Preparation and characterization of biodegradable urea-loaded microparticles as an approach for transdermal delivery

This work describes the formulation and characterization of urea-loaded microspheres prepared using various polymers such as ethyl cellulose (EC), cellulose acetate phthalate (CAP) and poly (D,L-lactic-co-glycolic acid) (PLGA), along with the utilization of a solvent evaporation technique. The effect of various formulation parameters (i.e. polymer type and concentration, vehicle type, polymer solution/vehicle volume ratio, drug/polymer ratio, homogenizer and stirrer speed, sonication time and speed, type of washing solution, drying and separation method) on the characteristics of microspheres was also evaluated. Results obtained indicated that, in the presence of urea, highest rate of EC microsphere production could be obtained at a drug/polymer ratio of 1:2 and a polymer solution/vehicle volume ratio of 1:50. In some cases, crystallization of urea was observed during the encapsulation process using cellulose derivative polymers. CAP microparticles showed a rough and tortuous surface while EC microparticles had a wider range of particle size. However, with the PLGA polymer, much better desired microparticles with a smaller size range of 1-3 microm were obtained. In general, PLGA microspheres were spherical in shape and possessed smooth surfaces with less pores in comparison with those obtained by the other polymers. The yield of particle production and the extent of urea encapsulation in PLGA particles were measured to be 68.87% +/- 5.3 and 40.5% +/- 3.4, respectively. The release study from PLGA microspheres revealed that up to 70% of the drug was released within a few days, through a four-stage release pattern.     

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.     

Solid lipid microparticles as an approach to drug delivery

Introduction: Solid lipid particles were introduced in the early 1990s as an alternative drug carrier system to emulsions, liposomes and polymeric microparticles. Although lipid nanoparticles have been the object of a substantial number of reviews, fewer are available on lipid microparticles (LMs), despite their distinct advantages, including biocompatibility, ease of production and characterisation, extended release properties and high loading.

Areas covered: This review presents an overview of the advantages and drawbacks of LMs, that is, lipid-based particles with dimensions in the micrometre range. Specific focus is on the role of the main excipients used for LM formulations, lipids and surfactants and their effects on LM properties. An update on preparation techniques and characterisation methods are also presented, with particular emphasis on more recent technologies. The interaction of LMs with biological systems and with cells in particular is reviewed. The various LM administration routes are examined, with special attention to most recent applications (i.e., pulmonary and nasal delivery).

Expert opinion: LMs represent attractive and versatile carrier systems; however, their pharmaceutical applicability has been rather limited. Investigation on the use of LMs for less-established administration routes, such as pulmonary delivery, may provide further interest within the area of LM-based systems, both in industry and in the clinic.     

盐酸维拉帕米PLGA纳米粒的成型工艺及制剂学性质研究

目的 优化影响盐酸维拉帕米乳酸/羟基乙酸共聚物(PLGA)纳米粒成型工艺的参数,并评价优化工艺后所制纳米粒的制剂学性质.方法 采用O/W超声乳化-溶剂挥发法制备盐酸维拉帕米PLGA纳米粒(VRP-PLGANP),以粒径、包封率和载药量为评价指标,采用单因素试验系统考察PLGA浓度、PLGA/VRP质量比、PVA浓度、有机相中丙酮浓度、外水相pH、内外相(O/W)体积比、探头超声时间、旋蒸时间共8个参数对纳米粒成型工艺的作用规律.结果 用优化处方工艺制备的纳米粒的包封率和载药量分别为65.78%±6.32%和22.75%±1.48%、平均粒径为150.4±6.9 nm、PDI=0.070±0.018(n=3),体外释放规律符合Weibull方程,具有一定的缓释特性.结论 所用方法可用于制备载两亲性药物的PLGA纳米粒.     

GM-1缓释微球的制备及体外释药特性研究

目的:制备GM-1的乳酸/羟基乙酸共聚物(PLGA)微球,考察其一般性质和体外释药特性。方法:应用W/O/W型乳化溶剂干燥法制备GM-1的PLGA微球,测定微球粒径、载药量、包封率和体外释药曲线。结果:微球形态规则,粒径约为(18±8)μm,载药量约为4.9%,包封率约为61%,微球体外释药规律符合Higuichi方程Q=0.153t1/2+0.03705(r=0.9950)。结论:GM-1微球体外释药特性及其制备工艺良好,体外具有明显缓释作用。     

尼索地平微球的制备

采用溶剂挥发法制备了尼索地平微球 ,考察了制备工艺中影响微球质量的 5个主要因素 ,筛选出较理想的处方和工艺。所得微球形态圆整 ,表面光滑 ,粒径 (18.2± 3.8) μm,载药量 2 1.2 % ,包封率 85 .4 %。     

Topical delivery of urea encapsulated in biodegradable PLGA microparticles: O/W and W/O creams

This study describes the formulation and characterization of O/W and W/O creams containing urea-loaded microparticles prepared with poly (D, L-lactic-co-glycolic acid) (PLGA) in order to encapsulate and stabilize urea. The solvent evaporation method was used for preparing PLGA microparticles containing urea. The microparticles size was evaluated by laser light diffractometry. The resulting microparticles were then incorporated in O/W and W/O creams and stability and the release pattern from the creams was evaluated by UV-spectrophotometry. The particle size of PLGA microparticles was in the range of 1–5 µm and most microparticles had a particle size smaller than 3 µm. The encapsulation efficiency was calculated as 40.5%?±?3.4. This study also examined release pattern of urea which varied among different formulations. The results showed that the release from O/W creams followed Higuchi kinetics while the release from W/O creams showed the zero order kinetics and the creams containing microparticulated urea had slower release than free urea creams.     

Long-term controlled release of PLGA microparticles containing antidepressant mirtazapine

The aim of the study was to prepare PLGA microparticles for prolonged release of mirtazapine by o/w solvent evaporation method and to evaluate effects of PVA concentration and organic solvent choice on microparticles characteristics (encapsulation efficiency, drug loading, burst effect, microparticle morphology). Also in vitro drug release tests were performed and the results were correlated with kinetic model equations to approximate drug release mechanism. It was found that dichloromethane provided microparticles with better qualities (encapsulation efficiency 64.2%, yield 79.7%). Interaction between organic solvent effect and effect of PVA concentration was revealed. The prepared samples released the drug for 5 days with kinetics very close to that of zero order (R^2?=?0.9549 – 0.9816). According to the correlations, the drug was probably released by a combination of diffusion and surface erosion, enhanced by polymer swelling and chain relaxation.     

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.     

In vitro dissolution of pH sensitive microparticles for colon-specific drug delivery

Objective: The objective of this work is to prepare oral dosage systems based on enteric materials in order to verify their possible use as Colon-Specific Drug Delivery Systems (CSDDSs).

Methodology: In particular, three different copolymers of methyl-methacrylate (MMA) - acrylic acid (AA) are synthesized with increasing percentage of MMA (from 70% to 73%) and they are used to produce microparticles by the double-emulsion solvent evaporation method. The microparticles, loaded using theophylline as model drug, are then tested for drug release under varying pH to reproduce what happens in the human GI tract.

Results: All the investigated systems have shown an effective pH sensitiveness: they show a good gastro-resistance, releasing the model drug only at higher pH, small intestine or colon, depending on the kind of used copolymer.

Conclusion: The results confirm the usefulness of both the materials and the methods proposed in this study for colon-specific delivery applications.     

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.     

Carboxymethyl xanthan microparticles as a carrier for protein delivery

Xanthan gum (XG) was derivatized to sodium carboxymethyl xanthan gum (SCMXG) and then cross-linked with aluminium ions (Al⁺³) to prepare BSA-loaded microparticles (MPs) from a completely aqueous environment. The derivatized gum was characterized by various physical methods. Discrete and spherical BSA-loaded MPs were obtained from SCMXG solution, the pH of which was adjusted to 6 and 7 and the BSA entrapment efficiency was found to reach as high as 82%. The protein release in acidic dissolution medium was faster than that in alkaline dissolution medium and was accounted for the higher swelling ratio of the MPs in acidic environment. Moreover, the pH of the gum solution used to prepare the MPs also influenced the swelling and consequently protein release considerably.     

Thrombin receptor agonist peptide entrapped in poly(D,L)-lactide-co-glycolide microparticles: Preparation and characterization

Thrombin receptor agonist peptide (TRAP-6) could advantageously replace thrombin in terms of accelerating wound healing being less expensive and more stable. To promote TRAP-6 pharmacological action as a tissue reconstruction stimulator this study investigated its entrapment within poly(D,L)-lactide-co-glycolide (PLGA) microparticles. Due to its low molecular weight and water solubility, TRAP-6 microencapsulated form is expected to be more useful. This paper reports TRAP-6 microencapsulation by a double (w/o/w) emulsion-evaporation technique. TRAP-6 release kinetics were evaluated by both chemical (HPLC) and biological assays in vitro. The results revealed a high level of TRAP-6 sensitivity to physico-chemical events during the microencapsulation. The surface morphology difference between control microparticles (without TRAP-6) and microparticles with entrapped TRAP-6 during in vitro degradation highlighted a particular role of TRAP-6. The results can allow one to optimize the microencapsulation procedure and to encounter a new promising approach to development of biodegradable polymer drug delivery systems for wound healing.     

PLGA-based biodegradable microspheres in drug delivery: recent advances in research and application

Biodegradable microspheres have been widely used in the field of medicine due to their ability to deliver drug molecules of various properties through multiple pathways and their advantages of low dose and low side effects. Poly (lactic-co-glycolic acid) copolymer (PLGA) is one of the most widely used biodegradable material currently and has good biocompatibility. In application, PLGA with a specific monomer ratio (lactic acid and glycolic acid) can be selected according to the properties of drug molecules and the requirements of the drug release rate. PLGA-based biodegradable microspheres have been studied in the field of drug delivery, including the delivery of various anticancer drugs, protein or peptide drugs, bacterial or viral DNA, etc. This review describes the basic knowledge and current situation of PLGA biodegradable microspheres and discusses the selection of PLGA polymer materials. Then, the preparation methods of PLGA microspheres are introduced, including emulsification, microfluidic technology, electrospray, and spray drying. Finally, this review summarizes the application of PLGA microspheres in drug delivery and the treatment of pulmonary and ocular-related diseases.     

Co-encapsulation of dexamethasone 21-acetate and SPIONs into biodegradable polymeric microparticles designed for intra-articular delivery

Objective: Intra-articular drug delivery systems still suffer from too short-lasting effects. Magnetic particles retained in the joint using an external magnetic field might prolong the local release of an anti-inflammatory drug. For the purpose, superparamagnetic iron oxide nanoparticles (SPIONs) and dexamethasone 21-acetate (DXM) were co-encapsulated into biodegradable microparticles.

Methods: Poly(D,L-lactide-co-glycolide) microparticles embedding both SPIONs and DXM were prepared by a double emulsion technique. The formulation was optimized in two steps, a screening design and a full factorial design, aiming at 10-μm particle diameter and high DXM encapsulation efficacy.

Results: The most significant parameters were the polymer concentration, the stirring speed during solvent extraction and the extractive volume. Increasing the polymer concentration from 200 to 300 mg ml^?1, both the microparticle mean diameter and the DXM encapsulation efficacy increased up to 12 μm and 90%, respectively. The microparticles could be retained with an external magnet of 0.8 T placed at 3 mm. Faster DXM release was obtained for smaller microparticles.

Conclusion: The experimental set-up offered the tools for tailoring a formulation with magnetic retention properties and DXM release patterns corresponding to the required specifications for intra-articular administration.     

Influence of the primary emulsification procedure on the characteristics of small protein-loaded PLGA microparticles for antigen delivery

Microparticles prepared from poly(lactic-co-glycolic acid) (PLGA) using a W₁/O/W₂ double emulsion solvent evaporation method are suitable vehicles for the delivery of proteins to antigen presenting cells, e.g. dendritic cells. In this study, the influence of different techniques for the preparation of the primary W₁/O emulsion was investigated with respect to the protein localization within the microparticles, morphological characteristics of these particles, protein burst release and the native state of the released protein. Bovine serum albumin bearing fluorescein isothiocyanate (FITC-BSA) was used as model protein. A static micromixer was applied for the preparation of the W₁/O/W₂ double emulsion. Employing a rotor-stator homogenizer (Ultra-Turrax®) for primary emulsification, microcapsules with a high burst release were produced, because nearly all FITC-BSA was attached to the outside of the particle wall. Using a high pressure homogenizer or an ultrasonic procedure resulted in the formation of microspheres with homogeneous protein distribution and a reduced burst release.     

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.     

Resveratrol solid lipid microparticles as dry powder formulation for nasal delivery,characterization and in vitro deposition study

This study focuses on development and in vitro characterisation of a nasal delivery system based on uncoated or chitosan-coated solid lipid microparticles (SLMs) containing resveratrol, a natural anti-inflammatory molecule, as an effective alternative to the conventional steroidal drugs. The physico-chemical characteristics of the SLMs loaded with resveratrol were evaluated in terms of morphology, size, thermal behaviour and moisture sorption. The SLMs appeared as aggregates larger than 20?μm. In vitro nasal deposition was evaluated using a USP specification Apparatus E 7-stage cascade impactor equipped with a standard or a modified nasal deposition apparatus. More than 95% of resveratrol was recovered onto the nasal deposition chamber and stage 1 of impactor, suggesting that the SLMs mostly deposited in the nasal cavity. Additionally, the SLMs were not toxic on RPMI 2650 nasal cell line up to a concentration of approximately 40?μM of resveratrol.     

In vivo and in vitro characteristics for insulin-loaded PLA microparticles prepared by w/o/w solvent evaporation method with electrolytes in the continuous phase

Insulin-loaded poly(lactide) (PLA) microparticles were successfully prepared by 6% w/v PLA in the organic phase, 10% w/v PVP and varied types of 5%w/v electrolytes in the continuous phase, by using a water-in-oil-in-water emulsion/solvent extraction technique. Addition of electrolytes such as NaCl, CaCl₂ into the external phase significantly improved insulin entrapment efficiency compared to the case of no additives. NaCl was the most effective for obtaining high entrapment efficiency, with microparticle yield 81.2%, trapping efficiencies 49%, insulin-loading level 5.5% w/w and mean particle size 14.8?µm. The distribution (%) of insulin on the PLA microparticles surface, outer layer and core were 8, 37 and 43%, respectively. The cumulative release of insulin had an upper limit of ～24% of the insulin load at 24 days. A steady release rate was 0.5?µg insulin/mg microparticles/day of insulin release maintained for 24 days. Total protein-leaking amount was reduced after addition of electrolytes in the continuous aqueous phase. Rabbit glucose levels were evaluated after subcutaneous 20?mg insulin-loaded PLA microparticles or PLA blank microparticles. Study results show that the insulin-loaded PLA microparticles significantly reduced the glucose level than PLA blank microparticles. The insulin-loaded PLA microparticles, physicochemical characterization data and the animal result obtained in this study may be relevant in optimizing the PLA microparticle formulation incorporation and delivery insulin carriers.     

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 degrees 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.