Magnetophoresis in combination with chemical enhancers for transdermal drug delivery

Purpose: The objective of the present work was to investigate the effect of combination of a novel physical permeation enhancement technique, magnetophoresis with chemical permeation enhancers on the transdermal delivery of drugs.

Methods: The in vitro drug transport studies were carried out across the freshly excised abdominal skin of Sprague-Dawley rats using transdermal patch systems (magnetophoretic and non-magnetophoretic) of lidocaine hydrochloride (LH). LH gel prepared using hydroxypropyl methylcellulose (HPMC) was spread over the magnets as a thin layer. To investigate the effect of chemical permeation enhancers, menthol, dimethyl sulfoxide, sodium lauryl sulfate and urea (5% w/v) were incorporated in the gels prior to loading on the patch system.

Results: The flux of lidocaine from magnetophoretic patch was ~3-fold higher (3.07?±?0.43 µg/cm²/h) than that of the control (non-magnetophoretic patch) (0.94?±?0.13 µg/cm²/h). Incorporation of chemical permeation enhancers in the gel enhanced the magnetophoretic delivery flux by ~4 to 7-fold.

Conclusions: The enhancement factor due to combination of chemical permeation enhancer was additive and not synergistic. Mechanistic studies indicated that magnetophoresis mediated drug delivery enhancement was via appendageal pathway.     

Formulation study of a patch containing propranolol by design of experiments

Objective: To evaluate the feasibility of a transdermal patch containing propranolol (PR).

Method: Skin penetration enhancers (SPEs) able to improve the skin permeability of PR were selected and a quality by design approach was applied to the development of the patch by a 2⁴ full factorial design. The permeation profile of PR from the formulations was assessed in in vitro permeation studies performed by using Franz diffusion cells and human epidermis as membrane. Finally, skin irritation was evaluated by the Draize test.

Results: N-methyl pyrrolidone (NMP) resulted as the best SPE: in addition, the critical factors influencing the PR diffusion through the human epidermis when loaded in the patch resulted in the matrix thickness (X₁, p?=?0.0957) and PR content (X₃, p?=?0.0004) which improved the flux; conversely, NMP lacked its enhancement effect when loaded in the patch and the increase in its concentration (X₄, p?=?0.006) affected the drug permeation through human epidermis. The flux of optimal formulation was 12.7?μg/cm²/h. On the basis of the steady-state concentration and clearance of PR, the estimated patch surface was 100–120 cm², since the activity of PR is related to its Senantiomer and no in vivo bioconversion occurs.

Conclusion: A patch containing (S)-PR was prepared and the (S)-PR flux (13.3?μg/cm²/h) permitted to confirm the suitability of a transdermal administration of PR. In particular, the use of a 50?μm thick methacrylic matrix containing 8% (S)-PR and 15% NMP can allow to develop a patch non-irritating to the skin, in order to ensure a constant permeation flux of PR over 48?h.     

Formulation and rheological evaluation of ethosome-loaded carbopol hydrogel for transdermal application

Objective: To select a suitable ethosome-loaded Carbopol hydrogel formulation, specifically tailored for transdermal application that exhibits (i) plastic flow with yield stress of approximately 50–80?Pa at low polymer concentration, (ii) relatively frequency independent elastic (G′) and viscous (G″) properties and (iii) thermal stability.

Methods: Carbopol (C71, C934, C941, C971 or C974) hydrogels were prepared by dispersing Carbopol in distilled water followed neutralization by sodium hydroxide. The effects of Carbopol grade, Carbopol concentration, ethosome addition and temperature on flow (yield stress and viscosity) and viscoelastic (G′ and G″) properties of Carbopol hydrogel were evaluated. Based on the aforementioned rheological properties evaluated, suitable ethosome-loaded Carbopol hydrogel was selected. In-vitro permeation studies of diclofenac using rat skin were further conducted on ethosome-loaded Carbopol hydrogel along with diclofenac-loaded ethosomal formulation as control.

Results: Based on preliminary screening, C934, C971 and C974 grades were selected and further evaluated for flow and viscoelastic properties. It was observed that ethosome-loaded C974 hydrogel at concentration of 0.50 and 0.75% w/w, respectively, demonstrated acceptable plastic flow with distinct yield stress and a frequency independent G′ and G″. Furthermore, the flow and viscoelastic properties were maintained at the 4, 25 and 32?°C. The results from in vitro skin permeation studies indicate that ethosome-loaded C974 hydrogel at 0.5% w/w polymer concentration exhibited similar skin permeation as that of ethosomal formulation.

Conclusion: The results indicate that suitable rheological properties of C974 could facilitate in achieving desired skin permeation of diclofenac while acting as an efficient carrier system for ethosomal vesicles.     

Formulation and delivery strategies of ibuprofen: challenges and opportunities

Ibuprofen, a non-steroidal anti-inflammatory drug (NSAID), is mostly administered orally and topically to relieve acute pain and fever. Due to its mode of action this drug may be useful in the treatment regimens of other, more chronic conditions, like cystic fibrosis. This drug is poorly soluble in aqueous media and thus the rate of dissolution from the currently available solid dosage forms is limited. This leads to poor bioavailability at high doses after oral administration, thereby increasing the risk of unwanted adverse effects. The poor solubility is a problem for developing injectable solution dosage forms. Because of its poor skin permeability, it is difficult to obtain an effective therapeutic concentration from topical preparations. This review aims to give a brief insight into the status of ibuprofen dosage forms and their limitations, particle/crystallization technologies for improving formulation strategies as well as suggesting its incorporation into the pulmonary drug delivery systems for achieving better therapeutic action at low dose.     

Physicochemical studies of binary eutectic of ibuprofen and ketoprofen for enhanced transdermal drug delivery

Methods: The thermodynamic, eutectic, and crystalline properties of ibuprofen and ketoprofen binary mixtures were investigated using differential scanning calorimetry (DSC) and X-ray powder diffractometry (XRPD). Results: The DSC studies showed that melting point (61°C), enthalpy (11.3 kJ/mol), and entropy of fusion (33.7 J/K/mol) of the binary eutectic were significantly lower than those of the individual anti-inflammatory drugs (NSAIDs). Due to the melting-point depression and enhanced skin lipid solubility, the steady-state flux of ibuprofen and ketoprofen from preparations of the binary eutectic increased as compared to pure NSAIDs using shed snakeskin as a model membrane. The NSAID membrane flux values were calculated by flux ratio equations based on drug thermodynamic data, and compared to experimental values obtained from permeation studies. Conclusion: The proposed flux ratio equations correctly predicted flux increase.     

Formulation and characterization of a captopril ethyl ester drug-in-adhesive-type patch for percutaneous absorption

Background: The ethyl ester of captopril has been shown to exhibit enhanced permeation across human skin compared to the parent drug. A drug-in-adhesive patch formulation of a captopril ethyl ester was therefore developed for optimum drug release. Method: A wide range of transdermal patches were prepared using two commercially available bioadhesive polymers. Investigational screening was conducted on the patches using microscopy, texture profile analysis, and infrared spectroscopy. Drug release profiles of suitable patches were obtained using both polydimethylsiloxane (Silastic?) and porcine skin in vitro. Results: Diffusion results across Silastic? showed a gradual plateau in flux with increased drug loading that may be attributable to intramolecular interactions while flux across porcine skin was seen to increase with increasing patch thickness and attained a therapeutic level. Conclusions: This study demonstrated that adhesion and drug loading are significant factors in optimizing a topical patch formulation for the delivery of a captopril prodrug.     

Proniosomal gel-mediated transdermal delivery of bromocriptine: in vitro and ex vivo evaluation

Vesicular systems endow large opportunities for the transdermal delivery of therapeutics. The present study was designed to investigate the potential of a novel class of vesicular system ‘proniosome’ as a carrier for transdermal delivery of bromocriptine (BCT). Proniosome formulations were prepared by the coacervation-phase separation method and the influence of factors like surfactant type and its amount, lipid concentration, cholesterol amount and drug content were studied. Span 60 was the most appropriate surfactant, and yielded vesicle size and percentage encapsulation efficiency of 1.3 µm and 98.9%, respectively. The developed system was characterised w.r.t. morphology, transition temperature, drug release, skin permeation and skin irritancy. Proniosomes exhibited a sustained release pattern of BCT in vitro. Skin permeation study revealed high penetration of proniosomes with sustained release of BCT through rat skin. The optimised proniosomal formulation showed enhanced transdermal flux of 16.15 μg/cm²/h as compared to 3.67 μg/cm²/h for drug dispersion. The developed formulations were observed as non-irritant to the rat skin and were found as quite stable at 4 and 25 °C for 90 days w.r.t. vesicle size and drug content. The dried proniosomal formulation could act as a promising alternative to niosomes and preferably for transdermal delivery of BCT.     

Influence of drug physicochemical characteristics on in vitro transdermal absorption of hydrophobic drug nanosuspensions

Abstract

The purpose of this paper was to study the influence of drug physicochemical characteristics on in vitro transdermal absorption of hydrophobic drug nanosuspensions. Four drug nanosuspensions were produced by high-pressure homogenization technique, which were the same in stabilizer and similar in particle size. Differential scanning calorimetry and powder X-ray diffraction analysis showed that the crystalline state of the nanocrystals did not change. In vitro permeation study demonstrated that the drug nanosuspensions have a higher rate of permeation that ranged from 1.69- to 3.74-fold compared to drug microsuspensions. Correlation analysis between drug physicochemical properties and J_ss revealed that log P and pKa were factors that influenced the in vitro transdermal absorption of hydrophobic drug nanosuspensions, and drugs with a log P value around 3 and a higher pKa value (when pKa?<?pH+2) would gain higher J_ss in this paper.     

Development of matrix patches for transdermal delivery of a highly lipophilic antiestrogen

The aim of this study was to develop matrix-type transdermal systems (TDSs) containing the highly lipophilic (log P = 5.82) antiestrogen (AE) and the permeation enhancers propylene glycol and lauric acid. For that purpose, permeation of AE from various adhesive matrices through excised skin of hairless mice was evaluated. It was found that pretreatment of the skin with permeation enhancers raised the transdermal flux of subsequently applied antiestrogen. Highest steady-state transdermal fluxes (1.1 µg cm^-2 h^-1) were obtained from Gelva®, polyacrylate adhesive, followed by 0.55 µg cm^-2 h^-1 from Oppanol® polyisobutylene, 0.31 µg cm^-2 h^-1 from BIO-PSA® silicone, and 0.12 µg cm^-2 h^-1 from Sekisui polyacrylate matrices. In order to develop TDS with high content of fluid permeation enhancer propylene glycol, two different strategies were investigated. One strategy was the addition of hydroxypropyl cellulose (HPC) as thickening agent to Gelva matrices. This allowed for propylene glycol loading levels of up to 30%, resulting in transdermal AE fluxes of 0.09 µg cm^-2 h^-1. On the other hand, a fleece-laminated backing foil was loaded with the described permeation enhancer formulation and laminated with polyacrylate adhesive layer, resulting in transdermal AE fluxes of 0.06 µg cm^-2 h^-1. However, application of these TDSs on skin pretreated with permeation enhancers raised the fluxes to 2.6 µg cm^-2 h^-1 from Gelva/HPC and 0.46 µg cm^-2 h^-1 from fleece/Sekisui.     

Development and optimization of self-nanoemulsifying drug delivery systems (SNEDDS) for curcumin transdermal delivery: an anti-inflammatory exposure

The purpose of this work is to develop novel lipid-based self-nanoemulsifying drug delivery systems (SNEDDS) as carriers for transdermal delivery of curcumin. SNEDDS containing black seed oil, medium chain mono- and diglycerides and surfactants, were prepared as curcumin delivery vehicles. Their formation spontaneity, morphology, droplet size, and drug loading were evaluated. Gel preparation containing two of the SNEDDS formulations were used in the carrageenan induced paw edema to evaluate the anti-inflammatory effect. Results showed droplet size as low as 71?nm. The highest drug loading was observed with SNEDDS-F6 of ～45?mg/g. In in-vivo investigation, SNEDDS-F6 exhibited significant anti-inflammatory activities in terms of 80% reduction in paw edema when compared with positive control. The prepared SNEDDS with the elevated entrapment efficiency, good transdermal penetration ability could be a suitable candidate for effective transdermal curcumin skin delivery.     

Studies on in vitro and in vivo transdermal flux enhancement of methotrexate by a combinational approach in comparison to oral delivery

Background: Methotrexate (MTX) causes systemic toxicity thereby limiting its use; hence, transdermal delivery would be a possible alternative. Method: A comparative in vitro/in vivo study was done to see the effect of the two-tier system of chemical and physical enhancers. MTX was loaded into polyacrylamide-based hydrogel patch to see the effect of enhancers. Result: Flux enhancement (161%) of MTX was achieved when ternary mixture of ethyl acetate:menthol:ethanol (1:1:1) was used in combination with square-wave iontophoresis for 1hour. Lower flux enhancement of 71%, 83%, and 93.5% was obtained in vitro with neat ethyl acetate, its binary composition with ethanol, and its ternary composition with ethanol and menthol, respectively, as compared to passive. However, with square-wave iontophoresis, it increased to 126%, 140%, and 161%, respectively. The mechanism of flux enhancement was supported by biophysical tools such as attenuated total reflectance–Fourier transform infrared spectroscopy (ATR–FTIR), scanning electron microscopy (SEM), and histopathology. ATR–FTIR studies demonstrated split in the asymmetric C–H vibration and amide II band with terpenes and iontophoresis, respectively. Additionally binary and ternary mixture of ethyl acetate demonstrated absence of ester peak accounting for lipid extraction. SEM of the skin samples treated with chemical enhancers in combination with square-wave iontophoresis showed both swelling and increased pore size of hair follicles, thus supporting higher permeation. Histopathological studies on treated skin samples of albino mice demonstrated epidermal thinning and focal disruptions, spongiosis, dermal edema, and appendageal dilatations. In vivo studies on mice demonstrated plasma concentration of 18.79μg/mL with ternary mixture of ethyl acetate in combination with square wave, which is twofold higher to oral delivery. The reversibility studies conducted in vivo on mice demonstrated that the histological changes induced by the above-mentioned enhancers were transient and reversible in 48 hours. Conclusion: The above results indicate that the above-mentioned enhancers are safe and well tolerated by the skin.     

Investigation on the synergistic effect of a combination of chemical enhancers and modulated iontophoresis for transdermal delivery of insulin

Purpose: The main objective of this study was to assess the flux enhancement of insulin transdermally by utilizing a complex of chemical enhancers in combination with modulated iontophoresis. Methods: The experiments were performed on porcine epidermis model under three different circumstances, namely, (a) 1-hour modulated iontophoresis alone; (b) pretreatment with vehicle and chemical enhancer combinations and (c) combination of (a) and (b). The mechanism of action of the enhancers was studied using infra-red spectra by derivative and curve-fitting techniques and Confocal laser scanning microscopy. The efficacy of the optimized combination was tested in vivo in streptozocin-diabetic Wistar rats. Results: A blend of 1,8 cineole, oleic acid and sodium deoxycholate in propylene glycol : ethanol (7:3) resulted in 45% enhancement, when permeation was performed in combination with iontophoresis as compared to the latter alone. In-depth analysis of infra-red spectra revealed that each of the enhancers acted differentially on lipid-protein domains of the stratum corneum thereby supporting the observed synergism. Movement of fluorescently labeled insulin depicted highlighted follicular regions and paracellular accumulation of the probe after iontophoresis and chemical enhancer treatment respectively. Presence of the fluorescent peptide in these regions 4 hour after treatment with the combination reinforced the results of the permeation studies. Finally the combination of modulated iontophoresis with chemical enhancer blend resulted in lowering of blood glucose for 8 hour in vivo. Conclusions: The study proved the applicability of modulated iontophoresis with chemical pretreatment in delivering insulin transdermally.     

Crystallization kinetics in as-synthesis high yield of a-Se100−xTex nanorods

The paper reports the synthesis of high yield of a-Se_100−xTe_x (x = 3, 6, 9 and 12) nanorods using one of the simplest approaches i.e. melt quenching technique. The morphology and microstructure of as-prepared alloys is studied using scanning Electron Microscopy (SEM) and transmission electron microscopy (TEM). From SEM investigation, it is observed that these powder samples of a-Se_xTe_100−x contain high yield of nanorods and their diameter is of the order of several hundred nanometers. The XRD patterns of these samples suggest that these nanorods are amorphous in nature. Crystallization kinetics in these nanorods of amorphous Se_xTe_100−x glasses are studied at different heating rates (5, 10, 15 and 20 K min⁻¹) under non-isothermal condition using differential scanning calorimetry. It is observed that the value of glass transition temperature and crystallization temperature varies with the composition and heating rate. From the heating rate dependence of glass transition temperature and crystallization temperature, the activation energy for structural relaxation (ΔE_t), the activation energy of crystallization (ΔE_c) and the order parameter (n) have been calculated. The composition dependence of the activation energy for thermal relaxation and activation energy for crystallization is discussed in terms of the structure of Se–Te glassy system.     

The effect of clove oil on the transdermal delivery of ibuprofen in the rabbit by in vitro and in vivo methods

The study was designed to evaluate skin permeation enhancement effect of essential oils from Eugenia caryophyllata (clove oil) in rabbits and to compare the in vitro absorption and in vivo permeation using ibuprofen as a model drug. The in vitro results indicated a significant permeation enhancement effect of the clove oil. The group with 1% oil appeared to the flux (239 μg/cm²/hr), and 3% oil was 293 μg/cm²/hr to some extent similar with 2% azone group (327 μg/cm²/hr). The enhancement ratio of clove oil was 7.3. In vivo results also demonstrated that clove oil showed a significant permeation enhancement effect, but the enhancement of clove oil was relatively weak than in vitro. The group with 3% oil exhibited the higher value of area under the curve (AUC) of 80.8 μg/mL·hr, which was 2.4 times the high of control. The AUC value of 3% oil group was similar to that of 2% azone group (89.8 μg/mL·hr). The GC-MS results indicated eugenol and acetyleugenol identified from clove oil might mainly contribute to enhance in vitro and in vivo absorption of ibuprofen because of its large quantities (90.93%).     

Damar Batu as a novel matrix former for the transdermal drug delivery: in vitro evaluation

Purpose: Damar Batu (DB) is a novel film-forming biomaterial obtained from Shorea species, evaluated in this study for its potential application in transdermal drug delivery system. Methods: DB was characterized initially in terms of acid value, softening point, molecular weight (M_w), polydispersity index (M_w/M_n), and glass transition temperature (T_g). Neat, plasticized films of DB were investigated for mechanical properties. The biomaterial was further investigated as a matrix-forming agent for transdermal drug delivery system. Developed matrix-type transdermal patches were evaluated for thickness and weight uniformity, folding endurance, drug content, in vitro drug release study, and skin permeation study. Results: On the basis of in vitro drug release and in vitro skin permeation performance, formulation containing DB/Eudragit RL100 (60 : 40) was found to be better than other formulations and was selected as the optimized formulation. IR analysis of physical mixture of drug and polymer and thin layer chromatography study exhibited compatibility between drug and polymer. Conclusion: From the outcome of this study, it can be concluded that applying suitable adhesive layer and backing membrane-developed DB/ERL100, transdermal patches can be of potential therapeutic use.     

葡甘聚糖-壳聚糖-聚乙烯醇复合胶黏剂的流变特性

为开发环境友好型木材胶黏剂, 利用差示扫描量热法(DSC)和流变仪分析了葡甘聚糖、 壳聚糖、 聚乙烯醇共混胶黏剂的热固化过程和流变特性。结果表明: 三元共混胶黏剂的流变特性呈明显的非线性, 黏度与剪切速率的关系可用Cross模型拟合, 黏度与温度的关系可用Arrhenius方程拟合, 前置因子K为1.25×10-6Pa·s, 流动活化能为54.24kJ/mol, 频率曲线可用四阶多项式拟合, 同时可得到胶黏剂的平均分子量随温度升高逐渐降低, 分子量分布随着温度升高逐渐增大。温度和时间扫描得到凝胶化温度110.4℃, 凝胶时间20.1min, 玻璃化转变温度87.4℃, 加热温度130℃。      

Experimental protocol to determine the ability of PET to crystallise

PET [poly(ethylene terephtalate)] is a semi-crystalline thermoplastic that is very suitable for forming processes and is widely used in various technologies. For specific applications, it is necessary to avoid the crystallization of the material by quenching from the melting state while for other applications this crystallization is required. It follows that the ability of PET to crystallize could be a crucial industrial problem, particularly because of the large range of PET proposed by plastic suppliers. This work deals with a calorimetric method able to discriminate this aptitude between various PET rapidly and to give a criterion of crystallizability.     

Liquid anti-solvent recrystallization to enhance dissolution of CRS 74, a new antiretroviral drug

This study concerns a new compound named CRS 74 which has the property of inhibiting Human Immunodeficiency Virus (HIV) protease, an essential enzyme involved in HIV replication process. It is proved in this study that the original CRS 74 exhibits poor aqueous solubility and a very low dissolution rate, which can influence its bioavailability and clinical response. In an attempt to improve the dissolution rate, CRS 74 was recrystallized by liquid anti-solvent (LAS) crystallization. Ethanol was chosen as solvent and water as the anti-solvent. Recrystallized solids were compared with the original drug crystals in terms of physical and dissolution properties. Recrystallization without additives did not modify the CRS 74 dissolution profile compared to the original drug. CRS 74 was then recrystallized using different additives to optimize the process and formulate physicochemical properties. Steric stabilizer in organic phase ensured size-controlling effect, whereas electrostatic stabilizer in aqueous phase decreased particle agglomeration. Cationic additives avoided drug adsorption onto stainless steel T-mixer. In general, additive improved drug dissolution rate due to improvement of wetting properties by specific interactions between the drug and the additives, and ensured continuous production of CRS 74 by electrostatic repulsion.     

Formulation optimization of unreinforced and lignin nanoparticle-reinforced phenolic foams using an analysis of variance approach

Formulations of unreinforced and lignin nanoparticle-reinforced phenolic foams were optimized using an analysis of variance approach. The variables studied in the formulation of phenolic foams were stirring speed (650–850 rpm) and blowing agent amount (1.5–3.5 wt.%). For lignin nanoparticle-reinforced phenolic foams, the variables were lignin nanoparticle weight fraction (1.5–8.5 wt.%) and blowing agent amount (1.5–3.5 wt.%). The responses measured for both foams were density, compressive modulus, and compressive strength. In addition, the morphology of the foams was observed using scanning electron microscopy (SEM) to determine cell size distributions. The results showed that the variables studied exhibited a strong influence on the responses and the cell size distribution of the foams. Statistical models allowed for prediction of the properties of the foams and for comparison of the properties of unreinforced and lignin nanoparticle-reinforced phenolic foams. The incorporation of lignin nanoparticles in phenolic foams results in a compressive modulus and compressive strength that has up to 128% and 174%, respectively, of the values for unreinforced foams. The amount of blowing agent saved to produce a reinforced foam was up to 31% of the amount necessary to produce an unreinforced foam of the same density.     

A rapid technique to evaluate the oxidative stability of a model drug

The objective of the current study was to investigate the oxidative induction time (OIT) as a measurement of the stability of an oxygen-sensitive model drug. The OIT was determined by differential scanning calorimetry and represents the time required for oxidative decomposition to occur at a given temperature. Samples were heated to a specific temperature under a nitrogen blanket then held isothermal while exposed to oxygen. The experiment proceeded until oxidative degradation of the sample was apparent from the real-time heat flow graphs. Variables investigated in this study included different lots and suppliers of a model drug as well as the addition of antioxidants. Results demonstrated that the stability of the drug was dependent on the supplier. All antioxidants investigated in this study improved oxygen stability of the model compound, as evidenced by a longer OIT. Butylated hydroxyanisole (BHA) was found to better stabilize the drug than butylated hydroxytoluene at equivalent concentrations. The combination of ascorbic acid and BHA provided the greatest protection against oxidation of the model compound. The results of this study demonstrate the usefulness of OIT to investigate the oxygen stability of pharmaceutical compounds.