Increase of ß2-integrin on adhesion of THP-1 cells to collagen vitrigel membrane.

When human monocyte-derived leukemia (THP-1) cells, which are floating cells, are stimulated with lipid peroxides, or Streptococcus suis, these cells adhere to a plastic plate or endothelial cells. However, it is unclear whether or not non-stimulated THP-1 cells adhere to collagen vitrigel membrane (CVM). In this study, firstly, we investigated the rate of adhesion of THP-1 cells to CVM. When THP-1 cells were not stimulated, the rate of adhesion to CVM was high. Then, to identify adhesion molecules involved in adhesion of THP-1 cells to CVM, expressions of various cell adhesion molecules on the surface of THP-1 cells adhering to CVM were measured. ß-actin, ß-catenin, and ß1-integrin expressions did not change in non-stimulated THP-1 cells cultured on CVM compared with those in cells cultured in a flask, but ß2-integrin expression markedly increased.

Lack of promoting effect of titanium dioxide particles on ultraviolet B-initiated skin carcinogenesis in rats.

Titanium dioxide (TiO(2)) is used in sunscreens and cosmetics as an ultraviolet light screen. TiO(2) has carcinogenic activity in the rat lung, but its effect on the skin has not been reported. We examined the promoting/carcinogenic effect of nano-size TiO(2) particles using a two-stage skin model. c-Ha-ras proto-oncogene transgenic (Hras128) rats, which are sensitive to skin carcinogenesis, and their wild-type siblings were exposed to ultraviolet B radiation on shaved back skin twice weekly for 10 weeks; then the shaved area was painted with a 100 mg/ml TiO(2) suspension twice weekly until sacrifice. All rats were killed at week 52 except for female Hras128 rats which were sacrificed at week 16 because of early mammary tumor development. Skin tumors developed in male Hras128 rats and mammary tumors developed in both sexes of Hras128 rats and in wild-type female rats, but tumor incidence was not different from controls. TiO(2) particles were detected in the upper stratum corneum but not in the underlying skin tissue layers. TiO(2) particles also did not penetrate a human epidermis model in vitro. Our data suggest that TiO(2) does not cause skin carcinogenesis, probably due to its inability to penetrate through the epidermis and reach underlying skin structures.

Effects of coating materials and size of titanium dioxide particles on their cytotoxicity and penetration into the cellular membrane.

In order to estimate the effects of the size and surface treatment (coating or non-coating) of titanium dioxide particles on their cytotoxicity and penetration into the cellular membrane, two types of non-treated titanium dioxide (TiO(2)) particles of 20 nm (LU175) and 250 nm (LU205) were exposed to CHO cells, RBL-2H3 cells, A431 cells, B16 melanoma, NHEK(F), and NHSF, and six types of surface-treated or non-treated TiO(2) particles of 35 nm were exposed to RBL-2H3 cells and NHSF. The order of half-maximal inhibitory concentrations (IC50s) of LU175 was NHSF < CHO, RBL-2H3 < A431 < B16 melanoma, NHEK(F). On the other hand, LU205 showed no cytotoxicity against any cells. Surface-treated TiO(2) showed much less cytotoxicity against RBL-2H3 cells than non-treated TiO(2). Then, between 0.5 and 10 mg of LU175 or LU205 was exposed to CHO cells. After 24 hr, the amount of LU175 in cellular cytosol increased dose-dependently. On the other hand, the amount of LU205 in cellular cytosol was much less than that of LU175. The proportion of surface-treated TiO(2) in the cellular cytosol of RBL-2H3 cells differed for each coating material. These results suggested that TiO(2) has different cytotoxicities among cell lines, and that of surface-treated TiO(2) was weaker than that of non-treated TiO(2). TiO(2) located in cytosol might be the main cause of cytotoxicity.

[Analysis of volcanic-ash-based insoluble ingredients of facial cleansers].

The substance termed "Shirasu balloons", produced by the heat treatment of volcanic silicates, is in the form of hollow glass microspheres. Recently, this substance has gained popularity as an ingredient of facial cleansers currently available in the market, because it lends a refreshing and smooth feeling after use. However, reports of eye injury after use of a facial cleanser containing a substance made from volcanic ashes are on the rise. We presumed that the shape and size of these volcanic-ash-based ingredients would be the cause of such injuries. Therefore, in this study, we first developed a method for extracting water-insoluble ingredients such as "Shirasu balloons" from the facial cleansers, and then, we examined their shapes and sizes. The insoluble ingredients extracted from the cleansers were mainly those derived from volcanic silicates. A part of the ingredients remained in the form of glass microspheres, but for the most part, the ingredients were present in various forms, such as fragments of broken glass. Some of the fragments were larger than 75 microm in length. Foreign objects having a certain hardness, shape, and size (e.g., size greater than 75 microm) can possibly cause eye injury. We further examined insoluble ingredients of facial scrubs, such as artificial mineral complexes, mud, charcoal, and polymers, except for volcanic-silicate-based ingredients. The amounts of insoluble ingredients extracted from these scrubs were small and did not have a sharp edge. Some scrubs had ingredients with particles larger than 75 microm in size, but their specific gravities were small and their hardness values were much lower than those of glass microspheres of ingredients such as "Shirasu balloons". Because the fragments of glass microspheres can possibly cause eye injury, the facial cleansers containing large insoluble ingredients derived from volcanic ashes should be avoided to use around eyes.

[Development of novel cell culture systems utilizing the advantages of collagen vitrigel membrane].

The white of an egg, rendered opaque by boiling, can be converted into a thin, transparent and rigid material like glass by evaporating the moisture. This phenomenon is known as the vitrification of heat-denatured proteins. We applied vitrification technology to a collagen gel and converted it into a rigid glass-like material. We attempted to rehydrate the glass-like material and succeeded in preparing a novel stable state of collagen gel that was a thin and transparent membrane with excellent gel strength and protein permeability. We called it "collagen vitrigel" because it was produced from the vitrification process of a traditional hydrogel. Further, a framework-embedded collagen vitrigel membrane that can be easily turned inside out with tweezers was prepared by inserting a nylon membrane ring in the collagen sol prior to the gelation, thereby allowing the membrane to function as a removable cell culture substratum. Different types of anchorage-dependent cells could be cultured on both surfaces of the substratum by the manipulation of two-dimensional cultures, and consequently a three-dimensional crosstalk model with paracrine effects from each cell type was reconstructed. Also, the collagen vitrigel membrane containing a bioactive molecule provided a drug delivery system (DDS) with sustainable release. In this review, we summarize the recent progress of applied studies using the collagen vitrigel membrane as follows: a corneal model for eye irritant and permeability tests, a skin model for sensitization test, a renal glomerular model for evaluating blood filtration, an endometrial model for developing a new treatment and a DDS of hepatocyte growth factor for improving liver disorder.

Involvement of macrophage inflammatory protein 1alpha (MIP1alpha) in promotion of rat lung and mammary carcinogenic activity of nanoscale titanium dioxide particles administered by intra-pulmonary spraying.

Titanium dioxide (TiO(2)) is evaluated by World Health Organization/International Agency for Research on Cancer as a Group 2B carcinogen. The present study was conducted to detect carcinogenic activity of nanoscale TiO(2) administered by a novel intrapulmonary spraying (IPS)-initiation-promotion protocol in the rat lung. Female human c-Ha-ras proto-oncogene transgenic rat (Hras128) transgenic rats were treated first with N-nitrosobis(2-hydroxypropyl)amine (DHPN) in the drinking water and then with TiO(2) (rutile type, mean diameter 20 nm, without coating) by IPS. TiO(2) treatment significantly increased the multiplicity of DHPN-induced alveolar cell hyperplasias and adenomas in the lung, and the multiplicity of mammary adenocarcinomas, confirming the effectiveness of the IPS-initiation-promotion protocol. TiO(2) aggregates were localized exclusively in alveolar macrophages and had a mean diameter of 107.4 nm. To investigate the underlying mechanism of its carcinogenic effects, TiO(2) was administered to wild-type rats by IPS five times over 9 days. TiO(2) treatment significantly increased 8-hydroxydeoxy guanosine level, superoxide dismutase activity and macrophage inflammatory protein 1alpha (MIP1alpha) expression in the lung. MIP1alpha, detected in the cytoplasm of TiO(2)-laden alveolar macrophages in vivo and in the media of rat primary alveolar macrophages treated with TiO(2) in vitro, enhanced proliferation of human lung cancer cells. Furthermore, MIP1alpha, also detected in the sera and mammary adenocarcinomas of TiO(2)-treated Hras128 rats, enhanced proliferation of rat mammary carcinoma cells. These data indicate that secreted MIP1alpha from TiO(2)-laden alveolar macrophages can cause cell proliferation in the alveoli and mammary gland and suggest that TiO(2) tumor promotion is mediated by MIP1alpha acting locally in the alveoli and distantly in the mammary gland after transport via the circulation.

[Analysis of preservatives used in cosmetic products: salicylic acid, sodium benzoate, sodium dehydroacetate, potassium sorbate, phenoxyethanol, and parabens].

Preservatives are used to inhibit the growth of microorganisms in cosmetic products. The Japanese standards for cosmetics set restrictions on the maximum amount of each preservative added to cosmetics as per the purpose of use of cosmetics. For the investigation into the actual conditions of commonly used preservatives in commercial cosmetics, we analyzed parabens, phenoxyethanol, sodium benzoate, sodium dehydroacetate, salicylic acid, and potassium sorbate by high-performance liquid chromatography (HPLC). Twenty-one samples were obtained from cosmetic product manufacturers located in 14 prefectures in Japan. Among different acid- and salt-based preservatives, sodium benzoate was observed to have been used in many products. These acid- and salt-based preservatives were used with parabens in personal washing products, such as shampoo and soap. The labels of two of the cosmetic product samples displayed inaccurate ingredient information, that is, a preservative other than the one used in the corresponding product was listed on them. The amount of preservatives used did not exceed regulatory limits in any of the analyzed samples.

[Detection of clobetasol propionate in a cream advertised to be effective against atopic dermatitis].

Addition of medical ingredients to cosmetics is prohibited. However, last year some cases of illegal cosmetics containing steroids were successfully identified. We have already reported an analytical method to detect steroids in cosmetics [Bull. Natl. Inst. Health Sci, 126, 51-56 (2008)]. In this study, we initially examined whether this method could be applied for the detection of some new steroids as target chemicals. We then used this developed method to detect steroids in cosmetics obtained from manufacturers by spot checks. These manufacturers have been advertising the effectiveness of a steroid-free cream against atopic dermatitis. The results revealed that clobetasol propionate (CP) was present in this facial moisturizing cream, which was available in the market. The steroid was extracted with methanol. After ultrasonication and centrifugation, the resulting supernatant was injected into the high-performance liquid chromatography system equipped with an ODS column. The separation was achieved using a mixture of acetonitrile and water as the mobile phase. The retention times of the observed peaks were in accordance with those of some preservatives and CP. The presence of CP was also confirmed by thin-layer chromatography. The concentration of CP in the cream was approximately 0.039%. CP is a steroid that has the strongest effect as compared to those of other steroids. The cream was therefore recalled for safety reasons.

[Studies on an analytic method for detection of prohibited ingredient, strontium dichloride in cosmetics].

Strontium dichloride is one of the prohibited ingredients in cosmetics due to the Japanese Pharmaceutical Affairs Act. We established the analytical method for strontium dichloride in cosmetics by capillary electrophoresis (CE). The toothpaste was dispersed into water. After ultrasonication for 10 min, the solution was centrifuged at 3000 rpm for 10 min. The supernatant was filtrated through a membrane (0.45 microm), diluted 100-times with water, and injected into CE. The calibration curve showed linear between the concentrations of strontium dichloride (from 2 to 50 microg/ml) and the peak area of strontium ion. Detection limit of strontium dichloride is 2 microg/ml. There was no interference of the ingredients in the toothpaste.

[Construction of three-dimensional human skin model involving dendritic cells and its application to skin sensitization test].

Recently, to study an in vitro evaluation method of skin irritation and acute toxicity, many three-dimensional human skin models consisting of normal human keratinocytes and fibroblasts have been used. However, these skin models did not have any dendritic cells so were difficult to apply to an in vitro skin sensitization test. On the other hand, a single cell-culture model using normal human dendritic cells was recently studied for an in vitro evaluation method of immune-sensitizing compounds. However, these models have various problems: 1) the life span of dendritic cells is short(within 1 week) and 2) it is difficult to apply water-insoluble samples to these models. To study an alternative to animal testing using immune-sensitizing compounds, we therefore constructed a three-dimensional human skin model consisting of three different cells, dendritic cells (keratinocytes, and fibroblasts) then exposed immune-sensitizing compounds and non-sensitizers to the new skin model for 1 h and investigated the effect of these compounds on cytokine release and expression of CD86. Due to immune-sensitizing compounds, the new skin model significantly released cytokine and significantly expressed CD86. On the other hand, non-sensitizers did not induce IL-1alpha, IL-2, and IL- 4 release and expression of CD86. These results suggest that the new skin model is suitable for study as an alternative to animal testing using immune-sensitizing compounds.

[Simultaneous determination of 9 ultraviolet absorbers in cosmetics by high-performance liquid chromatography].

Simultaneous determination for 9 ultraviolet absorbers those set a limit to the amount in cosmetics was performed. Ultraviolet absorbers were extracted from cosmetics with tetrahydrofuran (THF) by ultrasonication. After centrifugation, the supernatant was collected, and the sample solution was injected into the HPLC. Separation was archived using an ODS column with the mixture of THF and water as the mobile phase. Detection wavelength was set at 310 nm. The linearity was obtained between the peak areas and the concentrations of each ultraviolet absorber in the range of 5 - 100 microg/ml. In 70 commercial cosmetic products, such as sunscreen, face powder, foundation, massage cream, moisture lotion, lip balm and essence, 2-ethylhexyl-p-methoxycinnamate (EMC), 2-hydroxy-4-methoxybenzophenone (HMB), 4-tert-butyl-4'-methoxydibenzoylmethane (BMB) and 2-ethylhexyl salicylate (ES) were detected.

[Studies for analyzing prohibited ingredients such as cadmium sulfide in cosmetics].

Cadmium sulfide is one kind of the prohibited ingredients in cosmetics by the Japanese Pharmaceutical Affairs Act. We established the analytical method for cadmium sulfide in cosmetics by ICP-MS. Analytical procedures were as follows: Cosmetics of 1 g contained inorganic pigment were put into a 100 ml flask glass. After adding 100 ml of 12% nitric acid into the 100 ml flask glass, the filtrate was sonicated for 30 min. After sonicating, the mixture was centrifuged at 3000 rpm for 5 min and then the supernatant was filtrated through a millipore membrane filter (0.45 microm). After filtration, the filtrate was made up to 200 ml with 12% nitric acid. The solution was diluted 100 times with 12% of nitric acid and used as the test solution. The test solution of 100 microl was analyzed by ICP-MS (HP-4500, monitoring mass 111). The working curve from 1 to 1000 microg/l showed a linear line between the concentrations of cadmium and the peak areas. Detection limit of cadmium is 0.02 microg/l. There was no effect of the ingredients in the cosmetics on cadmium sulfide determination.

[Studies for analyzing prohibited ingredients such as mercury in cosmetics].

Mercury is one kind of prohibited ingredients in cosmetics by the Japanese Pharmaceutical Affairs Act. We established the analytical method for mercury in cosmetics by ICP-MS. Analytical procedures were as followed: Ten microl of 1 g/l mercury solution and 1 g of whitening cream were put into a 50 ml plastic tube. After adding 20 ml of 12% nitric acid into the 50 ml plastic tube, the mixture was sonicated for 10 min. After sonicating, the mixture was centrifuged at 3000 rpm for 10 min and then the supernatant was filtrated through a milli-pore membrane with the pore size of 0.45 microm and 0.1 microm. After filtration, the mixture was made up to 25 ml with 7% nitric acid and used as the test solution. The test solution of 100 microl was analyzed by ICP-MS (HP-4500, monitoring mass 202). The calibration curve from 1 to 1000 microg/l showed a linear line between the concentrations of mercury and the peak areas. Detection limit of mercury was 0.1 microg/l. There was no effect of the ingredients in the whitening cream on mercury determination.

[Analysis of Helindone Pink CN and Permaton Red in cheek rouge].

Analytical methods for red tar colors, Helindone Pink CN (R226) and Permaton Red (R228), in cheek rouge were developed. R226 and R228 were extracted from cheek rouge with chloroform by ultrasonication. After centrifugation, the supernatant was collected for the determination of R226 and R228. Methanol was then added to the residue for the extraction of Pigment Red 57-1 (R201) and Pigment Red 57 (R202). Each R226 and R228 was separately detected by the silica-gel thin-layer chromatography using the mixture of hexane and chloroform (2:1) or (3:1), or hexane and tetrahydrofuran (THF) (2:1) as a developing solvent. For the determination of R226 and R228, the extract in chloroform was injected into the HPLC equipped with Amide colomn and UV-VIS detector (detection wavelength 535 nm and 487 nm) using the mixture of hexane and THF as mobile phase. The linearity was obtained between the peak areas and the concentrations of R226 and R228 in the range of 0.625-10 microg/ml. R201 and R202 were determined using ODS column and the mixture of acetonitrile and phosphate buffer as mobile phase. Seven cheek rouge samples were analyzed. The red tar colors listed in each cheek rouge were contained in the range of 247 to 6574 microg/g.

[Studies for analyzing the prohibited ingredients such as selenium disulfide in cosmetics].

Selenium disulfide is one kind of prohibited ingredients in cosmetics by the Japanese Pharmaceutical Affairs Act. We established the analytical method for selenium disulfide in cosmetics by ICP-MS. Selenium disulfide of 20 mg was put into a teflon vessel. After adding 5 ml of concentrated nitric acid and 2 ml of the shampoo into the teflon vessel, the mixture was digested with microwave-oven. After digesting, the mixture was made up to 25 ml with milliQ water and then it was filtrated through a milli-pore membrane (0.45 micro). After filtration, the solution was diluted with 7% of nitric acid and used as the test solution. The test solution of 100 microl was analyzed by ICP-MS (HP-4500, monitoring mass 82). The working curve from 10 to 1000 microg/l showed a linear line between the concentrations of selenium and the peak areas. Detection limit of selenium disulfide is 22 microg/l. There was no effect of the ingredients in the shampoo on selenium disulfide determination.

[Studies for analyzing the prohibited ingredients such as disodium monofluorophosphate in cosmetics].

Disodium monofluorophosphate is one kind of the prohibited ingredients in cosmetics due to the Japanese Pharmaceutical Affairs Act. We established the analytical method for disodium monofluorophosphate in cosmetics by capillary electrophoresis (CE). The tooth paste of 1 g was put into a 50-ml plastic tube. After adding 7.0 mg of disodium monofluorophosphate and 50 ml of milliQ water into the plastic tube, the mixture was ultrasonicated for 10 min. After centrifuging, the supernatant was filtrated through a milli-pore membrane (0.45 microm). After filtration, the solutionwas put into a 100-ml volumetric flask, made up to 100 ml with milliQ water and used as the test solution. The mouthwash of 1 ml and 7.0 mg of disodium monofluorophosphate were put into a 100-ml volumetric flask, made up to 100 ml with milliQ water and used as the test solution. The testing solution was analyzed by CE. The working curve from 10 to 100 microg/ml showed a linear line between the concentrations of disodium monofluorophosphate and monofluorophosphate peak areas. Detection limit of disodium monofluorophosphate is 0.3 microg/ml. There was no interference of peak of monofluorophosphate with the ingredients in the tooth paste and mouthwash.

[Studies for analyzing the prohibited ingredients such as acetohexamide in cosmetics].

Acetohexamide (AH) is nominated as the prohibited ingredients in cosmetics in Japanese Pharmaceutical Affairs Act. So the analytical method for AH was investigated by HPLC. The lotion or milky lotion of 0.5g was put into a 10-ml volumetric flask. After adding 1.0ml of AH solution at 50 microg/ml into the volumetric flask, the mixture was made up to 10ml with methanol as the testing solution. Creams were procedured as follows; 0.5 g of cream was put into a 10-ml volumetric flask. After adding 1.0ml of tetrahydrofuran into the volumetric flask, the mixture was stirred for several minutes and the ingredients of the creams were dissolved. After adding 1.0ml of AH solution at 50 microg/ml into the volumetric flask, the mixture was made up to 10ml with methanol. One milliliter of the mixture including AH at 5 microg/ml was exactly put into a test tube with a cap and then 1 ml of water and 1 ml of hexane were added. After shaking vigorously, stand for several minutes. After centrifuging, the hexane layer was eliminated and the residual mixture was used as the test solution. The testing solution of 20 microl was analyzed by HPLC using the ODS column (CAPCELL PAK C18 column, 4.6 x 250mm), the mixture of acetonitrile and 50 mmol/l phosphate buffer(pH 5.3)(3:1) and the detection wavelength of 247 nm. The working curve from 0.5 to 6.0 microg/ml showed a linear line between the concentrations of AH and the peak areas. There was no interference of peak of AH with the ingredients such as methylparaben, ethylparaben in the lotions, milky lotion and creams.

[Studies for analyzing the prohibited ingredients such as cyproheptadine hydrochloride in cosmetics].

Cyproheptadine hydrochloride (CH) is nominated as the prohibited ingredients in cosmetics in Japanese Pharmaceutical Affairs Act. So the analytical method for CH was investigated by HPLC. The lotion or milky lotion of 0.5 g was put into a 10-ml volumetric flask. After adding 1.0ml of CH solution at 50 microg/ml into the volumetric flask, the mixture was made up to 10ml with methanol as the test solution. Creams were procedured as follows; 0.5 g of cream was put into a 10-ml volumetric flask. After adding 1.0 ml of tetrahydrofuran into the volumetric flask, the mixture was stirred for several minutes and the ingredients of the creams were dissolved. After adding 1.0 ml of CH solution at 50 microg/ml into the volumetric flask, the mixture was made up to 10ml with methanol. This mixture was transferred to a centrifuging tube with a cap and then the tube was centrifuged for 5 minutes at 3000 rpm. The supernatant was used as the test solution. The test solution of 20 microl was analyzed by HPLC using the ODS column (CAPCELL PAK C18 column, 4.6 x 250 mm), the mixture of 1% acetic acid with 10 mmol/l sodium octanesulfonate and acetonitrile (11:9) and the detection wavelength of 286 nm. The working curve from 0.5 to 6.0 microg/ml showed a linear line between the concentrations of CH and the peak areas. There was no interference of peak of CH with the ingredients such as methylparaben, ethylparaben in the lotions, milky lotion and creams.

Effect of arsenic-contaminated irrigation water on agricultural land soil and plants in West Bengal, India.

Total arsenic withdrawn by the four shallow tubewells, used for agricultural irrigation in the arsenic-affected areas of Murshidabad district per year is 6.79 kg (mean: 1.79 kg, range: 0.56-3.53 kg) and the mean arsenic deposition on land per year is 5.02 kg ha(-1) (range: 2-9.81 kg ha(-1)). Mean soil arsenic concentrations in surface, root of plants, below ground level (0-30 cm) and all the soils, collected from four agricultural lands are 14.2 mg/kg (range: 9.5-19.4 mg/kg, n = 99), 13.7 mg/kg (range: 7.56-20.7 mg/kg, n = 99), 14.8 mg/kg (range: 8.69-21 mg/kg, n = 102) and 14.2 mg/kg (range: 7.56-21 mg/kg, n = 300) respectively. Higher the arsenic in groundwater, higher the arsenic in agricultural land soil and plants has been observed. Mean arsenic concentrations in root, stem, leaf and all parts of plants are 996 ng/g (range: <0.04-4850 ng/g, n = 99), 297 ng/g (range: <0.04-2900 ng/g, n = 99), 246 ng/g (range: <0.04-1600 ng/g, n = 99) and 513 ng/g (range: <0.04-4850 ng/g, n = 297) respectively. Approximately 3.1-13.1, 0.54-4.08 and 0.36-3.45% of arsenic is taken up by the root, stem and leaf respectively, from the soil.

[Studies for analyzing prohibited ingredients such as estriol in cosmetics].

Estriol (EO) is nominated as the prohibited ingredients in cosmetics in Japanese Pharmaceutical Affairs Act. So the analytical method using HPLC for EO was investigated. After placing 1.0 ml of EO solution at 50 microg/ml and 0.5 g of the lotion into a 10-ml volumetric flask, the methanol was added to make until that volume and this solution was used as the testing solution. Milky lotion was procedured as follows: After placing 1.0 ml of EO solution at 50 microg/ml and 0.5 g of the milky lotion into a 10-ml volumetric flask, the methanol was added to make until that volume. The suspending mixture was moved to a centrifuging tube with a cap. After centrifuging at 3000 rpm for 5 minutes, the supernatant was used as the testing solution. The testing solution of 20 microl was determined by HPLC using the ODS column (CAPCELL PAK C18 column, 4.6 x 250 mm), the mixture of water and acetonitrile (31:9) and the detection wavelength of 285 nm. The working curve from 1.0 to 6.0 microg/ml showed a linear line between the concentrations of EO and the peak area. There was no interference of peak of EO from the lotion and milky lotion.