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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.

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

Wool and hair fibers absorb moisture similarly due to their keratin structure, with the amount of non-crystalline areas affecting the moisture uptake.

Understanding hair surface properties is key for effective hair care products.

Herbal cosmetics are becoming more popular because they are safer, have fewer side effects, and offer health benefits.

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

New physical methods like electrical currents, ultrasound, and microneedles show promise for improving drug delivery through the skin.

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

The model better predicts how water-loving and fat-loving substances move through the skin by including tiny pores and hair follicle paths.

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

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.

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

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

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.

Invasomes effectively deliver drugs through the skin and have potential for improved treatments.

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

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

Liposomes could improve how skin care products work but are costly and not very stable.

Nanoparticles can be used to deliver drugs to hair follicles, potentially improving treatments for conditions like acne and alopecia, and could also be used for vaccine delivery and gene therapy.

Wound healing insights can improve regenerative medicine.

New methods like nanoparticles and microneedles show promise for better skin drug delivery, especially for hair disorders.

Using sonophoresis can make it harder for certain drug-loaded liposomes to get through the skin.

Scientists identified three genes important for processing certain brain chemicals, thyroid hormones, and medications.

Using longer PEG chains helps nanoparticles penetrate hair follicles better, improving drug delivery for conditions like alopecia.

Liposomes improve the delivery and effectiveness of cosmetic ingredients but face challenges like cost and stability.

Microemulsions could improve how drugs are delivered and absorbed in the body.

Targeting drugs to hair follicles can treat skin conditions, but reaching deep follicle areas is hard and needs more research.