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Engineered vesicles deliver mitochondria to improve diabetic wound healing.

Zebrafish are useful for studying and developing treatments for human skin diseases.

The experiment successfully created a 3D model of a rat lung using a natural scaffold.

A new hydrogel made from human hair keratin can help regenerate skin and fight bacteria.

The Megsin-Cre transgene is a new tool for genetic manipulation in the skin and upper digestive tract.

Scientists created a 3D skin model that shows typical signs of aging, which can help in aging research.

The hydrogel helps wounds heal better by reducing inflammation and promoting skin regeneration.

Oncogenic melanocyte stem cells can develop into melanoma similar to human cases.

Combining 3D bioprinting and single-cell RNA sequencing improves skin regeneration.

Combining biochemical, immune, and mechanical signals can improve skin regeneration.

The engineered yeast strain BLYAS can quickly and sensitively detect androgenic chemicals.

The technique allowed noninvasive tracking of hair stem cell survival and growth, showing potential for hair loss research.

Improved understanding of stem cell mechanisms can enhance skin tissue engineering.

Scientists created a cell model to study and find treatments for a skin disease called RDEB.

Cell-based screening methods are useful and cost-effective for drug discovery but have pros and cons.

Smart delivery methods for CRISPR gene editing are crucial for clinical success.

Fluorescent proteins help visualize and understand tumor blood vessel growth.

Genetically modified stem cells from human hair follicles can lower blood sugar and increase survival in diabetic mice.

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.

Integrating biological networks improves drug repurposing and ADR prediction.

The method could grow hair in lab settings without using animals.

A specific gene region can control targeted and responsive gene expression in mice, useful for skin disorder treatments.

3D skin bioprinting has advanced but still faces challenges like safety and the need for better integration with sensors.

Mouse models help target specific genes in lymphatic cells for research.

Engineered exosomes with EGF and FGF improve hair growth in mice with hair loss.

Different scaffold patterns improve wound healing and immune response in mouse skin, with aligned patterns being particularly effective.

Mutations in certain skin proteins cause severe skin issues, while others have limited effects, highlighting the need to understand these proteins for better treatments.

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

3D skin models better mimic human skin and melanoma progression than older methods.

New technologies help us understand how the body reacts to medical implants, which can improve implant performance.