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Tissue-engineered grafts can help regenerate hair follicles.

Using Matrigel with stem cells improves tissue healing.

A detailed 3D model of human skin was created to help develop artificial skin.

Biomimetic scaffolds are better than traditional methods for growing cells and could help regenerate various tissues.

3D bioprinting holds promise for medicine but needs more research and clear regulations.

The method allows detailed observation of hair tissue structures.

Hydrogels are crucial for 3D bioprinting in tissue engineering.

The method effectively analyzes skin tissue changes, especially in the arrector pili muscle and nerve fibers with hair follicles.

Rat vibrissae have sensory terminals with specific structures that help detect hair movements.

Xeno-free three-dimensional stem cell masses are safe and effective for improving blood flow and tissue repair in limb ischemia.

Modified rat stem cells on a special scaffold improved blood vessel formation and wound healing in skin substitutes.

Using Wharton's jelly stem cells and scaffolds can help regenerate skin and hair.

The new therapy effectively targets brain tumors while minimizing damage to healthy tissue.

Scientists made structures that look like human hair follicles using stem cells, which could help grow hair without using actual human tissue.

Histocultures help personalize cancer treatments, study hair growth, and explore immune responses.

Scientists can now grow hair-like structures in a lab using special 3D culture systems, which could potentially help people with hair loss or severe burns.

Bioengineered skin models help reduce animal testing and advance research in cosmetics and skin disease.

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

New biofabrication technologies could lead to treatments for hair loss.

CD133+ cells are crucial for hair growth.

3D imaging of skin biopsies offers better accuracy but is time-consuming and can't clear melanin.

3D models and organoids improve liposarcoma research and therapy development.

3D bioprinting shows promise for better skin regeneration by creating structures similar to natural skin.

3D-printed mesoporous scaffolds show promise for personalized drug delivery with controlled release.

Neural organoids show promise for future CNS disease treatments.

Mechanoreceptors convert physical touch into electrical signals through specialized nerve structures.

Using a collagen sponge scaffold helps stem cells become more like skin cells.

3D bioprinted lung cancer models in a mouse-like structure offer a better way to study radiation effects without using live animals.

3D scaffolds are crucial for making lab-grown meat taste and feel like real meat.

The study concluded that changing the culture conditions can cause sika deer skin cells to switch from a flat to a 3D pattern, which is important for creating hair follicles.