Tolmetin sodium-loaded thermosensitive mucoadhesive liquid suppositories for rectal delivery; strategy to overcome oral delivery drawbacks

Tolmetin sodium (TS) is a nonsteroidal anti-inflammatory drug (NSAID) indicated for treatment of musculoskeletal issues. As other NSAID, TS displays a marked side effects on the gastro-intestinal (GI) tract after oral administration. Traditional solid suppositories can cause pain and discomfort for patients, may reach the end of the colon; consequently, the drug can undergo the first-pass effect. TS liquid suppository (TS-_LS) was developed to enhance patient compliance and rectal mucosal safety in high-risk patients receiving highly NSAID therapy. This work was conducted to optimize and evaluate Poloxamer P407/P188-based thermoresponsive TS-_LS by using mucoadhesive polymers such as methylcellulose (MC). TS-_LS was prepared by cold method and characterized their in vitro physicochemical properties as gelation temperature (GT), gel strength, bioadhesive properties, and in vitro release. The safety of the prepared suppository on rectum, stomach, and liver was evaluated histologically. Pharmacokinetic analyses were performed to compare rectal TS-_LS to orally Rhumtol^® capsules. The results showed that the optimized TS-_LS; composed of P407/P188/MC (21/9/0.5% w/w) displayed gelation at rectum temperature ～32.90?°C, gel strength of 21.35?s and rectal retention force at the administration site of 24.25?×?10²?dyne/cm². Moreover, TS-_LS did not cause any morphological damage to the rectal tissues. Pharmacokinetic parameters of optimized TS-_LS formulation revealed 4.6 fold increase in bioavailability as compared to Rhumtol^® capsules. Taken together, the results demonstrated that liquid suppository is a potential and physically safe rectal delivery carrier for improvement rectal bioavailability and in vivo safety of TS.     

Physicochemical Characterization and Evaluation of Buccal Adhesive Tablets Containing Omeprazole

The objective of this study was to develop an effective omeprazole buccal adhesive tablet with excellent bioadhesive force and good drug stability in human saliva. The omeprazole buccal adhesive tablets were prepared with various bioadhesive polymers, alkali materials, and croscarmellose sodium. Their physicochemical properties, such as bioadhesive force and drug stability in human saliva, were investigated. The release and bioavailability of omeprazole delivered by the buccal adhesive tablets were studied. As bioadhesive additives for the omeprazole tablet, a mixture of sodium alginate and hydroxypropylmethylcellulose (HPMC) was selected. The omeprazole tablets prepared with bioadhesive polymers alone had bioadhesive forces suitable for a buccal adhesive tablet, but the stability of omeprazole in human saliva was not satisfactory. Among alkali materials, only magnesium oxide could be an alkali stabilizer for omeprazole buccal adhesive tablets due to its strong waterproofing effect. Croscarmellose sodium enhanced the release of omeprazole from the tablets; however, it decreased the bioadhesive forces and stability of omeprazole tablets in human saliva. The tablet composed of omeprazole/sodium alginate/HPMC/magnesium oxide/croscarmellose sodium (20/24/6/50/10 mg) could be attached on the human cheek without disintegration, and it enhanced the stability of omeprazole in human saliva for at least 4 h and gave fast release of omeprazole. The plasma concentration of omeprazole in hamsters increased to a maximum of 370 ng/ml at 45 min after buccal administration and continuously maintained a high level of 146–366 ng/ml until 6 h. The buccal bioavailability of omeprazole in hamsters was 13.7% ± 3.2%. These results demonstrate that the omeprazole buccal adhesive tablet would be useful for delivery of an omeprazole that degrades very rapidly in acidic aqueous medium and undergoes hepatic first-pass metabolism after oral administration.     

Physicochemical Characterization and Evaluation of Buccal Adhesive Tablets Containing Omeprazole

The objective of this study was to develop an effective omeprazole buccal adhesive tablet with excellent bioadhesive force and good drug stability in human saliva. The omeprazole buccal adhesive tablets were prepared with various bioadhesive polymers, alkali materials, and croscarmellose sodium. Their physicochemical properties, such as bioadhesive force and drug stability in human saliva, were investigated. The release and bioavailability of omeprazole delivered by the buccal adhesive tablets were studied. As bioadhesive additives for the omeprazole tablet, a mixture of sodium alginate and hydroxypropylmethylcellulose (HPMC) was selected. The omeprazole tablets prepared with bioadhesive polymers alone had bioadhesive forces suitable for a buccal adhesive tablet, but the stability of omeprazole in human saliva was not satisfactory. Among alkali materials, only magnesium oxide could be an alkali stabilizer for omeprazole buccal adhesive tablets due to its strong waterproofing effect. Croscarmellose sodium enhanced the release of omeprazole from the tablets; however, it decreased the bioadhesive forces and stability of omeprazole tablets in human saliva. The tablet composed of omeprazole/sodium alginate/HPMC/magnesium oxide/croscarmellose sodium (20/24/6/50/10 mg) could be attached on the human cheek without disintegration, and it enhanced the stability of omeprazole in human saliva for at least 4 h and gave fast release of omeprazole. The plasma concentration of omeprazole in hamsters increased to a maximum of 370 ng/ml at 45 min after buccal administration and continuously maintained a high level of 146-366 ng/ml until 6 h. The buccal bioavailability of omeprazole in hamsters was 13.7% ± 3.2%. These results demonstrate that the omeprazole buccal adhesive tablet would be useful for delivery of an omeprazole that degrades very rapidly in acidic aqueous medium and undergoes hepatic first-pass metabolism after oral administration.     

Formulation and in vitro evaluation of a thermoreversible mucoadhesive nasal gel of itopride hydrochloride

Itopride hydrochloride (ITO HCl) is a prokinetic agent, used in the treatment of gastrointestinal motility disorders. The aim of the study was to develop stable mucoadhesive thermoreversible nasal gel to avoid first pass effect. ITO HCl was incorporated into the blends of thermoreversible polymers like poloxamer 407 and various mucoadhesive polymers in different concentrations to increase the contact of the formulations with nasal mucosa. The compatibility between the drug and the suggested polymers was studied by Fourier transform infrared and differential scanning calorimetry (DSC). The formulations were evaluated for clarity, pH, gelation temperature, mucoadhesive strength, gel strength, viscosity, and drug content. In addition, the in vitro drug release and the dissolution efficiency (DE)% were measured. The optimized formulations that showed the highest dissolution efficiency% (DE%) in saline phosphate buffer of pH 6.4 at 35?±?0.5?°C were chosen for stability testing at temperatures of 4?±?2 and 25?±?2?°C/60?±?5% RH. It was found that F1 and F17 that contain 18% w/v poloxamer 407 and 0.5% w/v of hydroxypropylmethyl cellulose K4M or methyl cellulose (MC), respectively, showed higher stability results as indicated by their higher t₉₀ values (days).     

Assemblies for in vitro measurement of bioadhesive strength and retention characteristics in simulated vaginal environment

The vaginal route of administration offers a promising option for local and systemic delivery of drugs. Conventional vaginal formulations are associated with limitations of poor retention, leakage, and messiness, thereby causing inconvenience to users. To overcome these limitations, formulations that adhere to the vaginal mucosa for a sufficient period of time need to be developed. Bioadhesion and retention are desirable characteristics of a vaginal formulation to achieve desired efficacy. These properties can be built in during formulation development by the use of bioadhesive polymers. In the present study, assemblies for in vitro measurement of bioadhesive strength and retention characteristics of vaginal formulations have been developed. A modified simulated vaginal fluid (SVFM) was used to simulate vaginal conditions for bioadhesion studies. Cellophane hydrated with SVFM and isolated sheep vaginal mucosa were used as model membranes. The bioadhesive potential of various polymers and their combinations was evaluated. Among the polymers evaluated, xanthan gum (XG), sodium alginate (SA), Polycarbophil (PC), and their combinations (XG + SA and XG + PC) were found to possess significant bioadhesive strength. In retention experiments, XG, SA, and combinations (XG + SA and XG + PC) were retained in isolated sheep vaginal tissue, while PC exhibited poor retention under experimental conditions. Based on the results of the study conducted, XG, SA, and combinations (XG + SA and XG + PC) have been proposed as potential candidates for developing bioadhesive vaginal drug delivery systems.     

Assemblies for In Vitro Measurement of Bioadhesive Strength and Retention Characteristics in Simulated Vaginal Environment

ABSTRACT

The vaginal route of administration offers a promising option for local and systemic delivery of drugs. Conventional vaginal formulations are associated with limitations of poor retention, leakage, and messiness, thereby causing inconvenience to users. To overcome these limitations, formulations that adhere to the vaginal mucosa for a sufficient period of time need to be developed. Bioadhesion and retention are desirable characteristics of a vaginal formulation to achieve desired efficacy. These properties can be built in during formulation development by the use of bioadhesive polymers. In the present study, assemblies for in vitro measurement of bioadhesive strength and retention characteristics of vaginal formulations have been developed. A modified simulated vaginal fluid (SVF_M) was used to simulate vaginal conditions for bioadhesion studies. Cellophane hydrated with SVF_M and isolated sheep vaginal mucosa were used as model membranes. The bioadhesive potential of various polymers and their combinations was evaluated. Among the polymers evaluated, xanthan gum (XG), sodium alginate (SA), Polycarbophil (PC), and their combinations (XG + SA and XG + PC) were found to possess significant bioadhesive strength. In retention experiments, XG, SA, and combinations (XG + SA and XG + PC) were retained in isolated sheep vaginal tissue, while PC exhibited poor retention under experimental conditions. Based on the results of the study conducted, XG, SA, and combinations (XG + SA and XG + PC) have been proposed as potential candidates for developing bioadhesive vaginal drug delivery systems.     

Ocular poloxamer-based ciprofloxacin hydrochloride in situ forming gels

The purpose of this study was to develop poloxamer-based in situ gelling formulations of ciprofloxacin hydrochloride (HCl) aiming at prolonging corneal contact time, controlling drug release, enhancing ocular bioavailability, and increasing patient compliance. The in situ forming gels were prepared using different concentrations of poloxamer 407 (P407) and poloxamer 188 (P188). Mucoadhesives such as hydroxypropylmethyl cellulose (HPMC) or hydroxyethyl cellulose (HEC) were added to the formulations to enhance the gel bioadhesion properties. The prepared formulations were evaluated for their in vitro drug release, sol-gel transition temperature, rheological behavior, and mucoadhesion force. The in vivo antimicrobial efficacy of selected ciprofloxacin HCl in situ gelling formulations was studied on infected rabbit's eyes and compared with that of the marketed conventional eye drops. The gelation temperature of the prepared formulations ranged from 28.00 to 34.03 degrees C. Increasing the concentrations of P407, HPMC, and HEC increased the viscosity and mucoadhesion force of the preparations and decreased the in vitro drug release. Ciprofloxacin HCl in situ forming gel formulae composed of P407/P188/HPMC (18/13/1.5%, wt/wt), and P407/P188/HEC (18/13/0.5%, wt/wt) showed optimum release and mucoadhesion properties and improved ocular bioavailability as evidenced by an enhanced therapeutic response compared with the marketed conventional eye drops.     

Ocular Poloxamer-Based Ciprofloxacin Hydrochloride In Situ Forming Gels

The purpose of this study was to develop poloxamer-based in situ gelling formulations of ciprofloxacin hydrochloride (HCl) aiming at prolonging corneal contact time, controlling drug release, enhancing ocular bioavailability, and increasing patient compliance. The in situ forming gels were prepared using different concentrations of poloxamer 407 (P407) and poloxamer 188 (P188). Mucoadhesives such as hydroxypropylmethyl cellulose (HPMC) or hydroxyethyl cellulose (HEC) were added to the formulations to enhance the gel bioadhesion properties. The prepared formulations were evaluated for their in vitro drug release, sol–gel transition temperature, rheological behavior, and mucoadhesion force. The in vivo antimicrobial efficacy of selected ciprofloxacin HCl in situ gelling formulations was studied on infected rabbit's eyes and compared with that of the marketed conventional eye drops. The gelation temperature of the prepared formulations ranged from 28.00 to 34.03°C. Increasing the concentrations of P407, HPMC, and HEC increased the viscosity and mucoadhesion force of the preparations and decreased the in vitro drug release. Ciprofloxacin HCl in situ forming gel formulae composed of P407/P188/HPMC (18/13/1.5%, wt/wt), and P407/P188/HEC (18/13/0.5%, wt/wt) showed optimum release and mucoadhesion properties and improved ocular bioavailability as evidenced by an enhanced therapeutic response compared with the marketed conventional eye drops.     

Development of a mucoadhesive dosage form for vaginal administration

The antimycotic imidazole derivative clotrimazole is employed locally for the treatment of genitourinary tract mycotic infections and is formulated as creams, foams, tablets, gels, irrigations, or pessaries. In this study, a new dosage form was developed by including bioadhesive polymers (polycarbophyl, hydroxypropylmethylcellulose, and hyaluronic sodium salt) into pessaries made of semisynthetic solid triglycerides. These polymers hold the delivery systems in the vaginal tract for a few days without any toxic effects or important physiological modifications, prolonging the permanence of the drug on the vaginal mucosa. Technological controls (compatibility with differential scanning calorimetry [DSC] studies, particle size analysis, and liquefaction time test) and biopharmaceutics studies for the evaluation of the release of the drug from the dosage form and of the bioadhesive properties were carried out. Moreover, a new test for the evaluation of the permanence of the drug in a simulated application site was developed from a modification of the Satnikar and Fantelli method for the evaluation of the liquefaction time of rectal suppositories. This test simulates the physiological vaginal condition and verifies the efficiency of the polymers in prolonging the permanence of the dosage form in the location where it is applied. The technological controls demonstrated that the presence of the polymers did not have an influence on the characteristics of the pessaries. On the other hand, there was an improvement in adhesivity of the pessaries in the in vitro adhesion test and prolonging of the liquefaction time in the liquefaction time test in the presence of mucoadhesive polymers, which increased with increasing polymer concentration. The presence of the mucoadhesive had a large influence on the permanence of the drug in the simulated application site because it modified the distribution of the drug along the simulated application site. In conclusion, the developed new formulations showed good technological and adhesion properties and the capacity of hold the dosage form in the target site. Among the employed bioadhesive polymers, the best behavior in the performed test was by polycarbophyl at its maximum concentration.     

Development of a Mucoadhesive Dosage Form for Vaginal Administration

The antimycotic imidazole derivative clotrimazole is employed locally for the treatment of genitourinary tract mycotic infections and is formulated as creams, foams, tablets, gels, irrigations, or pessaries. In this study, a new dosage form was developed by including bioadhesive polymers (polycarbophyl, hydroxypropylmethylcellulose, and hyaluronic sodium salt) into pessaries made of semisynthetic solid triglycerides. These polymers hold the delivery systems in the vaginal tract for a few days without any toxic effects or important physiological modifications, prolonging the permanence of the drug on the vaginal mucosa. Technological controls (compatibility with differential scanning calorimetry [DSC] studies, particle size analysis, and liquefaction time test) and biopharmaceutics studies for the evaluation of the release of the drug from the dosage form and of the bioadhesive properties were carried out. Moreover, a new test for the evaluation of the permanence of the drug in a simulated application site was developed from a modification of the Satnikar and Fantelli method for the evaluation of the liquefaction time of rectal suppositories. This test simulates the physiological vaginal condition and verifies the efficiency of the polymers in prolonging the permanence of the dosage form in the location where it is applied. The technological controls demonstrated that the presence of the polymers did not have an influence on the characteristics of the pessaries. On the other hand, there was an improvement in adhesivity of the pessaries in the in vitro adhesion test and prolonging of the liquefaction time in the liquefaction time test in the presence of mucoadhesive polymers, which increased with increasing polymer concentration. The presence of the mucoadhesive had a large influence on the permanence of the drug in the simulated application site because it modified the distribution of the drug along the simulated application site. In conclusion, the developed new formulations showed good technological and adhesion properties and the capacity of hold the dosage form in the target site. Among the employed bioadhesive polymers, the best behavior in the performed test was by polycarbophyl at its maximum concentration.     

Compaction Properties of Acrylic Resin Polymers with Plastic and Brittle Drugs

Abstract

Tensile strengths of compacts consisting of acrylic resin polymers in combination with a plastic drug (theophylline) and a brittle drug (sodium sulfathiazole) were investigated. The polymers studied included Eudragit RS PM, RL PM, S 100, L 100, and L 100-55. All compacts were compressed to a solid fraction of 0.81. The solid fraction, rather than compression force, was kept constant in order to account for the differences in packing characteristics and elastic and plastic deformational properties of different materials (1). Tensile strength profiles for the blends of the Eudragit S 100 and RL PM polymers with sodium sulfathiazole included approximately linear relationships between pure drug and pure polymer. The Eudragit L 100-55 exhibited a large peak in the tensile strength of compacts containing 20% sodium sulfathiazole. Significant differences between the physical-mechanical properties of the methacrylate ester and methacrylic acid copolymers were observed where the latter proved to be much stronger at all concentrations. The differences between the two categories of polymers were greater in compacts containing the plastic drug, theophylline. Peaks in tensile strengths were seen for both drugs with all three of the methacrylic acid copolymers, while the methacrylate ester copolymers maintained approximately linear relationships for all ratios of drug and polymer.     

Compaction Properties of Acrylic Resin Polymers with Plastic and Brittle Drugs

Tensile strengths of compacts consisting of acrylic resin polymers in combination with a plastic drug (theophylline) and a brittle drug (sodium sulfathiazole) were investigated. The polymers studied included Eudragit RS PM, RL PM, S 100, L 100, and L 100-55. All compacts were compressed to a solid fraction of 0.81. The solid fraction, rather than compression force, was kept constant in order to account for the differences in packing characteristics and elastic and plastic deformational properties of different materials (1). Tensile strength profiles for the blends of the Eudragit S 100 and RL PM polymers with sodium sulfathiazole included approximately linear relationships between pure drug and pure polymer. The Eudragit L 100-55 exhibited a large peak in the tensile strength of compacts containing 20% sodium sulfathiazole. Significant differences between the physical-mechanical properties of the methacrylate ester and methacrylic acid copolymers were observed where the latter proved to be much stronger at all concentrations. The differences between the two categories of polymers were greater in compacts containing the plastic drug, theophylline. Peaks in tensile strengths were seen for both drugs with all three of the methacrylic acid copolymers, while the methacrylate ester copolymers maintained approximately linear relationships for all ratios of drug and polymer.     

Formulation and evaluation of Methocel K15M bioadhesive matrix tablets

Methocel K15M is a bioadhesive polymer. Its adhesion and bioadhesion characteristics were evaluated by shear stress measurement and detachment force measurement methods, respectively. The effect of pH on adhesion was studied, and it was found that the maximum adhesion was between pH 5 and pH 6. Adhesion strength at different parts of the sheep intestine was studied; in the duodenal portion of the intestine, the adhesion was maximum. Chlorpheniramine maleate and diclofenac sodium drugs are formulated with Methocel K15M as matrix tablets. In vitro release studies revealed that some of the formulations showed initial first-order behavior followed by zero-order release behavior.     

Formulation and Evaluation of Methocel K15M Bioadhesive Matrix Tablets

Methocel K15M is a bioadhesive polymer. Its adhesion and bioadhesion characteristics were evaluated by shear stress measurement and detachment force measurement methods, respectively. The effect of pH on adhesion was studied, and it was found that the maximum adhesion was between pH 5 and pH 6. Adhesion strength at different parts of the sheep intestine was studied; in the duodenal portion of the intestine, the adhesion was maximum. Chlorpheniramine maleate and diclofenac sodium drugs are formulated with Methocel K15M as matrix tablets. In vitro release studies revealed that some of the formulations showed initial first-order behavior followed by zero-order release behavior.     

Development of in situ-forming hydrogels for hemorrhage control

We report the preparation of in situ-forming hydrogels, composed of oxidized dextran (Odex) and amine-containing polymers, for their potential use as a wound dressing to promote blood clotting. Dextran was oxidized by sodium periodate to introduce aldehyde groups to form hydrogels, upon mixing in solution with different polymers containing primary amine groups, including polyallylamine (PAA), oligochitosan and glycol chitosan. A series of experiments were conducted to identify the optimum gelation condition for the Odex-PAA system. The polymer concentration appeared to have a major effect on gelation time and the polymer weight ratio affected the resulting gel content and swelling. Other influencing factors included pH of the buffer used to dissolve each polymer, PAA molecular weight, and the type of individual material. The latter also contributed significantly to gel content and swelling. Thromboelastography was used to examine the effects of the in situ gelation on blood coagulation in vitro, where the Odex-PAA combination was found to be most pro-hemostatic, as indicated by a decrease in clotting time and an increase in clot strength. The results of this study demonstrated that in situ-forming hydrogels could promote clotting in vitro; however, further studies are required to determine if the same hydrogel formulations are effective in controlling hemorrhage in vivo.     

Interpolymer Complexation and its Effect on Bioadhesive Strength 6 Dissolution Characteristics of Buccal Drug Delivery Systems

During the process of development of mucoadhesive buccal delivery systems, interpolymer complex formation between carboxy vinyl polymer, which is similar to polyacrylic acid and other polymers as hydroxypropyl cellulose, carbopol-934, sodium carboxymethyl cellulose and polyvinyl pyrrolidone was studied as a function of pH. It was observed that carbopol-934 shows strong complexation with polyvinyl pyrrolidone and hydroxypropyl cellulose, but very little with sodium carboxymethyl cellulose. The degree of complexation is higher at acidic pH and decreases with an increase in pH. In further studies, when mucoadhesive buccal tablets were prepared using these polymer combinations, it was observed that the degree of complexation between the two polymers affected the rate and extent of drug release and also the bioadhesive strength of the tablets.     

Design and in vitro characterization of buccoadhesive tablets of timolol maleate

Objective: The purpose of this work was to develop and evaluate buccoadhesive tablets of timolol maleate (TM) due to its potential to circumvent the first-pass metabolism and to improve its bioavailability.

Methods: The tablets were prepared by direct compression using two release modifying polymers, Carbopol 974P (Cp-974p) and sodium alginate (SA). A 3² full factorial design was employed to study the effect of independent variables, Cp-974p and SA, in various proportions in percent w/w, which influences the in vitro drug release and bioadhesive strengths. Physicochemical properties of the drug were evaluated by ultraviolet, Fourier transform infrared spectroscopy (FTIR), differential scanning calorimetry (DSC) and powder X-ray diffraction (P-XRD). Tablets were evaluated for hardness, thickness, weight variation, drug content, surface pH, swelling index, bioadhesive force and in vitro drug release.

Results: The FTIR and DSC studies showed no evidence of interactions between drug, polymers and excipients. The P-XRD study revealed that crystallinity of TM remain unchanged in optimized formulation tablet. Formulation F9 achieves an in vitro drug release of 98.967%?±?0.28 at 8?h and a bioadhesive force of 0.088 N?±?0.01211.

Conclusion: We successfully developed buccal tablet formulations of TM and describe a non-Fickian-type anomalous transport as the release mechanism.     

Preparation and evaluation of in situ gelling ophthalmic drug delivery system for methazolamide

Purpose: In this study, a thermosensitive in situ gelling vehicle was prepared to increase the precorneal resident time and the bioavailability of methazolamide (MTA). Method: Poloxamer analogs were used as the gelling agents, and the in situ gel was obtained by using a cold method. The gelation temperature, rheological properties, in vitro release as well as in vivo evaluation (the elimination of MTA in aqueous humor and intraocular-lowering effect) of the optimized formulations were investigated. Results: The optimum concentrations of poloxamer analogs for the in situ gel-forming delivery system were 21% (w/w) poloxamer 407 and 10% (w/w) poloxamer P188. This formulation was able to flow freely under nonphysiological conditions and underwent sol–gel transition in the cul-de-sac upon placement into the eye. In vitro release studies demonstrated a diffusion-controlled release of MTA from the poloxamer solutions over a period of 10 hours. In vivo evaluation indicated that the poloxamer solutions had a better ability to retain drug than MTA eyedrops did. Conclusion: These results suggested that in situ gelling ophthalmic drug delivery system may hold some promise in ocular MTA delivery.     

可注射乙酰化乙二醇壳聚糖/泊洛沙姆复合水凝胶的制备及药物缓释研究EI北大核心CSCD

泊洛沙姆(poloxamer)是一种温敏性聚合物,在浓度为15.0%(质量分数,下同)~30.0%时可形成凝胶。为改善泊洛沙姆在体温下的成胶浓度和药物缓释性能,以泊洛沙姆407为基底,与新型温敏性乙酰化乙二醇壳聚糖复合,制得了温敏性乙酰化乙二醇壳聚糖/泊洛沙姆复合水凝胶。通过傅里叶变换红外光谱(FT-IR)、试管倒置法、旋转流变仪、扫描电子显微镜(SEM)和紫外-可见分光光度计(UV-vis)对乙酰化乙二醇壳聚糖/泊洛沙姆的结构、温敏性、力学性能、微观形貌和体外药物释放性能进行表征。结果表明,乙酰化乙二醇壳聚糖/泊洛沙姆溶液具有热可逆温敏性溶胶-凝胶转变行为。通过控制乙酰化乙二醇壳聚糖/泊洛沙姆的质量比,能够使溶胶-凝胶转变温度处于室温与体温(25~37℃)之间,缩短凝胶化时间(382s),降低泊洛沙姆407在体温下的成胶浓度(6%)。乙酰化乙二醇壳聚糖/泊洛沙姆复合水凝胶具有高度孔隙化的三维结构,其孔径大小处于10~60μm范围内,且表现出较高的力学性能。乙酰化乙二醇壳聚糖/泊洛沙姆复合水凝胶对抗癌药物吉西他滨具有缓释作用,载药凝胶的释药时间可达72 h。乙酰化乙二醇壳聚糖/泊洛沙姆复合水凝胶在可注射药物缓释载体方面具有重要的应用前景。     

Study of Drug Release from Pellets Coated with Surelease Containing Hydroxypropylmethylcellulose

The release of metoclopramide hydrochloride (a very water soluble cationic drug) and diclofenac sodium (a sparingly soluble anionic drug) from pellets coated with Surelease containing hydroxypropylmethylcellulose (HPMC) at different coating loads was investigated. The release rates of either drug at each coating composition decreased as the coating load increased. Inclusion of HPMC E15 increased the release rates of both drugs compared to pellets coated only with Surelease. This was thought to be due to the leakage of the soluble part of the film (HPMC E15) during dissolution, which left pores for drug release. The Surelease:HPMC E15 ratio had a major role in the release rates of drugs. Addition of HPMC E15 into Surelease did not change the release mechanism for metoclopramide hydrochloride (the mean value of n ≈ 0.57) from that of Surelease alone, and diffusion remained the main mechanism controlling the release. However, the release exponent (≈1.28) increased for diclofenac sodium on addition of HPMC E15, indicating a dissolutioncontrolled mechanism. Despite its lower water solubility, diclofenac sodium was released slightly faster than metoclopramide hydrochloride from pellets coated with Surelease containing HPMC E15 at equivalent coating loads.