Enhanced permeation parameters of optimized nanostructured simvastatin transdermal films: ex vivo and in vivo evaluation

Abstract

Objective: Detailed optimization process was carried out to enhance permeation parameters, and hence bioavailability, of simvastatin (SMV) transdermal films.

Methods: SMV solubility was investigated in various oils, surfactants and co-surfactants/co-solvents. Mixtures of the selected components were prepared to identify zone of nanoemulsion formation that was utilized in Extreme Vertices mixture design to develop SMV self-nanoemulsifying drug delivery systems (SNEDDS) with minimum globule size. Optimized SMV-SNEDDS were included in the preparation of transdermal films. A fractional factorial design was implemented to evaluate effects of the factors on the amount of SMV permeated. The optimized film was investigated for ex vivo skin permeation and in vivo pharmacokinetic parameters.

Results: The optimum SNEDDS formula was 0.09, 0.8 and 0.11 for Sefsol 218, tween 80 and PEG 200, respectively. Fractional factorial design depicted the optimized SMV transdermal film with 2% HPMC and 2% DMSO as permeation enhancer that showed 1.82-fold improvements in skin flux. The pharmacokinetic data showed higher C_max and almost doubled AUC compared with raw SMV-loaded films.

Conclusion: The two-step optimization implemented to optimize and control the experimental conditions for the preparation of SMV-SNEDDS-transdermal film with improved ex vivo skin permeation and enhanced in vivo parameters.     

Drug crystallization – implications for topical and transdermal delivery

ABSTRACT

Introduction: Crystallization of actives in skin following topical application was suggested by studies in the 1950s and 1960s but is poorly understood. In contrast, the problem of crystallization of actives on skin and in transdermal formulations has been known for many years.

Areas covered: With respect to crystallization in skin, this review describes early reports of a skin ‘reservoir’ and possible reasons underlying its genesis. Techniques to study crystallization on and in skin and in transdermal patches are outlined. The role of the vehicle in skin delivery is emphasised. Studies which have investigated permeation from crystalline particles are described. Approaches to limit crystallization of actives are discussed. Using supersaturation and antinuclean polymers, control of crystal size is possible; controlled release from crystals is also employed in transdermal patches.

Expert Opinion: Drug crystallization has significant implications for topical and transdermal delivery. Approaches have been developed to counteract the issue for transdermal patches but crystallization in and on the skin for other formulations remains unresolved. Greater knowledge of residence time of excipients and their interaction with skin at the molecular level is critical in order to address the problem. This will lay the foundations for better design of topical/transdermal formulations.     

Synthesis of Conjugated Chitosan and its Effect on Drug Permeation from Transdermal Patches

The aim of this study was to synthesis the conjugated chitosan by covalent attachment of thiol moieties to the cationic polymer, mediated by a carbodiimide to improve permeation properties of chitosan. Thioglycolic acid was covalently attached to chitosan by the formation of amide bonds between the primary amino groups of the polymer and the carboxylic acid groups of thioglycolic acid. Hence, these polymers are called as thiomers or thiolated polymers. Conjugation of chitosan was confirmed by Fourier transform-infrared and differential scanning calorimetric analysis. Matrix type transdermal patches of carvedilol were prepared using the different proportions of chitosan and chitosan-thioglycolic acid conjugates (2:0, 1.7:0.3, 1.4:0.6, 1:1, 0.6:1.4 and 0.3:1.7) by solvent casting technique. Prepared matrix type patches were evaluated for their physicochemical characterization followed by in vitro evaluation. Selected formulations were subjected for their ex vivo studies on Wistar albino rat skin and human cadaver skin using the modified Franz diffusion cell. As the proportion of conjugated chitosan increased, the transdermal patches showed increased drug permeation. The mechanism of drug release was found to be nonFickian profiles. The present study concludes that the transdermal patches of carvedilol using conjugated chitosan with different proportions of chitosan were successfully developed to provide improved drug permeation. The transdermal patches can be a good approach to improve drug bioavailability by bypassing the extensive hepatic first-pass metabolism of the drug.     

Development and optimization of curcumin-loaded mannosylated chitosan nanoparticles using response surface methodology in the treatment of visceral leishmaniasis

Objective: The study aims at formulation and optimization of macrophage-targeted curcumin-loaded mannosylated chitosan nanoparticles (Cur-MCNPs) of curcumin (CUR) to improve its therapeutic potential in the treatment of visceral leishmaniasis (VL).

Methods: Response surface methodology (RSM) using central composite design was employed to study the effect of formulation factors on physicochemical-dependent characteristics. Chitosan was coupled with d-mannose, by reductive amination, to prepare a mannosylated chitosan, a conjugate polymer and a subsequent formulation of Cur-MCNPs. Optimized formulation prepared using RSM was evaluated for in vitro release kinetics at physiological pH 7.4 and endosomal macrophage pH 4.5; in vivo pharmacokinetic profile and targeting potential were evaluated by fluorescence microscopy.

Results: Optimized Cur-MCNPs exhibited spherical and smooth surface with a mean particle size of 215 nm, polydispersity index of 0.381, zeta potential of + 24.37 mV and % entrapment efficiency of 82.12%. The pharmacokinetic study of optimized Cur-MCNPs showed significant improvement in the value of mean resident time (39.38 h) compared to free CUR solution (0.30 h) (p < 0.05). In vivo uptake study indicated that endocytosis took place effectively within the macrophages of reticuloendothelial system.

Conclusions: Thus, Cur-MCNPs could be considered as a promising delivery strategy towards active targeting of CUR to macrophages for the effective treatment of VL.     

Texturing formulations for uranium skin decontamination

Abstract

Context: Since no specific treatment exists in case of cutaneous contamination by radionuclides such as uranium, a nanoemulsion comprising calixarene molecules, known for their good chelation properties, was previously designed. However, this fluid topical form may be not suitable for optimal application on the skin or wounds.

Objective: To develop a texturing pharmaceutical form for the treatment of wounded skins contaminated by uranium.

Materials and methods: The formulations consisted in oil-in-water (O/W) nanoemulsions, loaded with calixarene molecules. The external phase of the initial liquid nanoemulsion was modified with a combination of thermosensitive gelifying polymers: Poloxamer and HydroxyPropylMethylcellulose (HPMC) or methylcellulose (MC). These new formulations were characterized then tested by ex vivo experiments on Franz cells to prevent uranyl ions diffusion through excoriated pig ear skin explants.

Results: Despite strong changes in rheological properties, the physico-chemical characteristics of the new nanoemulsions, such as the size and the zeta potential as well as macroscopic aspect were preserved. In addition, on wounded skin, diffusion of uranyl ions, measured by ICP-MS, was limited to less than 5% for both HPMC and MC nanoemulsions.

Conclusions: These results demonstrated that a hybrid formulation of nanoemulsion in hydrogel is efficient to treat uranium skin contamination.     

Nanoemulsions as potential vehicles for transdermal and dermal delivery of hydrophobic compounds: an overview

Introduction: In recent years, nanoemulsions have been investigated as potential drug delivery vehicles for transdermal and dermal delivery of many compounds especially hydrophobic compounds in order to avoid clinical adverse effects associated with oral delivery of the same compounds. Droplet size and surface properties of nanoemulsions play an important role in the biological behavior of the formulation.

Areas covered: In this review, current literature of transdermal and dermal delivery of hydrophobic compounds both in vitro as well as in vivo has been summarized and analyzed.

Expert opinion: Nanoemulsions have been formulated using a variety of pharmaceutically acceptable excipients. In many cases of dermal and transdermal nanoemulsions, the skin irritation or skin toxicity issues on human beings have not been considered which needs to be evaluated properly. In the last decade, much attention has been made in exploring new types of nanoemulsion-based drug delivery system for dermal and transdermal delivery of many hydrophobic compounds. This area of research would be very advantageous for formulation scientists in order to develop some nanoemulsion-based formulations for their commercial exploitation and clinical applications.     

Strategies for delivering local anesthetics to the skin: focus on liposomes,solid lipid nanoparticles,hydrogels and patches

Introduction: Dermal and transdermal drug delivery systems offer the possibility to control the release of the drug for an extended period of time. In particular, skin-delivery of local anesthetics (LA) is one of the most important strategies to increase the local drug concentration and to reduce systemic adverse reactions.

Areas covered: During the development phase of new formulations for skin-delivery of LA one should consider a set of desirable features such providing suitable adhesion, easy application/removal and also to be biocompatible, biodegradable and non-toxic. This review emphasizes the main strategies for skin-delivery of LA considering those features in relation to the composition of the delivery systems described. The topics highlight the relationships between physico-chemical studies and pharmaceutical applications for liposomes and solid lipid nanoparticles as well as the formulation and clinical applications for hydrogels and patches.

Expert opinion: The development of LA skin-delivery systems using hydrogels and different permeation enhancers, liposomes or lipid nanoparticles (as isolated carrier systems or as their dispersion in a gel-base) and patches have been explored as alternatives to commercial formulations, modifying the release rate of LA, increasing bioadhesive properties and reducing toxicity, resulting in an improved therapeutic efficacy. This review should provide to the reader a special emphasis on four delivery-systems, comprising the group of liposomes and lipid nanoparticles, hydrogels and patches technologies looking forward their application for skin anesthesia.     

Rapid pain relief using transdermal film forming polymeric solution of ketorolac

Context: Ketorolac is one of the most potent nonsteroidal anti-inflammatory drugs and is an attractive alternative to opioids for pain management.

Objective: Development and evaluation of transdermal ketorolac film forming polymeric solution.

Materials and methods: Eudragits^® RLPO, RSPO and E100 as well as polyvinyl pyrrolidone K30 dissolved in ethanol were used as film forming solutions. In vitro experiments were conducted to optimize formulation parameters. Different permeation enhancers were monitored for potentiality of enhancing drug permeation across excised pigskin.

Results: The use of 10% oleic acid, Lauroglycol^® 90 or Azone^® with 5% Eudragit^® RSPO, showed the highest enhancement effect on ketorolac skin permeation and showed faster analgesic effect compared to the ketorolac tablet. The formula comprising 5% Eudragit^® RSPO and 10% Lauroglycol^® 90 showed the greatest pharmacodynamic effect and thus was subjected to pharmacokinetic studies. The pharmacodynamic and pharmacokinetic results didn’t run paralleled to each other, as the ketorolac tablets showed higher plasma concentrations compared to the selected ketorolac transdermal formulation. This might be due to the induction of analgesia by the available ethanol in the transdermal preparation.

Conclusion: Optimized transdermal ketorolac formulation showed marked ability to ensure fast and augmented analgesic effect that is an essential request in pain management.     

Proniosomal transdermal therapeutic system of losartan potassium: development and pharmacokinetic evaluation

The purpose of the current study was to investigate the feasibility of proniosomes as transdermal drug delivery system for losartan potassium. Different preparations of proniosomes were fabricated using different nonionic surfactants, such as Span 20, Span 40, Span 60, Span 80, Tween 20, Tween 40, and Tween 80. Different formulae were prepared and coded as PNG-1 (proniosomal gel-1) to PNG-7. The best in vitro skin permeation profile was obtained with proniosomal formulation PNG-2 in 24?h. The permeability parameters such as flux, permeability coefficient, and enhancement ratio were significant for PNG-2 compared with other formulations (P?<?0.05). This optimized PNG-2 was fabricated in the form of transdermal patch using HPMC gel as a suitable base. Proniosomal transdermal therapeutic system (PNP-H) was found to be the optimized one as it gave better release of drug and better permeation in a steady-state manner over a desired period of time, that is, 24?h through rat skin. In vivo pharmacokinetic study of PNP-H showed a significant increase in bioavailability (1.93 times) compared with oral formulation of losartan potassium. The formulation appeared to be stable when stored at room temperature (30?±?2°C) and at refrigeration temperature (4?±?2°C) for 45 days.     

Novel Biomaterial for Transdermal Application: In vitro and In vivo Characterization

The objective of the present study was to evaluate a novel film forming biomaterial for its potential application in the preparation of unilaminate transdermal adhesive matrix systems. The biomaterial, Damar Batu (DB), was tried alone and in combination with Eudragit RL100 as a matrixing agent in the preparation of transdermal patches. Developed transdermal patches of Diltiazem hydrochloride (DH) were evaluated for thickness uniformity, weight uniformity, folding endurance and drug content. USP dissolution apparatus V was used for in vitro drug release studies. Modified Franz diffusion cell used for permeation study using excised human cadaver skin. Total 6 formulations were developed and on the basis of in vitro drug release and in vitro skin permeation profile F5 composed of DB: Eudragit RL100 (60:40) and carrying 20 %w/w DH was selected as an optimized formulation for in vivo study. The in vivo study results showed that F5 achieved the Cmax of about 269.76?±?1.52?ng/mL in 6?h and sustained the release of the drug till 24?h. The skin irritation study results proved that the novel biomaterial is non-sensitizing and non-irritating. Drug-polymer interaction study carried out to check the compatibility of drug and polymer showed the intactness of the drug in the formulation proving the compatibility of the polymer. It can be proposed from the outcome of the present study that by applying suitable adhesive layer and backing membrane, DB: Eudragit RL100 (60:40) transdermal patches can be of potential therapeutic use.     

Drug in adhesive type transdermal matrix systems of ondansetron hydrochloride: optimization of permeation pattern using response surface methodology

The present investigation aims at development of pressure sensitive adhesive (PSA) based drug in adhesive type transdermal systems of ondansetron hydrochloride with higher permeation flux. The effect of mixture of two chemical permeation enhancers (oleic acid and lauric acid diethanolamide); and drug loading dose on the ex vivo human cadaver skin permeation from the transdermal patches has been investigated using a d-optimal combined mixture design. Incorporation of chemical permeation enhancers significantly improved the permeability parameters and it was also found that blend of permeation enhancers is more effective than either permeation enhancer. Criterion of desirability was employed to numerically optimize the transdermal system. Optimized formulation was achieved with 67.5% lauric acid diethanolamide, 32.5% oleic acid and 10% drug loading in an acrylate based PSA matrix. Optimized formulation was found to be nonirritating and safe for dermatological application.     

Transdermal therapeutic system of isradipine: Effect of hydrophilic and hydrophobic matrix on <Emphasis Type="Italic">In Vitro</Emphasis> and <Emphasis Type="Italic">Ex vivo</Emphasis> characteristics

Isradipine (ISDP) is an effective calcium channel blocker used in the treatment of hypertension. It undergoes extensive first pass metabolism and bioavailability through the oral route is only about 15 to 24%. Hence we attempted to develop a matrix type controlled transdermal drug delivery system for ISDP. Formulations A1, A2, A3 were composed of Eudragit RL100 and hydroxypropyl methyl cellulose (HPMC) in 1:3, 1:1, 3:1 ratios; A4, A5, A6 were composed of Eudragit RS100 and HPMC in 1:3, 1:1, 3:1 ratios. All six formulations carried 5 mg of ISDP/patch area, 5% v/w of D-limonene, 15 % v/w of propylene glycol in methanol:dichloromethane (1:1). The physicochemical compatibility of the drug and the polymers was studied by infrared spectroscopy and differential scanning calorimetry. The results suggested no physicochemical incompatibility between the drug and the polymers. The prepared transdermal drug delivery system were evaluated for physicochemical characteristics, mainly in vitro release and ex vivo permeation. The ex vivo permeation studies were carried out across excised rat skin using Franz diffusion cell. All the formulations exhibited satisfactory physicochemical characteristics. Cumulative amount of the drug released in 36 h from the six formulations were 1695.32, 1527.89, 1455.54, 1485.65, 1282.81 and 916.88 μg/cm² respectively. Corresponding values for the cumulative amounts of drug permeated across the rat skin for the above matrix films were 1456.29, 1284.70, 1182.99, 1212.72, 1046.05, and 782.60 μg/cm² respectively. By fitting the data into zero order, first order and Higuchi models, it was concluded that drug release from matrix films followed Higuchi model and the mechanism of drug release was diffusion mediated. Based on the physical evaluation, in vitro drug release and ex vivo permeation characteristics, it was concluded that for potential therapeutic use, monolithic drug matrix films A1, may be suitable for the development of a transdermal drug delivery system of ISDP.     

Application of methyl methacrylate copolymers to the development of transdermal or loco-regional drug delivery systems

Introduction: Methyl methacrylate copolymers (Eudragit®) have been exploited to develop transdermal patches, medicated plasters (hereinafter patches) and, more recently, film-forming sprays, microsponges and nanoparticles intended to be applied on the skin.

Areas covered: The article reviews the information regarding the application of Eudragits in the design and development of these dosage forms focusing on the impact of formulative variables on the skin drug penetration and the patch adhesive properties.

Expert opinion: Eudragits combined with a large amount of plasticizers are used to design the pressure-sensitive adhesives, specialized materials used in the patch development. They have to assure the drug skin penetration and the contact with the skin. Most of the studies mainly deal with the former aspect. The authors used a Eudragit type opportunely plasticized to merely investigate the in vitro or in vivo skin permeability of a loaded drug. However, the summa of these data evidenced that a strict connection between the matrix hydrophilicity and drug penetration probably exists. The criticisms of adhesion are addressed in a limited number of papers reporting data on technological properties, namely tack, shear adhesion and peel adhesion, while the structural data of the Eudragit adhesives, rheology and surface free energy are not described, excepting the case of Eudragit E. Among other applications, micro- and nanosystems exploiting the ionizable nature of some Eudragits can offer novel opportunities to develop pH-sensitive drug delivery systems suitable for triggering its release onto the skin.     

Formulation,in vitro,and in vivo evaluation of matrix-type transdermal patches containing olanzapine

Transdermal patches of olanzapine were aimed to be prepared to overcome the side effects by oral application. The strategy was formulation of eudragit-based polymeric films to prepare transdermal patches by using nonionic (span-20), anionic (sodium lauryl sulfate), cationic surfactant (benzalkonium chloride), and vegetable oil (olive oil) as permeation enhancers. The patches were subjected to physicochemical, in vitro release and ex vivo permeation studies. On the basis of in vitro release performance, ERL 100:ERS 100 in the ratio of 3:2 was selected for incorporation of permeation enhancers. The permeation studies showed that formulation containing 10% span 20 (OD3) exhibited greatest cumulative amount of drug permeated (19.02?±?0.21?mg) in 72?h, so OD3 was concluded as optimized formulation and assessed for pharmacokinetic, pharmacodynamic, and skin irritation potential. In vivo studies of optimized olanzapine patch in rabbit model revealed prolongation of action with F_rel 116.09% during 72-h study period. Neuroleptic efficacy of transdermal patch was comparable to oral formulation during rotarod and grip test in Wistar albino rats with no skin irritation. Thus, developed formulation of olanzapine is expected to improve the patient compliance, form better dosage regimen, and provide maintenance therapy to psychotic patients.     

Spray-on transdermal drug delivery systems

Introduction: Transdermal drug delivery possesses superior advantages over other routes of administration, particularly minimizing first-pass metabolism. Transdermal drug delivery is challenged by the barrier nature of skin. Numerous technologies have been developed to overcome the relatively low skin permeability, including spray-on transdermal systems.

Areas covered: A transdermal spray-on system (TSS) usually consists of a solution containing the drug, a volatile solvent and in many cases a chemical penetration enhancer. TSS promotes drug delivery via the complex interplay between solvent evaporation and drug–solvent drag into skin. The volatile solvent carries the drug into the upper layers of the stratum corneum, and as the volatile solvent evaporates, an increase in the thermodynamic activity of the drug occurs resulting in an increased drug loading in skin.

Expert opinion: TSS is easily applied, delivering flexible drug dosage and associated with lower incidence of skin irritation. TSS provides a fast-drying product where the volatile solvent enables uniform drug distribution with minimal vehicle deposition on skin. TSS ensures precise dose administration that is aesthetically appealing and eliminates concerns of residual drug associated with transdermal patches. Furthermore, it provides a better alternative to traditional transdermal products due to ease of product development and manufacturing.     

Transdermal delivery of calcium channel blockers for hypertension

Introduction: Calcium channel blockers are a very important class of antihypertensive drugs. Most calcium channel blockers (CCBs) exhibiting low oral bioavailability are required to be taken more than once a day due to their short half-lives which result in poor patient compliance. There is an ineluctable requirement for improved drug-delivery devices for CCBs because of the quantum of their utilization and shortcoming associated with their conventional dosage forms.

Areas covered: There have been worthwhile research endeavors worldwide to investigate the skin permeation and to develop transdermal formulations of various categories of CCBs. This review explores the investigations on the feasibility and applicability of systemic delivery of various CCBs via skin.

Expert opinion: Transdermal delivery of CCBs has been particularly acknowledged as a potential drug-delivery route in the therapy of hypertension. Several overtures have been made to enhance delivery of these drugs via skin barrier. There have been remarkable research endeavors worldwide to investigate the skin permeation and to develop transdermal systems of various CCBs. Persistent advancement in this area holds promise for the long-term success in technologically advanced transdermal dosage forms being commercialized sooner rather than later.     

Design,development and characterization of buccal bioadhesive films of Doxepin for treatment of odontalgia

Abstract

Tricyclic antidepressants, as doxepin hydrochloride (DH), may have analgesic local effect due to its biochemical mechanism of action. Delivery of DH directly to the oral cavity could be an interesting alternative for toothache due to its analgesic local effect. One problem associated with the mucosal administration routes is the short residence time of the dosage form on the mucosal membranes. In this sense, we have developed new doxepin mucoadhesive films able of reducing pain and increasing the effectiveness of treatment. For this purpose, we tested three different polymers: chitosan, sodium hydroxypropylmethylcellulose (HPMC) and sodium carboxymethylcellulose (SCMC) in film elaboration. The results obtained show that all films are hydrophilic matrices that absorb water when placed in an aqueous media. All the films hydrated very quickly, reaching high percentage of swelling after just few minutes (5?min for SCMC, 2?min for HPMC and 30?min for chitosan). Moreover, the SCMC and HPMC films were dissolved whereas chitosan was not dissolved. Dissolution also leads to viscous liquids with a higher retention time over mucosal surfaces what may lead to adhesive interactions. In vitro permeation studies showed that for all the formulations studied, SCMC (19.91%), HPMC (69.5%) and chitosan (24.17%), the percentage of drug permeated increased compared to the drug solution (8.26%). Specifically the HPMC film presents greater amounts of doxepin permeated (49.27?±?4.47?µg/cm²).     

Egg albumin microspheres containing paracetamol for oral administration. II. In vivo investigation

Abstract

Egg albumin microspheres containing paracetamol for oral administration were prepared and their in vivo characteristics evaluated. The egg albumin microspheres were able to improve the organoleptic characteristics of paracetamol formulations. The pharmacokinetic characteristics of three different formulations of paracetamol were evaluated in six volunteers. The formulations administered orally were: (1) Paracetamol granulated with lactose (reference), (2) Egg albumin microspheres and (3) Egg albumin microspheres coated with polymethacrylate.     

Superiority of liquid crystalline cubic nanocarriers as hormonal transdermal vehicle: comparative human skin permeation-supported evidence

ABSTRACT

Objectives: The aim of this investigation was to explore the feasibility of various nanocarriers to enhance progesterone penetration via the human abdominal skin.

Methods: Four progesterone-loaded nanocarriers; cubosomes, nanoliposomes, nanoemulsions and nanomicelles were formulated and characterized regarding particle size, zeta potential, % drug encapsulation and in vitro release. Structural elucidation of each nanoplatform was performed using transmission electron microscopy. Ex vivo skin permeation, deposition ability and histopathological examination were evaluated using Franz diffusion cells.

Results: Each nanocarrier was fabricated with a negative surface, nanometric size (≤ 270 nm), narrow size distribution and reasonable encapsulation efficiency. In vitro progesterone release showed a sustained release pattern for 24 h following a non-Fickian transport diffusion mechanism. All nanocarriers exhibited higher transdermal flux relative to free progesterone. Cubosomes revealed a higher skin penetration with transdermal steady flux of 48.57.10^–2 ± 0.7 µg/cm² h. Nanoliposomes offered a higher percentage of skin progesterone deposition compared to other nanocarriers. Based on the histopathological examination, cubosomes and nanoliposomes were found to be biocompatible for transdermal application. Confocal laser scanning microscopy confirmed the ability of fluoro-labeled cubosomes to penetrate through the whole skin layers.

Conclusion: The elaborated cubosomes proved to be a promising non-invasive nanocarrier for transdermal hormonal delivery.     

Comparative single-dose pharmacokinetics of rasagiline in minipigs after oral dosing or transdermal administration via a newly developed patch

Abstract

1. A rasagiline transdermal patch was developed for the treatment of early and advanced Parkinson’s disease. Relevant pharmacokinetic parameters of rasagiline obtained after transdermal administration to minipigs were compared with those of rasagiline after oral administration.

2. A total of 18 minipigs were randomly divided into three groups (six animals for each group). A single dose of 1?mg rasagiline tablet was orally administrated to one group. Meanwhile, single dose of 1.25 and 2.5?mg (2 and 4?cm²) rasagiline patches were given (at the postauricular skin) to the other two groups, respectively. The pharmacokinetic parameters such as plasma half-life (t_1/2), time to peak plasma-concentration (T_max), mean residence time (MRT), area under the curve (AUC_(0–t)) were significantly (p?<?0.05) different between transdermal and oral administrations.

3. The plasma half-life (t_1/2) of rasagiline (1.25?mg patch: 11.8?±?6.5?h, 2.5?mg patch: 12.5?±?4.7?h) in minipig following transdermal administration was significantly prolonged as compared with that following the oral administration (1?mg tablet: 4.7?±?2.5?h). The dose-normalized relative bioavailability of rasagiline patch in minipig were 178.5% and 156.4%, respectively, for 1.25 and 2.5?mg patches compared with 1?mg rasagiline tablet. The prolonged t_1/2 and increased bioavailability of rasagiline patch suggested a possible longer dosing interval compared with oral tablet.