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Keratin from hair binds well to gold and BMP-2, useful for bone repair.

The hair cuticle is made of tough proteins that protect the hair, but more research is needed to fully understand its structure.

Protein microarrays are highly sensitive tools useful for disease diagnosis and studying proteins.

Human hair's structure makes it tough and resistant to breaking.

Smaller mesoporous nanoparticles can improve the effectiveness of topical drugs by penetrating skin furrows.

Phytochemicals are important for food and human health.

Hair fibers have fractal patterns with properties related to the golden mean, which may affect their functionality.

Microfluidic technology improves cell spheroid creation for better drug testing and tissue engineering.

PDI helps restore over-bleached hair's strength and structure by attaching special peptides.

Peptide drugs now target hard-to-reach proteins more effectively and specifically.

The new finasteride delivery system using chitosan-based nanoniosomes shows promise for prostate cancer prevention.

Understanding monosaccharide composition can improve the development of effective medicinal plant polysaccharides.

Minoxidil reacts to nitrosation 7 times more than phenol, mainly due to its -NH₂ groups, leading to the creation of N-nitrosominoxidil.

Cysteine formation on hair indicates damage, best detected at pH 4.5.

HAIRCARECUBE TM (HCC) helps hair products work better by getting active ingredients deeper into the hair.

Hair can be damaged by daily routines, but protein-based products can protect and improve it.

CMADK reduces hair damage from bleaching and permanent waving.

Insulin-dependent diabetes alters hair's molecular structure, making it useful for studying diabetes effects.

Keratin-based hydrogels from human hair and wool are promising for wound dressings and are more eco-friendly.

Thiadiazole chitosan conjugates improve hair manageability, moisture, and protection in conditioners.

Finasteride's molecular properties and active sites were identified using computational methods.

Cells from certain embryo parts can induce head formation in another embryo, involving complex signaling pathways.

Different combinations of human hair keratins affect how hair fibers form.

Nanocomposite patches improve drug delivery through the skin, offering controlled release and fewer side effects.

DiZyme accurately predicts nanozyme activities to aid in discovering new applications.

Spanlastics can improve drug delivery by effectively penetrating biological membranes.

APIs' stability is influenced by crystalline forms, pressure, and water.

Human hair becomes weaker and stretches more easily at higher temperatures.