Oral delayed-release system based on Zn-pectinate gel (ZPG) microparticles as an alternative carrier to calcium pectinate beads for colonic drug delivery.

A new oral timed-release system was developed for colon-targeted delivery of drugs. The system which consists of ketoprofen-loaded Zn-pectinate gel (ZPG) microparticles together with pectin/dextran mixtures in a tablet form, has been investigated, in vitro, using conditions chosen to simulate the pH and times likely to be encountered during transit to the colon. In order to find the suitable ZPG microparticles, the formulations were prepared by utilizing 2(3) factorial design and the effect of various formulation factors on the release and surface characteristics of the microparticles was studied. The results obtained implied that the release of ketoprofen from ZPG microparticles was greatly extended with the pectinate microparticles, which were prepared with 2.5 or 3% w/v pectin, 2.75% w/v Zn(CH3COO)2 and 2.5% w/v drug. Additionally, the analysis of variance results showed that the release of ketoprofen in simulated intestinal fluid (S.I.F., pH 7.4) was strongly affected by crosslinking agent concentration and initial drug amount, but not particularly affected by the amount of pectin added. The investigated drug concentration factor has significantly increased the drug entrapment efficiency (EE). The optimum colonic drug delivery ZPG/tablet system provided the expected delayed-release sigmoidal patterns with a lag-time of 4.125-4.85 h and t(50%) (the time for 50% of the drug to be released) at 7.45-8.70 h, depending on pectin/dextran ratio employed. The results also demonstrated that the untableted ZPG microparticles exhibited drug release profiles which were able to retard the release of ketoprofen in S.I.F. (pH 7.4) to be 5.28-37.82 times (depending on formulation parameters), lower than the conventional calcium pectinate beads. Therefore, this approach suggests that ZPG microparticles and their modified-release formulations are promising as useful controlled-release carriers for colon-targeted delivery of drugs.     

The effect of pectin on swelling and permeability characteristics of free films containing Eudragit RL and/or RS as a coating formulation aimed for colonic drug delivery

BACKGROUND AND THE PURPOSE OF THE STUDY: The potential of pectin as a bacterially degradable polysaccharide for colon drug delivery has been demonstrated. Due to the high solubility and swelling properties of pectin in aqueous media, it is frequently used in combination with water insoluble polymers for targeting drugs to the colon. The aim of this study was to evaluate free films containing pectin as a bacterially-degradable polysaccharide in combination with Eudragit RL (ERL) and/or RS (ERS) as a coating formulation for colonic drug delivery. METHODS: Isolated free films comprising 20% pectin and 80% ERL or ERS and their combination in 1:1 ratio were prepared by casting method. Then, free films were evaluated by water vapor transmission (WVT), swelling and permeability experiments for theophylline and indomethacin in different media. RESULTS: Formulations containing ERL exhibited higher WVT, swelling and permeability compared with formulations containing ERS. The permeability of theophylline through free films composed of pectin and eudragit polymers in simulated colonic media was not significantly different from those obtained in other media. However indomethacin free films containing pectin and ERL showed higher permeation in simulated colonic fluid (SCF) compared to the other media. MAJOR CONCLUSION: Formulation containing pectin and ERL may be suitable as a coating formulation for colon targeted delivery of drugs of low solubility such as indomethacin.     

Gastroretentive microparticles for drug delivery applications

Many strategies have been proposed to explore the possibility of exploiting gastroretention for drug delivery. Such systems would be useful for local delivery, for drugs that are poorly soluble at higher pH or primarily absorbed from the proximal small intestine. Generally, the requirements of such strategies are that the vehicle maintains controlled drug release and exhibits prolonged residence time in the stomach. Despite widespread reporting of technologies, many have an inherent drawback of variability in transit times. Microparticulate systems, capable of distributing widely through the gastrointestinal tract, can potentially minimise this variation. While being retained in the stomach, the drug content is released slowly at a desired rate, resulting in reduced fluctuations in drug levels. This review summarises the promising role of microencapsulation in this field, exploring both floating and mucoadhesive microparticles and their application in the treatment of Helicobacter pylori, highlighting the clinical potential of eradication of this widespread infection.     

Konjac glucomannan/xanthan gum enzyme sensitive binary mixtures for colonic drug delivery

The polysaccharide konjac glucomannan (KGM) is degraded in the colon but not the small intestine, which makes it potentially useful as an excipient for colonic drug delivery. With xanthan gum (XG) KGM forms thermoreversible gels with hitherto unexplored biodegradation properties. In this work, rheological measurements of KGM and KGM/XG systems incubated with and without Aspergillus niger beta-mannanase (used to mimic colonic enzymes) showed that KGM was degraded by the enzyme even when interacting with XG. Tablets with KGM/XG/sucrose matrices that varied in accordance with a simplex design and bore diltiazem as a typical highly soluble drug load were prepared by wet granulation, and in most cases were found to possess satisfactory mechanical strength and exhibit slow, nearly zero-order drug release. Drug release from these tablets remained zero-order, but was accelerated (presumably due to degradation of KGM), in the presence of A. niger beta-mannanase at concentrations equivalent to human colonic conditions. However, marked differences between Japanese and American varieties of KGM as regards degree of acetylation and particle size led to significant differences in swelling rate and drug release between formulations prepared with one and the other KGM: whereas a formulation with Japanese KGM released its entire drug load within 24h in the presence of beta-mannanase, only 60% release was achieved under the same conditions by the corresponding formulation with American KGM, suggesting that with this KGM it will be necessary to optimize technological variables such as compression pressure in order to achieve suitable porosity, swelling rate, and drug release. To sum up, the results of this study suggest that sustained release of water-soluble drugs in the colon from orally administered tablets may be achieved using simple, inexpensive formulations based on combinations of KGM and XG that take the variability of KGM characteristics into account.     

PEGylated-PLGA microparticles containing VEGF for long term drug delivery

The potential of poly(lactic-co-glycolic) acid (PLGA) microparticles as carriers for vascular endothelial growth factor (VEGF) has been demonstrated in a previous study by our group, where we found improved angiogenesis and heart remodeling in a rat myocardial infarction model (Formiga et al., 2010). However, the observed accumulation of macrophages around the injection site suggested that the efficacy of treatment could be reduced due to particle phagocytosis.     

Inhalable, bioresponsive microparticles for targeted drug delivery in the lungs

Objective There is a growing interest in developing bioresponsive drug delivery systems to achieve greater control over drug release than can be achieved with the conventional diffusion controlled polymeric delivery systems. While a number of such systems have been studied for oral or parenteral delivery, little or no work has been done on bioresponsive delivery systems for inhalation. Using the raised elastase levels present at sites of lung inflammation as a proof‐of‐concept model, we endeavoured to develop a prototype of inhalable elastase sensitive microparticles (ESMs). Methods Microparticles degradable by the enzyme elastase were formed by crosslinking the polymer alginate in the presence of an elastase substrate, elastin, using Ca⁺² ions and subsequent spray drying. Key findings The bioresponsive release of a protein cargo in the presence of elastase demonstrated the enzyme‐specific degradability of the particles. The microparticles showed favorable properties such as high drug encapsulation and good powder dispersibility. Potential polymer toxicity in the lungs was assessed by impinging the microparticles on Calu‐3 cell monolayers and assessing changes in transepithelial permeability and induction of cytokine release. The microparticles displayed no toxic or immunogenic effects. Conclusions With a manufacturing method that is amenable to scale‐up, the ability to be aerosolised efficiently from a first‐generation inhaler device, enzyme‐specific degradability and lack of toxicity, the ESMs show significant promise as pulmonary drug carriers.     

An investigation into the characteristics of chitosan/Kollicoat SR30D free films for colonic drug delivery

The purpose of the study was to establish the physico-mechanical, digestibility, permeability and swelling properties of chitosan/Kollicoat SR30D films as potential coatings for colonic drug delivery. Free films containing different ratios of chitosan to Kollicoat SR30D were prepared by casting/solvent evaporation method. The resultant mixed films were characterized in terms of puncture strength and elongation (%), glass transition temperature, swellability, polymer miscibility, permeability, and digestibility under different media. The mixed films possessed good mechanical properties, which could be used as film-coating materials for drug delivery. The extent of digestion was directly proportional to the amount of chitosan present within the film. No apparent miscibility was detected between the chitosan and Kollicoat SR30D, regardless of the film composition. The films were found to be susceptible to digestion by bacterial or β-glucosidase enzymes in simulated colonic fluid (SCF). The SCF with rat cecal bacterial enzymes had a more profound hydrolytic activity than that with β-glucosidase enzyme for the digestion of chitosan within the mixed films. Overall, the results indicated that such chitosan/Kollicoat SR30D films had potential as a coating system for drug delivery to the colon.     

新型肺部吸入微球的制备及性质的研究

目的 制备并研究用于肺部给药的新型微球给药系统.方法 利用喷雾干燥技术干燥载药固体脂质纳米粒(SLNs)胶体溶液,制备成肺部吸入微球,并研究微球的基本粉体学性质及SLNs、模型药物胸腺五肽的稳定性.结果 微球表面呈多孔形,具有较小的粒径4.8±0.4μm、较低的堆密度0.48±0.02 g·cm~(-3)、实密度0.71±0.06 g·cm~(-3).微球具有良好的吸人特性,排空率为85.0%±2.8%,有效部位沉积率为61.6%±3.0%,且能有效地分布到肺泡内.制备过程中的SLNs和胸腺五肽能保持很好的稳定性.结论 新型微球具有适宜的吸入特性,是一种具有应用前景的肺部给药系统.     

Use of spray-dried chitosan acetate and ethylcellulose as compression coats for colonic drug delivery: Effect of swelling on triggering in vitro drug release

Spray-dried chitosan acetate (CSA) and ethylcellulose (EC) were used as new compression coats for 5-aminosalicylic acid tablets. Constrained axial or radial swelling of pure CSA and EC/CSA tablets in 0.1 N HCl (stage I), Tris-HCl, pH 6.8 (stage II), and acetate buffer, pH 5.0 (stage III), was investigated. Factors affecting invitro drug release, i.e., % weight ratios of coating polymers, dip speeds of dissolution apparatus or pH of medium or colonic enzyme (β-glucosidase) in stage III, and use of a super disintegrant in core tablets, were evaluated. Swollen CSA gel dissolved at lower pH and became less soluble at higher pH. The mechanism of swelling was Fickian diffusion fitting well into both Higuchi’s and Korsmeyer-Peppas models. EC:CSA, at 87.5:12.5% weight ratio, provided lag time rendering the tablets to reach stage III (simulated colonic fluid of patients), and the drug was released over 90% within 12 h. The system was a dual time- and pH-control due to the insolubility of EC suppressing water diffusion and the swelling of CSA in the stages I and II. The erosion of CSA gel in the stage III induced the disintegration of the coat resulting in rapid drug release. The lower dip speed and higher pH medium delayed the drug release, while a super disintegrant in the cores enhanced the drug release and no enzyme effect was observed.     

Evaluation of PEG and mPEG-co-(PGA-co-PDL) microparticles loaded with sodium diclofenac

The aim of this study was to synthesize and evaluate novel biodegradable polyesters namely; poly(ethylene glycol)-Poly(glycerol adipate-co-ω-pentadecalactone), PEG-PGA-co-PDL-PEG, and poly(ethylene glycol methyl ether)-Poly(glycerol adipate-co-ω-pentadecalactone), PGA-co-PDL-PEGme as an alternative sustained release carrier for lung delivery compared with non-PEG containing polymer PGA-co-PDL. The co-polymers were synthesized through lipase catalysis ring opening polymerization reaction and characterized using GPC, FT-IR, ¹H-NMR and surface contact angle. Furthermore, microparticles containing a model hydrophilic drug, sodium diclofenac, were prepared via spray drying from a modified single emulsion and characterized for their encapsulation efficiency, geometrical particle size, zeta potential, tapped density, primary aerodynamic diameter, amorphous nature, morphology, in vitro release and the aerosolization performance. Microparticles fabricated from mPEG-co-polymer can be targeted to the lung periphery with an optimum in vitro deposition. Furthermore, a significantly higher in vitro release (p > 0.05, ANOVA/Dunnett’s) was observed with the PEG and mPEG-co-polymers compared to PGA-co-PDL. In addition, these co-polymers have a good safety profile upon testing on human bronchial epithelial, 16HBE14o- cell lines.     

原位凝胶应用于眼部给药研究进展

眼用原位凝胶具有独特的作用特点及优势,能显著提高药物的生物利用度。本文从眼用原位凝胶的分类、特点等方面进行了详细的介绍,并总结近年来国内外相关文献资料。作为一种新型制剂,眼用即型凝胶具有广阔应用前景。在眼部给药领域必将得到越来越多的关注和研究。     

Enhancing cytotoxicity of daunorubicin on drug-resistant leukaemia cells with microparticle-mediated drug delivery system

Multidrug resistance is considered as a major obstacle for effective tumour chemotherapy. With the ability to deliver drugs into tumour cells, microparticles may act as a drug delivery vehicle to overcome drug resistance. In the present study, we developed an approach employing daunorubicin-loaded microparticles to surmount the drug resistance in leukaemia. The microparticles, derived from the drug-sensitive cells K562 and the drug-resistant cells K562/ADR, composed of cellular material, can effectively package drugs using intracellular and extracellular drug-loading method, respectively. The results demonstrated that the microparticles significantly improved the drug anti-tumour effect, which was influenced by the preparation methods and the source of donor cells. We further confirmed that the uptake of microparticles is mediated by an energy-driven endocytic process and mainly associated with clathrin-independent endocytosis and macropinocytosis. These results indicated that the microparticle could serve as a promising drug vehicle for the treatment of drug-resistant leukaemia.     

From nanoemulsions to self-nanoemulsions,with recent advances in self-nanoemulsifying drug delivery systems (SNEDDS)

Introduction: Lipid-based drug delivery systems (LBDDS) are the most promising technique to formulate the poorly water soluble drugs. Nanotechnology strongly influences the therapeutic performance of hydrophobic drugs and has become an essential approach in drug delivery research. Self-nanoemulsifying drug delivery systems (SNEDDS) are a vital strategy that combines benefits of LBDDS and nanotechnology. SNEDDS are now preferred to improve the formulation of drugs with poor aqueous solubility.

Areas covered: The review in its first part shortly describes the LBDDS, nanoemulsions and clarifies the ambiguity between nanoemulsions and microemulsions. In the second part, the review discusses SNEDDS and elaborates on the current developments and modifications in this area without discussing their associated preparation techniques and excipient properties.

Expert opinion: SNEDDS have exhibit the potential to increase the bioavailability of poorly water soluble drugs. The stability of SNEDDS is further increased by solidification. Controlled release and supersaturation can be achieved, and are associated with increased patient compliance and improved drug loads, respectively. Presence of biodegradable ingredients and ease of large-scale manufacturing combined with a lot of ‘drug-targeting opportunities’ give SNEDDS a clear distinction and prominence over other solubility enhancement techniques.     

温敏性壳聚糖凝胶的阿霉素药物体外缓释研究

目的 壳聚糖辅以甘油磷酸钠制成温敏性凝胶，将该温敏性凝胶用作阿霉素药物栽体并观察其缓释特性。方法 制备负载阿霉素的温敏性壳聚糖凝胶，建立体外持续流动释放系统，应用紫外分光光度法测定阿霉素的含量，对该栽药凝胶进行体外的缓释实验。结果 制备了负载阿霉素的温敏性壳聚糖凝胶，并得到了其缓释曲线。结论 该温敏性凝胶能够用于负载并释放阿霉素，这为改善阿霉素使用途径提供了实验基础。     

In vivo pharmacokinetic study for the assessment of poly(L-aspartic acid) as a drug carrier for colon-specific drug delivery

Glucocorticoids remain one of the mainstays of therapy for acute attacks of inflammatory bowel disease despite systemic side effects that limit their use. Prodrugs that selectively deliver glucocorticoids to the colon may lower the required dose and side effects. Because enzymes of gut microflora are able to cleave certain peptide and ester bonds, the ability of an ester prodrug consisting of dexamethasone (DX) as model drug and poly(L-aspartic acid) (weight-average mol wt=30,000) as drug carrier was investigated to selectively release the drug in the large intestine. Prodrug and drug solutions (1.18 mg DX/ml DMSO) were administered to two groups of male Sprague-Dawley rats by intragastric infusion using an ALZET^® osmotic pump. All rats were infused for sufficient time to achieve steady state in both blood and GI-tract tissues. DX concentrations in blood and tissue samples were measured with HPLC. The steady state DX concentrations at these sites were used to calculate a drug delivery index (DDI). DX blood concentrations were significantly lower (p<0.05) after intragastric administration of the prodrug. Moreover, prodrug administration resulted in significantly higher DX concentrations in the cecum and colon mucosa and the cecum muscle tissue compared to DX administration (p<0.05). The prodrug led to an increase of the DX concentration in the large intestinal tissues by factors of 1.3–2.0 and to an 1.3-fold decrease of DX blood concentrations. Thus, this novel conjugate should both increase efficacy and reduce toxicity to some extent.     

The potential of magneto-electric nanocarriers for drug delivery

Introduction: The development and design of personalized nanomedicine for better health quality is receiving great attention. In order to deliver and release a therapeutic concentration at the target site, novel nanocarriers (NCs) were designed, for example, magneto-electric (ME) which possess ideal properties of high drug loading, site-specificity and precise on-demand controlled drug delivery.

Areas covered: This review explores the potential of ME-NCs for on-demand and site-specific drug delivery and release for personalized therapeutics. The main features including effect of magnetism, improvement in drug loading, drug transport across blood?brain barriers and on-demand controlled release are also discussed. The future directions and possible impacts on upcoming nanomedicine are highlighted.

Expert opinion: Numerous reports suggest that there is an urgent need to explore novel NC formulations for safe and targeted drug delivery and release at specific disease sites. The challenges of formulation lie in the development of NCs that improve biocompatibility and surface modifications for optimum drug loading/preservation/transmigration and tailoring of electrical–magnetic properties for on-demand drug release. Thus, the development of novel NCs is anticipated to overcome the problems of targeted delivery of therapeutic agents with desired precision that may lead to better patient compliance.     

Combination of time-dependent and pH-dependent polymethacrylates as a single coating formulation for colonic delivery of indomethacin pellets

The objective of this study was to evaluate the combination of pH-dependent and time-dependent polymers as a single coating for design of colon delivery system of indomethacin pellets. Eudragit S100 and Eudragit L100 were used as pH-dependent polymers and Eudragit RS was used as a time-dependent polymer. A statistical full factorial design was used in order to optimize formulations. Factors studied in design were percent of Eudragit RS in combination with Eudragit S and L and coating level. Dissolution studies of pellets in the media with different pH (1.2, 6.5, 6.8 and 7.2) showed that drug release in colon could be controlled by addition of Eudragit RS to the pH-dependent polymers. The lag time prior to drug release was highly affected by coating level. With combination of two factors, i.e. the percent of Eudragit RS and coating level, the optimum formulation was found to be the one containing 20% Eudragit RS, 64% Eudragit S and 16% Eudragit L, and a coating level of 10%. This formulation was reproduced and tested in continuous condition of dissolution, and also separately at pH 7.5. The results of in vitro experiments indicate that the proposed combined time-dependent and pH-dependent polymethacrylate polymer coating may provide a colonic delivery system for indomethacin.     

Brain delivery of intranasal in situ gel of nanoparticulated polymeric carriers containing antidepressant drug: behavioral and biochemical assessment

This study was aimed for brain delivery of Tramadol HCl (centrally acting synthetic opioid) following intranasal administration for treatment of depression. Chitosan nanoparticles (NPs) were prepared by ionic gelation method followed by the addition of developed NPs with in the Pluronic and HPMC-based mucoadhesive thermo-reversible gel. Developed formulation optimized based on the various parameters such as particle size, entrapment efficiency, in vitro release study. Depression induction was done by forced swim test and evaluated by various behavioral and biochemical parameters. Furthermore, results showed significantly increased in locomotors activity, body weight as compared to control group. It also showed alteration in biochemical parameters such glutathione level and catalase levels significantly increased other than lipid peroxidation and nitrite level was found to be decreased after intranasal administration of formulation. Thus, intranasal TRM HCl NP-loaded in situ gel was found to be a promising formulation for the treatment of depression.