Human papillomavirus (HPV) infection in the normal oral cavity was studied by the sensitive polymerase chain reaction (PCR) using primers for the L1 region of human papillomavirus DNA and high fidelity amplification system. Cells were scraped from the oral mucosae of 7 (mean age; 42 years) and 30 (mean age; 32 years) volunteers with and without skin warts, respectively. Human papillomavirus DNA was detected in 30/37 (81.1%) specimens and their copy numbers per cell were 10(-1) to 10(-4) (mean, 10(-3)). The human papillomavirus types determined by PCR-based sequencing analysis were HPV-18 (26/30; 86.7%), -61 (18/30; 60%), -59 (7/30; 23.3%), -16 (2/30; 6.7%), -6 (1/30; 3.3%) and an unknown type (HPV-X71) (1/30; 3.3%). Multiple human papillomavirus types were present in 17/30 (56.7%) specimens. HPV-6 was detected in 2 of 7 skin warts and differed from the human papillomavirus types of the corresponding oral specimens. These data suggest that human papillomavirus infection in the oral mucosa occurs much more frequently than previously considered.
The aim of this study is the improvement of the photostability of several natural anionic dyes, carmine (CM), carthamus yellow (CY), and annatto dye (ANA), by complexation with hydrotalcite. The composite of the dyes and hydrotalcite is prepared by the coprecipitation method. CM is successfully intercalated in the hydrotalcite layer when the amount of introduced CM is large. The photostability of CM in CM/HT composites is superior to the CM adsorbed on silica surface. The effect of the stability enhancement is larger when the amount of introduced CM exceeds 0.23 g/g-host, or when the layer charge density of the hydrotalcite is larger. CY is also stabilized by complexation with hydrotalcite, whereas ANA is not stabilized by complexation with hydrotalcite. The photostability of an anionic natural dye can be improved by intercalation into the hydrotalcite layer, if the dye has a hydrophilic nature and a rather planar structure. The intercalated dye is stabilized by the protection from the attack of the atmospheric oxygen. In addition, contribution of the electrostatic interaction between the positively charged hydrotalcite layer and the intercalated anionic dye is also proposed.
Flavylium dye, a model compound of natural anthocyanin, has a defect that its color stability is very poor. We have tried to complex the flavylium dye with several mesoporous silicas (FSM16, MCM41 and HMS) and succeeded to enhance the photostability of the dye against visible light irradiation. We have found that the light fastness is enhanced when the dye is incorporated into the mesoporous silicas exhibiting solid acidity that derives from an aluminum impurity. The solid acidity plays a role to
Flavylium dye, a model compound of natural anthocyanin, has a defect that its color Manuscript lick here to download Manuscript: MMM_rev.doc stability is very poor. We have complexed the flavylium dye with protonated zeolites and succeeded to enhance both the thermal and chemical stability of the dye. The aqueous dispersion of the flavylium/zeolite complex maintains its color even at 353 K or at pH=9, under which conditions the aqueous solution of the flavylium loses its color immediately. The stability is enhanced when the dye is incorporated into the pore of the zeolites, and a large stabilization effect is obtained by a tight adsorption with a narrow pore, as long as the dye is incorporated into the pore. Because of its enhanced color stability, the flavylium dye incorporated in the zeolite pore can be a candidate for an environmentally friendly coloring material.
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