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3D bioprinting shows promise for creating skin substitutes, but standardized methods are needed for clinical use.

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.

Reprogramming 3D environments can create hair follicles in the lab.

A new 3D culture system helps grow and study mouse skin stem cells for a long time.

The conclusion is that certain chemicals from Bacillus subtilis help improve plant root growth through a hormone-related process.

Biomimetic cell membrane-coated scaffolds significantly enhance tissue regeneration by mimicking natural cellular environments.

A plant protein biostimulant improved growth, photosynthesis, and nutrient content in hydroponically grown basil.

Zebrafish skin regeneration relies on cell behaviors and reactive oxygen species, with antioxidants reducing and hydrogen peroxide increasing regeneration.

A wearable patch speeds up healing of chronic wounds by monitoring and treating them.

Bacillus sp. TC5 products help hair regrowth and improve skin drug absorption.

PBX1 helps hair stem cells grow and change by turning on certain cell signals and preventing cell death, which may be useful for hair regrowth treatments.

3D cell cultures produce extracellular vesicles similar to those in the body.

Different types of skin cells create unique support structures that can affect skin cell growth and could help in skin repair.

RCS-01 therapy is safe and may improve skin structure by affecting gene expression.

The model helps test drugs for clubfoot fibrosis by mimicking cell environments and shows minoxidil reduces harmful collagen links.

Sequential monopolar-bipolar radiofrequency improves skin regeneration and quality better than monopolar alone.

Scientists made a mouse that shows how a specific protein in the skin changes and affects hair growth and shape.

The hydrogel helps bone growth and healing in jaw and facial defects.

Pen-type microwells are best for forming hair follicle germ structures.

Bioprinting could greatly improve health outcomes but faces challenges like material choice and ensuring long-term survival of printed tissues.

The study developed a tool to predict how gut microbes process foods and drugs, showing that similar compounds often share metabolic pathways and effects.

Hydra can help understand human hair follicle microbiomes and develop new skin disease therapies.

Spiny mice have resilient, large mitochondria that help them regenerate tissue.

New materials help control stem cell growth and specialization for medical applications.

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

Microfluidic models improve testing for aging, wound healing, and oral tissue, reducing animal testing.

Skin-on-a-chip devices better mimic human skin for research.

The new device improves human hair follicle cell growth and differentiation.

Organotypic culture systems can grow skin tissues that mimic real skin functions and are useful for skin disease and hair growth research, but they don't fully replicate skin complexity.