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Human hair surface varies in wettability, showing daily and monthly patterns.

The Cell Membrane Complex in hair has both water-attracting and water-repelling layers.

Nanovesicles improve drug delivery through the skin, offering better treatment outcomes and fewer side effects.

Changing disulfide bonds in human hair affects its melting behavior and thermal stability.

Disulfide bonds affect the melting behavior of hair's crystalline structure, but hair retains some stability even after these bonds are broken.

Phosphorylation of certain parts of the PIN3 protein is crucial for its role in plant root growth and response to gravity.

The mutated hairless gene causes hair loss by acting as a new type of corepressor affecting thyroid hormone receptors.

Human and mouse TGase3 enzymes are similar but differ near the activation site, crucial for their function in skin and hair development.

Bleaching hair removes its protective top layer and exposes more hydrophilic groups, changing its chemical surface and affecting how it interacts with products.

IPM enhances skin penetration of hydrophilic drugs.

Hair follicles are important for drug delivery through the skin, but better methods are needed to understand and improve this process.

FGF9 controls which receptors it binds to through a process where two FGF9 molecules join, and changes in FGF9 can lead to incorrect receptor activation.

Human hair's ability to get wet is complex and can change with treatments, damage, and environment.

A certain surfactant sticks to human hair, making it change from water-repelling to water-attracting, which could help in hair conditioning.

Niosomes are a promising and effective way to deliver drugs through the skin.

Human hair grows better in a special gel that mimics skin.

Serum formulations were better at delivering molecules to the hair bulb than nanoparticles.

Water and fatty acids affect hair's surface differently based on hair damage, and models can help understand hair-cosmetic interactions.

Hair follicles significantly increase the speed and amount of caffeine absorbed through the skin.

Niosomes are promising for skin drug delivery, offering benefits like improved drug penetration and stability.

The hair follicle pathway significantly affects how easily water-loving chemicals pass through the skin.

Hair fibers interact through classical forces, which are influenced by treatments and products, important for hair care and other applications.

Liposomal systems show promise for delivering drugs through the skin but face challenges like high costs and stability issues.

Hair follicles offer promising targets for delivering drugs to treat hair and skin conditions.

Hair growth is controlled by specific gene clusters and proteins, and cysteine affects hair gene expression in sheep.

Massage increases how deep both rigid and flexible liposomes can go into skin, with flexible ones going deeper, and covering the skin (occlusion) helps rigid ones more.

Surface and internal treatments can help prevent hair lipid loss during washing.

Lipid-coated silica nanoparticles penetrate human skin more deeply than bare silica nanoparticles.

Hair's internal fibers are arranged in a pattern that doesn't let much water in, and treatments like oils and heat change how much water hair can absorb.

Chitosan-coated spironolactone nano carriers effectively treat acne without side effects.