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A 3D cell model can rejuvenate stem cells to improve wound healing.

Different types of resting melanocyte stem cells have unique characteristics and vary in their potential to become other cells.

3D cell-derived matrices improve tissue regeneration and disease modeling.

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

Murine epidermal stem cells can develop into skin structures without rejection when implanted.

Single-cell transcriptomics reveals detailed cellular diversity and key pathways in tissue regeneration.

Researchers created long-lasting, diverse skin organoids from mouse hair follicle stem cells, useful for studying skin.

Researchers created hair-inducing human cell clusters using a 3D culture method.

Wharton's jelly stem cells show diverse traits and functions.

A 3D co-culture model improved stem cell function and wound healing.

Bone-forming cells grow well in 3D polymer scaffolds with 35 µm pores.

Using Matrigel with stem cells improves tissue healing.

Scientists developed a new way to create skin-like structures from stem cells using a special 3D gel and a device that improves cell organization and increases hair growth.

New methods have greatly improved our understanding of stem cell behavior and roles in the body.

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

Researchers successfully grew hair follicle stem cells from mice and humans, which could be useful for tissue engineering and regenerative medicine.

Alpha 6 + /MHCI - cells have stem cell traits and are similar to mouse hair follicle stem cells.

New cell sources for bone tissue engineering are promising due to easier harvesting and availability.

The method increases stem-like cells for better skin regeneration.

3D cell cultures produce extracellular vesicles similar to those in the body.

Human skin cells can be turned into versatile stem cells, but their ability to do so decreases with repeated use.

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

Stem cells can be used to create long-lasting skin cells for treating pigment disorders.

Different types of stem cells exist within individual skin layers, and they can adapt to damage, transplantation, or tumor growth. These cells are regulated by their environment and genetic factors. Tumor growth is driven by expanding, genetically altered cells, not long-lived mutant stem cells. There's evidence of cancer stem cells in skin tumors. Other cells, bacteria, and genetic factors help maintain balance and contribute to disease progression. A method for growing mini organs from single cells has been developed.

Hair-follicle stem cells can become neurons.

Nanofat with stem cells is promising for treating hair loss, scars, and skin rejuvenation.

Stem cells are more dynamic and adaptable than previously believed.