Preparation and characterization of chitosan microparticles for oral sustained delivery of gliclazide: in vitro/in vivo evaluation

Chitosan microparticles were prepared with tripolyphosphate (TPP) by ionic cross‐linking with gliclazide (GLZ) as a model drug. The particle sizes of TPP‐chitosan microparticles ranged from 675–887 µm with loading efficiencies of greater than 94%. Chitosan concentration, TPP solution pH, and glutaraldehyde volume solution added to the TPP cross‐linking solution affected drug release characteristics. Pectin interactions with cationic chitosan on the surface of TPP/chitosan microparticles led to the formation of polyelectrolyte complex films that improved drug sustained release performance. In vivo testing of the GLZ‐chitosan microparticles in diabetic albino rabbits demonstrated a significant antidiabetic effect of GLZ/chitosan microparticles after 8 h that lasts for 18 h compared with GLZ powder that produced a maximal hypoglycemic effect at 4 h, suggesting that GLZ/chitosan microparticles represent an improved system for the long‐term delivery of GLZ. Drug Dev Res 72: 235–246, 2011. © 2010 Wiley‐Liss, Inc.     

Design and development of gliclazide-loaded chitosan for oral sustained drug delivery: in vitro/in vivo evaluation

Gliclazide (GLZ)/Chitosan microparticles were prepared with tripolyphosphate (TPP) by ionic cross-linking. The particle sizes of TPP-chitosan microparticles were in the range 675-887 μm and the loading efficiencies of drug was more than 94.0%. Chitosan concentration, TPP solution pH and glutaraldehyde volume added to the TPP cross-linking solution had an effect on the drug release characteristics. The microparticles were examined with scanning electron microscopy and infrared spectroscopy. Furthermore, pectin can interact with cationic chitosan on the surface of these TPP/chitosan microparticles to form a polyelectrolyte complex film for the improvement of the drug sustained-release performances. In vivo testing of the GLZ-chitosan microparticles in diabetic albino rabbits demonstrated significant antidiabetic effect of GLZ/chitosan microparticles after 8 h which lasts for 18 h, compared with GLZ powder which produced maximum hypoglycaemic effect after 4 h, suggesting that GLZ/chitosan microparticles are a valuable system for the long-term delivery of GLZ.     

Heparin-immobilized pluronic/PVA composite microparticles for the sustained delivery of ionic drug

Heparin-immobilized Pluronic (F-68)/Polyvinylalcohol (PVA) composite microparticles were designed and characterized for the sustained drug delivery of ionic drug. Venlafaxine, antidepressant medication, was used as a model drug. For the efficient loading of ionic drug, heparin was immobilized into F-68/PVA composite microparticles. Differential scanning calorimetry (DSC) was used to understand the intra/intermolecular interactions in the heparin-immobilized F-68/PVA composite gels containing model drug. For the application as a sustained drug delivery system, the loading amount and release pattern of loaded drug were measured using high performance liquid chromatography (HPLC).     

Doxycycline hydrochloride-metronidazole solid lipid microparticles gels for treatment of periodontitis: development,in-vitro and in-vivo clinical evaluation

Objective: To formulate solid lipid microparticles (SLMs) encapsulating doxycycline hydrochloride (DH) and metronidazole (MT) for the treatment of periodontal diseases.

Methods: SLMs were prepared applying hot homogenization method, using different types of lipids and stabilized with various types and concentrations of surfactants. The optimized formula was subjected to freeze-drying followed by incorporation into poloxamer gel. Microbiological and clinical evaluation of the selected SLMs on patients suffering from periodontal diseases was performed.

Results: SLMs could entrap high percentage of both drugs (81.14% and 68.75 % for doxycycline hydrochloride and metronidazole respectively). Transmission electron microscopy images of SLMs showed nearly spherical particles. Freeze-dried SLMs showed satisfactory stability for three months. Combined drugs were molecularly dispersed in SLMs. Incorporation of the freeze-dried SLMs powder in poloxamer gel could control the drugs release for 72 h. In-vivo study revealed effective and safe use of SLMs gel for periodontitis treatment. Significant improvement in both microbiological and clinical parameters was observed as compared to scaling and root planing alone.

Conclusion: The formulated SLMs gel offers an applicable dosage form that can be injected directly into the periodontal pocket as adjunctive to scaling and root planing.     

Design,in vitro and in vivo evaluation of glipizide Eudragit microparticles

Glipizide microparticles made with Eudragit (RS 100 and RL 100), prepared by emulsion solvent evaporation technique were evaluated for various in-vitro properties viz. encapsulation efficiency, particle size and surface morphology, drug release pattern and in-vivo hypoglycaemic activity. The optimized formulation parameters were used to prepare smooth and spherical microparticles (2–32 µm) with higher entrapment efficiency (67–89%). Drug release patterns of glipizide microparticles of Eudragit RS 100 and Eudragit RL 100 with drug-to-polymer ratio of 1 : 4 (i.e. EGM14 and ELGM14) have shown gradual and extended release for 24 h with cumulative release of glipizide to the extent of 72.3% and 83.9%, respectively. However, EGM14 showed a significant in-vivo hypoglycaemic effect up to 12 h in rabbits while ELGM14 showed for 9 h. Hence, glipizide microparticles of Eudragit RS 100 (glipizide: polymer 1 : 4) is better suited for oral sustained release formulation.     

Ivermectin-loaded microparticles for parenteral sustained release: in vitro characterization and effect of some formulation variables

Ivermectin (IVM) is a BCS II drug with potent antiparasitic activity in veterinary applications. In this study, poly(lactide-co-glycolide) (PLGA) and poly(DL-lactide) (PLA) Ivermectin-loaded microparticles were prepared by the simple emulsion (O/W) solvent evaporation method in order to obtain sustained release formulations for parenteral applications. The effects of polymer end-groups (ester or free acid) and the addition of the hydrophilic polyvinylpyrrolidone polymer (PVP) in in vitro drug release profiles were also studied. X-ray diffraction (XRD) and differential scanning calorimetry (DSC) analysis showed that IVM was present in an amorphous state or as a molecular dispersion within the polymers or theirs mixtures with PVP and that a PVP-drug complex was formed. Drug entrapment efficiency in the microparticles (>90%) was independent of the polymer composition, the end groups and the presence of PVP. However, microscopic (SEM) observations showed that the addition of PVP led to more porous microparticles accompanied by the increased rates of drug release.     

Release of peptides from sustained delivery systems (microcapsules and microparticles) in vivo

Sustained delivery systems (microcapsules, microparticles, or implants) developed for once a month administration of peptides are efficacious and convenient. Long acting formulations of several bioactive peptides are based on microcapsules of a biodegradable polymer poly(dl -lactide-co-glycolide) (PLG), but a better understanding is required of the mechanism of the peptide release from the microcapsules, which is assumed to be primarily by diffusion through pores. In order to clarify this mechanism, microcapsules and microparticles of the agonist [d -Trp⁶]-LHRH and microcapsules of the LHRH antagonist SB-75 were given i.m. to rats 2 h and 1, 2, 4, 7, 14 and 21 days before histological and immunohistochemical investigation. Signs of biodegradation of the PLG matrix could be seen the first day after the injection, in a form of vacuole development in the interior of the particles and connected with the presence of macrophages within the matrix. The microcapsules showed excellent tissue-compatibility, and no significant foreign body reaction was detected. Immunohistochemical study on the microcapsules revealed no visible decrease in peptide concentration in the remnants of the matrix even 2 weeks after the injection. Evaluation of serum [d -TrP⁶]-LHRH showed that after an initial burst, both microcapsules and microparticles maintained elevated serum [d -Trp⁶]-LHRH levels for more than 3 weeks. Our results suggest that the previously proposed mechanisms do not reflect the experimental findings, particularly for the insoluble peptides. The peptide release from the PLG microcapsules or microparticles appears to be controlled mostly by the speed of the biodegradation of the polymer matrix and the diffusion of the peptides from the PGL is negligible.     

New in-situ gelling biopolymer-based matrix for bioavailability enhancement of glimepiride; in-vitro/in-vivo x-ray imaging and pharmacodynamic evaluations

Glimepiride (Gmp) a third generation of sulphonylurea is a weakly acidic hypoglycemic drug that belongs to Biopharmaceutical Classification System (BCS) class II. It suffers from poor solubility as well as erratic and variable therapeutic effect. The authors investigated the feasibility of utilizing two nontoxic and biodegradable biopolymers (casein (CA) and chitosan (CT)) as a new in-situ gelling tablet matrix to circumvent this limitation. Both polymers in different ratios were combined with constant dose of the drug and compressed by direct compression to produce constant weights of different tablet matrices. Basic tromethamine (Tris) was also included in each matrix as a pH modifier. Swelling indices, rheological properties of the swollen matrices, and their in-vitro drug release in simulating gastric fluid were assessed. The higher the ratio of casein in the tablet matrix, the lower its swelling index and the higher its viscosity indicate a shear thickening property. Intuitively, zero order drug diffusion in 0.1?N HCl prevailed for more than 8?hours from this gelled matrix. Both reduction of blood glucose level up till 11?hours and x-ray imaging of the selected tablets in the GIT of rabbits correlated well with the shear thickening properties. These findings propose a new stable, simple and affordable price matrix with large versatility.     

Topical drug delivery using chitosan nano- and microparticles

Introduction: Topical drug delivery offers important benefits for improving the therapeutic effect and reducing systemic side effects of the administered compounds. In addition, utilization of biopolymeric material-based systems can play a key role in developing new topical dosage forms and their applications. This review describes the advances that have been made, new strategies and as well as possible challenges of particular systems of chitosan used in topical drug delivery, including challenging innovations in topical usage of these systems that can make significant impact on clinical practice.

Areas covered: The main area covered is hypothesis that particulate carriers based on chitosan and its derivatives can penetrate the topical barriers from the body. For this reason, the novel studies described emphasize the fact that chitosan-based particular systems are popular that can be tailor-made according to in vitro and in vivo characterization. Such parameters, which are known to influence their in vivo performance, can be modulated by adjusting the formulation conditions of the chitosan-based particular systems for topical application.

Expert opinion: The topical application of drugs with particulate systems comprising a natural polymer, chitosan, is one of the most popular drug delivery routes. The aim of topical use of chitosan particles is to improve the drug bioavailability by prolonging the residence time of drugs applied topically or by enhancing the passing of drugs through the epithelial cells by opening the tight junctions between epithelial cells and also to reduce the side effects of the drugs.     

Catechin-loaded Eudragit microparticles for the management of diabetes: formulation,characterization and in vivo evaluation of antidiabetic efficacy

Catechin (CT) is natural molecule proved for antidiabetic activity. Clinical application of CT is highly restricted because of its low bioavailability and ineffectiveness in in vivo conditions. Therefore, the main objective of the present investigation was to formulate CT-loaded Eudragit RS 100 microparticles and evaluated for its potential against diabetes. CT microparticles showing highest entrapment efficiency of 92.3?±?6.5% and higher percentage yield of 63.46?±?4.3% was selected as optimised formulation. CT microparticles treated rats showed significantly lower blood glucose, cholesterol, LDL, free fatty acid and triglyceride concentrations in comparison to pristine CT-treated rats. The glucose and lipid profiles of microparticle formulation were akin to normal rats. Moreover, CT microparticles did not produce obesity even after 60 days which is a comment side effect of antidiabetic drugs. These results indicate that the CT microparticles can be applied as potential and safe carrier for the treatment of diabetes.     

Formulation and evaluation of novel solid lipid microparticles as a sustained release system for the delivery of metformin hydrochloride

Abstract

The low encapsulation efficiency of conventional solid lipid microparticles (SLMs) especially for hydrophilic drugs has remained a challenge to drug formulation experts. This work seeks to address the issue of inefficient delivery of metformin hydrochloride (MTH), a potent hydrophilic oral antihyperglycemic agent, using novel SLMs based on solidified reverse micellar solutions (SRMS) prepared by melt-emulsification using a lipid derived from Capra hircus and Phospholipon® 90H. Characterization based on size, morphology, zeta potential, polydispersity index, encapsulation efficiency (EE%), loading capacity (LC) and time-resolved stability were carried out on the SLMs. The in vitro release of MTH from the SLMs was performed in phosphate buffer (pH 7.4) while the in vivo antidiabetic properties were investigated in alloxan-induced diabetic rats. Stable, spherical and smooth SLMs were obtained. Loading of MTH into the SLMs had no effect on the surface charge of the particles. The SLMs with 1.0%w/w PEG 4000 resulted in significantly (p?<?0.05) higher EE% while those with 2.0%w/w gave the least. The LC values ranged from 20.3 to 29.1 and 14.6 to 24.1 for SLMs containing 500?mg and 250?mg of MTH, respectively. The in vitro release studies revealed significant release of MTH from the SLMs whereas the in vivo antidiabetic studies indicated that novel SLMs containing 500?mg of MTH gave significantly (p?<?0.05) higher glucose reduction than glucophage®. This research has shown that SLMs based on SRMS offer a new and better approach of delivering MTH, thus encouraging further development of this formulation.     

Preparation of honokiol-loaded chitosan microparticles via spray-drying method intended for pulmonary delivery

It has been demonstrated that spray-drying is a powerful method to prepare dry powders for pulmonary delivery. This paper prepared dispersible dry powders based on chitosan and mannitol containing honokiol nanoparticles as model drug. The results showed that the prepared microparticles are almost spherical and have appropriate aerodynamic properties for pulmonary delivery (aerodynamic diameters was between 2.8–3.3 μm and tapped density ranging from 0.14–0.?18?g/cm³). Moreover, surface morphology and aerodynamic properties of the powders were strongly affected by the content of mannitol. Fourier transform infra-red (FTIR) spectrum of powders indicated that the honokiol nanoparticles were successfully incorporated into microparticles. In vitro drug release profile was also observed. The content of mannitol in powders significantly influenced the release rate of honokiol from matrices.     

Formulation and evaluation of novel tableted chitosan microparticles for the controlled release of clozapine

Controlled release formulations of clozapine microparticulated tablets were prepared by using chitosan. Microparticles were characterized for particle size and size distribution. Microparticles were compressed into tablets using the directly compressible excipients. SEM photographs of the fractured part of the tablet revealed the presence of discrete particles in the tablets, suggesting that the system chosen is ideal for tableting. Drug release from the tableted microparticles exhibited an initial burst effect, but the release decreased with increasing extent of cross-linking. Tablets were coated with chitosan or cellulose acetate, which significantly lowered the initial burst effect when compared to uncoated tablets. Drug release from chitosan-coated tablets was slightly higher than the tablets coated with cellulose acetate. Tablets prepared were effective in delivering clozapine over a period of 12?h.     

Testosterone solid lipid microparticles for transdermal drug delivery. Formulation and physicochemical characterization

Purpose: The main objective of the study was to formulate and characterize testosterone (TS) solid lipid microparticles (SLM) to be applied as a transdermal delivery system.

Methods: Testosterone SLMs were formulated using an emulsion melt homogenization method. Various types and concentrations of fatty materials, namely glyceryl monostearate (GM), glyceryl distearate (GD), stearic acid (SA) and glyceryl behanate (GB) were used. The formulations contained 2.5 or 5?mg TS?g^?1. Morphology, particle size, entrapment efficiency (EE), rheological properties and thermal behaviour of the prepared SLM were examined. In vitro release characteristics of TS from various prepared SLM were also evaluated over 24?h using a vertical Franz diffusion cell. In addition, the effect of storage and freeze-drying on particle size and release pattern of TS from the selected formulation was evaluated.

Results: The results indicated that the type of lipid affected the morphology and particle size of SLM. A relatively high drug percentage entrapment efficiency ranging from 80.7–95.7% was obtained. Rheological studies showed plastic flow characteristics of the prepared formulations. DSC examination revealed that TS existed in amorphous form in the prepared SLM. Release studies revealed the following rank order of TS permeation through cellophane membrane after application of various formulations: 5% GM?<?5% GD?<?5% SA?<?5% GB?<?2.5% GM?<?2.5% SA?<?10% GD?<?10% GB. The drug permeation through excised abdomen rat skin after application of 10% GB–2.5?mg TS?g^?1 SLM was lower than that permeated through cellophane membrane. Moreover, SLM containing 10% GB–2.5?mg TS?g^?1 stored at 5°C showed good stability as indicated by the release study and particle size analysis. Trehalose showed high potential as a cryoprotectant during freeze drying of the selected SLM formulation.

Conclusions: The developed TS SLM delivery system seemed to be promising as a TS transdermal delivery system.     

Development and in-vivo evaluation of insulin-loaded chitosan phthalate microspheres for oral delivery

Novel chitosan phthalate microspheres containing insulin were prepared by emulsion cross-linking technique. The feasibility of these microspheres as oral insulin delivery carriers was evaluated. The pH-responsive release behaviour of insulin from microspheres was analysed. The ability of chitosan phthalate-insulin microspheres to enhance intestinal absorption and improve the relative pharmacological availability of insulin was investigated by monitoring the plasma glucose and insulin level of streptozotocin-induced diabetic rats after oral administration of microspheres at insulin dose of 20 IU kg(-1). In simulated gastric fluid (pH 2.0), insulin release from the microspheres was very slow. However, as the pH of the medium was changed to simulated intestinal fluid (pH 7.4), a rapid release of insulin occurred. The relative pharmacological efficacy for chitosan phthalate microspheres (18.66 +/- 3.84%) was almost four-fold higher than the efficacy of the chitosan phthalate-insulin solution administration (4.08 +/- 1.52%). Chitosan phthalate microspheres sustained the plasma glucose at pre-diabetic level for at least 16 h. These findings suggest that the microsphere is a promising carrier as oral insulin delivery system.     

Preparation of sustained release rifampicin microparticles for inhalation

Objectives The aim of this research was to develop a novel carrier‐free dry powder formulation of rifampicin for inhalation with controlled‐release properties. Methods Rifampicin dihydrate (RFDH) microcrystals were prepared by a polymorphic transformation of rifampicin. The prepared RFDH microcrystals were coated with poly (dl ‐lactide‐co‐glycolide) or poly (dl ‐lactide), using a spray‐dryer equipped with two different types of three‐fluid (3F) spray nozzles. The physicochemical and aerodynamic properties of the coated RFDH microcrystals were compared with those of conventional matrix microparticles. Key findings The coated RFDH powder, encapsulating 50% of rifampicin, was successfully prepared by simple in‐situ coating methods using two different types of 3F nozzles and had mass median aerodynamic diameter values of 3.5–4.5 µm . The thin flaky morphology of RFDH powders, providing good aerosolization properties, was maintained after coating. The coated RFDH formulations showed relatively low initial rifampicin release, compared with the uncoated RFDH crystals, followed by slow rifampicin release (about 70%) over 8 h in phosphate‐buffered saline media (pH 7.4). Significant chemical degradations were not observed from the crystalline‐structured RFDH formulations, while the amorphous‐structured matrix formulations showed chemical degradation in six months. Conclusions These polymer coated RFDH formulations may be a valuable alternative in the treatment of tuberculosis since the carrier‐free formulation offers the benefit of delivering a maximum‐potency formulation of the antibiotic directly to the site of infection, and long drug residence times may be achieved by the controlled release of the drug.     

Development and in vitro/in vivo evaluation of Zn-pectinate microparticles reinforced with chitosan for the colonic delivery of progesterone

The colon is a promising target for drug delivery owing to its long transit time of up to 78?h, which is likely to increase the time available for drug absorption. Progesterone has a short elimination half-life and undergoes extensive first-pass metabolism, which results in very low oral bioavailability (～25%). To overcome these shortcomings, we developed an oral multiparticulate system for the colonic delivery of progesterone. Zn-pectinate/chitosan microparticles were prepared by ionotropic gelation and characterized for their size, shape, weight, drug entrapment efficiency, mucoadhesion and swelling behavior. The effect of cross-linking pH, cross-linking time and chitosan concentration on progesterone release were also studied. Spherical microparticles having a diameter of 580–720?µm were obtained. Drug entrapment efficiency of ～75–100% was obtained depending on the microparticle composition. Microparticle mucoadhesive properties were dependent on the pectin concentration, as well as the cross-linking pH. Progesterone release in simulated gastric fluids was minimal (3–9%), followed by burst release at pH 6.8 and a sustained phase at pH 7.4. The in vivo study revealed that the microparticles significantly increased progesterone residence time in the plasma and increased its relative bioavailability to ～168%, compared to the drug alone. This study confirms the potential of Zn-pectinate/chitosan microparticles as a colon-specific drug delivery system able to enhance the oral bioavailability of progesterone or similar drugs.     

格列齐特缓释片的人体生物等效性

目的:进行试验制剂格列齐特缓释片和市售参比制剂达美康缓释片的人体生物等效性研究,评价缓释制剂的释放特点、稳态血浓度和波动度。方法:采用高效液相色谱法测定单剂和多剂交叉给药格列齐特经时血浓度,计算其药动学参数,并进行方差分析和双单侧t检验。结果:试验制剂和参比制剂单剂口服给药格列齐特半衰期(t1/2)为(24.2±2.5)h和(23.8±3.2)h,血浓度峰值(Cmax)为(1.9±0.6)mg.L-1和(2.2±0.5)mg.L-1,达峰时间(tmax)为(6.9±1.0)h和(6.4±1.0)h,药时曲线下面积(AUC0-72)为(54.7±14.2)mg.h.L-1和(58.8±16.4)mg.h.L-1,相对生物利用度(F)为(93.7±8.4)%。试验制剂和参比制剂多剂给药格列齐特AUCSS为(59.7±24.4)mg.h.L-1和(62.6±25.5)mg.h.L-1,Cmax为(3.4±1.3)mg.L-1和(3.8±1.4)mg.L-1,Cmin为(1.89±0.8)mg.L-1和(1.6±0.9)mg.L-1,波动系数(DF)为(61.3±17.9)%和(87.5±21.5)%,生物利用度F为(95.9±11.2)%。结论:格列齐特缓释制剂单剂和多剂双周期双交叉口服给药,3因素方差分析和双单侧t检验,格列齐特主要药动学参数符合生物等效的假设,为生物等效制剂。与市售参比制剂比,试验制剂缓释、波动度小的特征明显。     

Alginate-based sustained release drug delivery systems for tuberculosis

Drug delivery systems have wide biomedical applications owing to their distinct therapeutic advantages, such as controlled release of drugs over prolonged periods, protection against premature drug degradation, reduction in drug toxicity and drug–drug interactions. All these factors are important considerations in the treatment of chronic infectious diseases such as tuberculosis. In tuberculosis, patient non-compliance is a vexing problem which is responsible not only for treatment failure, but also for the emergence of multi-drug resistant cases. Alginate, a natural polymer, has attracted researchers owing to its ease of availability, compatibility with hydrophobic as well as hydrophilic molecules, biodegradability under physiological conditions, lack of toxicity and the ability to confer sustained release potential. It is not therefore surprising that the controlled release phenomenon of this polymer has been documented for a vast array of drugs. In particular, the ability of alginate to co-encapsulate multiple antitubercular drugs and offer a controlled release profile is likely to have a major impact in enhancing patient compliance for better management of tuberculosis.     

Alginate/chitosan microparticles for tamoxifen delivery to the lymphatic system

The efficacy of drug candidates is frequently limited by their inability to reach the target site of action, especially when they are administered through conventional dosage forms or drug delivery systems. Targeted drug delivery systems have increased the amount of drug reaching the site and simultaneously decrease the amount being distributed to other parts of the body. Microspheres have emerged as a remedial measure to improve site-specific drug delivery to a considerable extent. As an application, lung-targeting albumin loaded ofloxacin microspheres (ALOME) were prepared by water in oil emulsion method. The appearance and size distribution were examined by scanning electron microscopy, and the aspects such as in vitro release characteristics, stability, drug loading, loading efficiency, pharmacokinetics and tissue distribution in albino mice were studied. The experimental results showed that the microspheres have an average particle size of 11.32 μm. The drug loading and loading efficiency were (66.95 and 94.8%) respectively. The in vitro release profile of the microspheres matched the Korsmeyer's Peppas release pattern, and the release after 1 h was 42%, while for the original drug, ofloxacin, under the same conditions, 90.02% released in the first half an hour. After intravenous administration (15 min), the drug concentration of microspheres group in lung of albino mice was 432 μg g⁻¹ while that of controlled group was 1.32 μg g⁻¹ ALOME found to release the drug to a maximum extent in the target tissue, lung. Histopathological studies proved the tissue compatibility of ALOME to be safe.