Solvent-mediated alterations of the stratum corneum

Transdermal Route: A Viable Option for Systemic Delivery of Antidepressants

The high rise in the population suffering from depression depicts the need for improved and highly effective treatment options for this condition. Efforts to develop existing drugs into user-friendly dosage forms with a number of advantages in major depressive states, including but not limited to: sustained drug release, reduced drug dosing frequency, improved tolerance and adherence, suitability for use in diverse populations and different treatment scenarios, as well as less central nervous system side effects are required. One such non-invasive drug delivery route that could provide the aforementioned benefits in the treatment of depression is the transdermal route. A number of conventional and emerging transdermal delivery strategies have been investigated for some potent antidepressants and results depict the potential of this route as a viable means for systemic delivery of therapeutically relevant doses of the tested agents, with Emsam®, the commercially available patch of selegiline, being an evidence for the same. The investigated approaches include the formulation of transdermal patches, use of vesicular drug carriers, pro-drug approach, microemulsification, chemical as well as physical enhancement technologies. This review provides a comprehensive account of the rationale, developments made till date, scope and future prospects of delivering antidepressants via the transdermal1 route of administration.

In Vitro Drug Transfer Due to Drug Retention in Human Epidermis Pretreated with Application of Marketed Estradiol Transdermal Systems

Study objective was to assess skin-to-skin drug transfer potential that may occur due to drug retention in human epidermis (DRE) pretreated with application of estradiol transdermal drug delivery systems (TDDS) and other estradiol transdermal dosage forms (gels and sprays). TDDS (products-A, B, and C) with varying formulation design and composition, and other estradiol transdermal products (gel and spray) were applied to heat separated human epidermis (HSE) and subjected to in vitro drug permeation study. Amounts of DRE were quantified after 24 h. The DRE with product-B was significantly (P < 0.001) higher than that with product-C, product-A, gel, and spray. However, products-A and C, gel, and spray showed almost the same (P > 0.05) amounts of DRE. A separate in vitro permeation study was carried out to determine amounts of drug transferred from drug-retaining epidermis to untreated HSE. The amounts of drug transferred, due to DRE after 8 h, with product-C were significantly (P < 0.001) higher than those with products-A and B, gel, and spray. The in vitro study results indicate a high potential of skin-to-skin drug transfer due to the DRE after labeled period of using estradiol TDDS, though the clinical relevance of these findings is yet to be determined.

Potent enhancement of transdermal absorption and stability of human tyrosinase plasmid (pAH7/Tyr) by Tat peptide and an entrapment in elastic cationic niosomes

Enhancement of transdermal absorption through rat skin and stability of the human tyrosinase plasmid (P) using Tat (T) and an entrapment in elastic cationic niosomes (E) were described. E (Tween61:cholesterol:DDAB at 1:1:0.5 molar ratio) were prepared by the freeze-dried empty liposomes (FDELs) method using 25% ethanol. TP was prepared by a simple mixing method. TPE was prepared by loading T and P in E at the T:P:E ratio of 0.5:1:160 w/w/w. For gel formulations, P, TP, PE and TPE were incorporated into Carbopol 980 gel (30 µg of plasmid per 1 g of gel). For the transdermal absorption studies, the highest cumulative amounts and fluxes of the plasmid in viable epidermis and dermis (VED) were observed from the TPE of 0.31 ± 0.04 µg/cm(2) and 1.86 ± 0.24 µg/cm(2)/h (TPE solution); and 4.29 ± 0.40 µg/cm(2) and 25.73 ± 2.40 µg/cm(2)/h (TPE gel), respectively. Only plasmid from the PE and TPE could be found in the receiving solution with the cumulative amounts and fluxes at 6 h of 0.07 ± 0.01 µg/cm(2) and 0.40 ± 0.08 µg/cm(2)/h (PE solution); 0.10 ± 0.01 µg/cm(2) and 0.60 ± 0.06 µg/cm(2)/h (TPE solution); 0.88 ± 0.03 µg/cm(2) and 5.30 ± 0.15 µg/cm(2)/h (PE gel); and 1.02 ± 0.05 µg/cm(2) and 6.13 ± 0.28 µg/cm(2)/h (TPE gel), respectively. In stability studies, the plasmid still remained at 4 ± 2 °C and 25 ± 2 °C of about 48.00-65.20% and 27.40-51.10% (solution); and 12.34-38.31% and 8.63-36.10% (gel), respectively, whereas at 45 ± 2 °C, almost all the plasmid was degraded. These studies indicated the high potential application of Tat and an entrapment in elastic cationic niosomes for the development of transdermal gene delivery system.

Transdermal delivery of methotrexate: past, present and future prospects

Methotrexate has been reported as an immunosuppressant and an antimetabolite widely used in the treatment of rheumatoid arthritis and psoriasis. However, it causes various toxicities and has low bioavailability when taken orally, thus, it is desirable that the drug be delivered transdermally. The water solubility and charged structure of methotrexate, however, limits its use via the transdermal route mainly due to the highly organized microstructure of the stratum corneum. Hence, various technologies, such as chemical enhancers, iontophoresis, electroporation, ultrasound and microneedles, either alone or in combination, are being explored to enhance its permeability by disrupting the barrier property of the skin. The present article discusses the past, present and future of transdermal delivery of methotrexate.

The enhancing effect of ion-pairing on the skin permeation of glipizide

The purpose of the present study was to investigate the permeation of glipizide (GP) and observe the effect of an interaction with amines as counter ions, including diethylamine, triethylamine, ethanolamine, diethanolamine, triethanolamine, N-(2-hydroxylethyl) piperidine. Permeation experiments were performed in vitro, using rat abdominal skin as a barrier. The lipophilic donor system consisting of isopropyl myristate (IPM) and ethanol (EtOH; EI system, 8:2) produced a marked enhancement of GP flux through rat skin. All the amines investigated in this study had performed an enhancing effect on GP flux, and triethylamine had the most potent enhancing effect on GP in the vehicle IPM:EtOH = 8:2(w/w). In the presence of counter ions, the solubility of GP in the donor solution (IPM:EtOH = 8:2) was increased and the log K (o/w) of GP was decreased, which may due to higher solubility of the GP in the IPM:EtOH = 8:2(w/w). (13)C NMR spectroscopy was used to identify the ion-pairing formation between GP and the respective counter ion. It was surprising that all the four enhancers examined, such as isopropyl myristate, propylene glycol, N-methyl-2-pyrrolidone, azone, and oleic acid, had no enhancing effect on the percutaneous permeation of GP. This study showed that the formation of ion-pairs between GP and counter ions is a useful method to promote the skin permeation of GP.

Combined effects of iontophoretic and chemical enhancement on drug delivery

This paper reports measurements of the release characteristics of the model drug salbutamol from a liquid crystalline vehicle across both human and hairless murine skin in vitro. The use of oleic acid and iontophoresis as penetration enhancement techniques, used separately and simultaneously, was also investigated. Over a period of 12h, salbutamol base did not diffuse from the vehicle across excised human skin while, in contrast, over a period of 2h, the drug passively transported across hairless murine skin. The diffusion co-efficient for the drug in this tissue was estimated to be 4.54+/-0.60x10(-9)cm(2)s(-1) with a permeability co-efficient of 7.03+/-0.83x10(-7)cms(-1). A current of density of 0.39mAcm(-2) facilitated a significant transport of salbutamol from the liquid crystalline vehicle across excised human skin but with a small (<0.1) transport number. The quantity of salbutamol transported across excised hairless murine skin under the same conditions was significantly greater with a transport number of 0.68. The alteration of the permeability of the tissue was less than that of the human skin and a full recovery of the pre-iontophoretic permeability of murine skin was consistently observed. The incorporation of either oleic or lauric acid into the monoglyceride component of the vehicle at a concentration of 0.1M had a marked effect on the transport of salbutamol across both human and murine skin. The initial passive permeation of the drug across the skin was not affected but the rate of drug delivery during iontophoresis was typically observed to increase by a factor greater than two. The post-iontophoretic transport of salbutamol across either tissue was also substantially enhanced in the presence of the fatty acid. The analogous use of stearic acid did not significantly influence the iontophoretic or the post-iontophoretic transport of salbutamol across excised human skin. The investigation also revealed a synergistic combination of the fatty acid and anodal iontophoresis to enhance the in vitro transport of other drug substances, including nicotine and diltiazem hydrochloride across murine skin. Oleic acid increased both the iontophoretic and post-iontophoretic transport of nicotine, so that the enhancement of drug delivery was greater than that caused by the current alone. The investigation also indicated that the barrier properties of the skin recover following the constant current iontophoresis in the presence of oleic or lauric acids.

Ternary complexes of flurbiprofen with HP-beta-CD and ethanolamines characterization and transdermal delivery

Binary and multicomponent systems complexes prepared with HP-beta-CD and/or with monoethanolamine (MEA), diethanolamine (DEA) or triethanolamine (TEA) were obtained. The results of solid-state studies indicated the presence of strong interactions between the components in the binary and the ternary systems. Drug solubility and dissolution rate in water were notably improved by employing the HP-beta-CD and the alkanolamines. The combined use of cosolvency and complexation with MEA in the presence of HP-beta-CD on the permeation of flurbiprofen through the human skin was evaluated. The combination of IPM, PG, and HP-beta-CD yield the highest permeation for the flurbiprofen-MEA complex.

Feasibility of transdermal delivery of fluoxetine

Feasibility of developing a transdermal drug delivery of fluoxetine has been investigated. Permeation studies of fluoxetine across human cadaver skin were carried out using Franz diffusion cells. The receptor phase consisted of pH 7.4 phosphate buffer maintained at 37 degrees C. Permeation enhancement of fluoxetine, either in the salt or base form, was achieved using various enhancers like azone, SR-38, and ethanol. Various O/W microemulsion systems of fluoxetine were developed to study their effect on the skin permeation of fluoxetine. The results indicated that ethanol at 65% vol/vol was able to increase the permeation of fluoxetine the most, while microemulsion systems showed decrease in the permeation of fluoxetine. The permeation of fluoxetine obtained using a 65% vol/vol ethanolic solution was found to be sufficient to deliver the required dose (20-80 mg) from a patch of feasible size. The results seem promising for developing a transdermal drug delivery system of fluoxetine.

The effect of pretreatment with terpenes on transdermal iontophoretic delivery of arginine vasopressin

This study investigates the effects of terpenes and iontophoresis on the in vitro permeation of arginine vasopressin (AVP) through rat skin and the biophysical changes induced by the chemical enhancers in the stratum corneum (SC) lipids by FT-IR spectroscopy. Pretreatment with terpenes (e.g. 5% w/v, carvone, pulegone, cineole and menthol in EtOH:W (2:1) system) increased (P < 0.05) the flux of AVP in comparison to control (not pretreated with enhancer) but was not significantly different (P > 0.05) in comparison to iontophoresis. Amongst different terpenes studied maximum enhancement ratio was observed with cineole. In combination, iontophoresis did not further increase (P > 0.05) the permeation of AVP through the enhancer pretreated epidermis in comparison to pretreatment with enhancer or iontophoresis alone. Hence it was concluded that although the combination was effective in flux enhancement compared to control, there was no synergism in action between terpenes and iontophoresis. FT-IR spectroscopic studies revealed that EtOH:W (2:1) system is not effective in lipid extraction. The area under the symmetric and asymmetric stretching peaks at 2850 and 2920 cm(-1) revealed that at the concentration used terpenes did not extract any lipids from the epidermis. The mode of action of terpenes is attributed to the breaking of hydrogen bonds between the ceramide head groups of lipids in the SC leading to greater fluidization of the SC lipids.

Transdermal delivery of zidovudine: effect of vehicles on permeation across rat skin and their mechanism of action

The purpose of this study was to investigate the effects of various solvent systems containing water, ethanol, propylene glycol (PG), and their binary combinations on the ex vivo permeation of zidovudine (AZT) across Sprague-Dawley rat skin using Franz diffusion cells at 37 degrees C. Further, saturation solubility and epidermis/vehicle partition coefficient of AZT in the solvent systems, and their effect on percentage hydration of epidermis using thermogravimetric analysis were determined to understand the mechanisms by which these solvent systems change drug permeability properties. All binary combinations of PG, ethanol and water significantly increased saturation solubility of AZT. Maximum AZT flux was observed with 66.6% ethanol among ethanol-water solvents, with 33.3% PG in PG-water solvents and with 100% ethanol among PG-ethanol combinations. PG-water and PG-ethanol solvents neither reduced the lag time nor increased AZT flux across rat skin. In addition, high concentrations of PG in both water and ethanol reduced steady state flux of AZT. Further, thermogravimetric studies revealed that solvents containing high PG concentrations dehydrate epidermis. Among all the solvent combinations, highest flux and short lag time were achieved with ethanol at 66.6% in water and hence is a suitable vehicle for transdermal delivery of AZT.

Effect of vehicles on the transdermal delivery of melatonin across porcine skin in vitro

Melatonin is a good candidate for transdermal drug delivery considering its variable oral absorption, a short biological half-life and extensive first pass metabolism. The purpose of this study was to investigate the effect of various vehicles on the in vitro permeation of melatonin across porcine skin. The skin permeation studies were carried out with vertical diffusion cells using dermatomed porcine skin. The flux of melatonin from isopropyl myristate, Lauroglycol FCC and ethanol were respectively 1.5, 1.4 and 1.3 times higher than that observed with water (P<0.001). However, flux values of melatonin with Labrasol, propylene glycol and mineral oil were significantly lower than that of water (P<0.001). There was no significant difference between the flux of melatonin from the following vehicles: Transcutol, Phosol 50 PG, ethyl oleate, PEG 400 and water (F=0.2082, P>0.05). In general, vehicles with high melatonin solubility showed low permeability coefficient values. The flux had no correlation to the solubility data, suggesting that high solubility values do not translate to high drug permeation. The present study suggests that isopropyl myristate, Lauroglycol FCC and ethanol may be used as potential vehicles in the transdermal delivery of melatonin.

The development of delivery agents that facilitate the oral absorption of macromolecular drugs

Macromolecules comprise a growing group of new drugs with great clinical promise. To date, the therapeutic application of these drugs has been limited, because they are effective only when administered parenterally. Unfortunately, macromolecular drugs are not absorbed following nonparenteral dosing, because the mechanisms of the human body are designed to degrade and/or exclude them. To overcome the numerous obstacles to the noninvasive delivery of these drugs, various approaches are under investigation including the use of delivery agents to promote drug absorption. This review provides a summary of the novel approaches currently in progress in the areas of transdermal, transmucosal, and oral delivery of macromolecular drugs facilitated by delivery agents. We review our own novel work in this area in some detail, including the methods developed for the synthesis of the delivery agents, in vitro screening techniques developed to select compounds for in vivo testing, and the results of in vivo screening in both rats and primates, including preliminary safety and efficacy studies. Finally, the results of Phase I clinical studies showing the oral delivery of heparin are presented.

Percutaneous penetration studies for risk assessment

During the last few years the general interest in the percutaneous absorption of chemicals has increased. It is generally accepted that there is very few reliable quantitative and qualitative data on dermal exposure to chemicals in the general population and in occupationally exposed workers. In order to predict the systemic risk of dermally absorbed chemicals and to enable agencies to set safety standards, data is needed on the rates of percutaneous penetration of important chemicals. Standardization of in vitro tests and comparison of their results with the in vivo data could produce internationally accepted penetration rates and/or absorption percentages very useful for regulatory toxicology. The work of the Percutaneous Penetration Subgroup of EC Dermal Exposure Network has been focussed on the standardization and validation of in vitro experiments, necessary to obtain internationally accepted penetration rates for regulatory purposes. The members of the Subgroup analyzed the guidelines on percutaneous penetration in vitro studies presented by various organizations and suggested a standardization of in vitro models for percutaneous penetration taking into account their individual experiences, literature data and guidelines already in existence. During the meetings of Percutaneous Penetration Subgroup they presented a number of short papers of up to date information on the key issues. The objective was to focus the existing knowledge and the gaps in the knowledge in the field of percutaneous penetration. This paper is an outcome of the meetings of the Percutaneous Penetration Subgroup and reports the presentations on the key issues identified throughout the 3-year duration of the Dermal Exposure Network (1997-1999).

Chemical enhancement of percutaneous absorption in relation to stratum corneum structural alterations

The outermost layer of the skin, stratum corneum (SC), provides an outstanding barrier against the external environment and is also responsible for skin impermeability toward most solutes. The barrier function is related to the unique composition of the SC lipids and their complex structural arrangement. The lipoidal matrix of the SC, therefore, is a target of penetration enhancer action. The literature on the skin barrier structure and function and on the mechanisms of action of some well established permeation promoters, with a focus on their impact on SC structural alterations, is reviewed. Data obtained from infrared, thermal, and fluorescence spectroscopic examinations of the SC and its components imply enhancer improved permeation of solutes through the SC is associated with alterations involving the hydrocarbon chains of the SC lipid components. Data obtained from electron microscopy and X-ray diffraction reveals that the disordering of the lamellar packing is also an important mechanism for increased permeation of drugs induced by penetration enhancers.

Effects of iontophoresis and electroporation on the stratum corneum. Review of the biophysical studies

This review focuses on the effects induced by iontophoresis and electroporation on the stratum corneum of the skin. Hence, the aims were: (1) to contribute to the understanding of the mechanisms of drug transport by these methods; (2) to evaluate the safety issues associated with current application. Complementary biophysical methods were used to provide a complete picture of the stratum corneum. Even though the mechanism of drug transport is believed to be different, i.e., electrophoresis for iontophoresis and creation of new aqueous pathways for electroporation, the effects on the stratum corneum detected minutes after current application are very similar. For both methods, the major findings were: (1) a disorganisation of the lipid bilayers of the stratum corneum; (2) an increase in skin hydration; (3) a larger decrease in skin resistance induced by electroporation as compared to iontophoresis. These changes were partly reversible and depended on the amount of electrical charges transferred. The mechanisms of stratum corneum perturbations are discussed. These perturbations could explain partly the increase in drug transport. If iontophoresis is considered as a safe method of drug delivery, the data augurs for the safety of electroporation.

Effect of penetration enhancers and iontophoresis on the ultrastructure and cholecystokinin-8 permeability through porcine skin

The present study explores the effect of chemical penetration enhancers and iontophoresis on the in vitro permeability of cholecystokinin-8 (CCK-8) through porcine epidermis and on the ultrastructural changes in stratum corneum as observed by transmission electron microscopy (TEM). Enhancer [i.e., ethanol (EtOH), and 10% oleic acid in combination with ethanol (OA/EtOH)] pretreatment significantly increased (p < 0.01) the permeability coefficient of CCK-8 in comparison with the control (pretreated epidermis without enhancer). Iontophoresis further increased the permeability of CCK-8 (p < 0.01) through the enhancer-pretreated epidermis in comparison with the control. These results showed the synergistic effect of iontophoresis and enhancers such as OA/EtOH that provides an additional driving force to maintain and control the target flux of CCK-8. The ultrastructure of stratum corneum treated with ethanol demonstrated a loss of structural components in the superficial stratum corneum cell layers. OA/EtOH transformed the highly compact cells of stratum corneum into a looser network of filaments, creating an increased free volume and greater intracellular surface area. Treatment of stratum corneum with OA/EtOH followed by iontophoresis resulted in further swelling of stratum corneum cell layers. In conclusion, OA/EtOH in combination with iontophoresis increased the permeability of CCK-8 by loosening and swelling of stratum corneum cell layers.

Proliposome-based transdermal delivery of levonorgestrel

Mesophasic proliposomal system for levonorgestrel was developed and evaluated both in vitro and in vivo. The vesicles were mostly unilamellar, however, few vesicles were multilamellar which budded off spontaneously upon hydration. The release of drug from this system adhered to zero order kinetics. The effect of alcohols and volatile oils on transdermal flux was investigated. The flux was found to be the highest for alcohol, and followed by that for lemon oil. The in vivo studies indicate the requirement for a loading dose, since, a significant lag phase was observed before the therapeutic levels were reached. This system was, however, superior to the PEG-based ointment system which was employed as the control formulation. The results demonstrate the potential of proliposomal system for efficacious transdermal delivery of hydrophobic drugs.

Mutual hairless rat skin permeation-enhancing effect of ethanol/water system and oleic acid

The mutual hairless rat skin permeation-enhancing effect of ethanol (EtOH)/water systems and oleic acid (OA) was investigated with model lipophilic (estradiol, progesterone, levonorgestrel) and hydrophilic drugs (zalcitabine, didanosine, zidovudine). The aqueous solubility and hairless rat skin permeation rate of each drug, saturated in various compositions of EtOH/water system (with and without OA), was determined at 37 degrees C. The hairless rat skin permeation rates of ethanol from EtOH/water systems (with and without OA) were also measured to investigate the skin permeation-enhancing mechanism of EtOH/water systems and OA. Both saturated solubility and steady-state permeation rates of each drug in EtOH/water systems increased exponentially as the volume fraction of ethanol increased, reached the maximum value, and then decreased with further increases in the ethanol volume fraction. Moreover, the hairless rat skin permeation rate of each drug had a good linear relationship with that of ethanol up to 70% (v/v) of ethanol in the EtOH/water system. The addition of OA in the EtOH/water system (70:30 and 60:40 for lipophilic and hydrophilic drugs, respectively) further enhanced the skin permeation rate of both ethanol and drugs. However, > 2.0% (v/v) OA was required to achieve the plateau level in the skin permeation rate of lipophilic drugs, whereas only 0.3% (v/v) OA was required for hydrophilic drugs. The skin permeation rate of ethanol also increased with the addition of OA in the EtOH/water systems (70:30 and 60:40), reached the plateau level with < 1.0% (v/v) OA, and did not significantly change with higher OA concentration. These results suggest that the addition of OA in the EtOH/water system is a useful method to enhance the hairless rat skin permeation rate of both hydrophilic and lipophilic drugs, with more enhancement for hydrophilic drugs.

An investigation into the transdermal delivery of nifedipine

A systematic attempt to develop a transdermal delivery system for nifedipine is presented. Measured physicochemical properties influencing percutaneous absorption such as solubility and partition coefficient confirmed the drug's potention for such a formulation approach. However, studies involving permeation through hairless mouse skin from a range of hydrophilic and hydrophobic donor vehicles indicated inadequate penetration. Attempts to increase the drug flux through the animal skin or a range of artificial membranes alone or in parallel by use of the penetration enhancers sodium lauryl sulphate 1% and propylene glycol 20% in a sodium carboxymethylcellulose 3% gel base failed to raise the drug flux to an acceptable level. Likewise increase in the drug thermodynamic gradient across the skin by use of mixed solvents or supersaturated drug solutions was ineffective if an aqueous receiving phase was used. Collectively the results suggest that the development of a transdermal delivery system for the chemically unmodified drug in humans is unlikely to be successful.

Transdermal delivery of dideoxynucleoside-type anti-HIV drugs. 2. The effect of vehicle and enhancer on skin permeation

The effects of vehicles and enhancers on the skin permeation of the dideoxynucleoside-type anti-HIV drugs Zalcitabine (DDC), Didanosine (DDI), and Zidovudine (AZT) were studied using hairless rat skin at 37 degrees C. After each drug was saturated in various volume fractions of ethanol (EtOH)/water or EtOH/tricaprylin (TCP) cosolvent system for 48 h at 37 degrees C, an in vitro skin permeation study was conducted using Valia-Chien permeation cells for 30 h. The skin permeation rates of DDC, DDI, and AZT from both EtOH/water and EtOH/TCP cosolvent systems increased as the volume fraction of ethanol was increased, reached maximum values at 50-60% (v/v) of ethanol, and then decreased with further increase of ethanol volume fraction. The EtOH/water cosolvent system seems to enhance the skin permeation of these drugs by increasing both the solubility of drug in the vehicles and partitioning of drug into the skin. The skin permeation enhancing effect of EtOH/TCP seems to be solely due to the increase in partitioning of drug into the skin. Addition of 1.0% (v/v) of permeation enhancers, such as oleic acid (OA) and N-methyl-2-pyrrolidone (NMP), in the EtOH/TCP (50:50) cosolvent system could not significantly increase the permeation rate of these drugs. Incorporation of viscous TCP into ethanol probably reduced the thermodynamic activity of enhancers to distribute from the vehicle to the skin. However, incorporation of 1.0% (v/v) of OA in the EtOH/water (60:40) cosolvent system dramatically enhanced the skin permeation of these drugs while reducing the lag time. The permeation rates of these drugs increased as OA concentration was increased up to 0.3% (v/v) in the EtOH/water (60:40) cosolvent system and reached a plateau with further addition of OA. Using a saturated solution in the EtOH/water (60:40) cosolvent system containing 1.0% (v/v) OA, DDC, and AZT reached the target permeation rate required to maintain a therapeutic system level across hairless rat skin. Although only DDC reached the target permeation rate across human cadaver skin, these results suggest that the mutual enhancement effect of ethanol and OA may make transdermal delivery of dideoxynucleoside-type anti-HIV drugs feasible.

A mechanistic study of the effects of the 1-alkyl-2-pyrrolidones on bilayer permeability of stratum corneum lipid liposomes: a comparison with hairless mouse skin studies

The influence of a series of 1-alkyl-2-pyrrolidones (C2-C8) on the transport behavior of lipophilic and polar/ionic permeants across hairless mouse skin was recently investigated by employing a physical model approach that treats the stratum corneum barrier as a diffusional system of parallel lipoidal and pore pathways. In this previous study, the transport enhancement effects (enhancement factor, EHMS) on the lipoidal pathway of the stratum corneum were found to be essentially the same for all steroidal probe permeants investigated at various concentrations of these 1-alkyl-2-pyrrolidones. In the present research, the relationship between solute transport enhancement in the lipoidal pathway of hairless mouse skin and the transport enhancement in the stratum corneum lipid liposome bilayer was studied by comparing the enhancement factor for the lipoidal pathway in the hairless mouse skin, EHMS, with that for the stratum corneum lipid liposome, ESCLL, at equal solution concentrations of the 1-alkyl-2-pyrrolidones. The release rates of D-mannitol, D-glucose, 3-O-methyl-D-glucose, sucrose, and raffinose from stratum corneum lipid liposomes were determined, and the ESCLL values for these permeants were compared with the EHMS values obtained with hairless mouse skin using the steroidal permeants. An important finding in this study was a semiquantitative correlation between the enhancement effects induced by the 1-alkyl-2-pyrrolidones, except 1-ethyl-2-pyrrolidone, with the liposome bilayer using sugar molecules as permeants and those found with the lipoidal pathway in hairless mouse skin using steroid molecules as permeants.(ABSTRACT TRUNCATED AT 250 WORDS)

Fluorescence anisotropy studies on the interaction of the short chain n-alkanols with stratum corneum lipid liposomes (SCLL) and distearoylphosphatidylcholine (DSPC)/distearoylphosphatidic acid (DSPA) liposomes

Previously, the action of the short chain n-alkanols (from C1 to C5) and isopropanol as possible enhancers on the transport of lipophilic and polar/ionic permeants across hairless mouse skin was investigated. In the present study, the steady-state fluorescence anisotropy was measured as a means of estimating the changes in fluidity caused by the n-alkanols at different depths in the stratum corneum lipid liposomes (SCLL). Some selected experiments with the distearoylphosphatidylcholine (DSPC)/distearoylphosphatidic acid (DSPA) liposomes were performed for relative comparisons. The effects of the n-alkanols on polarity sensitive parameters such as fluorescence lifetimes, fluorescence quantum yield ratios, and emission maxima were studied in the SCLL. The polarity of the bilayer decreased as the fluorescent probe was placed closer to the bilayer center and the n-alkanols did not alter this gradient. Assessment of the depth-dependent effects of the n-alkanols using SCLL showed that most of the significant changes in fluidity induced by the n-alkanols were observed at intermediate depths (C2-C9) and there was little or no increase in fluidity in the deep hydrophobic region close to the bilayer center. These results suggest that the short chain n-alkanols work as effective 'fluidizing' agents at the intermediate depths (C2-C9) in the bilayer.