In-vitro transdermal permeation of oxycodone: (I) effect of PH, delipidization and skin stripping

The effect of pH, skin stripping and delipidization on the in-vitro transdermal permeation of a weak base analgesic, oxycodone (pKa=8.53), was studied using hydrodynamically calibrated Valia-Chien diffusion cells. Saturated oxycodone. HCl solutions in citrate-phosphate buffers ranging from pH 4 to 10 were used as the donor solution. Skin samples from the abdominal and dorsal sites of hairless rats, abdominal site of hairless mouse, rabbit pinna ear, as well as human cadaver skin were used in permeation studies. The pHs at which maximum flux attained varied from 6.5 to 7.5 depending upon animal model. The permeabilities of protonated form through intact skin of all the animal models used, was about 7-15 fold lower than that of nonionic form. The unexpected high permeation rate at pHs ranges 4 to 6.5 across human cadaver could be attributed to the possible damage upon storage. The skin stripping and delipidizaton process appeared to increase the permeation rates of oxycodone and the degree enhancement is dependent upon the pH in the donor compartment.     

The influence of chirality,physicochemical properties,and permeation enhancers on the transdermal permeation of amlodipine across rat skin

Purpose: This study was aimed at investigating the possible relationship between the physical properties and the permeation of S-amlodipine and RS-amlodipine and studying the possible enantioselectivity of permeation of amlodipine in the presence and absence of enhancers, such as terpene enhancers and ethanol. Method: The solubility of S-amlodipine and RS-amlodipine was measured using the shake-flask method. The thermodynamic properties were investigated by differential scanning calorimetry (DSC). The type of racemate amlodipine was investigated by DSC and Fourier transform infrared spectroscopy (FTIR). The permeability of racemate and enantiomers of amlodipine through rat epidermis in vitro was investigated using the modified Franz diffusion cell. Results: The aqueous solubility of S-amlodipine was higher than that of RS-amlodipine. The melting temperature and enthalpy of fusion of S-amlodipine were lower than those of RS-amlodipine. RS-amlodipine was a racemic compound. The permeation of the enantiomers of amlodipine from RS-amlodipine reservoir showed no significant differences in the presence and absence of enhancers, but the permeation of S-amlodipine from S-amlodipine reservoir was significantly higher than that of RS-amlodipine from RS-amlodipine reservoir 30% ethanol, 50% ethanol, and terpene enhancers could not influence the difference in permeation between S-amlodipine and RS-amlodipine, but 75% ethanol could reduce the difference. Conclusion: These results suggested that there was no enantioselectivity of the enantiomers of amlodipine from RS-amlodipine reservoir in the presence and absence of enhancers, but the differences in physical properties between S-amlodipine and RS-amlodipine led to the difference in permeation across rat skins.     

Cannabidiol bioavailability after nasal and transdermal application: effect of permeation enhancers

Context: The nonpsychoactive cannabinoid, cannabidiol (CBD), has great potential for the treatment of chronic and ‘breakthrough’ pain that may occur in certain conditions like cancer. To fulfill this goal, suitable noninvasive drug delivery systems need to be developed for CBD. Chronic pain relief can be best achieved through the transdermal route, whereas ‘breakthrough’ pain can be best alleviated with intranasal (IN) delivery. Combining IN and transdermal delivery for CBD may serve to provide patient needs-driven treatment in the form of a nonaddictive nonopioid therapy. Objective: Herein we have evaluated the IN and transdermal delivery of CBD with and without permeation enhancers. Materials and Methods: In vivo studies in rats and guinea pigs were carried out to assess nasal and transdermal permeation, respectively. Results: CBD was absorbed intranasally within 10 minutes with a bioavailability of 34–46%, except with 100% polyethylene glycol formulation in rats. Bioavailability did not improve with enhancers. The steady-state plasma concentration of CBD in guinea pigs after transdermal gel application was 6.3 ± 2.1 ng/mL, which was attained at 15.5 ± 11.7 hours. The achievement of a significant steady-state plasma concentration indicates that CBD is useful for chronic pain treatment through this route of administration. The steady-state concentration increased by 3.7-fold in the presence of enhancer. A good in vitro and in vivo correlation existed for transdermal studies. Conclusion: The results of this study indicated that CBD could be successfully delivered through the IN and transdermal routes.     

Influence of hydroxypropyl-beta-cyclodextrin on the transdermal permeation and skin accumulation of oxybenzone

The objective of the present study was to determine the effects of hydroxypropyl-β-cyclodextrin (HPCD) concentration on the transdermal permeation and skin accumulation of a model ultraviolet (UV) absorber, oxybenzone. The concentration of oxybenzone was held constant at 2.67 mg/mL for all formulations, while the HPCD concentrations varied from 0 to 20% (w/w). Complexation of oxybenzone by HPCD was demonstrated by differential scanning calorimetry. A modified Franz cell apparatus was used in the transdermal experiments, with aliquots of the receptor fluid assayed for oxybenzone by high-performance liquid chromatography. From the permeation data, flux of the drug was calculated. Skins were removed from the diffusion cells at specified time points over a 24-hr period and the oxybenzone content in the skin determined. The aqueous solubility of oxybenzone increased linearly with increasing HPCD concentration, following a Higuchi A_L-type complexation. The stability constant of the reaction was calculated from the phase-solubility diagram and found to be 2047 M^-1. As the concentration of HPCD was increased from 0 to 10%, transdermal permeation and skin accumulation of oxybenzone increased. Maximum flux occurred at 10% HPCD, where sufficient cyclodextrin was added to completely solubilize all oxybenzone. When the concentration of HPCD was increased to 20%, both transdermal permeation and skin accumulation decreased. These data suggest the formation of a drug reservoir on the surface of the skin.     

Nanoethosomes for transdermal delivery of tropisetron HCl: multi-factorial predictive modeling,characterization, and ex vivo skin permeation

Objective: The aim of the present work is to exclusively optimize and model the effect of phospholipid type either egg phosphatidylcholine (EPC) or soybean phosphatidylcholine (SPC), together with other formulation variables, on the development of nano-ethosomal systems for transdermal delivery of a water-soluble antiemetic drug. Tropisetron HCl (TRO) is available as hard gelatin capsules and IV injections. The transdermal delivery of TRO is considered as a novel alternative route supposing to improve BAV as well as patient convenience.

Methods: TRO-loaded ethanolic vesicular systems were prepared by hot technique. The effect of formulation variables were optimized through a response surface methodology using 3?×?2²-level full factorial design. The concentrations of both PC (A) and ethanol (B) and PC type (C) were the factors, while entrapment efficiency (Y₁), vesicle size (Y₂), polydispersity index (Y₃), and zeta potential (Y₄) were the responses. The drug permeation across rat skin from selected formulae was studied. Particle morphology, drug–excipient interactions, and vesicle stability were also investigated.

Results: The results proved the critical role of all formulation variables on ethosomal characteristics. The suggested models for all responses showed good predictability. Only the concentration of phospholipid, irrespective to PC type, had a significant effect on the transdermal flux (p?Conclusion: The study suggests the applicability of statistical modeling as a promising tool for prediction of ethosomal characteristics. The ethanolic vesicles were considered as novel potential nanocarriers for accentuated transdermal TRO delivery.     

Microneedle-assisted transdermal delivery of Zolmitriptan: effect of microneedle geometry,in vitro permeation experiments,scaling analyses and numerical simulations

Objective: The present study was aimed to investigate the effect of salient microneedle (MN) geometry parameters like length, density, shape and type on transdermal permeation enhancement of Zolmitriptan (ZMT).

Methods: Two types of MN devices viz. AdminPatch^® arrays (ADM) (0.6, 0.9, 1.2 and 1.5?mm lengths) and laboratory fabricated polymeric MNs (PM) of 0.6?mm length were employed. In the case of PMs, arrays were applied thrice at different places within a 1.77?cm² skin area (PM-3) to maintain the MN density closer to 0.6?mm ADM. Scaling analyses was done using dimensionless parameters like concentration of ZMT (C_t/C_s), thickness (h/L) and surface area of the skin (Sa/L²).

Results: Micro-injection molding technique was employed to fabricate PM. Histological studies revealed that the PM, owing to their geometry/design, formed wider and deeper microconduits when compared to ADM of similar length. Approximately 3.17- and 3.65-fold increase in ZMT flux values were observed with 1.5?mm ADM and PM-3 applications when compared to the passive studies. Good correlations were observed between different dimensionless parameters with scaling analyses. Numerical simulations, using MATLAB and COMSOL software, based on experimental data and histological images provided information regarding the ZMT skin distribution after MN application.

Discussion: Both from experimental studies and simulations, it was inferred that PM were more effective in enhancing the transdermal delivery of ZMT when compared to ADM.

Conclusions: The study suggests that MN application enhances the ZMT transdermal permeation and the geometrical parameters of MNs play an important role in the degree of such enhancement.     

Synthesis and transdermal permeation of novel N4-methoxypoly(ethylene glycol) carbamates of cytarabine

Background: Cytarabine is a deoxycytidine analogue commonly used in the treatment of hematological malignant diseases. Its clinical utility, however, is severely limited by its short plasma half-life because of the catabolic action of nucleoside deaminases. Method: In this study, N⁴-carbamate derivatives of cytarabine (1) were synthesized and evaluated for transdermal penetration because this mode of administration may circumvent its limitations. The synthesis of these compounds was achieved in a two-step process. First, the methoxypoly(ethylene glycol) was activated by p-nitrophenyl chloroformate. Second, the activated intermediates were reacted with cytarabine in the presence of N-hydroxysuccinamide to give the N⁴-methoxypoly(ethylene glycol) carbamate derivatives. The transdermal flux values of the N⁴-carbamates of cytarabine were determined in vitro by Franz diffusion cell methodology. Aqueous solubility and log D (pH 7.4) values were determined and assessed for correlation with transdermal flux values. Results: The synthesized carbamates, particularly, (9)–(13), showed increased solubility in both aqueous and lipid media. Log D values decreased as the oxyethylene chain lengthened. Conclusion: Although none of the derivatives showed significantly higher transdermal penetration than cytarabine (1), it should be mentioned that the mean for cytarabine N⁴-methoxyethyleneoxycarbamate (8) was 10 times higher and the median was 2 times higher.     

Effect of hydrophilic and hydrophobic polymers on permeation of S-amlodipine besylate through intercalated polymeric transdermal matrix: 3(2) designing,optimization and characterization

Objective: Innovation in material science has made it possible to fabricate a pharmaceutical material of modifiable characteristics and utility, in delivering therapeutics at a sustained/controlled rate. The objective of this study is to design and optimize the controlled release transdermal films of S-Amlodipine besylate by intercalating hydrophilic and hydrophobic polymers.

Methods: 3(2) factorial design and response surface methodology was utilized to prepare formulations by intercalating the varied concentration of polymers(A) and penetration enhancer(B) in solvent. The effect of these independent factors on drug release and flux was investigated to substantiate the ex-vivo, stability and histological findings of the study.

Results: FTIR, DSC revealed the compatibility of drug with polymers; however, the semicrystallinity in drug was observed under PXRD. SEM micrographs showed homogeneous dispersion and entanglement of drug throughout the matrix. Results from the permeation study suggested the significant effect of factors on the ex vivo permeation of drug. It was observed that drug release was found to be increased with an increase in hydrophilic polymer concentration and PE. The formulations having polymers (EC:PVPK-30) at 7:3 showed maximum drug release with highest flux (102.60?±?1.12?µg/cm²/h) and permeability coefficient (32.78?±?1.38?cm/h). Significant effect of PE on lipid and protein framework of the skin was also observed which is responsible for increased permeation. The optimized formulation was found to be stable and showed no-sign of localized reactions, indicating safety and compatibility with the skin.

Conclusion: Thus, results indicated that the prepared intercalated transdermal matrix can be a promising nonoral carrier to deliver effective amounts of drug.     

The effects of pressure-sensitive adhesives and solubilizers on the skin permeation of testosterone from a matrix-type transdermal delivery system

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

Evaluation of the transdermal permeation behavior of Proterguride from drug in adhesive matrix patches through hairless mouse skin

The transdermal in vitro permeation behavior of the highly potent dopamine agonist Proterguride was investigated using hairless mouse skin as a model membrane. Drug in adhesive matrix formulations based on different types of pressure-sensitive adhesives (Eudragit® E 100 and Gelva®7883 as acrylates, Oppanol® B 15 SFN as polyisobutylene, and BioPSA® 7-4202 as silicone) with a drug load of 3% by weight were manufactured. All patches were examined for drug crystallization by polarized microscopy immediately after the manufacturing process and after storage for 30 days in sealed aluminium laminate bags at ambient temperature and at 40°C, respectively. Furthermore, the influence of the drug load in acrylate-based formulations onto the steady-state flux of Proterguride was examined. The Eudragit® E 100 system delivered a significantly higher steady-state flux than the systems based on Oppanol® B 15 SFN and also a somewhat higher steady-state flux than the Gelva®-based patch. An addition of 10% by weight of the crystallization inhibitor povidone 25 did not significantly influence the steady-state flux of Proterguride from acrylate matrices. The lipophilic silicone and polyisobutylene adhesives facilitated drug crystallization within the short storage periods at both conditions, probably due to the absence of povidone 25, which was incompatible with these polymers. Varying the drug load in acrylate-based formulations led to a linear increase of the steady-state flux until the steady-state flux of Proterguride leveled off and the patches tended to drug crystallization. It was found that Gelva®-based patches show good physical stability, good skin adhesion, and moderate flux values and, thus, can be evaluated as a basis for a suitable formulation for the transdermal administration of Proterguride.     

Transdermal delivery of tadalafil. I. Effect of vehicles on skin permeation

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

The effect of skin penetration enhancers on the transdermal delivery of pyridostigmine bromide

Abstract

In vitro skin penetration studies of pyridostigmine bromide through human cadaver skin were conducted using a diffusion cell with constant hydrodynamic conditions. The results indicate that the drug penetrates poorly through human cadaver skin. However, skin penetration enhancers such as sodium oleate, sodium lauryl sulfate, n-decyl methyl sulfoxide, and N,N-dimethyldodecylamine-N-oxide substantially enhanced the permeability coefficient of the drug through human cadaver skin. The penetration enhancement of pyridostigmine bromide could be due to increased partitioning of the drug in the skin or due to the decreased tortuosity of the porous pathway in the stratum corneum.     

The effect of skin penetration enhancers on the transdermal delivery of pyridostigmine bromide

In vitro skin penetration studies of pyridostigmine bromide through human cadaver skin were conducted using a diffusion cell with constant hydrodynamic conditions. The results indicate that the drug penetrates poorly through human cadaver skin. However, skin penetration enhancers such as sodium oleate, sodium lauryl sulfate, n-decyl methyl sulfoxide, and N,N-dimethyldodecylamine-N-oxide substantially enhanced the permeability coefficient of the drug through human cadaver skin. The penetration enhancement of pyridostigmine bromide could be due to increased partitioning of the drug in the skin or due to the decreased tortuosity of the porous pathway in the stratum corneum.     

The skin permeation mechanism of ketotifen: evaluation of permeation pathways and barrier components in the stratum corneum

To evaluate the pathways and barrier components in the stratum corneum (SC) for the permeation of ketotifen, the effect of delipidization on the permeation and partition was examined under several donor pHs. Assuming that ionized ketotifen (KTH+) and un-ionized ketotifen (KT) contribute independently in both permeation and partition, the intrinsic permeability coefficients and SC/water partition coefficients of both species were estimated. Delipidization enlarged the permeability of KTH+ 100 times. This suggested that the lipid phase functions as the barrier against KTH+. KT has an intrinsic permeability 100 times larger than that of KTH+. Delipidization did not result in a significant change in permeability of KT. This suggested that the permeability of KT through the lipid phase is comparable to that through the aqueous phase in delipidized SC; that is, the lipid phase functions as a highly permeable pathway for KT. On the other hand, the permeability coefficient of KTthrough delipidized SC was 1/34 of that through the pure aqueous layer, which had a thickness equivalent to SC. Since this suggests that the permeability of KT through the proteinaceous phase is much lower than that through the aqueous phase, the proteinaceous phase can be assumed to function as a barrier against the permeation of KT. From these results, it is concluded that the predominant permeation pathway for KT is through the lipid phase. The SC/water partition coefficient of KT was cut in half by delipidization, but the value was still more than 100. These results show that the proteinaceous phase functions not only as the barrier, but also as the depot for KT. The knowledge obtained here will be useful for formulation design and for the selection of enhancers in a transdermal therapeutic system of ketotifen.     

Photophysical studies and in vitro skin permeation/retention of Foscan/nanoemulsion (NE) applicable to photodynamic therapy skin cancer treatment

In this work we evaluated the photophysical and in vitro properties of Foscan, a second-generation photosensitizer drug (PS) widely used in systemic clinical protocols for cancer therapy based on Photodynamic Therapy (PDT). We employed biodegradable nanoemulsions (NE) as a colloidal vehicle of the oil/water (o/w) type focusing in topical administration of Foscan and other photosensitizer drugs. This formulation was obtained and stabilized by the methodology described by Tabosa do Egito et al., based on the mixture of two phases: an aqueous solution and an organic medium consisting of nonionic surfactants and oil. The photodynamic potential of the drug incorporated into the NE was studied by steady-state and time-resolved spectroscopic techniques. We also analyzed the in vitro biological behavior carried out in mimetic biological environment protocols based on the animal model. After topical application in a skin animal model, we evaluated the Foscan/NE diffusion flux into the skin layers (stratum corneum and epidermis + dermis) by classical procedures using Franz Diffusion cells. Our results showed that the photophysical properties of PS were maintained after its incorporation into the NE when compared with homogeneous organic medium. The in vitro assays enabled the determination of an adequate profile for the interaction of this system in the different skin layers, with an ideal time lag of 6 h after topical administration in the skin model. The Foscan diffusion flux (J) was increased when this PS was incorporated into the NE, if compared with its flux in physiological medium. These parameters demonstrated that the NE can be potentially applied as a drug delivery system (DDS) for Foscan in both in vitro and in vivo assays, as well as in future clinical applications involving topical skin cancer PDT.     

In vivo skin permeation of sodium naproxen formulated in pluronic F-127 gels: effect of Azone and Transcutol

The objective of this study was to determine the penetration of sodium naproxen, formulated in Pluronic F-127 (PF-127) gels containing Azone and Transcutol as penetration enhancers, through human skin in vivo. It was found that the combination of Azone and Transcutol in PF-127 gels enhanced sodium naproxen penetration, with enhancement ratios of up to two fold compared with the formulation containing only Transcutol. These results were confirmed by TEWL and ATR-FTIR spectroscopy, suggesting a synergic action for Azone and Transcutol. Because of the thermo-reversible behavior of Pluronic gels, the influence of the components added to the gel formulations on viscosity, as a function of temperature, was also studied.     

Design of antihistaminic transdermal films based on alginate–chitosan polyelectrolyte complexes: characterization and permeation studies

The purpose of this study was to develop suitable matrix-type transdermal drug delivery systems of Ketotifen fumarate (KF) as antiasthmatic drugs. Chitosan–alginate polyelectrolyte complex (PEC) films were used as drug release regulators for KF. Antihistaminic films with variable PEC compositions were prepared using different ratios of chitosan (CTS) to sodium alginate (ALG). Propylene glycol (PG) was used as plasticizer; Tween 80 (T₈₀) and Span 20 (S₂₀) were used as permeability enhancers. Nine formulations were obtained by film casting method and characterized in terms of weight uniformity, thickness, folding endurance, moisture lost, and moisture absorption. In addition, drug release and permeation through rat abdominal skin mounted in Franz cell were investigated. All formulations were found to be suitable in terms of physicochemical characteristics, and there was no significant interaction between the used drug and polymers. It was noticed that when T₂₀ is used as permeation enhancer, a satisfactory drug release pattern was found where 99.88% of drug was released and an amount of 2.121?mg/cm² of KF was permeated after 24?h. For the optimal formulation, a permeability coefficient of 14.00?±?0.001?cm h^?1 and a latency time of 0.35?±?0.02?h were found. The in-vitro analysis showed controlled release profile which was fitted by Korsmeyer–Peppas model (R²?=?0.998). The obtained results suggested that new controlled release transdermal formulations of asthmatic drugs could be suitably designed as an alternative to the common forms.     

Enhancement effect of p-menthane-3,8-diol on in vitro permeation of antipyrine and indomethacin through Yucatan micropig skin

The enhancing effect of p-menthane-3,8-diol (MDO) on skin permeation of antipyrine (ANP) and indomethacin (IM) through Yucatan micropig skin in vitro was compared with l-menthol. p-menthane-3,8-diol is a metabolite of l-menthol and has little odor. It is easy to combine the vehicle because of lower lipophilicity than l-menthol. All formulations contained 40% (v/v) ethanol. The permeation of ANP increased with MDO about three times that without enhancer by increasing ANP concentration in the skin. However, the MDO effect was about a quarter that of l-menthol. The permeation of IM with MDO was about 15 times that with no enhancer and it was almost the same as that with l-menthol. The lag time of permeation was not significantly changed by MDO, which was not so in the case of l-menthol. Skin concentration of IM increased about 11 times and six times with MDO and l-menthol, respectively. MDO and l-menthol partitioned to the skin relatively high concentrations, 5.9 and 2.5 mg/cm³, respectively. The solubility of IM in the skin was improved by MDO, and consequently, the permeation of IM was enhanced.     

Evaluation of the physicochemical stability and skin permeation of glucosamine sulfate

Glucosamine sulfate (GS) is known to stop the degenerative process of osteoarthritis. Because most of the GS formulation on the market is in the oral form, an alternative formulation such as a transdermal delivery system (TDS) is necessary in order to increase patient compliance. As the initial step to develop a TDS of GS, the physicochemical stability and permeation study in rat skin were examined. Evaluation of the stability of GS at different pHs showed the compound to be most stable at pH 5.0. The degradation rate constant at 25°C was estimated to be 5.93 ×10^- 6 hr^- 1 (t₉₀~ 2.03 years) in a pH 5 buffer solution. Due to its hydrophilic characteristic, low skin permeability was expected of GS. However, the skin permeation rate was determined to be 13.27 µg/cm²/hr at 5% concentration. Results of this study suggest the possibility of developing GS into a transdermal delivery system.