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Nucleic acids trigger chemokine production in skin cells, affecting skin inflammation.

Researchers developed a new way to measure gene activity in single hair follicles and found that a specific gene's activity changes with different amounts and times of treatment.

Ionizable lipid nanoparticles are the best for delivering gene-editing therapies.

ePUKs could be valuable for regenerative medicine due to their wound healing abilities.

The enzyme from Bacillus cereus can be used in detergents and leather processing.

The new ddPCR method reliably detects unwanted viruses in CAR-T cell products, ensuring their safety for patients.

PCR genotyping in cre-loxP mice can be inaccurate due to unintended gene deletions in non-target tissues.

MsPG3 protein gathers at root hair tips, aiding growth.

The KRTAP11-1 gene promoter is crucial for specific expression in sheep wool cortex.

Researchers developed a method to label and study human hair follicle stem cells using a fluorescent protein.

A new model helps study acne and test treatments.

The CUBIC protocol allows detailed 3D visualization of proteins in mouse skin biopsies.

Truncated hHb1 keratin may play a role in breast cancer cell transformation.

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

Keratins K6 and K16 are expressed more freely in regenerating mouse skin than K1 and K10.

Cutaneous gene therapy could become a viable treatment for skin and hair disorders with improved vector development and gene expression control.

Hair cells grown in a lab showed specific hair proteins.

A cluster of sulfur-rich hair protein genes was found on chromosome 17.

Transfected cells with VEGF and FGF2 genes improve skin wound healing by enhancing blood flow and regeneration.

The B2 genes are crucial for hair growth in rats.

K15 gene is mainly active in the basal layers of hair follicles and epithelia, aiding early skin cell development.

The research suggests that a specific skin gene can be controlled by signals within and between cells and is wrongly activated in certain skin diseases.

Newly designed proteins can effectively degrade specific proteins in cells, offering a promising alternative for targeted protein degradation.

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

Nanotechnology in dermatology shows promise for better drug delivery and treatment effectiveness but requires more safety research.

Tannin effectively inhibits and degrades biofilms from certain bacteria and fungi.

New technologies help us better understand how skin microbes affect skin diseases.