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Protein composition greatly affects the function of keratin biomaterials.

Human hair movement is affected by its inner structure and chemical treatments.

Biomagnetic forces can deform red blood cells, not just mechanical factors.

Keratose, derived from human hair, is a non-toxic biomaterial good for tissue regeneration and integrates well with body tissues.

Photobiomodulation is effective and safe for healing injuries and improving appearance.

Biomagnetic forces can deform red blood cells.

New technologies help us understand how the body reacts to medical implants, which can improve implant performance.

The research improved understanding of hair and skin properties across different ethnicities and conditions.

Premature infants have less elastic hair than full-term infants.

Cell growth improved the strength of 3D bioprinted structures.

Bioactive inorganic particles-based biomaterials show promise for improving skin wound healing.

New techniques can record electromagnetic fields in hair follicles for potential medical use.

Fluid viscosity affects fracture design and proppant placement in hydraulic fracturing.

The new method improves bone repair by enhancing cell loading and stability in bioprinted scaffolds.

Human hair and skin friction vary by ethnicity, hair type, and environmental conditions.

Hair cuticles remain stable and resilient under stress due to strong protein content and crosslinking.

Human hair's strength and flexibility vary by ethnicity, damage, and treatment.

Mechanical forces are crucial for hair regeneration in skin organoids.

Kinematic alignment in knee surgery often requires smaller femoral components than mechanical alignment.

Water makes hair more flexible, especially the outer layer.

Murine skin wounds become less stiff over time as they heal.

Polycaprolactone and barium titanate composites show promise for use in biomedical applications.

The method effectively measures hair elasticity and could be useful in forensics.

The active ingredient improves the strength of damaged hair fibers.

Gsdma3 affects hair growth by controlling Wnt5a, which influences hair cell development.

Mice with a Gsdma3 gene mutation have thicker skin and longer hair follicle openings due to increased β-catenin levels.

A protein called sFRP4 from skin cells stops the development of pigment-producing cells in hair.

Bleaching and combing damage hair's surface and mechanical properties.