Formulation of microemulsion systems for transdermal delivery of aceclofenac

An ONW microemulsion system was developed to enhance the skin permeability of aceclofenac. Of the oils studied, Labrafil M 1944 CS was chosen as the oil phase of the microemulson, as it showed a good solubilizing capacity. Pseudo-ternary phase diagrams were constructed to obtain the concentration range of oil, surfactant, Cremophor ELP, and co-surfactant, ethanol, for micoemulsion formation. Eight different formulations with various values of oil of 6-30%, water of 0-80%, and the mixture of surfactant and co-surfactant (at the ratio of 2) of 14-70%. The in vitro transdermal permeability of aceclofenac from the microemulsions was evaluated using Franz diffusion cells mounted with rat skin. The level of aceclofenac permeated was analyzed by HPLC and the droplet size of the microemulsions was characterized using a Zetasizer Nano-ZS. Terpenes were added to the microemulsions at a level of 5%, and their effects on the skin permeation of aceclofenac were investigated. The mean diameters of the microemulsions ranged between approximately 10-100 nm, and the skin permeability of the aceclofenac incorporated into the microemulsion systems was 5-fold higher than that of the ethanol vehicle. Of the various terpenes added, limonene had the best enhancing ability. These results indicate that the microemulsion system studied is a promising tool for the percutaneous delivery of aceclofenac.     

Novel chemical permeation enhancers for transdermal drug delivery

Transdermal drug delivery has been accepted as a potential non-invasive route of drug administration, with advantages of prolonged therapeutic action, decreased side effect, easy use and better patient compliance. However, development of transdermal products is primarily hindered by the low permeability of the skin. To overcome this barrier effect, numerous new chemicals have been synthesized as potential permeation enhancers for transdermal drug delivery. In this review, we presented an overview of the investigations in this field, and further implications on selection or design of suitable permeation enhancers for transdermal drug delivery were also discussed.     

A novel electronic skin patch for delivery and pharmacokinetic evaluation of donepezil following transdermal iontophoresis

The nature of Alzheimer's disease limits the effectiveness of available oral treatments. The aim of this study was to assess the feasibility of transdermal iontophoretic delivery of donepezil in a hairless rat model as a potential treatment modality in Alzheimer's and to evaluate the effect of current densities on its pharmacokinetics. Donepezil loaded integrated Wearable Electronic Drug Delivery (WEDD^®) patches supplied current levels of 0, 0.13, 0.26 and 0.39 mA. Plasma extracted donepezil was analyzed by HPLC. Noncompartmental analysis was used to characterize disposition of the drug. The amount delivered across hairless rat skin and areas under the curve (AUC) were found to rise in proportion to the current levels. Peak plasma levels of 0.094, 0.237 and 0.336 μg/ml were achieved at 0.13, 0.26 and 0.39 mA respectively. Time to peak plasma concentrations was after termination of current and same for all current levels. Transdermal elimination half-life was significantly increased from the true value of 3.2 h due to depot formation, prolonging complete absorption of the drug. Donepezil was successfully delivered iontophoretically at levels sufficient to produce pharmacodymanic effect. Pharmacokinetic analysis demonstrated linear kinetics at the current levels used and flip flop kinetics following iontophoretic administration.     

Development of transferosomal gel for trans-dermal delivery of insulin using iodine complex

Abstract

The main object of this current research was to examine transferosomes as a transdermal delivery system for insulin, to overwhelm the difficulties related with its subcutaneous delivery. Transferosomal gel formulations were prepared by rotary evaporation sonication technique. The result revealed that insulin was successfully entrapped (78%) in optimized formulations (2.5 I.U. of the drug and 25% of sodium cholate) with cumulative percent drug release (83.11?±?3.782). The glucose lowering study revealed that the transferosomal gel with chemical penetration enhancer showed better glucose lowering effect as compared to the control gel. Consequently, this study authenticated that the transferosomal gel can be used as a possible substitute to the conventional formulations of insulin with progressive permeation characteristics for transdermal application.     

Investigation of the carbopol gel of solid lipid nanoparticles for the transdermal iontophoretic delivery of triamcinolone acetonide acetate

The purpose of this study was to investigate solid lipid nanoparticles (SLN) hydrogel for transdermal iontophoretic drug delivery. Triamcinolone acetonide acetate (TAA), a glucocorticoids compound, was employed as the model drug. SLN containing the drug triamcinolone acetonide acetate (TAA-SLN) and their carbopol gel with stable physicochemical properties were prepared. The use of TAA-SLN carbopol gel as a vehicle for the transdermal iontophoretic delivery of TAA was evaluated in vitro using horizontal diffusion cells fitted with porcine ear skin. We found that the TAA-SLN gel possessed good stability, rheological properties, and high electric conductance. Transdermal penetration of TAA from TAA-SLN gel cross the skin tissue was significantly enhanced by iontophoresis. The enhancement of the cumulative penetration amount and the steady-state penetration flux of the penetrated drug were related to the particle size of TAA-SLN and the characteristics of the applied pulse electric current, such as density, frequency, and on/off interval ratio. These results indicated that SLN carbopol gel could be used as a vehicle for transdermal iontophoretic drug delivery under suitable electric conditions.     

Effect of permeation enhancers on transdermal delivery of fluoxetine: In vitro and in vivo evaluation

The aim of this study was to investigate the feasibility of transdermal fluoxetine (FX) delivery. The effects of chemical forms (base or salt) and permeation enhancers on in vitro skin permeation of FX were assessed using hairless mouse, rat and human cadaver skin. The optimized formulations from the in vitro studies were then evaluated in an in vivo pharmacokinetic study in rats. The in vitro skin permeation studies suggested that the FX base (FXB) and isopropyl myristate (IPM)–limonene mixture could be suitable for transdermal delivery of FX. The permeation parameters of FX through human cadaver skin were well correlated with that through hairless mouse and rat skin, suggesting that these animal models can be used for predicting the permeability of FX through human skin. After transdermal administration of FX with IPM or the IPM–limonene mixture to rats, the mean steady-state plasma concentration (C_ss) was 66.20 or 77.55 ng/mL, respectively, which was maintained over 36 h and had a good correlation with the predicted C_ss from the in vitro data. These in vitro and in vivo data demonstrated that permeation enhancers could be a potential strategy for transdermal delivery of FX.     

表面活性剂-醇质体增强多烯紫杉醇经皮给药的渗透性研究(英文)

皮肤的屏障作用使大部分药物无法实现透皮给药。本文以改善难溶性大分子模型药物多烯紫杉醇(docetaxel,DTX)的经皮渗透性为主体思路,研制了DTX的表面活性剂-醇质体(surfactant-ethanlic liposomes,SEL)。SEL由磷脂、乙醇、胆酸钠、DTX和磷酸盐缓冲液组成,采用薄膜分散法制备。对SEL的囊泡形态(冷冻蚀刻电镜法)、粒径大小及分布进行了表征,并测定包封率和载药量。采用体外扩散池实验研究了DTX表面活性剂-醇质体的经皮渗透性。结果表明,当磷脂与表面活性剂的比例为85:15时,DTX的稳态透皮速率和累计透皮量均为最高,且优于表面活性剂脂质体、醇质体和普通脂质体。最优处方的粒径分布、形态和载药量均较为稳定。本研究表明,通过将DTX包载于SEL中可显著改善DTX的经皮渗透性。     

Passive and iontophoretic transdermal delivery of phenobarbital: Implications in paediatric therapy

The objective of this investigation was to evaluate phenobarbital transdermal delivery for possible use in paediatric care. In vitro experiments were performed using intact pig skin and barriers from which the stratum corneum had been stripped to different extents to model the less resistant skin of premature babies. Cathodal iontophoretic delivery of phenobarbital was superior to anodal transport and optimised delivery conditions were achieved by reduction of competing co-ion presence in the drug formulation. Phenobarbital transport across intact or partially compromised skin was controlled by iontophoresis which was more efficient than passive diffusion. Across highly compromised skin, however, passive diffusion increased drastically and iontophoretic control was lost. Overall, this study demonstrates the feasibility of phenobarbital transdermal delivery for paediatric patients.     

Formulation and evaluation of ketorolac transdermal systems

The effects of pressure-sensitive adhesives and vehicles on the in vitro permeation of ketorolac and in vivo pharmacokinetics were studied. Duro-Tak 87-2196® showed the highest in vitro permeation profiles, and propylene glycol monolaurate-diethylene glycol monoethyl ether (DGME) (60:40, v/v) and propylene glycol monocaprylate-DGME (60:40, v/v) revealed the most favorable in vitro and in vivo results. The decreased C_max and prolonged T_max and half-life were obtained with the ketorolac transdermal systems compared with oral administration, indicating that the ketorolac transdermal systems may have a prolonged effect with reduced toxic event. There was an excellent relationship found between in vitro permeation flux and in vivo AUC_0-∞.     

Iontophoresis: a potential emergence of a transdermal drug delivery system

The delivery of drugs into systemic circulation via skin has generated much attention during the last decade. Transdermal therapeutic systems propound controlled release of active ingredients through the skin and into the systemic circulation in a predictive manner. Drugs administered through these systems escape first-pass metabolism and maintain a steady state scenario similar to a continuous intravenous infusion for up to several days. However, the excellent impervious nature of the skin offers the greatest challenge for successful delivery of drug molecules by utilizing the concepts of iontophoresis. The present review deals with the principles and the recent innovations in the field of iontophoretic drug delivery system together with factors affecting the system. This delivery system utilizes electric current as a driving force for permeation of ionic and non-ionic medications. The rationale behind using this technique is to reversibly alter the barrier properties of skin, which could possibly improve the penetration of drugs such as proteins, peptides and other macromolecules to increase the systemic delivery of high molecular weight compounds with controlled input kinetics and minimum inter-subject variability. Although iontophoresis seems to be an ideal candidate to overcome the limitations associated with the delivery of ionic drugs, further extrapolation of this technique is imperative for translational utility and mass human application.     

Optimization of ibuprofen gel formulations using experimental design technique for enhanced transdermal penetration

The aims of this study were to develop a transdermal gel formulation for ibuprofen using experimental design techniques and to evaluate its pharmacokinetic properties. The three factors chosen for factorial design were the concentrations of drug, polyoxyethylene(5)cetyl/oleyl ether and ethanol and the levels of each factor were low, medium and high. Skin permeation rates and lag times of ibuprofen were evaluated using the Franz-type diffusion cell in order to optimize the gel formulation. The permeation rate of ibuprofen significantly increased in proportion to the drug concentration, but significantly decreased in proportion to POE(5)cetyl/oleyl ether concentration. Ethanol concentration was inversely proportional to the lag time. The pharmacokinetic properties of the optimized formulation were compared with those of two marketed products in rats. The relative bioavailability of ibuprofen gel compared to the two marketed products was 228.8% and 181.0%. In conclusion, a transdermal ibuprofen gel was formulated successfully using the technique of experimental design and these results helped in finding the optimum formulation for transdermal drug release.     

A polysaccharide-based hydrogel as a green platform for enhancing transdermal delivery

The potential role of using carrageenan/locust bean gum (coded as κC: LBG) hydrogel to enhance transdermal delivery of hydrophilic actives was investigated in this study. To this purpose, κC:LBG hydrogel embedded with arbutin (coded as κC:LBG:AR) was investigated for their viscosity, physical-chemical, thermal and morphological properties, in vitro cytotoxicity, and release profile, and the in vivo performance was compared to arbutin cream. The κC:LBG:AR hydrogel showed viscosity values higher than those found in κC:LBG. Overall, both hydrogels demonstrated smooth surfaces and are cytocompatible in vitro. DSC showed that κC:LBG:AR hydrogel enhanced transdermal delivery through the skin by changing the structural organization of the lipid bilayer. The κC:LBG:AR hydrogel showed a significant increase in skin hydration and reduction in the melanin index as compared with commercial cream. These findings suggest that κC:LBG hydrogel possesses great potential to be used as a green platform for enhancing transdermal delivery.     

氟康唑脂质体凝胶的制备及体外透皮实验（英文）

目的制备氟康唑脂质体凝胶,并研究其性质。方法以薄膜分散法制备氟康唑脂质体,透射电镜观察脂质体的形态,粒度分布仪测定粒径,透皮吸收扩散池测定脂质体凝胶的透皮吸收。结果氟康唑脂质体的包封率为47.68%。脂质体粒径均匀,平均粒径为250±8nm。氟康唑脂质体凝胶的累积透过量（25.27%）低于非脂质体凝胶（36.72%）,而脂质体凝胶的药物皮内滞留量（162±15μg·cm^-2于非脂质体凝胶（48±6μg·cm^-2结论氟康唑脂质体凝胶剂可显著提高药物的皮内滞留量,有望成为氟康唑的一种外用新剂型。     

Development and characterization of transdermal drug delivery systems for diltiazem hydrochloride

Transdermal drug delivery system of diltiazem hydrochloride was developed to obtain a prolonged controlled drug delivery. Both the matrix diffusion controlled (MDC) and membrane permeation controlled (MPC) systems were developed. The matrix diffusion controlled systems used various combinations of hydrophilic and lipophillic polymers, whereas membrane permeation controlled systems were developed using the natural polymer chitosan. The MDC systems were prepared using the cast film method and the MPC systems by an adhesive sealing technique. Both the systems were characterized for in vitro and in vivo performance. The MDC systems were characterized for physicochemical properties such as tensile strength, moisture content, and water vapor transmission. The in vitro release studies showed that the release from the matrix diffusion controlled transdermal drug delivery systems follows a nonfickian pattern and that from the membrane permeation controlled transdermal drug delivery systems follow zero-order kinetics. The release from the matrix systems increased on increasing the hydrophilic polymer concentration, but the release from the membrane systems decrease on cross-linking of the rate controlling membrane and also on addition of citric acid to the chitosan drug reservoir gel. The in vivo studies of the selected systems showed that both systems are capable of achieving the effective plasma concentration for a prolonged period of time. The MPC system achieved effective plasma concentration a little more slowly than the MDC system, but it exhibited a more steady state plasma level for 24 hr.     

In vitro and in vivo iontophoretic transdermal delivery of an anti-parkinsonian agent

To objective of this work was to study the feasibility of iontophoretic delivery of SLV 318 (7-(4-benzyl-1-piperazinyl)-2(3H)-benzoxazolone methanesulfonate) across hairless rat skin in vitro and in vivo. The effect of counter-ions and temperature were investigated for optimizing SLV 318 solubility. The effect of electrode efficiency and total current applied on the delivery of SLV 318 were studied using Franz diffusion cells and samples were analyzed using HPLC. Delivery increased with increasing concentration. For current-time combinations, electrode had to be replaced every 9 h. Passive, iontophoretic (0.1 mA/cm² for 1 h) and intravenous studies were performed in vivo. Blood samples collected were analyzed using LC-MS/MS. SLV 318 had higher solubility with NaCl (75 mM) as a counter-ion at 25 °C than with other counter-ions tested. In vivo iontophoresis significantly enhanced the permeation and also reduced its lag time (P < 0.05). The C_max of SLV 318 during 1 h iontophoresis was 6.56 ± 0.68 ng/mL at 1.31 ± 0.29 h (T_max) as compared to 2.96 ± 0.29 ng/mL at 25.32 ± 0.67 h (T_max) by 24 h passive permeation. The in vitro and in vivo data has shown the feasibility to enhance delivery of SLV 318 by iontophoresis.     

不同基质和透皮促进剂对秋水仙碱凝胶剂体外透皮特性的影响

目的优选秋水仙碱凝胶剂基质和相应的透皮促进剂,为制备秋水仙碱透皮给药新制剂提供参考资料。方法采用改良的Franz扩散池法,并通过RP-HPLC法测定接收液中秋水仙碱的含量。结果3种基质的秋水仙碱凝胶体外透皮比率为Carbopol基质凝胶>HPMC基质凝胶>CMC-Na基质凝胶。以Carbopol为基质,加入几种透皮促进剂后,秋水仙碱凝胶的体外透皮速率为丙二醇>冰片>氮酮>薄荷油。结论凝胶剂作为秋水仙碱透皮吸收新剂型可行。     

Potential and problems of developing transdermal patches for veterinary applications

A new frontier in the administration of therapeutic drugs to veterinary species is transdermal drug delivery. The primary challenge in developing these systems is rooted in the wide differences in skin structure and function seen in species ranging from cats to cows. The efficacy of a transdermal system is primarily dependent upon the barrier properties of the targeted species skin, as well as the ratio of the area of the transdermal patch to the species total body mass needed to achieve effective systemic drug concentrations. A drug must have sufficient lipid solubility to traverse the epidermal barrier to be considered for delivery for this route. A number of insecticides have been developed in liquid ‘pour-on’ formulations that illustrate the efficacy of this route of administration for veterinary species. The human transdermal fentanyl patch has been successfully used in cats and dogs for post-operative analgesia. The future development of transdermal drug delivery systems for veterinary species will be drug and species specific. With efficient experimental designs and available transdermal patch technology, there are no obvious hurdles to the development of effective systems in many veterinary species.     

Poloxamer gel as vehicle for transdermal iontophoretic delivery of arginine vasopressin: evaluation of in vivo performance in rats

The present study describes the formulation and evaluation for pharmacokinetic and pharmacodynamic activity of arginine vasopressin (AVP), a nanopeptide with antidiuretic activity on being delivered by transdermal iontophoresis. Poloxamer 407 was used to form stable gels that did not reduce the release of AVP. The release rate from the gel followed Higuchi kinetics indicating that the dominant mechanism of release is diffusion. Iontophoresis alone and in combination with chemical enhancers was used to augment the transdermal permeation of AVP. The results of both pharmacokinetic and pharmacodynamic studies emphasize the dimension of 'rapid onset' achieved by iontophoresis. The correlation between pharmacokinetic data and pharmacodynamic activity was only qualitative. Histopathological studies revealed that skin toxicity caused by either iontophoresis or chemical enhancers when used alone could be reduced by using a combination of both the techniques in tandem.     

Selection of high efficient transdermal lipid vesicle for curcumin skin delivery

Curcumin shows effective anti-inflammatory activities but is seldom used in clinic because of its poor solubility in water and vulnerablity to sunshine ultraviolet effect. Novel lipid vesicles have been developed as carriers for skin delivery. In this paper, lipid vesicles—propylene glycol liposomes (PGL), Ethosomes and traditional liposomes, were prepared as curcumin carriers respectively. Their morphology, particle size and encapsulation efficiency and drug release behavior in vitro were evaluated. Transdermal efficiency and deposition quantity in abdominal skin were also measured with Franz diffusion device. Carrageenan-induced paw edema was established to evaluate the anti-inflammatory effect. From the result, the particle size order of lipid vesicles was: PGL (182.4 ± 89.2 nm) < Ethosomes (289 ± 132.1 nm) < traditional liposomes (632.9 ± 184.1 nm). The order of particle dispersion coefficient was as the same as that of particle size. The sequence of encapsulation efficiency was: PGL > Ethosomes > traditional liposomes. PGL had the best encapsulation efficiency of 92.74 ± 3.44%. From anti-inflammatory experiment, PGL showed the highest and longest inhibition on the development of paw edema, followed by Ethosomes and Traditional liposomes. With the elevated entrapment efficiency, good transdermic ability and sustained-release behavior, PGL may represent an efficient transdermal lipid vesicle for skin delivery.