Enhanced delivery of mitomycin C derivatives through hairless mouse and rat skins

The percutaneous permeation characteristics of two lipophilic mitomycin C derivatives with aromatic moieties were determined using excised hairless mouse and rat skins and compared with those of mitomycin C (MMC). 1a-N-Benzylmitomycin C penetrated more readily through both kinds of skin than MMC without metabolic conversion. 1a-N-Benzyloxycarbonylmitomycin C effected a 4-fold increase in the delivery of MMC through the rat skin and was completely converted to MMC by an enzyme in rat skin. However, saturation of the metabolic conversion activity was observed in the hairless mouse skin.     

Effect of vehicles and penetration enhancers on the in vitro percutaneous absorption of tenoxicam through hairless mouse skin

The effects of vehicles and penetration enhancers on the in vitro permeation of tenoxicam from saturated solutions through dorsal hairless mouse skin were investigated. Various types of vehicles, including ester-, alcohol-, and ether-types and their mixtures, were used as vehicles, and then a series of fatty acids and amines were employed as enhancers, respectively. Even though the fluxes of tenoxicam from saturated pure vehicles were generally low (0.1-1.1 microg/cm2 per h), the skin permeability of tenoxicam was significantly increased by the combination of diethylene glycol monoethyl ether (DGME) and propylene glycol monolaurate (PGML) or propylene glycol monocaprylate (PGMC); the highest fluxes were achieved at 40% of DGME in both of the two cosolvents. The marked synergistic enhancement was also obtained by using propylene glycol (PG)-oleyl alcohol (OAl) cosolvent. The greatest flux was attained by the addition of unsaturated fatty acids at 3% concentration to PG. But saturated fatty acids failed to show a significant enhancing effect. The enhancement factors with the addition of oleic acid (OA) or linoleic acid (LOA) to PG were 348 and 238, respectively. Tromethamine (TM) showed an enhancing effect by the increased solubility; however, triethanolamine (TEA) did not show a significant enhancing effect. Rather, it decreased the fluxes of tenoxicam when added to PG with fatty acids. The above results indicate that the combinations of lipophilic vehicles like OA, LOA or OAl and hydrophilic vehicles like PG can be used for enhancing the skin permeation of tenoxicam.     

Enhanced delivery of mitomycin C prodrugs through the skin

The percutaneous permeation characteristics through the excised rat skin of seven lipophilic 1a-N-substituted derivatives of mitomycin C (I) were determined in relation to their physicochemical and pharmaceutical properties. Among the four derivatives of compound I [benzyl (II), benzoyl (III), benzylcarbonyl (IV) and benzoyloxycarbonylmitomycin C (V)] possessing aromatic pro-moieties with different linkage structures, compounds II and V showed higher steady-state penetration rates than I. II penetrated the skin without metabolic conversion, while V was completely converted to I. Three alkoxycarbonyl-type derivates of I [propyl (VI), pentyl (VII), and nonyloxycarbonylmitomycin C (VIII)] with different alcoholic pro-moieties were studied to elucidate the effect of the carrier moiety on their permeation. VII showed an improved permeability, but the most lipophilic prodrug, VIII, failed to enhance the delivery of I. Compounds III and VI, which had high melting points and low biphasic solubilities, only slightly permeated the skin. Permeation rates of the test compounds reached a plateau in the concentration range over their solubilities in the vehicle; the maximum rates of II, V and VII were, respectively, 6.5, 5.3 and 3.4 times larger than that of I.     

Effect of penetration enhancers on in vitro percutaneous penetration of nimesulide through rat skin

The influence of several penetration enhancers alone and/or in various combinations on the percutaneous penetration of nimesulide (NM) from Carbopol 934 based gel formulations was investigated. Skin permeation studies were performed using Franz-type diffusion cells and full-thickness abdominal rat skin. Various types of compounds such as ethanol, isopropyl alcohol, propylene glycol, Transcutol, Tween 80 and oleic acid were employed as penetration enhancers. The steady-state flux, the lag time and permeability coefficients of NM for each formulation were calculated. The results showed that the skin permeability of NM from gels tested was significantly increased (P < 0.05) by isopropyl alcohol (40%) and the combination of oleic acid (3%) with Transcutol (30%) when compared with the control formulation. In conclusion, these substances could be considered as penetration enhancers for NM topical formulations.     

Evaluation of penetration enhancement of lidocaine by nonionic surfactants through hairless mouse skin in vitro

The effect of two nonionic surfactants (polyoxyethylene sorbitan monoesters) on percutaneous absorption of lidocaine in the presence of various concentrations of propylene glycol is reported. Comparisons were made in vitro using excised hairless mouse skin as the barrier membrane. Under infinite dose conditions, steady-state flux was enhanced by surfactants at high propylene glycol concentrations. The same trend was observed following application of a thin layer of formulation to the skin (finite-dose conditions). However, penetration behavior was complex due to: (a) changes in vehicle composition following application, (b) temperature changes resulting from evaporation or moisture uptake, and (c) depletion of lidocaine as a result of penetration with compositions that lost water by evaporation. Two peaks in the flux versus time curve were observed. Surfactant monomer concentration in the vehicles was increased in the presence of propylene glycol.     

Effect of vehicles and enhancers on the in vitro permeation of melatonin through hairless mouse skin

The effects of vehicles and penetration enhancers on the in vitro permeation of melatonin through dorsal hairless mouse skin were investigated. Propylene glycol laurate (PGL), isopropyl myristate (IPM), propylene glycol monolaurate (PGML) and propylene glycol monocaprylate (PGMC) showed high permeation fluxes and PGL, PGML and PGMC decreased lag time significantly. In both of the binary co-solvents of diethylene glycol monoethyl ether (DGME)-PGL and DGME-IPM, the highest fluxes were achieved at 20% of DGME, which were 10.5 +/- 1.5 and 9.1 +/- 2.4 microg/cm2/h, respectively. Among fatty acids used as a permeation enhancer, capric acid and oleic acid in DGME-PGL (80:20 v/v) showed relatively high enhancing effects. Capric acid also shortened the lag time of melatonin from 2.4 +/- 0.7 to 1.3 +/- 0.2 h. Oleic acid, however, failed to shorten the lag time. Therefore, for effective solution formulations in terms of permeation flux and lag time, capric acid-containing DGME-PGL (80:20 v/v) could be used to enhance the skin permeation of melatonin.     

Mechanistic study of alkyl azacycloheptanones as skin permeation enhancers by permeation and partition experiments with hairless mouse skin

In previous studies (Yoneto et al., 1995. J Pharm Sci 84:312-317; Kim et al., 1992. Int J Pharm 80:17-31; and Warner et al., 2001. J Pharm Sci 90:1143-53), the transport enhancing effects of four homologous series of enhancers-the n-alkanols, 1-alkyl-2-pyrrolidones, 1,2-alkanediols, and N,N-dimethylalkanamides - on the transport of steroidal permeants across hairless mouse skin (HMS) were investigated. Isoenhancement concentrations are defined as the aqueous concentrations for which different enhancers induce the same extent of permeant transport enhancement, E, for the lipoidal pathway of the stratum corneum (SC). Our studies have shown that the E = 10 isoenhancement concentrations of these four homologous series were nearly the same when compared at the same n-alkyl group chain length and therefore that the contribution of the polar head group toward the enhancer potency was found to be essentially constant. In the present study, we have determined the isoenhancement concentrations (E = 10) for the 1-alkyl-2-azacycloheptanone series [1-butyl-2-azacycloheptanone (BAZ), 1-hexyl-2-azacycloheptanone (HAZ), and 1-octyl-2-azacycloheptanone (OAZ)] and compared the results with those of the previously studied four homologous series. We have found that the E = 10 isoenhancement concentrations (aqueous phase concentrations) of the 1-alkyl-2-azacycloheptanones (Azs) are around 10 times lower than those for the previously studied four homologous series when compared at the same alkyl group chain length. This indicates an approximately 10 times higher potency of Azs. This finding was a point of interest because the polar group of Azs is similar to that of 1-alkyl-2-pyrrolidones (Aps). To further probe the nature of the mechanism of action of the Azs and Aps and to better understand the lower E = 10 isoenhancement concentrations found with the Azs, it was decided (a) to determine the equilibrium partitioning (uptake) of the Azs and the Aps from the aqueous phase into the HMS SC at E = 10, and (b) to determine the equilibrium partitioning (uptake) of a surrogate permeant, estradiol (E2beta), into the SC in the absence of and in the presence of Azs and Aps at E = 10. The following were the outcomes from the two partitioning studies. Firstly, at the E = 10 isoenhancement concentrations, the extent of partitioning (uptake) of the Azs and Aps into the intercellular lipids of the HMS SC was found to be approximately the same, even though the E = 10 isoenhancement concentrations (aqueous phase concentrations) of the Aps were around 10 times greater than those of the Azs. We interpret this to mean (whereas the potencies of the Azs are around ten times greater than those of the Aps when related to their aqueous concentrations) that the potencies of the two enhancer series are about the same when expressed in terms of their concentrations in the intercellular lipid phase of the SC. Another outcome of the partitioning studies has been the finding that the extent of partitioning into the intercellular lipids of the SC at E = 10 isoenhancement conditions for both the Azs and Aps is essentially independent of the n-alkyl chain length (from butyl to octyl). A third result from these experiments has been that the partitioning of E2beta (the surrogate permeant) into the HMS SC under E = 10 isoenhancement concentration conditions is approximately the same with the Aps and Azs as enhancers. For both the Aps and Azs, the E2beta SC partitioning enhancement was found to be in the range of 5-6 at E = 10. This comparable partitioning enhancement for E2beta in the presence of Aps and Azs at E = 10 suggests that the same mechanism was involved and that these enhancers act, in part but to a significant extent, by inducing a higher partitioning tendency of the permeant into the transport rate-limiting lipoidal domains of the SC. (c) 2003 Wiley-Liss, Inc. and the American Pharmaceutical Association J Pharm Sci 92:297-310, 2003     

Effect of penetration enhancers on the transdermal delivery of bupranolol through rat skin

Bupranolol (BPL) is a suitable drug candidate for transdermal drug delivery system development based on its favorable physicochemical and pharmacokinetic properties. The effect of different penetration enhancers on the permeation of BPL across rat skin was studied using side-by-side diffusion cells. 2-Pyrrolidone (PY), 1-methyl-2-pyrrolidone (MPY), and propylene glycol (PG) at various concentrations were used as penetration enhancers along with 0.4% w/v aqueous suspension of BPL. Menthol at different concentrations in isopropanol-water (6:4) mixture also was used as an enhancer wherein BPL at 0.4% w/v was completely solubilized. Skin pretreatment studies were carried out with all the above enhancers to understand their role in the penetration enhancement effect. PY and MPY at 5% w/v concentrations increased the permeation of BPL by 3.8- and 2.4-fold, respectively, versus control (p < .01). PG at 10% and 30 w/v concentrations increased the flux of BPL by 2.5- and 5.0-fold, respectively, versus control (p < .001). Menthol at 2% w/v concentration increased the flux of BPL by 3.8-fold (p < .01) and further increase in menthol concentration significantly decreased the flux of BPL. Overall, pyrrolidones and menthol at low concentrations (5% w/v or less) and PG at 30% w/v concentration were effective as penetration enhancers for BPL.     

Effect of some penetration enhancers on the permeation of glibenclamide and glipizide through mouse skin

The purpose of this investigation was to study the effect of some penetration enhancers on in vitro permeation of glibenclamide and glipizide through mouse skin. Ethanol in various concentrations, N-methyl-2-pyrrolidinone, transcutol, propylene glycol and terpenes like citral, geraniol and eugenol were used as penetration enhancers. The in vitro skin permeation experiments were conducted by both simultaneous application of drug and enhancer solution and by pretreatment of the skin with neat enhancer. At the end of the experiment drug retained in the skin was estimated. The flux values (microg/cm2/h) of both drugs significantly (p < 0.05) increased in the presence of penetration enhancers, except transcutol and propylene glycol. The glibenclamide flux values ranged from 1.42 +/- 0.09 without enhancer, to 18.25 +/- 1.21 in a combination of 50% ethanol and 5% eugenol. Glipizide flux values ranged from 3.21 +/- 0.51 without enhancer, to 57.21 +/- 5.25 in a combination of 50% ethanol and 5% eugenol. Skin retention and solubility of both drugs increased with all penetration enhancers compared to control (except propylene glycol). As the target permeation rates for glibenclamide and glipizide were calculated to be 193.8 and 184.8 microg/h respectively, the present study showed that the required permeation rates for both drugs could be achieved with the aid of enhancers by increasing the area of application in an appreciable range.     

Model analysis of flux enhancement across hairless mouse skin induced by chemical permeation enhancers

Previous permeant partitioning studies with hairless mouse skin (HMS) in the presence of several chemical skin permeation enhancers have revealed that, when such enhancers induce significant skin permeability coefficient enhancement, it is accompanied by significant enhancement in the equilibrium uptake (partitioning) of the permeant into the intercellular lipid component of the stratum corneum (SC). Particularly, it was found that the 1-alkyl-2-pyrrolidones and the 1-alkyl-2-azacycloheptanones, at aqueous solution concentrations that gave skin permeation enhancement (E) of 10 for corticosterone (CS, the permeant), enhanced the equilibrium uptake of beta-estradiol (E2beta, a surrogate permeant) from the aqueous phase into the intercellular lipids of HMS SC by a factor of 5-7. This finding raised the question of whether this uptake enhancement induced by the permeation enhancer under equilibrium conditions would be essentially the same as that determined kinetically from time-dependent permeation experiments utilizing appropriate SC membrane models and Fick's laws of diffusion to treat the data. HMS transport experiments were conducted with CS as the permeant and 1-octyl-2-pyrrolidone (OP) and 1-hexyl-2-azacyloheptanone (HAZ) as the enhancers. In treating the experimental data, a one-layer skin transport model (SC only) and a two-layer model (SC layer and the epidermis/dermis layer) were both investigated. Both the partition coefficient enhancement (E(K)) and the diffusion coefficient enhancement (E(D)) were deduced from the data treatment. The results showed that when the total transport enhancement of CS was around 11, E(K) was in the range of 6-8 and E(D) was in the range of 1.5-1.9 using both the one-layer and the two-layer models. This E(K) value was found to be in good agreement with the E2beta partition enhancement obtained directly under equilibrium conditions in previous studies. This indicates that (a) the rate-limiting domain for the transport of the lipophilic permeants across HMS and the HMS SC intercellular lipid domain probed in the equilibrium partitioning experiments are essentially the same, and (b) the total flux enhancement (E) of lipophilic permeants across HMS was driven mainly by enhancing the partitioning of the permeant into the rate-limiting domain (E(K)) and secondarily by enhancing the diffusion coefficients (E(D)) of the permeant in the domain. Comparison of the one-layer and two-layer skin model results revealed that non-steady-state transport of lipophilic compounds across HMS was better described by the two-layer model because the dermis/viable epidermis played a significant role in lipophilic permeant binding.     

Improved acitretin delivery through hairless mouse skin by cyclodextrin complexation

The effects of four cyclodextrins, i.e., 2-hydroxypropyl-β-cyclodextrin, randomly methylated β-cyclodextrin (MβCD), γ-cyclodextrin and 2-hydroxypropyl-γ-cyclodextrin, on the aqueous solubility of acitretin were investigated. Of the four cyclodextrins tested MβCD displayed the largest effect. The aqueous solubility of the drug could be increased even further by pH adjustment. Thus, the solubility of acitretin in an aqueous pH 7.5 buffer solution containing 23% (w/v) MβCD was determined to be 1.96 mg/ml. Acitretin is insoluble in water. The flux of acitretin through hairless mouse skin was determined to be 0.032 mg h⁻¹ cm⁻² from a pure propylene glycol vehicle but 0.201 mg h⁻¹ cm⁻² from an aqueous MβCD containing vehicle.     

Lipophilic metronidazole derivatives and their absorption through hairless mouse skin

Previously we have shown that the diacyl glyceryl ester of naproxen is absorbed into excised mouse skin and slowly degraded to release naproxen. In the present work we have synthesised some organic acid and fatty acid derivatives of metronidazole, and studied the in-vitro degradation in aqueous buffer solutions and serum as well as their permeation through hairless mouse skin. The derivatives were enzymatically degraded in serum to form metronidazole. Only the acetic acid and butyric acid derivatives were able to permeate hairless mouse skin intact. The fatty acid derivatives released metronidazole within the skin. The metronidazole delivery through the skin was significant when the metronidazole oleate was used. This compound could therefore be considered as a suitable pro drug for dermal applications.     

Effect of pH and penetration enhancers on electroosmotic flow and flux through skin

We have investigated the effect of pH and four penetration enhancers on the electroosmotic volume flow (EVF) and flux through skin to get more detailed understanding of this phenomenon and its effect on flux. The results were evaluated in relation EVF and the permeability change by current induced skin damage. At pH 7.4, we have confirmed that the direction of convective solvent flow is from anode to cathode. At pH 4.0, no permselectivity was observed and it seems that this pH is close to the isoelectric point of skin. At pH 3.0, the permselectivity of skin is reversed. From the difference in flux between just before (47 μg/cm² h) and after (32 μg/cm² h) cathodal current-off, the magnitude of EVF is estimated to be smaller than 1.5 μl/cm² h, if we consider the recovery of skin to a lower permeability after current-off. At pH 7.4, Oleic acid (OA) and propylene glycol monolaurate (PGML) increased the passive flux markedly. Synergistic effect in flux between OA and current was observed for both anodal and cathodal current. The use of isopropyl myristate (IPM) in combination with anodal current resulted in reduced flux when compared to the flux of anodal current alone. Cathodal flux of OA or PGML treated skin increased continuously until the current was off. However, to the contrary of our expectation, flux decreased after current-off. We think this is mainly due to the recovery of damaged skin (flux decreasing effect), though the disappearance of EVF may slightly increase the flux. For IPM and propylene glycol, the combination of enhancer with cathodal current inhibited the flux, similar to that observed for anodal delivery. Overall, these results provide further information on the role of electroosmosis and the effect of penetration enhancers in combination with current on flux through skin.     

Transdermal permeation of apomorphine through hairless mouse skin from microemulsions

The in vitro transdermal absorption of apomorphine from microemulsions was studied using the skin of the hairless mouse as a membrane. Two microemulsions (no. 1 and 2) were prepared and thickened both containing 3.9% of apomorphine hydrochloride. The lipophilicity of the drug was increased by forming apomorphine-octanoic acid ion-pairs. The fluxes of the drug from the microemulsions through hairless mouse skin were 100 microg h(-1) cm(-2) from no. 1 and 88 microg h(-1) cm(-2) from no. 2. Apomorphine in microemulsions, protected from light with antioxidants, showed no degradation for up to 6 months.     

Status of terpenes as skin penetration enhancers

Since its introduction, transdermal drug delivery has promised much but, in some respects has still to deliver on that initial promise, due to inherent limitations imposed by the percutaneous route. The greatest obstacle for transdermal delivery is the barrier property of the stratum corneum. Many approaches have been employed to breach the skin barrier, of which, the most widely used one is that of chemical penetration enhancers. Of the penetration enhancers, terpenes are arguably the most highly advanced and proven category and are classified as generally regarded as safe (GRAS) by the Food and Drug Administration. This paper presents an overview of the investigations on the feasibility and application of terpenes as sorption promoters for improved delivery of drugs through skin.     

Comparison of the effect of ultrasound and of chemical enhancers on transdermal permeation of caffeine and morphine through hairless mouse skin in vitro

The effect of ultrasound (US) on permeation of two model drugs, caffeine (CAF) and morphine (MOR), through hairless mouse skin in vitro was compared with that of three chemical enhancers. Low-frequency (40 KHz), low-power (<0.5 W/cm(2)) US was used; the effect of high-frequency US (1.5-3.0 MHz) was also evaluated in the case of CAF. The chemical enhancers, tested in combination with propylene glycol (PG), were benzalkonium chloride (BAC) oleyl alcohol (OA) and alpha-terpineol (TER). The high-frequency US enhancement of CAF transdermal flux was not statistically significant, while low frequency produced a small but significant increase of the enhancement factor. The effect of US on CAF permeation, however, was lower than that produced by chemical enhancers, in particular OA. The effect of low-frequency US on permeation of MOR was significantly greater (about 10-fold) when compared, on the same frequency and intensity basis, with the effect on CAF. The most active chemical enhancer for MOR, OA, had practically the same effect as low-frequency US. Sonicated skin, although showing slight histological changes, recovered its original low permeability characteristics after turning off sonication. Within the tested system, chemical enhancement appears to offer some advantages over low-frequency US.     

The in-vitro percutaneous absorption of glycerol trioleate through hairless mouse skin

The chemical composition of the aqueous receptor fluid in one-chambered diffusion cells used for in-vitro percutaneous absorption studies has been shown to significantly affect the apparent extent of absorption of the triglyceride, glycerol trioleate. Using murine skin samples it was found that the addition of albumin to the receptor fluid resulted in an increase in the apparent extent of absorption, while the presence of the bacteriostatic agent thiomersal resulted in a decrease. The viability of the skin samples had no effect on absorption. It was determined that the chemical species in the receptor fluid was the free fatty acid. Albumin presumably bound the fatty acid, thereby creating a sink which enabled the fatty acid to partition from the skin into the receptor fluid.     

Effect of penetration enhancers on skin permeation of trazodone hydrochloride from matrix type transdermal formulation through mouse and human cadaver epidermis

A transdermal dosage form of trazodone hydrochloride (TZN) may be useful in the treatment of moderate to severe depression in schizophrenic patients by providing prolonged duration of action. It will also improve patient compliance and bioavailability. Controlled input of TZN would attenuate fluctuating plasma level of TZN resulting from oral therapy. The aim of the current investigation was to evaluate its flux and the effects of various penetration enhancers, viz., isopropyl myristate (IPM), isopropyl palmitate (IPP), butanol and octanol on transdermal permeation from matrix-based formulations through the skin. The enhancing effect on the permeation of TZN was determined using the mouse and human cadaver epidermis. In vitro permeation data were collected at 37 degrees C using Keshary-Chien diffusion cells. The skin permeation was then evaluated by measuring the steady state permeation flux of TZN, enhancement ratio and the diffusion parameter. The highest enhancing effect was obtained with IPM followed by butanol, octanol and IPP. In general, higher fluxes were observed through mouse epidermis as compared with the human cadaver epidermis. The skin retention of TZN for both the species in the presence of different enhancers was nearly 3 times higher than for the control formulation. Based on the observed results, a transdermal patch of about 70 cm2 consisting of 10 % IPM should be able to attain and maintain therapeutic plasma concentration of TZN at 0.75 mg/mL over a period of 24 h.     

The metabolism of 7-ethoxycoumarin and 7-hydroxycoumarin by rat and hairless mouse skin strips

The metabolism of 7-ethoxycoumarin and 7-hydroxycoumarin was studied in rat and hairless mouse skin strips. These preparations supported de-ethylation, sulphation and glucuronidation reactions. The de-ethylation reaction was inducible in both species by pretreatment with either 5,6-benzoflavone or 3-methylcholanthrene. The hairless mouse strips exhibited a greater basal de-ethylase activity than rat strips, although the latter was the more responsive to inducers. Accompanying the increase in de-ethylation activity was a change in the pattern of metabolites, with a large increase in the percentage of the unconjugated metabolite. When 7-hydroxycoumarin was employed as the primary substrate the glucuronide was the major metabolite formed by strips from both species. The glucuronidation and sulphation activities were unchanged by 3-methylcholanthrene pretreatment.