating dosage form that is able to sustain release both hydrophobic and hydrophilic drugs within its extended gastric retention time has been developed.     

Box-Behnken效应面法优化盐酸左氧氟沙星胃漂浮缓释片处方

目的：探讨Box-behnken效应面法在优化盐酸左氧氟沙星胃漂浮缓释片处方过程中的应用。方法：以盐酸左氧氟沙星为模型药物,采用湿法制粒压片法制备左氧氟沙星胃漂浮缓释片剂。利用Box-behnken实验设计,考察三种缓释材料HPMCK 4M、卡泊姆CP934P及海藻酸钠(SA)对不同时间点释药性能和对漂浮片漂浮性能的影响,通过二项式方程拟合建立因素与响应值之间的数学关系以优化处方,对体外释药数据进行方程拟合,探讨其释药机理。结果：通过优化后的最佳处方为HPMC K4M 30 %、卡泊姆CP934P 12.3 %、海藻酸钠(SA) 28.6%,优化处方的实测值与预测值之间的偏差较小;药物的释药机制为骨架溶蚀与药物扩散双重作用。结论：Box-behnken效应面法优化法建立的模型可以用于盐酸左氧氟沙星缓释片处方的优化。     

Formulation and evaluation of oil entrapped gastroretentive floating gel beads of loratadine

A gastro retentive controlled release system of loratadine was formulated to increase the residence time in stomach and to modulate the release behaviour of the drug. Oil entrapped floating microbeads prepared by the emulsion gelation method were optimized by 23 factorial design and a polymer ratio of 2.5:1.5 (pectin/sodium alginate) by mass, 15% (m/V) of oil (mineral oil or castor oil) and 0.45 mol L(-1) calcium chloride solution as the optimized processing conditions for the desired buoyancy and physical stability. In vitro drug release in the fed state conditions demonstrated sustained release of loratadine for 8 h, which best fitted the Peppas model with n<0.45. The ethyl cellulose coating on microbeads optimized by 22 factorial design resulted in a controlled release formulation of loratadine that provided zero-order release for 8 h.     

Comparison and Suitability of Gel Matrix for Entrapping Higher Content of Enzymes for Commercial Applications

To check the suitability of enzyme entrapped beads for use in pharmaceutical industry, amylase enzyme was entrapped in agar/agarose, polyacrylamide gels and calcium alginate beads. Sodium alginate of 1% concentration was found to be best with respect to immobilization efficiency and calcium alginate beads so obtained were not much susceptible to breakage. When sodium alginate- amylase mixture was added from a height of about 20-30 cm. into CaCl₂ solution, size of beads was large at higher alginate concentration due to the increase in the size of droplet formation before entering into CaCl₂ solution. Enzyme entrapped polyacrylamide and agar/agarose gels were fragile and could not withstand repeated use whereas enzyme entrapped in large calcium alginate beads was used successfully for 50 cycles for the conversion of starch into product without much damage to the beads under stirring conditions. Amylase preparation was also mixed with urease, lysozyme and coimmobilized in large sized calcium alginate beads. These beads were used for 10 repeated cycles to check the conversion of substrates into their products by their respective enzymes and we concluded that an enzyme or mixture of two or three enzymes can be immobilized in the same large sized calcium alginate beads. This will save the additional cost of bioreactor, manpower, maintenance conditions required for the conversion of one drug into another using enzyme/s entrapped in large sized beads.     

Formulation and In Vitro evaluation of pH sensitive oil entrapped polymeric blended gellan gum buoyant beads of clarithromycin

Background and the purpose of the study

A gastroretentive pH sensitive system has been a frontier approach to release the drug in controlled manner in stomach and duodenum. The aim of this study was to develop buoyant beads of gellan based, wherein, the oil was entrapped, blended with hydroxypropyl methyl cellulose or carbopol 934 in order to evaluate its potential for targeted sustained delivery of clarithromycin in the gastric region.

Methods

Buoyant beads of gellan was developed by inotropic gelation technique using calcium carbonate as gas forming agent and the drug polymer dispersion was emulsified with mineral oil. The oil was entrapped and blended with hydroxypropyl methyl cellulose or carbopol 934. The developed beads were evaluated in terms of diameter,% floating, encapsulation efficiency, In vitro drug release, In vivo gastric residence efficacy and clarithromycine concentration in the mucosa of the experimental animal model.

Results

The scanning electron microscope photograph indicated that the prepared beads were spherical in shape and buoyancy, encapsulation efficiency and drug content obtained from all batches were satisfactory. Particle size and percentage buoyancy of the gel beads increased by raising the concentration of calcium carbonate. The formulation exhibited sustained release profile and was best fitted in the Peppas model with n<0.45. Subsequent coating of microbeads exhibited zero-order sustained pattern of the drug release up to 8 hrs. Batch B₄ showed comparatively better residence and the drug concentration in the gastric mucosa of the treated animals.

Conclusion

The result provides evidence that the prepared optimized formulation may be used effectively for pH sensitive gastric targeted antibiotic such as clarithromycin.     

Evaluation of drug release kinetics and physico-chemical characteristics of metronidazole floating beads based on calcium silicate and gas-forming agents

In the present investigation metronidazole-loaded alginate beads consisting of calcium silicate as a porous carrier or NaHCO₃ as a gas-forming agent were prepared for local eradication of Helicobacter Pylori. Gelation method was used for preparation of conventional sodium alginate beads. Drug entrapment efficiency, drug loading, floating properties, drug release, crystallinity and release kinetic as well as morphology of the prepared beads were assessed. The silicate based beads showed slower release pattern, compared to the gas-forming beads due to network structure strengthening effect of the calcium silicate. Furthermore, the gas-forming-based beads had shorter initial buoyancy lag time, owing to the fact that the NaHCO₃ produced larger pores than those of silicate treated ones. Drug entrapment efficiency ranged between 61.7 and 93.1% for the prepared formulations. The maximum value of drug loading for gas-forming and silicate-based beads were 66.64% and 34.97%, respectively. Kinetically, release pattern of metronidazole in simulated gastric fluid from the beads fitted best to Reciprocal powered time, Weibull and log-probability models with the respect overall mean percentage error values of 4.50, 5.30 and 7.76. By and large, these systems can float in the gastric condition and control the drug release from the beads.     

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。     

Floating dosage forms to prolong gastro-retention--the characterisation of calcium alginate beads

Floating calcium alginate beads, designed to improve drug bioavailability from oral preparations compared with that from many commercially available and modified release products, have been investigated as a possible gastro-retentive dosage form. A model drug, riboflavin, was also incorporated into the formula.

The aims of the current work were (a) to obtain information regarding the structure, floating ability and changes that occurred when the dosage form was placed in aqueous media, (b) to investigate riboflavin release from the calcium alginate beads in physiologically relevant media prior to in vivo investigations.

Physical properties of the calcium alginate beads were investigated. Using SEM and ESEM, externally the calcium alginate beads were spherical in shape, and internally, air filled cavities were present thereby enabling floatation of the beads. The calcium alginate beads remained buoyant for times in excess of 13 h, and the density of the calcium alginate beads was <1.000 g cm⁻³. Riboflavin release from the calcium alginate beads showed that riboflavin release was slow in acidic media, whilst in more alkali media, riboflavin release was more rapid.

The characterisation studies showed that the calcium alginate beads could be considered as a potential gastro-retentive dosage form.     

Preparation of a novel floating ring capsule-type dosage form for stomach specific delivery

Study objectives were to develop a unique floating ring capsule dosage form which combines gastric soluble and insoluble portions, and to evaluate its suitability for stomach specific drug delivery. New floating ring capsules were developed using different polymers and were compared for various parameters. The formulation with HPMC and sodium CMC has better floating properties. The effects of polymers concentration on drug release were studies by in vitro release studies. The interaction studies of combined drug with polymers were determined using FT-IR spectroscopy. The entrapped air within the gel barrier and lower densities of HPMC and sodium CMC resulted in better floating behavior. Steady slow gel formations showed prolonged drug release. The in vitro release rates were generally found to be faster with low concentration of carbopol showing release within 2 h, while formulations containing high amount of HPMC showed release in 8 h. In particular, the higher concentration of HPMC formulation shows the best drug release performance. A very low change in peak shift was observed only with sodium alginate formulations. Further, FT-IR measurements confirmed the absence of any chemical interactions. Results indicate that new floating ring capsule is a promise dosage form for stomach specific delivery.     

Chitosan-alginate multilayer beads for controlled release of ampicillin

The aim of this study is to develop multilayer beads with improved properties for controlled delivery of the antibiotic ampicillin. Ionotropic gelation was applied to prepare single and multilayer beads using various combinations of chitosan and Ca²⁺ as cationic components and alginate and polyphosphate as anions. Beads prepared with higher concentrations of chitosan entrapped more ampicillin. During incubation in simulated gastric fluid, the beads swelled and started to float but did not show any sign of erosion. Single layer chitosan–alginate beads released 70% of the drug within 4 h. Multilayer beads released only 20–30% in the same period of time. During subsequent incubation in simulated intestinal fluid, both single and multilayer beads continued to release drug. At least part of this release is due to disintegration of the beads. The rate of release both in gastric and intestinal fluid and the kinetics of disintegration in intestinal fluid can be controlled by changing the chitosan concentration in the coagulation fluid. The release of the drug can also be controlled by the degree of cross-linking using polyphosphate. Cross-linked multilayer beads were prepared that released only 40% of the entrapped drug during 24 h. It is concluded that chitosan–alginate multilayer beads, cross-linked with polyphosphate offer an opportunity for controlled gastrointestinal passage of compounds with low molecular weight like ampicillin.     

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.     

Preparation and characterisation of gastroretentive alginate beads for targeting H. pylori

Abstract

There are various obstacles in the eradication of Helicobacter pylori (H. pylori) infections including low drug levels due to short gastric residence times and poor accessibility of the drug at the site of the infection. In this study, calcium alginate beads containing metronidazole were prepared by ionotropic gelation with diameters ranging from 2 to 3?mm and bulk densities ranging from 0.11 to 0.23?g/cm³. These beads failed buoyancy tests and released the drug rapidly. The formulation was modified in order to improve floating and modify their drug release profile through addition of oil and coating with chitosan. Upon modification, buoyancy improved and drug release was sustained. This novel formulation will ensure retention for a longer period in the stomach and control the release of drug, ensuring high local drug concentrations, leading to improved eradication of the bacteria.     

Development of hollow/porous calcium pectinate beads for floating-pulsatile drug delivery.

The purpose of this work was to develop hollow calcium pectinate beads for floating-pulsatile release of diclofenac sodium intended for chronopharmacotherapy. Floating pulsatile concept was applied to increase the gastric residence of the dosage form having lag phase followed by a burst release. To overcome limitations of various approaches for imparting buoyancy, hollow/porous beads were prepared by simple process of acid-base reaction during ionotropic crosslinking. The floating beads obtained were porous (34% porosity), hollow with bulk density<1 and had Ft50% of 14-24 h. In vivo studies by gamma scintigraphy determined on rabbits showed gastroretention of beads up to 5 h. The floating beads provided expected two-phase release pattern with initial lag time during floating in acidic medium followed by rapid pulse release in phosphate buffer. This approach suggested the use of hollow calcium pectinate microparticles as promising floating-pulsatile drug delivery system for site- and time-specific release of drugs acting as per chronotherapy of diseases.     

载葛根素的海藻酸镁胃内滞留释药系统的研究

采用滴制法制备微丸\选取海藻酸钠为载体材料,氯化镁为交联剂,碳酸氢钠为制泡剂,海藻酸钠与镁离子发生交联反应制得胃漂浮微丸,考察微丸的外观、粒径、微观结构、漂浮性以及释药行为.为延长药物在胃靶向释放时长,在单因素实验的基础上,以Eudragit L100和Eudragit RSALO作为载体材料制备载药固体分散体,粉碎过...     

Emulsion gel beads of calcium pectinate capable of floating on the gastric fluid: effect of some additives,hardening agent or coating on release behavior of metronidazole

Emulsion gel (EMG) beads of calcium pectinate capable of floating in the gastric condition were developed using an emulsion-gelation method and their release properties were investigated. Attempts to modify the drug release were made by applying some additives into the starting solution prior to bead formation, by hardening with glutaraldehyde, and by coating with polymer. The metronidazole-loaded EMG beads were found to float on simulated gastric fluid. Increasing the drug to pectin ratio in the beads slowed the drug release from the conventional and the EMG beads. However, the drug release from these beads was rapid, i.e., about 80% of drug loading released within 20–80 min. The additives (PEG10000, glyceryl monostearate and Eudragit^® L) had a slight, insignificant, effect on the drug release. Using 2% glutaraldehyde as a hardening agent prolonged the drug release. Coating the beads with Eudragit^® RL significantly sustained the drug release while the beads remained buoyant. The results suggest that EMG beads are suitable as a carrier for intragastric floating drug delivery and that their release behaviour could be modified by hardening with glutaraldehyde or by coating with Eudragit^® RL.     

A Novel Approach to the Oral Delivery of Micro- or Nanoparticles

A novel oral multiple-unit dosage form which overcame many of the problems commonly observed during the compression of microparticles into tablets was developed in this study. Micro- or nano-particles were entrapped in beads formed by ionotropic gelation of the charged polysaccharide, chitosan or sodium alginate, in solutions of the counterion, tripolyphosphate (TPP) or calcium chloride (CaCl₂), respectively. The described technique did not change the physical properties of the microparticles, and it allowed a high microparticle loading (up to 98%). The ionic character of the polymers allowed pH-dependent release of the microparticles. Chitosan beads disintegrated and released the microparticles in 0.1 N HC1, while calcium alginate beads stayed intact in 0.1 N HC1 but rapidly disintegrated in simulated intestinal fluids. Coating the calcium alginate beads with cellulose acetate phthalate resulted in an enteric drug delivery system. Scanning electron microscopy and dissolution and disintegration tests were used to characterize the microparticle-containing beads. The disintegration time of the beads was studied as a function of the solution viscosity of the polysaccharide, gelation time, counterion concentration, and method of drying.     

阿西美辛海藻酸钙凝胶微丸释药影响因素考察

目的:考察阿西美辛海藻酸钙凝胶微丸的释药机制。方法:采用滴制法制备阿西美辛海藻酸钙微丸,考察海藻酸钠浓度,钙离子浓度,投药量,滴头直径大小对药物释放的影响。结果:海藻酸钠浓度增加,钙离子浓度增加,滴头直径增加,释药速率减慢。结论:在体外释放度实验中,阿西美辛海藻酸钙凝胶微丸具有良好的缓释作用,海藻酸钙凝胶微丸是一种非常有潜力的药物载体。     

Use of floating alginate gel beads for stomach-specific drug delivery.

Two types of alginate gel beads capable of floating in the gastric cavity were prepared. The first, alginate gel bead containing vegetable oil (ALGO), is a hydrogel bead and its buoyancy is attributable to vegetable oil held in the alginate gel matrix. The model drug, metronidazole (MZ), contained in ALGO was released gradually into artificial gastric juice, the release rate being inversely related to the percentage of oil. The second, alginate gel bead containing chitosan (ALCS), is a dried gel bead with dispersed chitosan in the matrix. The drug-release profile was not affected by the kind of chitosan contained in ALCS. When ALCS containing MZ was administered orally to guinea pigs, it floated on the gastric juice and released the drug into the stomach. Furthermore, the concentration of MZ at the gastric mucosa after administration of ALCS was higher than that in the solution, though the MZ serum concentration was the same regardless of which type of gel was administered. These release properties of alginate gels are applicable not only for sustained release of drugs but also for targeting the gastric mucosa.     

Morphology and buoyancy of oil-entrapped calcium pectinate gel beads

A new emulsion-gelation method to prepare oil-entrapped calcium pectinate gel (CaPG) beads capable of floating in the gastric condition was designed and tested. The gel beads containing edible oil were prepared by either being gently mixed or homogenized an oil phase and a water phase containing pectin, and then extruded into calcium chloride solution with gentle agitation at room temperature. The gel beads formed were then separated, washed with distilled water, and dried at 37 degrees C for 12 hours. A model of the emulsion-gelation process to illustrate the formation of oil-entrapped CaPG beads was proposed. The effect of selected factors, such as type of oil, percentage of oil, and type of pectin on morphology and floating properties was investigated. The oil-entrapped calcium pectinate gel beads floated if a sufficient amount of oil was used. Scanning electron photomicrographs demonstrated very small pores, ranging between 5 and 40 microm, dispersed all over the beads. The type and percentage of oil play an important role in controlling the floating of oil-entrapped CaPG beads. The results suggested that oil-entrapped CaPG beads were promising as a carrier for intragastric floating drug delivery.     

Floating-bioadhesive gastroretentive Caesalpinia pulcherrima-based beads of amoxicillin trihydrate for Helicobacter pylori eradication

Abstract

Context: An oral dosage form containing floating bioadhesive gastroretentive microspheres forms a stomach-specific drug delivery system for the treatment of Helicobacter pylori.

Objectives: To prepare and evaluate controlled release floating bioadhesive gastroretentive chitosan-coated amoxicillin trihydrate-loaded Caesalpinia pulcherrima galactomannan (CPG)-alginate beads (CCA-CPG-A), for H. pylori eradication.

Materials and methods: CCA-CPG-A beads were prepared by ionotropic gelation, using 2³ factorial design with quantity of drug, combination of CPG with sodium alginate and concentration of calcium chloride as variables. Beads facilitated mucoadhesion to gastric mucosa with floating nature caused by chitosan coating for wide distribution throughout GIT. Developed beads were evaluated for characteristics like beads size-morphology, entrapment efficiency, DSC, XRD, FTIR, swelling ratio, in vitro mucoadhesion, in vitro drug release, in vitro floating and in vitro H. pylori growth inhibition studies. CCA-CPG-A beads were studied in Wistar rats for in vivo gastric mucoadhesion, in vivo H. pylori growth inhibition studies using PCR amplification of isolated DNA, rapid urease test.

Result: Developed beads possess drug release of 79–92%, entrapment efficiency of 65–89%, mucoadhesion of 61–89%. In vivo mucoadhesion study showed more than 85% mucoadhesion of beads even after 7th hour. In vitro–in vivo growth inhibition study showed complete eradication of H. pylori.

Discussion: CPG-alginate and chitosan in beads interacts with gastric mucosubstrate surface for prolonged gastric residence with floating bioadhesion mechanism for H. pylori eradication in rats.

Conclusion: Floating bioadhesive CCA-CPG-A beads offer a promising drug delivery system for H. pylori eradication at lower dose, reduced adverse effect and enhance bioavailability.