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Certain human skin cells marked by CD44 and ALDH are rich in stem cells capable of long-term skin renewal.

Conditioned media from mesenchymal stem cells show promise for tissue repair and disease treatment, but more research is needed on their safety and effectiveness.

The conclusion is that the cornea has two types of stem cells, with Lrig1+ cells being key for renewal in aging corneas, independent of CD44.

The niche environment controls stem cell behavior and plasticity, which is important for tissue health and repair.

Wnt proteins from certain skin cells are crucial for normal hair growth and renewal.

The document concludes that stem cell inactivity is actively controlled and important for tissue repair and balance.

Planarian regeneration begins with a specific gene activation caused by injury, essential for healing and tissue regrowth.

Low-level laser therapy may help stem cells grow and function better, aiding in healing and tissue repair.

Hair growth phase and certain genes can speed up wound healing, while an inflammatory mediator can slow down new hair growth after a wound. Understanding these factors can improve tissue regeneration during wound healing.

Certain transcription factors are key in controlling skin stem cell behavior and could impact future treatments for skin repair and hair loss.

TGF-β signaling is crucial for stem cell maintenance, differentiation, and has implications for cancer treatment.

The method allows for 3D tracking of hair follicle stem cells and shows they can regenerate hair for up to 180 days.

Super-enhancers controlled by pioneer factors like SOX9 are crucial for stem cell adaptability and identity.

Researchers isolated a new type of stem cell from mouse skin that can renew itself and turn into multiple cell types.

Skin stem cells are maintained by signals from nearby cells and vary in their ability to renew and mature.

Stem cell therapies show promise for treating various diseases but face challenges in clinical use and require better monitoring techniques.

Dental pulp stem cells are better for tissue repair, while fat tissue stem cells may be more suited for wound healing and hair growth.

Stem cell niches support, regulate, and coordinate stem cell functions.

The conclusion is that hair growth can be improved by activating hair cycles, changing the surrounding environment, healing wounds to create new hair follicles, and using stem cell technology.

Mesenchymal stem cells help improve wound healing by reducing inflammation and promoting skin cell growth and movement.

Radiation mainly affects keratinocyte stem cells, not melanocyte stem cells, causing hair to gray.

Coating surfaces with human hair keratin improves the growth and consistency of important stem cells for medical use.

Small molecule IM boosts hair growth by changing stem cell metabolism.

The conclusion is that skin and hair patterns are formed by a mix of cell activities, molecular signals, and environmental factors.

3D bioprinting could improve skin repair and treat conditions like vitiligo and alopecia by precisely placing cells.

NFIC helps rat dental cells grow and turn into bone-like cells.

New materials help control stem cell growth and specialization for medical applications.

Temporary ROS production in cultured human hair follicles promotes growth and stem cell activation.

Adult stem cells with Tp63 can form hair and skin cells when placed in new skin, showing they have hidden abilities for skin repair.

Hair follicle stem cells can change their role to ensure proper hair development.