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Magnetic nanovesicles from stem cells can improve hair growth by staying in the skin longer.

Scientists made human hair magnetic by coating it with special nanoparticles.

Merkel cells may have roles in sensing magnetic fields, creating fingerprints, Reiki energy healing, passing on environmental information to offspring, and influencing hair shape.

The conclusion is that a new method combining magnetic tweezers and traction force microscopy may help understand skin cell interactions and diseases.

Human hair has bipolar electrical charges because of a gap in the hair follicle's electromagnetic field.

Human hair has bipolar electrical charges due to gaps in the hair follicle's electromagnetic fields.

Researchers developed a new type of memory using antiferromagnets that is stable, not disrupted by magnets, and works at room temperature.

The document concludes that while there are promising methods to control CRISPR/Cas9 gene editing, more research is needed to overcome challenges related to safety and effectiveness for clinical use.

CRISPR/Cas9 has improved precision and control but still faces clinical challenges.

MRI can effectively image skin structures noninvasively.

Researchers made minoxidil efficiently using cobalt ferrite nanoparticles as a reusable catalyst.

A pulsed electrical field safely and effectively increased hair growth.

Rice bran extract and low-frequency electromagnetic fields together may help treat vitiligo and white hair.

Exposure to 50 Hz electromagnetic fields may help mice grow hair faster.

Mobile phone radiation may cause DNA damage in human ear hair follicle cells.

Low-frequency electromagnetic fields help regenerate hair follicles using a mix of skin cells.

The compound (NH4)2Mn0.17Cu0.83Cl4.2H₂O has a specific structure, shows weak magnetism at low temperatures, and undergoes phase changes at high temperatures.

The combined therapy significantly increased hair density and was safe for treating hair loss.

Low-frequency electromagnetic fields can boost molecules related to hair growth in human skin cells.

Biomaterials combined with stem cells show promise for improving tissue repair and medical treatments.

Photobiomodulation helps reduce pain, lessen inflammation, heal wounds, and can be used in skin treatments. It also boosts hair growth in women with hair loss and may help fight microbes and prevent respiratory issues in COVID-19.

Microencapsulation helps protect and track therapeutic cells, showing promise for treating various diseases, but more work is needed to improve the technology.

Low-level laser therapy is the most supported treatment for hair loss, but other methods show promise.

Surgical robots have improved but still can't perform tasks or make decisions on their own.

The new hydrogel dressing with natural molecules helps heal wounds faster and improves skin repair.

3D bioprinting in plastic surgery could lead to personalized grafts and fewer complications.

New CRISPR/Cas9 variants and nanotechnology-based delivery methods are improving cancer treatment, but choosing the best variant and overcoming certain limitations remain challenges.

The document concludes that both internal stem cell factors and external influences like the environment and hormones affect hair loss and aging, with potential treatments focusing on these areas.

Scientists created a lab-grown hair follicle model that behaves like real hair and could improve hair loss treatment research.

New nanofiber technology improves wound healing by supporting cell growth and delivering treatments directly to the wound.