INFLUENCE OF TOTAL SURFACE-AREA OF CORE MATERIAL ON YIELD OF DEPOSITED COACERVATE

被引：3

作者：

DITTRICH, M

MELICHAR, L

SMETANOVA, V

机构：

[1] Faculty of Pharmacy, Charles University, Department of Pharmaceutical Technology, 50165, Hradec Králové Czechoslovakia

来源：

JOURNAL OF MICROENCAPSULATION | 1993年 / 10卷 / 01期

关键词：

D O I：

10.3109/02652049309015311

中图分类号：

O69 [应用化学];

学科分类号：

081704 ;

摘要：

Influence of total surface area of core material on yield of deposited coacervate was evaluated. A simple coacervation method was employed. Spherical sieve fractionated particles of polystyrene prepared by the emulsion solvent evaporation method were used as a model core substance. A mixed polymer system-aqueous solution of gelatin and potassium salt of cellulose acetate phthalate was used as a wall material. A sodium sulphate solution acted as a desolvating agent. Results obtained clearly show an opposite effect of the size of core material and derived total surface area on the yield of attached coacervate. While keeping the amount of core material constant, the amount of deposited coacervate increased both with the decreased size of core particles (increased total surface area), and increased concentration of desolvating agent. The proportion of wall material gradually increases with the increased concentration of sodium sulphate solution in the range from 1 to 9 per cent of the weight of microcapsules. Analysis of variance was used for the evaluation of obtained data.

引用

页码：45 / 54

页数：10

共 23 条

[1]

Benita S., Donbrow M., Effect of polyisobutylene on ethylcellulose-walled microcapsules: wall structure and thickness of salicylamide and theophylline microcapsules, Journal of Pharmaceutical Sciences, 71, pp. 205-210, (1982)

[2]

Benita S., Hoffman A., Donbrow M., Microencapsulation of paracetamol using polyacrylate resins (Eudragit retard), kinetics of drug release and evaluation of kinetic model, Journal of Pharmacy and Pharmacology, 37, pp. 391-395, (1985)

[3]

Donbrow M., Drug release kinetics and microencapsulation design, Development of Drugs and Modern Medicines, (1986)

[4]

Donbrow M., Benita S., Release kinetics of sparingly soluble drugs from ethylcellulose-walled microcapsules: salicylamide microcapsules, Journal of Pharmacy and Pharmacology, 34, pp. 547-551, (1982)

[5]

El-Egakey M.A., El-Khawas F., Iskandar A.G., Abdel-Khalek M.M., Micro-encapsulation by polyethyleneglycols, Die Pharmazie, 29, pp. 466-468, (1974)

[6]

Jalsenjak I., Nixon J.R., Senjkovic R., Stivic I., Sustained-release dosage forms of microencapsulated isoniazid, Journal of Pharmacy and Pharmacology, 32, pp. 678-680, (1980)

[7]

Jalsenjak I., Kondo T., Effect of capsule size on permeability of gelatin-acacia microcapsules toward sodium chloride, Journal of Pharmaceutical Sciences, 70, pp. 456-457, (1981)

[8]

Kawashima Y., Handa T., Kasai A., Takenaka H., Lin S.Y., The effect of wall thickness and hardness of the coating film on the drug release rate of theophylline granules coated with chitosan-sodium tripolyphosphate complex, Chemical and Pharmaceutical Bulletin, 33, pp. 2469-2474, (1985)

[9]

Kondo T., Preparation and permeability characteristics of microcapsule membranes, Journal of Controlled Release, 11, pp. 215-224, (1990)

[10]

Lin S.Y., Ho L.T., Chiou W.L., Microencapsulation and controlled release of insulin from polylactic acid microcapsules, Biomaterials, Medical Devices, and Artificial Organs, 13, pp. 187-201, (1986)

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