Transdermal iontophoresis of the dopamine agonist 5-OH-DPAT in human skin in vitro.

The feasibility of transdermal iontophoretic delivery of a potent dopamine agonist 5-OH-DPAT was studied in vitro in side by side diffusion cells across human stratum corneum (HSC) and dermatomed human skin (DHS) according to the following protocol: 6 h of passive diffusion, 9 h of iontophoresis and 5 h of passive diffusion. The influences of the following parameters on the flux were studied: donor solution pH, NaCl concentration, drug donor concentration, current density and skin type. A current density of 0.5 mA cm(-2) was used, except for one series of experiments to study the current density effect. Probably due to the influence of the skin perm-selectivity and the competition with H(+), increase in pH from 3 to 5 resulted in a significant increase in flux. Further increase in pH to 6 did not further increase the flux. The iontophoretic transport was found to increase linearly with concentration and current density, providing a convenient way to manage dose titration for Parkinson's disease therapy. Increase in concentration of NaCl dramatically reduced the flux of 5-OH-DPAT as a result of ion competition to the transport. When DHS was used, the iontophoretic transport was less. Also, with DHS the response in flux profile, by switching the current on and off, was shallower than that with HSC. With the optimum condition, a delivery of 104 microg of 5-OH-DPAT per cm(2) patch per hour is feasible, indicating that the therapeutic level could be achieved with a smaller patch size than required in case of rotigotine. Thus, based on this in vitro study, transdermal iontophoretic delivery of 5-OH-DPAT is very promising.     

In vitro transdermal iontophoretic transport of timolol maleate: effect of age and species.

Transdermal iontophoresis would be a promising method for the systemic delivery of water soluble and ionic drugs of relatively high molecular size, including peptides. In the present study, the effect of biological parameters such as age of the animal and species variation (rat, rabbit, mouse, guinea pig and human) on the transdermal iontophoretic transport was studied using timolol maleate (TM) as a model drug. The iontophoretic transport of TM across the skins obtained from the rats of different age groups was found to be similar. The results of the present study suggest that the age of the animal (Wistar rats: 1-8 months) did not appear to influence the transdermal iontophoretic transport of TM significantly. The amount of TM transported during iontophoresis (2 h) was significantly different among the different skin species. But the total amount of TM transported up to 24 h (2 h iontophoresis+22 h post-iontophoretic passive diffusion) was not significantly different among the different species studied. The present study provides further evidence that iontophoresis technique reduces the interspecies differences in the transdermal permeation of drugs, which is normally observed in passive diffusion of drugs. However, it must be noted that excised skins have been used in the present study to investigate the role of age and species variation on the iontophoretic transport of TM. The influence of these parameters under in vivo conditions might be different considering the physiological differences in different species and in the animals of different age groups.     

Reverse iontophoretic monitoring in premature neonates: feasibility and potential.

Premature neonates represent a fragile patient population, often subjected to intensive clinical care and multiple drug therapy, which must be monitored carefully and continuously. The difficult and painful nature of repetitive blood sampling, particularly in this population, has provided considerable impetus for the development of noninvasive methods for monitoring blood analytes. Reverse iontophoresis, a relatively new technology already used for the transdermal monitoring of blood glucose levels in adults, may be particularly well-suited to exploit the unique properties of preterm neonatal skin. The underdevelopment of the premature infant's epidermis, and more specifically the stratum corneum (SC), results in an increased permeability to molecular transport. In this study, we have investigated the feasibility of reverse iontophoretic monitoring of two model drugs, caffeine and theophylline, which are often administered to premature neonates. To this purpose, tape-stripped porcine skin in vitro, which has been previously demonstrated to be an excellent model for premature neonatal skin, was employed. Reverse iontophoresis across intact membranes enabled a quantifiable extraction of both drugs predominantly at the cathode compartment. The mechanism of extraction of these essentially neutral drugs (caffeine and theophylline being uncharged at pH 7.4) was electroosmosis. However, when the SC was removed by progressive tape-stripping, the amounts of drugs extracted by reverse iontophoresis were equivalent to those obtained by passive diffusion. In these circumstances, therefore, the benefit and usefulness of the applied electric field had been lost. In summary, the absence of an at least partially functional skin barrier obviates, in the case of neutral molecules, the control (and directional transport) offered by iontophoresis; in contrast, for ionized species, where the principal iontophoretic transport mechanism is electromigration, the approach should be valid.     

Delivery of nalbuphine and its prodrugs across skin by passive diffusion and iontophoresis.

The in vitro transport of nalbuphine (NA) and its prodrugs across various skins was investigated in order to assess the effects of prodrug lipophilicity on passive as well as iontophoretic permeation. The passive diffusion of NA and its prodrugs increased with the drug lipophilicity. Iontophoresis significantly increased the transport of NA and its prodrugs; the enhancement ratio was highest for NA and decreased as the drug lipophilicity increased. Measurements using intact and stratum corneum (SC)-stripped skins showed that the SC was the major skin diffusion barrier for the passive permeation of NA and nalbuphine pivalate (NAP). The iontophoretic permeation of NA and NAP across intact and SC-stripped skins indicated that the SC layer was not rate-limiting for the permeation of NA, but remained the rate-limiting barrier for transdermal permeation of NAP. Permeation studies using SC-stripped and delipidized skins suggested that the intercellular pathway was the predominant route for the passive permeation of NA and NAP as well as the iontophoretic permeation of NAP across the SC. The relative rates of passive and iontophoretic permeation across Wistar rat skins demonstrated that a significant amount of NA may permeate skin via the appendageal routes, whereas NAP permeated predominantly through the lipid matrix.     

Bioadhesive film for the transdermal delivery of lidocaine: in vitro and in vivo behavior.

The aim of this work was to study, in vitro and in vivo, the behavior of a skin bioadhesive film containing lidocaine. The film characterization included drug transport studies through skin in vitro and in vivo tape stripping with and without iontophoresis. We studied the effect of drug loading in order to identify the release mechanism. Finally, the release rate was compared with a lidocaine commercial gel, to assess the therapeutic value. From the data obtained it can be concluded that the monolayer film acts as a water-permeable transdermal/dermal patch on application to the skin. The permeation kinetics across the skin was not linear, but the patch acted as a matrix controlling drug delivery. Additionally, the permeation rate increased with drug loading. The in vivo experiments with tape stripping indicated that the presence of water during film application is essential to achieve not only the proper adhesion but also an effective accumulation. The application of electric current to the patch can further increase the amount of drug accumulated in the stratum corneum.     

In vitro iontophoresis of R-apomorphine across human stratum corneum. Structure-transport relationship of penetration enhancement.

To achieve a therapeutical effect of the anti-Parkinson's drug R-apomorphine via iontophoresis delivery, enhancement strategies in vitro were explored using three structurally related enhancers, lauric acid (LA), dodecyltrimethylammonium bromide (DTAB) and Laureth-3 oxyethylene ether (C(12)EO(3)). Human stratum corneum and shed snake skin were pretreated with 0.15 M each enhancer solution in propylene glycol (PG). Thereafter, passive diffusion, iontophoretic transport and post-iontophoretic passive diffusion were investigated. Compared to the control (PG pretreatment), a slight inhibition on both passive and iontophoretic delivery was observed with cationic surfactant DTAB pretreated stratum corneum. Pretreatment with anionic surfactant LA resulted in a great enhancement on passive delivery, but only a small enhancing effect on the iontophoretic delivery. Unlike the others, the nonionic surfactant C(12)EO(3) substantially increased iontophoretic transport rate of R-apomorphine by 2.3-fold, whereas passive delivery was basically unchanged or slightly affected. The magnitude of enhancing effect of C(12)EO(3) was dependent on the surfactant concentration and the pretreatment duration. Moreover, comparison of transport data through shed snake skin with human stratum corneum indicates that both shunt- and intercellular pathways are involved in the iontophoretic transport of R-apomorphine.     

In vitro and in vivo iontophoresis of a tripeptide across nude rat skin

The iontophoretic delivery across nude rat skin of a tripeptide (Threonme-Lysine-Proline), which is positively charged at pH 7.4, has been measured in vitro and in vivo. The peptide was delivered from a poloxamer gel which demonstrated thermoreversible properties: the gel is a liquid at room temperature, a feature which facilitates preparation, whereas, at 37°C, the gel solidifies and provides a welldefined delivery system. The in vitro studies showed that: (a) iontophoresis significantly enhanced peptide delivery compared to passive transport; (b) peptide delivery was directly proportional to the applied continuous direct current density over the range 0.18–0.36 mA/cm²; (c) following 6 h of iontophoresis, minimal degradation of the peptide in either the donor or receptor phases of the diffusion cell (by electrolysis and/or metabolism) was observed; (d) exposure of the skin to direct current prior to the application (without current) of the tripeptide lowered the barrier function to the passive transport of Thr-Lys-Pro. In vivo, a single intravenous injection of radiolabeled tripeptide was rapidly eliminated (primarily in the urine) with an apparent half-life of less than 30 min. When the peptide was delivered by iontophoresis, considerable enhancement over passive diffusion was again achieved; the cumulative delivery of tripeptide in vivo was predictable from the in vitro results. In addition, and once more in parallel to the in vitro findings, pre-exposure of the skin to the iontophoretic current lowered barrier function to the subsequent passive delivery of the peptide. Skin sectioning and radioassay demonstrated that, relative to passive diffusion, iontophoresis produced (i) greater localization of the peptide in the skin, and (ii) delivery of peptide to deeper layers of the skin. Finally, histological and electron microscopical examination or rat skin following 3 hours of iontophoresis (at 0.36 mA/ cm²) in vivo did not reveal any gross morphological changes.     

Buccal iontophoretic delivery of atenolol.HCl employing a new in vitro three-chamber permeation cell.

The present work showed that the iontophoretic approach was feasible to enhance buccal drug delivery. A new in vitro horizontal three-chamber iontophoretic permeation cell has been developed to reflect the in vivo iontophoretic drug delivery more closely, electrodes were positioned on the epithelial side in separate chambers. Iontophoretic delivery of atenolol.HCl across porcine buccal mucosa increased proportional to (a) increased initial donor concentration in the range of 0.027 M to 0.10 M atenolol.HCl, (b) increased "on time" of current on/off ratio valued 50/50, 75/25 and 90/10 resulting in enhancement ratios 19, 58, and 112 respectively, initially applying 0.10 M atenolol.HCl and (c) increased current density valued 0.1, 0.2, 0.3, and 0.4 mA/cm(2) obtaining enhancement ratios 6, 18, 36, and 58 respectively, initially applying 0.10 M atenolol.HCl. Microscopy of hematoxyilin-eosin stained sections of porcine buccal mucosae conducting 8-h passive permeation showed minute morphological alterations whereas 8-h iontophoretic treatment showed disordering of the outer epithelial cell layers, alterations being more pronounced in mucosae from reference chambers than donor chambers. The results demonstrated the feasibility of the iontophoretic approach to enhance and control the rate of buccal drug delivery, hence the usefulness of the new permeation cell.     

Lithium monitoring by reverse iontophoresis in vivo

BACKGROUND: We investigated reverse transdermal iontophoresis as an alternative, noninvasive method for lithium monitoring in vivo. The objectives of such an approach would be to facilitate compliance with treatment and to improve the quality of life for bipolar patients. METHODS: We studied 23 bipolar or schizo-affective patients. Over a 2-h period, we extracted lithium and other cations across intact skin by application of an electric current (0.8 mA) and quantified the concentrations by ion chromatography. A blood sample provided comparative reference values for the drug and other electrolytes. RESULTS: Lithium, sodium, potassium, and calcium were efficiently extracted by iontophoresis. Lithium extraction fluxes were proportional to the corresponding serum concentrations, whereas sodium, potassium, and calcium extraction fluxes were relatively constant, consistent with their stable concentrations in blood. Normalization of the lithium extraction flux with that of sodium, which acted as an "internal standard", permitted calibration of the monitoring procedure without the need for a blood measurement. This conclusion was tested retrospectively by dividing the patients into two groups. The reverse iontophoretic extraction data from the first subset (a) established the proportionality between lithium iontophoresis (or the relative electrotransport of lithium and sodium) and (b) predicted lithium blood concentrations in the second subset of patients. The predictive ability was very good, with the internal standard concept providing substantial benefit. CONCLUSIONS: Reverse iontophoresis appears to offer a novel and accurate method for lithium monitoring.     

Noninvasive sampling of phenylalanine by reverse iontophoresis.

While iontophoresis is typically associated with drug delivery across the skin, the symmetry of the technique permits its application to the essentially noninvasive withdrawal of biologically important analytes from the subcutaneous space to the body's surface. The identification of other substances which can be monitored by this procedure, and to its optimization and development as a more general clinical chemistry tool, is a long-term objective. In this paper, we describe a preliminary in vitro investigation into the feasibility of extracting and analyzing the amino acid, phenylalanine, with the ultimate aim to develop a diagnostic test for phenylketonuria, a potentially fatal metabolic disease in infants. Over a subdermal concentration range of 1-10 mM phenylalanine, reverse iontophoretic extraction was rapid, easily detectable and highly linear. Manipulation of the electrolyte composition surrounding the cathode (i.e., the site of collection of the iontophoretically-extracted material) enabled phenylalanine to be electrotransported at a rate of approximately 6 nmol/cm(2)/h when present subdermally at 1 mM. The potential exists, therefore, to use this approach for the noninvasive detection of systemic amino acid levels in vivo. However, such a development will necessitate a suitable and convenient analytical approach (e.g., a biosensor), with a sensitivity about 10-times greater than that used in this work, which can be combined successfully with the reverse iontophoretic extraction technology.     

An analysis of solute structure-human epidermal transport relationships in epidermal iontophoresis using the ionic mobility: pore model.

This study sought to examine the extent the ionic mobility-pore model, used to describe epidermal iontophoretic structure-permeability relationships, could describe a range of published iontophoretic data. The model incorporates, as determinants of iontophoretic transport, solute size, solute mobility, total current applied, presence of extraneous ions, determined by conductivities of both donor and receptor solutions, permselectivity of the epidermis, as well as a solute pore interaction term which together provided an excellent regression for iontophoretic permeability. The 'pore' radii for solute transport estimated from literature iontophoretic permeabilities using the model ranged from 6.8 to 17 A depending on the degree of hydration and conformation of solute assumed. The pore size range is consistent with transport through the polar intercellular and transappendageal pathway for transport. The pore restriction form of the model better describes the data obtained to date than other models described previously (Yoshida, N.H., Roberts, M.S., Solute molecular size and transdermal iontophoresis across excised human skin. J. Control. Release 25 (1993) 177-195).     

Correlation of transdermal iontophoretic phenylalanine and mannitol transport: test of the internal standard concept under DC iontophoresis and constant resistance AC iontophoresis conditions.

The purpose of this study was to test the feasibility of using an internal standard approach to predict the transdermal flux of phenylalanine (Phe) across human epidermal membrane (HEM) in vitro during iontophoresis of constant direct current (DC), constant skin resistance alternating current (AC) with DC offset (AC-plus-DC), symmetric constant resistance AC (AC-only), and constant current DC with the application of a polyelectrolyte. Under the constant current DC and AC-plus-DC conditions, a linear relationship between the permeation of Phe and that of mannitol was observed with a slope close to unity. The ratios of the Phe permeability coefficients to those of mannitol during iontophoresis with different HEM samples were essentially constant with significantly smaller inter-sample and intra-sample variabilities than those of the raw Phe permeability coefficient data. This demonstrates that mannitol is a good internal standard for predicting the transdermal iontophoretic flux of Phe under these two conditions. On the other hand, the correlations of the permeability coefficients of Phe and mannitol under the AC-only iontophoresis and iontophoresis with the polyelectrolyte are poorer than those observed during DC and AC-plus-DC iontophoresis. The poor correlations are believed to be related to Phe being a zwitterion and its anionic form in HEM. Previously, iontophoretic transport of glucose has been demonstrated to be essentially the same as that of mannitol. The good correlations between Phe and mannitol transport across HEM during DC and AC-plus-DC iontophoresis in the present study therefore suggest that glucose and its extraction can be used as the internal standard for iontophoretic Phe monitoring.     

Contributions of electromigration and electroosmosis to peptide iontophoresis across intact and impaired skin.

d-(Arg)-Kyotorphin iontophoresis was investigated across intact and impaired skins in vitro. Iontophoretic flux increased from 68+/-12 to 538+/-116 nmol cm(-2) h(-1) when the peptide concentration in the anodal compartment was raised from 5 to 40 mM. Electromigration was the principal transport mechanism, accounting for approximately 70% of total peptide delivery. Reducing the number of competing ions in the formulation significantly increased iontophoretic flux but did not affect convective solvent flow. The latter was independent of peptide concentration indicating that skin permselectivity was not modified by kyotorphin transport. Total iontophoretic flux was unaffected when the stratum corneum was removed by tape-stripping (146+/-34 versus 150+/-26 nmol cm(-2) h(-1)). However, the contributions of the different transport mechanisms were significantly altered: (i) electromigration decreased, as more of the charge was carried by anions from the sub-dermal milieu; (ii) electroosmosis was absent; and (iii) passive permeation increased significantly. Transport rates across intact and impaired skin barriers were statistically indistinguishable when the donor electrolyte composition was modified; increased competition from anions was mitigated by the decreased Na+ levels in the formulation. Removal of Cl- ions from the receiver phase further increased peptide delivery, and also increased anodal electroosmosis.     

Iontophoresis: electrorepulsion and electroosmosis.

Over the last 10-15 years, the electrical enhancement of drug delivery across the skin has undergone intense investigation. During this period, considerable amounts of experimental data have been generated, and the successful enhancement of a diverse array of molecules has been achieved. Indeed, the commercial exploitation of the method can be envisaged within the next few years. Despite this progress, however, the mechanistic understanding of iontophoresis remains a challenging scientific question that is yet to be fully resolved. The routes of permeation under the influence of an applied electrical potential, and the molecular interactions of the transporting drug with these pathways, have resisted unequivocal and unambiguous identification. Equally, the relative contributions of electrorepulsion and electroosmosis to the total iontophoretic flux have proven difficult to quantify, due to the difficulty of designing appropriate experiments. The situation is further complicated by the fact that it has now been established that certain lipophilic cations, in particular, can associate strongly with the skin during their iontophoretic delivery, thereby altering the electrical properties of the membrane, and changing the mechanism of transport. In this short communication, the roles of electrorepulsion and electroosmosis have been reconsidered from a simple theoretical point of view, and experimental approaches by which their relative importance may be estimated have been proposed and subjected to initial evaluation.     

In vitro and in vivo comparisons of constant resistance AC iontophoresis and DC iontophoresis.

A previous in vitro constant electrical resistance alternating current (AC) iontophoresis study with human epidermal membrane (HEM) and a model neutral permeant has shown less inter- and intra-sample variability in iontophoretic transport relative to conventional constant direct current (DC) iontophoresis. The objectives of the present study were to address the following questions. (1) Can the skin electrical resistance be maintained at a constant level by AC in humans in vivo? (2) Are the in vitro data with HEM representative of those in vivo? (3) Does constant skin resistance AC iontophoresis have less inter- and intra-sample variability than conventional constant current DC iontophoresis in vivo? (4) What are the electrical and the barrier properties of skin during iontophoresis in vivo? In the present study, in vitro HEM experiments were carried out with the constant resistance AC and the conventional constant current DC methods using mannitol and glucose as the neutral model permeants. In vivo human experiments were performed using glucose as the permeant with a constant skin resistance AC only protocol and two conventional constant current DC methods (continuous constant current DC and constant current DC with its polarity alternated every 10 min with a 3:7 on:off duty cycle). Constant current DC iontophoresis was conducted with commercial constant current DC devices, and constant resistance AC iontophoresis was carried out by reducing and maintaining the skin resistance at a constant target value with AC supplied from a function generator. This study shows that (1) skin electrical resistance can be maintained at a constant level during AC iontophoresis in vivo; (2) HEM in vitro and human skin in vivo demonstrate similar electrical and barrier properties, and these properties are consistent with our previous findings; (3) there is general qualitative and semi-quantitative agreement between the HEM data in vitro and human skin data in vivo; and (4) constant skin resistance AC iontophoresis generally provides less inter- and intra-subject variability than conventional constant current DC.     

Controlled transdermal iontophoresis by ion-exchange fiber.

The objective of this study was to assess the transdermal delivery of drugs using iontophoresis with cation- and anion-exchange fibers as controlled drug delivery vehicles. Complexation of charged model drugs with the ion-exchange fibers was studied as a method to achieve controlled transdermal drug delivery. Drug release from the cation-exchange fiber into a physiological saline was dependent on the lipophilicity of the drug. The release rates of lipophilic tacrine and propranolol were significantly slower than that of hydrophilic nadolol. Permeation of tacrine across the skin was directly related to the iontophoretic current density and drug concentration used. Anion-exchange fiber was tested with anionic sodium salicylate. The iontophoretic flux enhancement of sodium salicylate from the fiber was substantial. As the drug has to be released from the ion-exchange fiber before permeating across the skin, a clear reduction in the drug fluxes from the cationic and anionic fibers were observed compared to the respective fluxes of the drugs in solution. Overall, the ion-exchange fibers act as a drug reservoir, controlling the release and iontophoretic transdermal delivery of the drug.     

Transdermal iontophoresis of rotigotine: influence of concentration, temperature and current density in human skin in vitro.

Iontophoretic transport of rotigotine across human stratum corneum (HSC) was studied in vitro in side by side diffusion cells according to the following protocol: 6 h of passive diffusion, 9 h of iontophoresis followed by 5 h of passive diffusion. A current density of 0.5 mA cm(-2) was applied. The parameters studied were the influence of the rotigotine concentration in donor phase and the influence of the molecular weight of the co-ions. To this end, Na(+) was replaced by tetra ethyl ammonium (TEA(+)) or tetra butyl ammonium (TBA(+)) (both at pH 5 and 6). In addition, the influence of the acceptor phase temperature (32 degrees C versus room temperature), the replacement of HSC by dermatomed human skin (DHS), and the relation between drug transport and current density were examined. The estimated steady-state flux (Flux(ss)) gradually increased with the drug concentration in the donor phase in a linear manner. The flux was also linearly correlated with the applied current density providing a convenient approach to individual dose titration. The use of TEA(+) as co-ion increased the rotigotine iontophoretic flux significantly, while TBA(+) did not. Replacing HSC by DHS reduced the iontophoretic rotigotine transport, while an increase in temperature to 32 degrees C increased the rotigotine flux. The maximum Flux(ss) achieved was around 80 nmol cm(-2) h(-1) indicating that by means of iontophoresis, a therapeutic level of rotigotine might be achieved with a reasonable patch size.     

Comparison of the effects of short, high-voltage and long, medium-voltage pulses on skin electrical and transport properties.

High-voltage pulses have been shown to increase rates of transport across skin by several orders of magnitude on a time scale of minutes to seconds. Two main pulse protocols have been employed to promote transport: the intermittent application of short ( approximately 1 ms) high-voltage (approximately 100 V across skin) pulses and a few applications of long (=100 ms) medium-voltage (>30 V across skin) pulses. In order to better evaluate the benefits of each protocol for transdermal drug delivery, we compared these two protocols in vitro in terms of changes in skin electrical properties and transport of sulforhodamine, a fluorescent polar molecule of 607 g/mol and a charge of -1. Whereas both protocols induced similar alterations and recovery processes of skin electrical resistance, long pulses of medium-voltage appeared to be more efficient in transporting molecules across skin. Skin resistance decreased by three (short pulses) and two (long pulses) orders of magnitude, followed by incomplete recovery in both cases. For the same total transported charge, long pulses induced faster and greater molecular transport across skin than short pulses. In addition, a greater fraction of the aqueous pathways created by the electric field was involved in molecular transport when using long pulse protocols. Transport was concentrated in localized transport regions (LTRs) for both protocols but LTRs created by long pulses were an order of magnitude larger than those formed by short pulses and the short pulses created an order of magnitude more LTRs. Overall, this study is consistent with the creation of fewer, but larger aqueous pathways by long, medium-voltage pulses in comparison to short, high-voltage pulses.     

Distribution of khellin in excised human skin following iontophoresis and passive dermal transport

The aim of this work was to study in vitro khellin distribution into human skin after passive or iontophoretic transport. The experiments were performed on excised human skin, using vertical Franz-type diffusion cells. The effects of current application and reservoir pH were studied. At the end of the experiments the skin was sliced thinly and the drug was extracted and analyzed by HPLC. The results showed that khellin is able to penetrate through stratum corneum, to reach basal epidermis and upper dermis. The application time proved to be an important parameter. Current application (30 min; 0.5 mA/cm²), with a donor at pH 7.0, favored khellin accumulation even if the drug is not ionized. On the contrary, the use of a formulation at pH 3.2 inhibited drug accumulation. Leaving the drug reservoir in contact with the skin for 30 min after current application led to a dramatic increase of khellin concentration. A combination of dermal iontophoresis and passive diffusion is then a useful technique to govern khellin distribution in the skin.     

Optimization of iontophoretic transdermal delivery of a peptide and a non-peptide drug

In vitro iontophoretic transdermal delivery (ITD) of a tripeptide, enalaprilat (EP) and a non-peptide, cromolyn sodium (CS), across frozen hairless guinea pig (HGP) skin were investigated. Parameters for optimization of ITD included the influence of ionic strength (μ), buffer type and size, drug loading in the donor and the effect of pH. Drug permeation into the receptor compartment was monitored using HPLC assay methods developed for the study. An optimum μ of 6.66 mM in acetate buffer was found necessary for efficient ITD of CS. An exponential decrease in the flux of CS was observed with an increasing μ. Buffer ions larger than acetate ions inhibited the transport of CS ions. With an increase in the donor concentration of CS, a hyperbolic relationship for the increase in flux was observed. For EP, permeation was not detectable when μ was increased to greater than 31 mM in phosphate-buffered solution. With an increase in pH above the pK_a1 (3.55) for EP, a linear decrease in flux was observed. Higher drug loading of EP in the donor compartment provided better permeation. Effect of freezing of HGP skin on the iontophoretic delivery of EP and CS was also evaluated. Flux values for either of the drugs studied were similar when frozen or fresh skins were used. Reversibility studies indicated that no gross current induced permeation changes occurred with the HGP skin. Passive permeation of either of the drugs investigated was negligible.