Preparation of curcuminoid niosomes for enhancement of skin permeation

Curcuminoids (curcumin, desmethoxycurcumin, and bisdesmethoxycurcumin) are major bioactive substances found in turmeric (Curcuma longa L.) extracts and possess antioxidant, anti-inflammatory, antimicrobial and anticancer properties. In this study, curcuminoid niosomes prepared with a series of Span non-ionic surfactants were developed to enhance the skin permeation of curcuminoids. Formulations were evaluated based on aggregation of niosomes, curcuminoid loading, % entrapment efficiency and in vitro permeation of curcuminoids through shed snake skin. Optimal formulations of curcuminoid niosomes including sorbitan monooleate, cholesterol, and Solulan C-24 at a mole ratio of 47.5:47.5:5 were obtained. Up to 11 micromoles of curcuminoids could be loaded in the niosome with a % entrapment efficiency of 83%. About 90% of the niosomes had a diameter of 12.25 +/- 5.00 microm. The niosomes significantly enhanced permeation of curcuminoids compared with a methanolic solution of curcuminoids: 4% of entrapped curcuminoids traversed the shed snake skin, whereas permeation from the methanolic solution was undetectable. The fluxes of curcumin, desmethoxycurcumin, and bisdesmethoxycurcumin were 1.117, 0.263, and 0.057 microg/(cm2h), respectively, consistent with the relative hydrophobicity of curcumin > desmethoxycurcumin > bisdesmethoxycurcumin. In conclusion, our data show that curcuminoids can be successfully formulated as niosomes and that such formulations have improved properties for transdermal delivery.     

Effect of positively and negatively charged liposomes on skin permeation of drugs

To clarify the effect of the surface charge of liposomes on percutaneous absorption, the permeation of liposomal drugs through rat skin was investigated in vitro and in vivo. Liposomes were prepared using egg yolk lecithin (EPC, phase transition temperature, -15 to -17 degrees C), cholesterol and dicetylphosphate (DP) or stearylamine (SA) (10:1:1, mol/mol). Also examined was the penetration behavior of positively and negatively charged liposomes, using a fluorescent probe (Nile Red). The in vitro penetration rate of melatonin (MT) entrapped in negatively charged liposomes was higher than that of positively charged ones (p<0.05). When the percutaneous absorption of ethosuximide (ES) encapsulated was estimated in vivo, the absorption of ES from negatively charged liposomes was slightly higher than that from positively charged liposomes. Additionally, the absorption of ES from both types of liposomes was superior to that from the lipid mixtures consisting of the same composition as the vesicles. The percutaneous absorption of betahistine (BH) from a gel formulation containing negatively charged liposomes of BH was much more than that from the formulation with positively charged ones, with 2-fold higher AUC (p<0.05). Histological studies revealed that the negatively charged liposomes diffused to the dermis and the lower portion of hair follicles through the stratum corneum and the follicles much faster than the positive vesicles at the initial time stage after application. Thus, the rapid penetration of negatively charged liposomes would contribute to the increased permeation of drugs through the skin.     

Physicochemical properties and skin permeation of Span 60/Tween 60 niosomes of ellagic acid

Ellagic acid (EA) is a potent antioxidant phytochemical substance which has limitation to use due to its poor biopharmaceutical properties, low solubility and low permeability. The aim of the present study was to develop niosomal formulations obtained from the mixture of Span 60 and Tween 60 that could encapsulate EA for dermal delivery. The EA-loaded niosomes were prepared with 1:0, 2:1, 1:1, 0:1 Span 60 and Tween 60, using polyethylene glycol 400 (PEG 400), propylene glycol (PG) or methanol (MeOH) as a solubilizer. The influence of formulations on vesicle size, entrapment efficiency and stability of EA-loaded niosomes was investigated. It was found that all ratios of surfactants could produce EA-loaded niosomes when using 15% (v/v) PG, 15% (v/v) PEG 400 or 20% (v/v) MeOH. The niosomes were spherical multilamellar vesicles showing the localization of EA in the vesicles. The vesicle sizes of the niosomes after extrusion were 124-752 nm with PI less than 0.4. The percentages of entrapment efficiency (% E.E.) of all EA-loaded niosomes varied between 1.35% and 26.75% while PEG 400 niosomes gave the highest % E.E. The most stable and highest entrapped formulation was 2:1 Span 60 and Tween 60 niosomes. Additionally, the in vitro skin permeation revealed that penetration of EA from the niosomes depended on vesicle size, the amount of EA entrapped and the added solubilizers which could act as a permeation enhancer. From skin distribution study, the EA-loaded niosomes showed more efficiency in the delivery of EA through human epidermis and dermis than EA solution. The results indicated that the Span 60 and Tween 60 niosomes may be a potential carrier for dermal delivery of EA.     

Effect of permeation enhancers and organic acids on the skin permeation of indapamide

The aim of present study was to investigate the transdermal properties of indapamide and to explore the efficacy of various permeation enhancers and organic acids with regard to the percutaneous absorption of indapamide. Permeation experiments were performed in vitro, using rat abdominal skin as a barrier. In the permeation studies, 2-chamber diffusion cells were used. The results obtained indicate that N-dodecylazepan-2-one, N-methyl-2-pyrrolidone, menthol and oleic acid had a strong enhancing effect on the permeation of indapamide and N-dodecylazepan-2-one exhibited the most potent enhancing effect. All eight of the organic acids chosen had a potent enhancing effect on the permeation of indapamide across rat abdominal skin. Among the organic acids examined, lactic acid had the greatest enhancing effect. The formation of an ion-pair between indapamide and organic acids may be responsible for the enhanced skin permeation of indapamide. Although the exact reason remains unknown, it is worth carrying out further investigations.     

Charged liposomes as carriers to enhance the permeation through the skin

INTRODUCTION: In recent years, there has been increased interest in developing charged liposomes as carriers for transdermal drug delivery. It is necessary to modify the basic composition of the liposomes in order to enhance the penetration properties of the vesicles through the skin. Charged liposomes offer several advantages compared with previous drug delivery systems. AREAS COVERED: This paper provides a brief overview of the different drug delivery systems that exist which aim to improve the permeation of drugs through the skin, focusing on the use of charged liposomes for transdermal delivery. We propose a classification of such liposomes based on the origin of the charge given to the vesicles. EXPERT OPINION: Despite the advances that are occurring in the design of charged liposomes for transdermal drug delivery, the long-term stability continues to be a drawback in such systems. The presence of charge on the surface of the vesicles favors the electrostatic repulsion among them, creating a ζ potential positive or negative that prevents their aggregation and flocculation. However, there is loss of the encapsulated drug, which limits the in vivo use of these systems. It should be emphasized that charged liposomes are indeed a promising candidate for use in gene therapy and vaccine targeting, in a great diversity of diseases, for which drugs are administered by the percutaneous route.     

Charged liposomes as carriers to enhance the permeation through the skin

Introduction: In recent years, there has been increased interest in developing charged liposomes as carriers for transdermal drug delivery. It is necessary to modify the basic composition of the liposomes in order to enhance the penetration properties of the vesicles through the skin. Charged liposomes offer several advantages compared with previous drug delivery systems.

Areas covered: This paper provides a brief overview of the different drug delivery systems that exist which aim to improve the permeation of drugs through the skin, focusing on the use of charged liposomes for transdermal delivery. We propose a classification of such liposomes based on the origin of the charge given to the vesicles.

Expert opinion: Despite the advances that are occurring in the design of charged liposomes for transdermal drug delivery, the long-term stability continues to be a drawback in such systems. The presence of charge on the surface of the vesicles favors the electrostatic repulsion among them, creating a ζ potential positive or negative that prevents their aggregation and flocculation. However, there is loss of the encapsulated drug, which limits the in vivo use of these systems. It should be emphasized that charged liposomes are indeed a promising candidate for use in gene therapy and vaccine targeting, in a great diversity of diseases, for which drugs are administered by the percutaneous route.     

离子导入对降纤酶经皮渗透的影响

目的研究离子导入对降纤酶经皮渗透的影响。方法利用水平式扩散池，对降纤酶进行离子导入透过大鼠皮肤和人尸表皮的渗透性试验，对电极极性、渗透介质的pH以及离子强度等影响进行考察。结果离子导入阳极转运时，在pH 6.4的磷酸盐缓冲介质中，降纤酶的表观经皮渗透系数为（1.2±0.4）×10^-4 cm·h^-1，明显高于阴极转运［（4.3±1.4）×10^-5 cm·h^-1］；在pH 7.4磷酸盐缓冲介质中，降纤酶阳极离子导入经皮渗透量为（25±5）×10^-14 mol·cm^-2高于pH 6.4介质经皮渗透量［(15±4)×10^-14 mol·cm^-2］。结论离子导入阳极转运能够促进降纤酶的经皮渗透，电渗作用有重要影响。     

Hyaluronic acid gel-core liposomes (hyaluosomes) enhance skin permeation of ketoprofen

Since FDA approval of the first transdermal patch in 1979, the utilizing of skin as a route of systemic drug administration has attracted the attention of the formulation scientists. The liposomes research in the area of transdermal drug delivery has been around for decades. This study aimed at comparing the latest gel-core liposomes (hyaluosomes) with nonconventional liposomal systems such as propylene glycol (PG)-liposomes, ethosomes, transferosomes and conventional liposomes loaded with ketoprofen. The modified thin-film hydration method was used to prepare these liposomal systems; size, zeta potential, EE%, TEM, rheological properties, in vitro release and ex vivo permeation studies were performed. Vesicle size and PDI ranged from 160?nm to 700?nm and 0.15 to 0.5, respectively. More interestingly, thermal gelation and shear-thinning characteristics were only recorded with hyaluosomes; while Newtonian behavior and low viscosity values (2 mPas.s to 6?mPa.s) were shown with all other liposomal systems. Hyaluosomes recorded superior (3-fold increases) transdermal permeation characteristics (flux and permeability coefficient), compared with other liposomal systems. With the advancement in liposomal sciences, this study warrants hyaluosomes as a promising transdermal liposomal system for favorable rheological characteristics as well as superior transdermal permeation that proved greater capacity than conventional and other non-conventional liposomal systems.     

Effect of ethanol pretreatment on skin permeation of drugs

It has been demonstrated that ethanol (EtOH) can enhance skin permeation of drugs when simultaneously applied with drugs. However, only a few studies have reported on the pretreatment effect of EtOH on skin permeations. In this study, the pretreatment effects of EtOH on skin permeation of drugs were investigated by measuring changes in skin permeation and electrical skin resistance. Permeabilities of deuterium oxide (D2O), isosorbide mononitrate (ISMN), isosorbide dinitrate (ISDN), calcein sodium (CA-Na), and fluorescein isothiocyanate-dextran 4?kDa (FD-4, 3.3-4.4?kDa) were evaluated through Yucatan micropig skin pretreated with different concentrations of EtOH solution. From the results, almost constant skin permeabilities of D2O and ISDN were observed independent of EtOH concentration. Skin permeabilities of ISMN, CA, and FD-4 increased with low concentrations of EtOH, but decreased with high concentrations of EtOH. At 99.5% EtOH pretreatment, skin permeabilities of hydrophilic compounds (ISMN, CA, and FD-4) decreased to non-detectable levels. In addition, low molecular ion transports were almost constant at any EtOH concentration. Since molecular (ion) sizes of ISMN, CA, and FD-4 are larger than Na⁺, Cl^－, and D2O, permeation pathway sizes for hydrophilic compounds in the skin barrier may be remarkably decreased by pretreatment with high concentrations of EtOH. However, the permeability coefficient of ISDN was not influenced by any EtOH concentration, since ISDN is a lipophilic, low-molecular compound that permeated through the lipophilic stratum corneum pathway. The present results show useful information for repeatedly and topically applied formulations containing EtOH, and also contribute to the effective use of alcohol formulations.     

Vesicular aceclofenac systems: A comparative study between liposomes and niosomes

Vesicular delivery systems have been reported to serve as local depot for sustained drug release. Aceclofenac multilamellar liposomes and niosomes were prepared and a comparative study was done between them through evaluation of entrapment efficiency, particle size, shape, differential scanning calorimetry and in vitro drug release. A stability study was carried out by investigating the leakage of aceclofenac and the change in the vesicles particle size when stored at (2–8°C) for 3 months. The anti-inflammatory effect of aceclofenac vesicles was assessed by the rat paw oedema technique. Results showed that the entrapment efficiency and the in vitro release of aceclofenac from the vesicles can be manipulated by varying the cholesterol content, the type of surfactant as well as the type of charge. Niosomes showed better stability than liposomes. Both vesicular systems showed significant sustained anti-inflammatory activity compared to the marketed product, with niosomes being superior to liposomes as manifested by both oedema rate and inhibition rate percentages suggesting their effectiveness as topical anti-inflammatory delivery systems.     

Vesicular aceclofenac systems: a comparative study between liposomes and niosomes

Vesicular delivery systems have been reported to serve as local depot for sustained drug release. Aceclofenac multilamellar liposomes and niosomes were prepared and a comparative study was done between them through evaluation of entrapment efficiency, particle size, shape, differential scanning calorimetry and in vitro drug release. A stability study was carried out by investigating the leakage of aceclofenac and the change in the vesicles particle size when stored at (2-8 degrees C) for 3 months. The anti-inflammatory effect of aceclofenac vesicles was assessed by the rat paw oedema technique. Results showed that the entrapment efficiency and the in vitro release of aceclofenac from the vesicles can be manipulated by varying the cholesterol content, the type of surfactant as well as the type of charge. Niosomes showed better stability than liposomes. Both vesicular systems showed significant sustained anti-inflammatory activity compared to the marketed product, with niosomes being superior to liposomes as manifested by both oedema rate and inhibition rate percentages suggesting their effectiveness as topical anti-inflammatory delivery systems.     

Effect of counter-ions and penetration enhancers on the skin permeation of flurbiprofen

The aim of this work was to investigate the percutaneous absorption of flurbiprofen (FP) using counter-ions as enhancers as well as to compare their enhancing activity with penetration enhancers in vitro. The in vitro permeation studies of FP were performed in isopropyl myristate (IPM) solution by two-chamber diffusion cells, using rat abdominal skin as a model. Among the penetration enhancers examined, including the cosolvents of propylene glycol and ethanol (EtOH), oleic acid, menthol, laurocapram, sorbitan monooleate, and N-methyl-2-pyrrolidone (NMP), 10% (w/w) EtOH and NMP exhibited the most potent solubilization and enhancing effects of FP from IPM, with a flux of (372.60 ± 45.12) µg/cm²/h and (474.21 ± 46.64) µg/cm²/h, respectively. Ten percent (w/w) EtOH/IPM binary system was used to investigate the effect of the counter-ions, namely diethylamine (DEA), triethylamine (TEA), ethanolamine (EtA), diethanolamine (DEtA), triethanolamine (TEtA), and N-(2′-hydroxyethanol)-piperdine (HEPP). The cumulative amounts were markedly increased in the presence of the counter-ions, and the highest flux of (1297.53 ± 121.81) µg/cm²/h was obtained by DEA. This was related to the decreased lipophilicity and different physicochemical properties of the ion-pairs. In particular, we proved the formation of an FP/amine ion-pair in solution by ¹H-NMR. The results suggest that the counter-ions are more efficient than penetration enhancers. © 2009 Wiley-Liss, Inc. and the American Pharmacists Association J Pharm Sci 99: 1826–1837, 2010     

盐酸利多卡因纳米高分子脂质体的制备与体外透皮实验研究

【摘要】目的 采用赖氨酸壳聚糖十八烷基季铵盐(OQLCS)/胆固醇包载盐酸利多卡因制备纳米高分子脂质体（LID-PLs）,并研究其体外透皮渗透情况。方法 采用反相蒸发法制备LID-PLs 和盐酸利多卡因传统脂质体 (LID-CLs),用激光粒度仪/Zeta电位仪测试其粒径;建立测定盐酸利多卡因浓度的HPLC法;使用离体小鼠皮和Franz 扩散池进行体外透皮实验,评价不同时间点LID-PLs、LID-CLs和盐酸利多卡因注射液（LID-IJ）的体外透皮渗透情况。结果 LID-PLs组粒径小于LID-CLs组[（61.2±8.14）nm vs（219±7.51）nm]。所建立的HPLC法专一性好,盐酸利多卡因的保留时间为3.899 min,空白纳米高分子脂质体、空白透皮接收液对盐酸利多卡因的测定均无影响,其标准曲线方程为=0.051X-2.701(r = 0.999 9)。LID-PLs组在5 min、10 min、30 min、2 h、4 h、6 h、8 h、12 h及24 h的平均累积透过量均明显高于LID-CLs组和LID-IJ组（P < 0.05或P < 0.01）。LID-CLs组在10 min、30 min、1.5 h、2 h、4 h、6 h、8 h、 12 h、24 h的平均累积透过量均明显高于LID-IJ组（P < 0.05或P < 0.01）。结论 LID-PLs制备简单,具有良好的透皮释放行为,所建立的HPLC方法准确可靠。     

Effect of emulsification on the skin permeation and UV protection of catechin

Abstract

An anti-aging effect may be obtained by skin application of tea catechins (Camellia sinensis) since they have high ultraviolet (UV)-protection activity. In this study, the skin permeation of catechin (C), epicatechin (EC), epigallocatechin (EGC), epicatechin gallate (ECg) and epigallocatechin gallate (EGCg) was determined and compared, and the effect of emulsification on the skin permeation of C was measured. The UV-protective effect of C was also determined. The in vitro skin permeability of each catechin derivative was determined using side-by-side diffusion of cells. The UV-protective effect of C was determined by applying different concentrations of C to the solution or emulsion on a three-dimensional cultured human skin model or normal human epidermal keratinocytes with UV-irradiation. ECg and EGCg with gallate groups showed lower skin permeability than C, EC and EGC without gallate groups, suggesting that the skin permeability of catechin derivatives may be dependent on the existence of a gallate group. Interestingly, the skin permeation of C was increased by an o/w emulsification. In addition, the C emulsion showed a significantly higher UV-protective effect by C than that with its aqueous solution. These results suggest that the o/w emulsion of catechin derivatives is probably useful as a cosmetic formulation with anti-aging efficacy.     

Effect of N-methyl-2-pyrrolidone on skin permeation of estradiol.

N-Methyl-2-pyrrolidone (NMP) increased the skin permeation of estradiol (E2) in Yucatan micropig epidermis using a modified Franz-type diffusion cell. The addition of NMP significantly increased the fluxes of E2 from water and soybean oil. The flux and skin concentration of E2 were higher from soybean oil than from water and increased with increasing NMP concentrations in soybean oil. Correlation was observed with E2 flux and skin concentration (R(2) = 0.804) NMP enhanced E2 skin permeation because NMP made E2 skin concentration higher. Thus, NMP (10%) was added to the oily gel made by isocetyl isostearate and hydrogenated phospholipid. E2 permeation from the gel without NMP was the same as that from soybean oil suspension. The flux of E2 from the gel with NMP was 0.6 microg/h per cm(2) and might be sufficient for estrogen replacement therapy.     

Comparative characterization of the physicochemical behavior and skin permeation of extruded DPPC liposomes modified by selected additives

The purpose of the present study was to analyze the influence of cholesterol (CHOL), stearylamine (SA), dicetyl phosphate (DCP), and xylenesulfonic acid sodium salt (SXS) in extruded DPPC (1,2-dipalmitoyl-sn-glycero-3-phosphocholine) liposomes on their size, shape, and skin permeation of the model drug progesterone. The additives were incorporated in different molar ratios in relation to the phospholipid content. It could be proven that different molar ratios of the additives to lipids were able to modify liposome size, zeta potential, and the characteristic phase transition temperature of the lipids. In standard skin diffusion experiments SA and SXS increased the progesterone permeation two- to fourfold respectively after 48 h compared to the control.     

Effect of lactic acid and iontophoresis on drug permeation across rabbit ear skin

The aim of this paper was to explore the efficacy of lactic acid as permeation enhancer for drug molecules across the skin. Three model permeants were chosen: acetaminophen (non-ionized), buspirone hydrochloride (cationic drug) and ibuprofen lysine (anionic drug). We also explored the association of lactic acid and iontophoresis as a means of enhancing drug delivery. Permeation experiments were performed in vitro, using rabbit ear skin as barrier. The results obtained indicate that lactic acid has some effects on model drug permeation across the skin. The effect was more evident with the anionic drug ibuprofen. Cathodal intophoresis increased ibuprofen transport, but when lactic acid was associated with cathodal iontophoresis, a concentration-dependent reduction of ibuprofen iontophoretic flux was observed, probably for the competition by the co-ion. The application of electric current (anodal iontophoresis) to a solution of acetaminophen produced an increase in its transport, due to the presence of an electroosmotic contribution; however, the effect of the association of anodal iontophoresis and lactic acid produced no further enhancement.