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The 3D skin model mimics pemphigus vulgaris and helps test treatments.

The nanofibers effectively treated infected diabetic wounds by killing bacteria and aiding wound healing without toxicity.

A new 3D-printed microscope stage makes long-term imaging of live tissue easier and more accessible.

Jackfruit leaf-derived silver nanoparticles in gel form effectively fight infections, especially against E. coli.

The nanoplatform helps heal wounds by balancing bacteria-killing and inflammation-reducing functions.

The DNA hydrogel helps heal diabetic wounds by absorbing fluids, warming, sticking to tissue, killing bacteria, and aiding tissue and hair regrowth.

Transglutaminases work through a ping-pong mechanism, and human plasma and platelet transglutaminases have similar catalytic subunits.

The hydrogel with silver and mangiferin helps heal wounds by killing bacteria and aiding skin and tissue repair.

Bacterial augmentation improves hair composting and nutrient availability.

Genetic changes in mice help understand skin and hair disorders, aiding treatment development for acne and hair loss.

The study created a mouse model to mimic degenerative diseases for testing tissue repair and new therapies.

Researchers found a new way to isolate sweat glands from the scalp for study and culture.

Advances in mechanobiology and immunology could lead to scarless wound healing.

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

The new nanocomposite films are stronger, protect against UV, speed up wound healing, and are antibacterial without being toxic.

The hydrogel helps heal infected wounds by lowering pH, reducing bacteria, and promoting cell growth.

A new method was developed to efficiently grow skin hair follicles from stem cells, potentially aiding alopecia treatment.

A fungal enzyme was used to make compounds more soluble, aiding drug discovery and crop protection.

The study created hair-bearing skin models that lack a key protein for skin layer attachment, limiting their use for certain skin disease research.

Scientists can mimic hair disorders by altering genes in lab-grown human hair follicles, but these follicles lack some features of natural ones.

Cytokeratin 19 and cytokeratin 15 are key markers for monitoring the quality and self-renewing potential of engineered skin.

Skin bacteria, specifically Streptococcus and Staphylococcus, help in hair regrowth after skin injury and speed up wound healing.

Bio-degradable polymers can replace petroleum plastics using eco-friendly methods for a sustainable future.

Microencapsulation helps protect and track therapeutic cells, showing promise for treating various diseases, but more work is needed to improve the technology.

Bone marrow stem cells from Guizhou miniature pigs can grow well and become different cell types, useful for tissue engineering.

Organoids and hair-on-chip technologies show promise for hair regeneration but face clinical challenges.

Precise cell manipulation technologies are advancing but still face challenges in improving accuracy for medical use.

Certain bacteria can boost lentil growth and improve soil used for farming.

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