Long-Term Permeation Kinetics of Estradiol: (IV) A Theoretical Approach to the Simultaneous Skin Permeation and Bioconversion of Estradiol Esters

Abstract

A theoretical non-steady-state treatment was developed to analyze the kinetics of metabolism during the course of dermal uptake or skin permeation of estradiol esters across the hairless mouse skin. The first-order rate constants for the metabolism reaction of estradiol acetate → estradiol and estradiol diacetate → estradiol acetate → estradiol were determined. The theoretical drug concentration profile calculated from the present model was found to be agreed reasonably well with the experimental data determined in the early stage of skin uptake/metabolism studies (<24 hr). For the skin permeation of estradiol acetate and diacetate and their concurrent metabolism, the experimental Q vs. t profiles were also observed to agree well with the theoretical results for a period of up to 28 hr. A deviation was observed at later phase of experiments, which can be attributed to the reduction in enzyme activity during the permeation studies, possibly due to the result of skin aging.     

Long-Term Permeation Kinetics of Estradiol: (V) Development and Evaluation of Transdermal Bioactivated Hormone Delivery System

Abstract

Based on the results of simultaneous skin permeation and bioconversion profiles, a Transdermal Bioactivated Hormone Delivery (TBHD) System was developed from the microreservoir partition-controlled drug delivery technology for the transdermal controlled delivery of estradiol prodrugs.

Using the in vitro skin permeation apparatus developed earlier, the kinetics of release and skin permeation of estradiol prodrugs from the TBHD system and the regeneration of estradiol were simultaneously studied. Results indicated that all prodrugs are totally converted by the esterase to estradiol during the course of skin permeation.

The release rate of estradiol was found to be first enhanced by the esterification of the OH groups at 3- and 17-position and then decreased as the alkyl chain length increased.

The rate of regeneration of estradiol from the prodrugs was found to follow the order of: diacetate > valerate > heptanoate > acetate > cypionate.     

Transdermal Dual-Controlled Delivery of Testosterone and Estradiol: (II) Enhanced Skin Permeability and Membrane-Moderated Delivery

In the second report of this series of investigations, series of alkanols, alkanoic acids and propyl alkanoates were evaluated for their potential as skin permeation enhancers for testosterone and estradiol delivered from a multilaminate-type transdermal drug delivery (m-TDD) system. Results indicated that permeation rates vary with the length of alkyl chain and the maximum enhancement effect is attained with alkanol having n=6-8 (n is the number of methylene groups), alkanoic acid having n=8-10, and propyl alkanoate having n=10-12. The enhancing effect of series of sorbitan esters and polysorbates on the skin permeation of testosterone was also studied; and the results indicated that sorbitan esters are effective skin permeation enhancer, while polysorbates are not. The effect of enhancer loading on the skin permeation rates of testosterone and estradiol, the barrier property of permselective membrane, the dosage rate ratio of testosterone/estradiol was extensively studied; and the effect of variation in the location of enhancer in the m-TDD system on the skin permeation of estradiol and testosterone was also investigated. The permselective membrane has been shown to be effective in controlling the delivery and skin permeation of estradiol. By simultaneous application of an appropriate skin permeation enhancer in testosterone reservoir layer and a permselective membrane with controlled thickness sandwiched between the estradiol- and testosterone-reservoir layer, the skin permeation rates of testosterone and estradiol from the m-TDD system can be modulated and the dosage rate ratio of testosterone/estradiol can be varied to suite for a particular therapeutic application.     

Long-Term Skin Permeation Kinetics of Estradiol (I): Effect of Drug Solubilizer-Polyethylene Glycol 400

Abstract

A skin permeation cell was recently developed to overcome the deficiencies noted in the currently available in vitro diffusion cells, and to provide a cell design which is suitable for studying the long-term drug permeation kinetics through the skin and is also sensitive enough for assessing the mechanisms of skin permeation by a high performance liquid chromatography.

To evaluate the rote of drug reservoir concentration in the kinetics of skin permeation as well as to maintain a sink condition in the receptor solution, the water-miscible polyethylene glycol (PEG) 400 was incorporated into the saline solution to act as a solubilizer to enhance the aqueous solubility of the relative water-insoluble estradiol. The equilibrium solubility of estradiol at 37°C was observed to in crease exponentially as increasing the volume fraction of PEG 400 added.

The rates o f permeation of estradiol across the male and female hairless mouse, whole and stripped skins excised freshly from the abdominal region, were measured a t various PEG concentrations and the permeability coefficients were determined. The permeability co-efficients were found t o decrease as increasing the PEG concentration. A linear relationship was established between th e permeability co-efficients and the skin /solution partition coefficients and the steady-stated if fusivity was calculated. Effect of sex was assessed.

The rate of permeation and the permeability coefficient across the stratum corneum were determined, using t h e multi-laminated dif-fusional resistance model. Results demonstrated that the stratum corneum acts as the rate-limiting barrier in the skin permeation of estradiol and the incorporation of upto 40% v/v PEG 400 does not in-fluence the barrier propertiesof stratum corneum, even though PEG 400 has been found to affect the aqueous solubility, permeability co-efficient, and skin /solution partition coefficient of estradiol.     

Long-Term Skin Permeation Kinetics of Estradiol (I): Effect of Drug Solubilizer-Polyethylene Glycol 400

A skin permeation cell was recently developed to overcome the deficiencies noted in the currently available in vitro diffusion cells, and to provide a cell design which is suitable for studying the long-term drug permeation kinetics through the skin and is also sensitive enough for assessing the mechanisms of skin permeation by a high performance liquid chromatography.

To evaluate the rote of drug reservoir concentration in the kinetics of skin permeation as well as to maintain a sink condition in the receptor solution, the water-miscible polyethylene glycol (PEG) 400 was incorporated into the saline solution to act as a solubilizer to enhance the aqueous solubility of the relative water-insoluble estradiol. The equilibrium solubility of estradiol at 37°C was observed to in crease exponentially as increasing the volume fraction of PEG 400 added.

The rates o f permeation of estradiol across the male and female hairless mouse, whole and stripped skins excised freshly from the abdominal region, were measured a t various PEG concentrations and the permeability coefficients were determined. The permeability co-efficients were found t o decrease as increasing the PEG concentration. A linear relationship was established between th e permeability co-efficients and the skin /solution partition coefficients and the steady-stated if fusivity was calculated. Effect of sex was assessed.

The rate of permeation and the permeability coefficient across the stratum corneum were determined, using t h e multi-laminated dif-fusional resistance model. Results demonstrated that the stratum corneum acts as the rate-limiting barrier in the skin permeation of estradiol and the incorporation of upto 40% v/v PEG 400 does not in-fluence the barrier propertiesof stratum corneum, even though PEG 400 has been found to affect the aqueous solubility, permeability co-efficient, and skin /solution partition coefficient of estradiol.     

Long-Tern Skin Permeation Kinetics of Estradiol: (II) Kinetics of Skin Uptake,Binding, and Metabolism

Abstract

The in vitro skin permeation system developed in this laboratory was utilized to investigate the kinetics of uptake, binding, and metabolism of estradiol, the female hormone, by the hairless mouse skin. The kinetics of uptake of estradiol and its subsequent metabolism to estrone by the skin were examined by exposing one side of a freshly excised skin to an estradiol solution, while the other side of the skin was protected with an impermeable aluminum foil.

The results concluded that the stratum corneum plays a rate-limiting role in the uptake and binding of estradiol and its metabolism to estrone by the skin. The mechanisms of the uptake and binding of estradiol to whole skin tissue (with stratum corneum) showed a sex dependence, with the rate higher in the female than in the male mouse. On the other hand, no sex-dependent difference was observed in the mechanism and rate of metabolism to estrone.

After stripping off the rate-limiting stratum corneum, the mechanisms of the uptake, binding and metabolism of estradiol all became sex dependent with identical rates observed between male and female mice in the initial 14 hrs of the experiment; Between 14 to 21 hrs, the rates increased substantially with the female skin, but not with the male skin. The increase in the rate of uptake of estradiol by the female skin was related primarily to the increased rate of metabolism of estradiol to estrone.     

Skin Permeation of Lidocaine from Crystal Suspended Oily Formulations

ABSTRACT

In vitro permeation of lidocaine (lidocaine base, LID) through excised rat skin was investigated using several LID-suspended oily formulations. The first skin permeation of LID from an LID-suspended oily solution such as liquid paraffin (LP), isopropyl myristate (IPM), polyoxyethylene (2) oleylether (BO-2), and diethyl sebacate (DES) was evaluated and compared with that from polyethylene glycol 400 (PEG400) solution, a hydrophilic base. The obtained permeation rate of LID, J_app, from PEG400, LP, IPM, BO-2, and DES was in the order of DES>BO-2 = IPM>LP>PEG400, and increased with LID solubility in the oily solvents, although LID crystals were dispersed in all solvents. Subsequently, oily formulations that consisted of different ratios of the first oily solvent (IPM, BO-2, or DES) (each 0–20%), the second oily solvent (LP) and an oily mixture of microcrystalline wax/white petrolatum/paraffin (1/5/4) were evaluated. BO-2 groups at a concentration of 5% and 10% had the highest J_app among the oily formulations, although a higher BO-2 resulted in lower skin permeation. In addition, pretreatment with BO-2 increased the skin permeation of LID. These results suggest that the penetration enhancing effect by the system may be related to the skin penetration of BO-2 itself. Finally, mathematical analysis was done to evaluate the effect of BO-2, and it was shown that BO-2 improved the LID solubility in stratum corneum lipids to efficiently enhance the LID permeation through skin.     

Long-Tern Skin Permeation Kinetics of Estradiol: (II) Kinetics of Skin Uptake, Binding, and Metabolism

The in vitro skin permeation system developed in this laboratory was utilized to investigate the kinetics of uptake, binding, and metabolism of estradiol, the female hormone, by the hairless mouse skin. The kinetics of uptake of estradiol and its subsequent metabolism to estrone by the skin were examined by exposing one side of a freshly excised skin to an estradiol solution, while the other side of the skin was protected with an impermeable aluminum foil.

The results concluded that the stratum corneum plays a rate-limiting role in the uptake and binding of estradiol and its metabolism to estrone by the skin. The mechanisms of the uptake and binding of estradiol to whole skin tissue (with stratum corneum) showed a sex dependence, with the rate higher in the female than in the male mouse. On the other hand, no sex-dependent difference was observed in the mechanism and rate of metabolism to estrone.

After stripping off the rate-limiting stratum corneum, the mechanisms of the uptake, binding and metabolism of estradiol all became sex dependent with identical rates observed between male and female mice in the initial 14 hrs of the experiment; Between 14 to 21 hrs, the rates increased substantially with the female skin, but not with the male skin. The increase in the rate of uptake of estradiol by the female skin was related primarily to the increased rate of metabolism of estradiol to estrone.     

Transdermal delivery of physostigmine: effects of enhancers and pressure-sensitive adhesives

The purpose of this study was to investigate the effects of various pressure- sensitive adhesives (PSA) on the percutaneous absorption of physostigmine across hairless mouse skin. In addition, the influences of various vehicles and polyvinylpyrrolidone (PVP) on the percutaneous absorption of physostigmine from PSA matrix across hairless mouse skin were evaluated using a flow-through diffusion cell system at 37°C. Physostigmine showed the highest permeability from silicone adhesive matrix, followed by polyisobutylene (PIB), styrene- isoprene-styrene (SIS), acrylic, and styrene-butadiene-styrene (SBS) matrix. Among acrylic adhesives, the permeability of physostigmine was the highest from grafted acrylic adhesive. Polyvinyl pyrrolidone inhibited the crystallization of physostigmine in the PIB adhesive matrix and enhanced the permeability of physostigmine from the PIB adhesive matrix. When esters of sorbitol and fatty acid, polyethylene glycol (PEG) alkyl esters, and caprylic/capric triglycerides were tested, the more lipophilic was a surfactant, the higher the permeation rate within the same group of surfactants. The enhancement effect of PEG derivatives was lower than that of non-PEG derivatives. Among non-linear fatty acid derivatives, linoleate derivatives showed higher permeability of physostigmine than oleate derivatives. This study showed that several non-ionic surfactants, including PEG-20 evening primrose glyceride, enhanced the permeation of physostigmine across hairless mouse skin better than oleic acid.     

Evaluation of silicone-based pressure-sensitive adhesives for transdermal drug delivery [II] effect of penetrant lipophilicitv

Abstract

An adhesive polymer drug dispersion-type transdermal drug delivery (a-TDD) system, consisting of a single drug-loaded adhesive polymer layer sandwitched between a drug-impermeable backing membrane and a detachable release liner, was developed from two silicone-based pressure-sensitive adhesive polymers for the controlled administration of drugs. The effect of variation in penetrant lipophilicity, using a series of testosterone derivatives with an increasing number of methyl groups in the steroid skeleton, on the release kinetics from the a-TDD system and skin permeation rate profiles was investigated. Absence of a methyl group at the 19th position of testosterone increased the flexibility of the steroid molecule and thus yeilded higher diffusivity and greater skin permeation rate. Addition of esters at the 17 ß-position resulted in a reduction in diffusivity with an increase in the alkyl chain length of the ester. These esters were found to be bioconverted to testosterone during permeation through the intact hairless rat skin.     

Transdermal Delivery of Physostigmine: Effects of Enhancers and Pressure-Sensitive Adhesives

ABSTRACT

The purpose of this study was to investigate the effects of various pressure- sensitive adhesives (PSA) on the percutaneous absorption of physostigmine across hairless mouse skin. In addition, the influences of various vehicles and polyvinylpyrrolidone (PVP) on the percutaneous absorption of physostigmine from PSA matrix across hairless mouse skin were evaluated using a flow-through diffusion cell system at 37°C. Physostigmine showed the highest permeability from silicone adhesive matrix, followed by polyisobutylene (PIB), styrene– isoprene–styrene (SIS), acrylic, and styrene–butadiene–styrene (SBS) matrix. Among acrylic adhesives, the permeability of physostigmine was the highest from grafted acrylic adhesive. Polyvinyl pyrrolidone inhibited the crystallization of physostigmine in the PIB adhesive matrix and enhanced the permeability of physostigmine from the PIB adhesive matrix. When esters of sorbitol and fatty acid, polyethylene glycol (PEG) alkyl esters, and caprylic/capric triglycerides were tested, the more lipophilic was a surfactant, the higher the permeation rate within the same group of surfactants. The enhancement effect of PEG derivatives was lower than that of non-PEG derivatives. Among non-linear fatty acid derivatives, linoleate derivatives showed higher permeability of physostigmine than oleate derivatives. This study showed that several non-ionic surfactants, including PEG-20 evening primrose glyceride, enhanced the permeation of physostigmine across hairless mouse skin better than oleic acid.     

Potential Use of Ascorbic Acid–Based Surfactants as Skin Penetration Enhancers

ABSTRACT

6-O-Ascorbic acid alkanoates (ASCn) are amphiphilic molecules having physical-chemical properties that depend on the alkyl chain length. The derivatives of low molecular weight (n < 11) have enough aqueous solubility to produce self-assemblies at room temperature (≈25°C), while those with longer alkyl chains possess a critical micellar temperature (CMT) higher than 30°C. At higher temperatures (T° > CMT), ASCn aqueous suspensions turn into either micellar solutions or gel phases, depending on the length of the hydrophobic chain. On cooling, coagels are produced, which possess a lamellar structure that exhibit sharp X-ray diffraction patterns and optical birefringence. The semisolid consistency of such coagels is an interesting property to formulate dermatological pharmaceutical dosage forms able to solubilize and stabilize different drugs. The objective of the present study was the evaluation of the enhancing permeation effect of ASCn with different chain lengths and to correlate permeability changes with histological effects. With this purpose, ASCn coagels containing anthralin (antipsoriasic drug) or fluorescein isothiocyanate (FITC, hydrophobic fluorescent marker) were assayed on rat skin (ex vivo) and mice skin (in vivo), respectively. Also, histological studies were performed aimed at detecting some possible side effects of ASCn. No inflammatory cellular response was observed in the skin when ASCn coagels were applied, suggesting non-irritating properties. Light microscopy indicated slight disruption and fragmentation of stratum corneum. The penetration of ASCn through rat skin epidermis was very fast and quantitatively significant. The permeation of anthralin was significantly increased when the drug was vehiculized in ASCn coagels, compared to other pharmaceutical systems. The results indicated that ASC12 seems to have the highest enhancing effect on FITC permeation. ASC12 appears to be the compound that possesses the highest capacity to enhance the penetration of the drugs. Furthermore, it has the highest permeation of the serie.     

Transdermal Dual-Controlled Delivery of Testosterone and Estradiol: (I) Impact of system Design

Abstract

A multilaminate-type transdermal drug delivery (m-TDD) system was designed with the objective of delivering testosterone and estradiol simultaneously but at different daily dosage rates. To achieve such a dual-controlled transdermal delivery, skin permeation enhancer and permselective membrane were incorporated into the system. The results demonstrated that skin permeation enhancer, which is incorporated into the testosterone reservoir layer, and permselective membrane, which is added onto the drugreleasing surface of estradiol reservoir layer, can both alter the overall rate of skin permeation for both drugs. The skin permeation enhancer was observed to enhance the skin permeation rate of testosterone, while the permselective membrane was shown to reduce the skin permeation rate of estradiol. The addition of permselective membrane was observed to modify the release kinetics of estradiol from the matrix diffusion-controlled drug delivery to membrane permeation-controlled drug delivery. Other factors which may affect the deliver rate of drug, e.g., the thickness of permselective membrane and loading dose of drugs, were also studied. Furthermore, evaluation of physical stability of this mTDD system demonstrated that the inter-layer migration of drugs is at minimum.     

Transdermal Dual-Controlled Delivery of Testosterone and Estradiol: (I) Impact of system Design

A multilaminate-type transdermal drug delivery (m-TDD) system was designed with the objective of delivering testosterone and estradiol simultaneously but at different daily dosage rates. To achieve such a dual-controlled transdermal delivery, skin permeation enhancer and permselective membrane were incorporated into the system. The results demonstrated that skin permeation enhancer, which is incorporated into the testosterone reservoir layer, and permselective membrane, which is added onto the drugreleasing surface of estradiol reservoir layer, can both alter the overall rate of skin permeation for both drugs. The skin permeation enhancer was observed to enhance the skin permeation rate of testosterone, while the permselective membrane was shown to reduce the skin permeation rate of estradiol. The addition of permselective membrane was observed to modify the release kinetics of estradiol from the matrix diffusion-controlled drug delivery to membrane permeation-controlled drug delivery. Other factors which may affect the deliver rate of drug, e.g., the thickness of permselective membrane and loading dose of drugs, were also studied. Furthermore, evaluation of physical stability of this mTDD system demonstrated that the inter-layer migration of drugs is at minimum.     

Comparison of In Vitro Dissolution and Permeation of Fluconazole from Different Suppository Bases

Fluconazole suppositories were prepared in hydrophilic, lipophilic, and amphiphilic bases. In vitro evaluation was conducted to compare the effect of different bases on the release and permeation of fluconazole. Four types of suppository bases were evaluated: hydrophilic (polyethylene glycol, PEG), lipophilic (cocoa butter, CB; Witepsol W45® WW45), and amphiphilic (Suppocire AP® SAP, a polyglycolized glyceride). The uniformity of dosage units prepared with each base was determined by ultraviolet (UV) spectroscopy. The influence of suppository base on the release of fluconazole was studied using USP dissolution apparatus I. Rate constants for each release pattern were determined and compared using a one-way analysis of variance (ANOVA) on ranks. The order of in vitro dissolution of fluconazole from the bases was as follows: PEG > (SAP = WW45) > CB. Results suggest that in vitro release of fluconazole is greater from a hydrophilic base (PEG). Preliminary permeation studies were conducted on each type of base using Franz diffusion cells. Permeation was studied through the rat rectal membrane, and normal saline was used as the receptor medium. A modified reverse-phase high-performance liquid chromatography (HPLC) method was used and validated for analyzing fluconazole. Flux values (μg/cm²/hr) were calculated and compared using a one-way ANOVA (p <. 001). The order of permeation was as follows: SAP > (PEG = WW45) > CB. The increased permeation characteristics seen with the SAP base are probably due to an alteration of the membrane characteristics due to the surface active properties of the base.     

Transdermal Delivery of Tadalafil. I. Effect of Vehicles on Skin Permeation

Transdermal delivery that avoids the presystemic disposition can provide an alternative to oral administration of tadalafil. Accordingly, the aim of this study was to select the best vehicle as the first step in optimization of tadalafil transdermal delivery. The vehicles were used neat or in selected binary combinations and were evaluated for drug solubilization and transdermal delivery. The drug solubility in pure vehicles were ranked as polyethylene glycol (PEG) 400 >?propylene glycol (PG) >?ethanol >?ethyl oleate (EO) >?isopropyl myristate (IPM) >?water. The solubility in binary systems containing ethanol at 2:1 ratios with EO or IPM was greater than that obtained with pure ethanol, EO, or IPM. This effect could be due to the cosolvency effect. The transdermal drug delivery from pure vehicles was ranked as IPM >?EO >?ethanol >?PG >?PEG >?water. The delivery from binary mixtures of ethanol with either IPM or EO was higher than that obtained from pure solvents with the delivery increasing with increasing ethanol concentration in the mixtures. The delivery from binary mixtures was synergistic rather than additive. The study thus demonstrated a potential of tadalafil transdermal delivery. Binary combinations of ethanol with either IPM or EO provided the first step forward toward the development of transdermal delivery system for tadalafil.     

Potential use of ascorbic acid-based surfactants as skin penetration enhancers

6-O-Ascorbic acid alkanoates (ASCn) are amphiphilic molecules having physical-chemical properties that depend on the alkyl chain length. The derivatives of low molecular weight (n < 11) have enough aqueous solubility to produce self-assemblies at room temperature ( approximately 25 degrees C), while those with longer alkyl chains possess a critical micellar temperature (CMT) higher than 30 degrees C. At higher temperatures (T degrees > CMT), ASCn aqueous suspensions turn into either micellar solutions or gel phases, depending on the length of the hydrophobic chain. On cooling, coagels are produced, which possess a lamellar structure that exhibit sharp X-ray diffraction patterns and optical birefringence. The semisolid consistency of such coagels is an interesting property to formulate dermatological pharmaceutical dosage forms able to solubilize and stabilize different drugs. The objective of the present study was the evaluation of the enhancing permeation effect of ASCn with different chain lengths and to correlate permeability changes with histological effects. With this purpose, ASCn coagels containing anthralin (antipsoriasic drug) or fluorescein isothiocyanate (FITC, hydrophobic fluorescent marker) were assayed on rat skin (ex vivo) and mice skin (in vivo), respectively. Also, histological studies were performed aimed at detecting some possible side effects of ASCn. No inflammatory cellular response was observed in the skin when ASCn coagels were applied, suggesting non-irritating properties. Light microscopy indicated slight disruption and fragmentation of stratum corneum. The penetration of ASCn through rat skin epidermis was very fast and quantitatively significant. The permeation of anthralin was significantly increased when the drug was vehiculized in ASCn coagels, compared to other pharmaceutical systems. The results indicated that ASC12 seems to have the highest enhancing effect on FITC permeation. ASC12 appears to be the compound that possesses the highest capacity to enhance the penetration of the drugs. Furthermore, it has the highest permeation of the serie.     

Skin permeation of lidocaine from crystal suspended oily formulations

In vitro permeation of lidocaine (lidocaine base, LID) through excised rat skin was investigated using several LID-suspended oily formulations. The first skin permeation of LID from an LID-suspended oily solution such as liquid paraffin (LP), isopropyl myristate (IPM), polyoxyethylene (2) oleylether (BO-2), and diethyl sebacate (DES) was evaluated and compared with that from polyethylene glycol 400 (PEG400) solution, a hydrophilic base. The obtained permeation rate of LID, Japp, from PEG400, LP, IPM, BO-2, and DES was in the order of DES>BO-2=IPM>LP>PEG400, and increased with LID solubility in the oily solvents, although LID crystals were dispersed in all solvents. Subsequently, oily formulations that consisted of different ratios of the first oily solvent (IPM, BO-2, or DES) (each 0-20%), the second oily solvent (LP) and an oily mixture of microcrystalline wax/white petrolatum/paraffin (1/5/4) were evaluated. BO-2 groups at a concentration of 5% and 10% had the highest Japp among the oily formulations, although a higher BO-2 resulted in lower skin permeation. In addition, pretreatment with BO-2 increased the skin permeation of LID. These results suggest that the penetration enhancing effect by the system may be related to the skin penetration of BO-2 itself. Finally, mathematical analysis was done to evaluate the effect of BO-2, and it was shown that BO-2 improved the LID solubility in stratum corneum lipids to efficiently enhance the LID permeation through skin.     

The Effects of Pressure-Sensitive Adhesives and Solubilizers on the Skin Permeation of Testosterone from a Matrix-Type Transdermal Delivery System

ABSTRACT

Matrix-type transdermal delivery systems of testosterone (TS) were formulated with three different pressure-sensitive adhesives (PSA). The effects of PSA, skin permeation enhancers, and solubilizers on the rat skin permeation rate of TS were systematically investigated. Without a solubilizer, the skin permeation rate of TS reached its maximum value when only 2% of TS was loaded in the matrix and the crystal formation in the matrix was very rapid and severe. Two surfactants differing in their hydrophile–lipophile balance (HLB) number were, therefore, considered. Span 80, which was of the lower HLB number, was more effective than Tween 80 in increasing the solubility, and thereby increasing the permeation rate of TS. Moreover, the concentrations of both the solubilizer and the skin permeation enhancer affected the skin permeation rate. Thus, the highest skin permeation rate (4.14 µg/cm²/hr) was achieved when 2% TS was loaded in DuroTak® 87-2516 together with 10% Span 80 and 3% dodecylamine, the permeation enhancer. In vivo study showed that the application of an experimental patch on rat abdominal skin resulted in a prompt and significantly higher plasma concentration of TS than that of a commercial product (Testoderm®) designed to apply on the scrotal skin. The area under the curve (AUC) increased linearly as the loading dose of TS increased up to 6%. Thus, based on these results, a non-scrotal matrix-type transdermal delivery system of TS could be developed.     

Enhancement of in vitro skin permeation of verapamil

Abstract

A number of compounds including aliphatic esters, alkanols and amides were investigated for their ability to enhance the in vitro permeation rate of verapamil across hairless mouse skin. While several of them did enhance the permeation rate, the best results were obtained with the lauric acid derivatives. On analysis of the permeation rate data it was found that while most of the compounds increased the solubility of verapamil in skin and hence its partition coefficient from the delivery system, the lauric acid derivatives also increased its diffusivity in skin. Permeation of verapamil from delivery systems containing these lauric derivatives was further investigated through delipidized and stripped skin. It was found that most of these derivatives enhanced the permeation of verapamil across both whole and delipidized skin, indicating that in addition to their action on the skin lipids, they must also have some effect on the proteins in the stratum corneum.