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Sheep cells were successfully modified to include a spider silk protein gene.

Polyelectrolytes can improve cell surfaces for better medical applications.

The model helps understand scar contraction and develop new treatments.

ELIP-based CRISPR delivery improves heart disease gene editing but needs more testing.

The research found a way to develop hair growth materials by targeting a specific signaling pathway.

3D bioprinting can effectively regenerate hair follicles and skin tissue in wounds.

A new neural network helps identify key regulators in cell changes, aiding in understanding diseases and finding new treatments.

Fish cell spheroids are a promising tool for replicating real-life conditions in research.

The study developed mouse models to help research and treat hair and sweat gland issues.

3D bioprinting advancements are improving skin regeneration for wound healing and personalized reconstruction.

Improving the environment and cell interactions is key for creating human hair in the lab.

New technologies show promise in healing wounds, treating cancer, autoimmune diseases, and genetic disorders.

Biomimetic biomaterials can improve skin healing by mimicking natural tissue and reducing immune rejection.

Scientists used stem cells to create a model of the skin disease Epidermolysis Bullosa simplex, which helped them understand its molecular mechanisms and could aid in finding treatments.

Biomaterials can improve non-viral gene delivery by enhancing DNA uptake and reducing toxicity.

The new GelMet hydrogel can effectively support skin cell growth for tissue engineering.

Layer-by-Layer self-assembly is promising for biomedical uses like tissue engineering and cell therapy, but challenges remain in material safety and process optimization.

A new method was developed to grow and maintain human hair follicle stem cells for hair reconstruction.

The new microneedle method delivers hair loss treatment more effectively by enhancing growth pathways.

Animal models help study psoriasis but have limitations and don't fully mimic the human disease.

Newly designed proteins can effectively degrade specific proteins in cells, offering a potential new therapy method.

Regulating keratinocyte growth in engineered skin can improve wound healing.

The review says that stem cells are beneficial for making skin replacements.

Key genes can rewire networks, changing skin appendage types.

Scientists created cell lines to study a genetic skin disorder using CRISPR technology.

Tissue-engineered skin can support hair growth after grafting, especially with mouse-derived dermis.

Gene therapy shows promise for enhancing physical traits but faces ethical, safety, and regulatory challenges.

Non-viral vectors show promise for safe and effective CRISPR/Cas9 gene editing in treating diseases.

Overexpressing ornithine decarboxylase and v-Ha-ras in keratinocytes leads to invasiveness and malignancy.