Quantitative evaluation of aqueous isopropanol enhancement of skin flux of terbutaline (sulfate). I. Ion associations and species equilibria in the formulation

[Enhancing effects of ion-pair complexes on skin permeation of cromolyn in vitro]

Lipophilic ion-pair complexes of 3-dl-alpha-tocopherylcarbonyl-1-n-alkyl-pyridinium-cromolyn (TAP-CG) were designed to enhance the percutaneous absorption of cromolyn (CG), and the effect of n-alkyl chainlength of the ion-pair complexes on the CG permeation through hairless mouse skin was evaluated in vitro. The permeation rates of CG were examined in isopropyl myristate (IPM) suspension using static Keshany-Chien type diffusion cells at 32 degrees C. The permeation parameters, steady-state flux, diffusion coefficient, partition coefficient between skin and IPM, and permeability coefficient were determined. Steady-state fluxes of CG increased linearly with the increasing n-alkyl chain-length of TAP-CG, and 3-dl-alpha-tocopherylcarbonyl-1-n-hexyl-pyridinium-cromolyn (THP-CG) produced the highest CG flux (0.62 +/- 0.11 nmol.cm-2.h-1), which was 14-fold greater than that of CG.Na in IPM suspension and more than 480-fold greater than that of CG.Na in aqueous solution due to increasing lipophilicity. In the case of TAP-CG with longer n-alkyl chainlength than THP-CG, however, the steady-state fluxes of CG decreased due to the high molecular weight and/or the high lipophilicity of the ion-pair complexes. It is suggested that lipophilic ion-pair complexes, especially THP-CG, are effective in absorption of cromoglicate through the skin. The results would be useful for studies on the role of each counterion in the lipophilic ion-pair complexes.

The apparent lipophilicity of quaternary ammonium ions is influenced by galvani potential difference, not ion-pairing: a cyclic voltammetry study

PURPOSE

This work examines whether ion-pairing contributes to the apparent lipophilicity of cations, which is seen by a shake-flask or titrimetic method to be influenced by the nature and concentration of counter-ions.

METHODS

To solve this problem, the lipophilicity of several quaternary ammonium drugs was measured by cyclic voltammetry in the 1,2-dichloroethane/water system. The standard ionic partition coefficient values so obtained (log Pdce(o,C)) were correlated with log Poct values calculated by the CLOGP algorithm for the respective neutral molecules.

RESULTS

The standard (i.e., intrinsic) lipophilicity values are shown to depend on a, the structure of the ion (nature, volume, charge), and b, on the Galvani potential difference at the ITIES (interface between two immiscible electrolyte solutions).

CONCLUSIONS

The standard lipophilicity values were not influenced by counter-ions. In contrast, simulations showed that the increased apparent lipophilicity of cations, as measured by the shake-flask method in the presence of lipophilic anions, is fully accounted for by the resulting increase in the Galvani potential difference.

Ion pair skin transport of a zwitterionic drug, cephalexin

The ion pair skin transport of cephalexin was investigated using various counter ions and solvents. The permeability of cephalexin was enhanced by 1-alkylsulfonates (ASs) at pH 3.0 and by tetraalkylammoniums (AAs) at pH 7.0; the enhancing ratio increased with the number of carbon atoms in their alkyl chains. The corresponding effects of these additives were observed on the partitioning of cephalexin. Most of the additives did not affect the skin transport of D-mannitol and cortisone. These results suggest that the enhanced transport of cephalexin results from the ion pair formation with additives. Although ASs increased the partitioning of cephalexin above that of AAs, the transport enhancement effect of ASs was lower than AAs having the same number of carbon atoms in their alkyl chains, indicating higher diffusivity of the ion pairs with AAs in skin. Moreover, the transport enhancement by AAs increased even more when ethanol-buffer solutions were used as solvents. The conductivity measurement of dissolving solutes in donor solvents showed that the further enhancement might be caused by the increasing ion pair formation in solvents with low dielectric constants. To obtain the maximum enhancement of skin transport of zwitterionic drugs via ion pair concept, one should select a counter ion having high lipophilicity and small volume, and a solvent with suitable pH and low dielectric constant.

Quantitative evaluation of aqueous isopropyl alcohol enhancement on skin flux of terbutaline (sulfate). 2. Permeability contributions of equilibrated drug species across human skin in vitro

This paper demonstrates the usefulness of an equilibria-cotransport model for understanding the isopropyl alcohol-enhanced transport of an ionizable model compound, terbutaline in its sulfate salt form, through human skin in vitro. With the same isopropyl alcohol concentrations (0 - 80% v/v) present at both sides of skin, the permeation experiments were conducted using split-thickness skin and dermis membranes. The equilibria-cotransport model was consistent with total terbutaline flux and a terbutaline-to-sulfate flux ratio, both increased with increasing isopropyl alcohol and/or terbutaline sulfate concentrations. From the saturated drug solutions, aqueous isopropyl alcohol enhanced terbutaline skin flux about 10 - 100-fold with the maximum at 60 - 80% isopropyl alcohol. This overall flux enhancement was qualitatively separated into the contributions of isopropyl alcohol effects on both equilibrated donor concentrations and skin permeabilities of protonated terbutaline, terbutaline-sulfate ion pair anion, and neutral terbutaline-sulfate (2:1) ion triplet. In addition to altering the species equilibria, isopropyl alcohol was found to enhance the transport of both neutral and ionic species of terbutaline sulfate across stratum corneum.

Acid-base properties of terbutaline in terms of protonation macro- and microconstants

The acid/base chemistry of terbutaline was characterized at the molecular level in terms of protonation macroconstants and microconstants. The macroconstants were measured by potentiometry and calculated by standard evaluation methods. The stepwise macroconstant values were log K1 = 11.01, log K2 = 9.89, and log K3 = 8.57 at 25.0 degrees C and 0.2 M ionic strength. The microconstants were deduced using the relationships between macro- and microconstants and an appropriate data set of model compounds (resorcinol and phenylephrine). The molecule of terbutaline contains three ionizable functional groups. In the unprotonated form of the molecule, the two identical phenolate groups are slightly more basic than the secondary amino group, whereas the amino basicity significantly exceeds that of the phenolate site, when the other phenol is protonated. This is due to the large phenolate-phenolate intramolecular interaction. The phenolate-phenolate and the phenolate-amino interactivity parameters were found to be -1.21 and -0.41 log E units, respectively.

Enhanced permeation of polar compounds through human epidermis. I. Permeability and membrane structural changes in the presence of short chain alcohols

The influence of alcohol chain length on polar compound permeation in human skin was investigated to further understand alcohol-enhanced permeation mechanisms. Both thermodynamic and kinetic variables associated with the enhanced permeation of mannitol were ascertained in the presence of high concentrations of short chain alcohols. Permeation of mannitol through human epidermis in the presence of 75% (v/v) alcohol-saline mixtures was determined in symmetric, side-by-side diffusion cells at 32 degrees C. Permeability coefficients increased with increasing alcohol chain length (iso-propanol > ethanol > methanol). Uptake of mannitol into the epidermal tissue increased in the presence of the short chain alcohols, but was independent of alcohol chain length. In addition, mannitol solubility decreased in the presence of the short chain alcohols, but again was independent of alcohol chain length. Therefore, increased mannitol permeability with increasing alcohol chain length could not be attributed to thermodynamic variables. Changes in the amount and conformation of stratum corneum lipids and proteins were determined by Fourier transform infrared (FTIR) spectroscopy. Stratum corneum lipid conformation and mobility was not significantly altered in the presence of the short chain alcohols. However, decreased absorbance of the alkyl chain suggested lipid extraction, which increased with increasing alcohol chain length. Stratum corneum protein conformation was altered in the presence of the short chain alcohols. Decreased infrared absorbance of the Amide I band maximum suggested extraction of stratum corneum proteins, which increased with increased alcohol chain length. These results suggest a correlation between enhanced permeation and extraction of lipids as well as proteins from human skin in the presence of 75% (v/v) aqueous alcohol solutions.