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Disulfide bonds are crucial for hair structure during keratinization.

Oxidation changes the structure of hair protein filaments, causing them to compact and rearrange.

Keratin structure changes during keratinization, but the exact model remains uncertain.

Hair keratins evolved from ancient proteins, diversifying through gene changes, crucial for forming claws and later hair in mammals.

Disulfide bonds in keratin fibers break more easily under stress, especially when wet, affecting fiber strength.

Sheep hair follicle transglutaminases are calcium-dependent.

Juglone from walnut extracts may help repair damaged hair.

Water-soluble wool keratin can protect human hair from damage during treatments.

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

Different keratin types have unique amino acid patterns that are evolutionarily conserved.

The effectiveness of reducing agents on hair fibers depends on their electrode potentials.

Cysteines in wool fibers are accessible and form important disulfide bonds.

The 3D structure of a key hair protein was modeled, revealing specific helical structures and stabilization features.

New hair perming method using tyrosine is gentler and can be done with a blow-dryer.

The genetic variation in the KAP13-3 gene may affect cashmere fiber traits in Liaoning goats.

Nucleophilic reagents break down hair keratin, forming more lanthionine and lysinoalanine than in wool.

Microsporum gypseum fungus breaks down keratin in hair by digesting it enzymatically, starting with less keratinized parts.

The research explains how a human enzyme binds and processes its substrate, which could relate to its role in biological functions and hair loss.

Alkylated keratin from human hair can help deliver growth factors for bone healing.

Keratin hydrogels can be customized for better tissue healing.

The S250C variant in a gene may cause autoimmunity and immunodeficiency by impairing protein function.

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

Mutations in the enzyme don't significantly change how it binds to its specific substances.

S100A3 protein is crucial for hair shaft formation in mice.

Cysteine-rich keratins evolved independently in mammals, reptiles, and birds for hard skin structures like hair, claws, and feathers.

Disrupted cysteine metabolism may cause hair breakage in Alopecia Areata, suggesting potential treatments like N-acetylcysteine.

Cysteine strengthens hair, and glutamine fuels hair growth.

Sheep wool follicles absorb different amino acids at various rates and locations, which could affect wool growth based on diet and genetics.

Thioglycolic acid and L-cysteine change hair structure differently during perms, affecting hair strength and curling efficiency.

N-acetyl-cysteine shows promise in treating various diseases and may improve skin and hair conditions, but more research is needed on dosages and long-term effects.