Water-in-oil microemulsions containing triglyceride oil for personal care applications are described. The W/O type of microemulsions based on triglyceride oils such as soya oil and sunflower oil are suitable for skin cleansing shower oils. The microemulsions of the patent application allow the use of several mild surfactants, thereby obviating the use of aliphatic amine based anionic surfactants for personal cleansing. The microemulsion based on coconut oil serves like a ‘two-in-one’ formulation for prewash hair conditioning like a typical hair-oil and subsequently like a shampoo for cleansing the hair.

Water-in-oil microemulsions containing triglyceride oil for personal care applications are described. The W/O type of microemulsions based on triglyceride oils such as soya oil and sunflower oil are suitable for skin cleansing shower oils. The microemulsions of the patent application allow the use of several mild surfactants, thereby obviating the use of aliphatic amine based anionic surfactants for personal cleansing. The microemulsion based on coconut oil serves like a ‘two-in-one’ formulation for prewash hair conditioning like a typical hair-oil and subsequently like a shampoo for cleansing the hair.

The present invention relates to novel aqueous N-acyl glycinate compositions wherein the said compositions are free-flowing, pumpable, phase-stable on long-term storage, and processable at sub-zero temperatures; more specifically below −5° C. The present invention also relates to the use of these aqueous N-acyl glycinate compositions in preparing isotropic aqueous skin and hair cleansing formulations such as body wash, shower gels, shampoos, and other.

Shampoo compositions having an anionic surfactant, cationic deposition polymer, sheet-like microcapsules and an aqueous carrier. The shampoo composition delivers both good in use benefits, while maintaining a consumer desirable appearance. The sheet-like microcapsules can also contain perfumes, extracts, dyes, colorants, and/or benefit agents.

A method of repairing damaged hair, comprising the step of applying a composition to the hair, wherein the composition comprises a soluble zinc compound and a cleansing surfactant; and wherein the composition has a pH of from 3 to 5.

A method of repairing damaged hair, comprising the step of applying a composition to the hair, wherein the composition comprises a soluble zinc compound and a cleansing surfactant; and wherein the composition has a pH of from 3 to 5.

The present invention relates to a composition for preventing hair loss or promoting hair growth, comprising ginsenoside Rg4 or a mixture of ginsenosides Rg2, Rg4, Rg6, and Rh1 as an active ingredient. Treatment with ginsenoside Rg4 or the mixture of ginsenosides Rg2, Rg4, Rg6, and Rh1 in human hair follicle dermal papilla cells exhibits a desirable effect of forming three-dimensional spheres capable of inducing hair follicle formation and growth and increasing the size thereof, exhibits a desirable effect of activating Wnt/β-catenin signaling, which is important for hair follicle cell activation and regeneration, and exhibits a desirable effect of increasing the expression levels of ALPL, VCAN, BMP2, and FGF7 genes, which are important for hair follicle formation and growth. Thus, ginsenoside Rg4 or the mixture of ginsenosides Rg2, Rg4, Rg6, and Rh1 can be usefully utilized as a composition for preventing hair loss and promoting hair growth.

The present disclosure relates to silica particles comprising repeating units of (SiO.sub.4/2) that are spherical in shape, which has the benefit of compatibility with personal care components and the resulting personal care applications. The present disclosure also relates to methods of preparing silica particles.

A bacterial ferment obtained by a method including the following steps: (a) culturing Lactobacillus species in at least one growth medium for at least 24 hours; (b) separating the mixture via centrifugation; (c) adding lactic acid to the supernatant obtained from step b) in an amount sufficient to lower the pH value of the supernatant; (d) stabilizing the resulting mixture with the addition of at least one preservative and/or at least one multifunctional; and optionally (e) filtering the mixture to remove any final precipitation.

A bacterial ferment obtained by a method including the following steps: (a) culturing Lactobacillus species in at least one growth medium for at least 24 hours; (b) separating the mixture via centrifugation; (c) adding lactic acid to the supernatant obtained from step b) in an amount sufficient to lower the pH value of the supernatant; (d) stabilizing the resulting mixture with the addition of at least one preservative and/or at least one multifunctional; and optionally (e) filtering the mixture to remove any final precipitation.