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The study created hair-bearing skin models that lack a key protein for skin layer attachment, limiting their use for certain skin disease research.

Hair follicle culture helps study cell interactions and effects of substances on tissue growth.

Transplanted bone marrow cells actively move, form clusters, and grow after transplantation.

Hair follicle cells and intestinal tissue can create strong, functional blood vessel replacements.

Microspheric skin organoids can be used for drug testing, identifying Minoxidil as a Wnt pathway activator.

3DEEP reveals early hair follicle stem cell formation and niche establishment before hair bulb development.

A small 3D skin model helps study how immune cells move in the skin.

Magnetic fields help create complex 3D soft structures for biomedical use.

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

A new method to study dog skin diseases using lab-grown skin cells was developed.

Scientists developed a method to grow human fetal skin and digits in a lab for 3-4 weeks, which could help study skin features and understand genetic interactions in tissue formation.

Printing human stem cells and a special matrix during surgery can help grow new skin and hair-like structures in rats.

Using adipose tissue-derived fragments improves early skin graft success.

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

Diabetic patients' stem cells make vascular grafts more prone to clots, but new methods may improve grafts.

Neonatal blood vessels rearrange and stabilize as adults, with adult vessels better at self-repair after injury.

Researchers created early-stage hair-like structures from skin cells, showing how these cells can self-organize, but more is needed for complete hair growth.

A method was developed to grow hair follicles in a lab for research on hair growth and health.

Scientists successfully grew mini hair follicles using human skin cells, which could help treat baldness.

Researchers developed a 3D skin model with its own immune and blood vessel cells to better understand skin health and disease.

Scientists have made progress in creating replacement teeth, hair, and glands that work, which could lead to new treatments for missing teeth, baldness, and dryness conditions.

Intravital imaging helps us better understand stem cells in their natural environment and could improve knowledge of organ regeneration and cancer development.

Schizophrenia risk genes may affect early brain development, contributing to the disease.

The Multi-Organ-Chip improves the growth and quality of skin and hair in the lab, potentially replacing animal testing.

SKO-derived SKP-like cells may help with hair regeneration and skin restoration.

Special astrocytes improved learning and memory in rats after a stroke.

Skin organoids can model tuberculosis infection and help test treatments.