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

A new device, IVL-PPF Microsphere®, was created to deliver a hair loss drug for up to 3 months with one injection, potentially replacing daily pills.

Organoid technology is improving personalized medicine by better predicting drug responses and treatments.

New bio-ink can print complex tissues and organs.

A 3D skin model helps study wound healing better than traditional methods.

Advanced human skin models improve drug development and could replace animal testing.

Microfluidic technology improves cell spheroid creation for better drug testing and tissue engineering.

Microtechnology methods improve organoid production for medical research.

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

Perhexiline can effectively target ovarian cancer cells left after treatment.

Organoids can revolutionize medicine by modeling diseases and aiding in personalized treatments.

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

Small extracellular vesicles from stem and immune cells show promise for treating various diseases but face challenges in clinical use.

The Multi-Organ-Chip improves the growth and quality of skin and hair in the lab, potentially replacing animal testing.

3D models and organoids improve liposarcoma research and therapy development.

Advancements in cultured models improve understanding and treatment of gallbladder cancer.

PINK1 is important for controlling gut immune responses linked to early Parkinson's disease.

Forensic DNA phenotyping faces challenges due to inconsistent terminology, limited genetic understanding, and debates over technology and models.

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.

Keratinocyte stem cells are crucial for skin renewal and have potential in wound healing and tissue regeneration.

Asia has made significant progress in tissue engineering and regenerative medicine, but wider clinical use requires more development.

Bioengineered skin models help reduce animal testing and advance research in cosmetics and skin disease.

Microfluidics can create precise, efficient delivery systems for food and cosmetics, but scaling up is challenging.

The model shows that filament flexibility and amino acid differences affect how fast intermediate filament proteins assemble.

The Spherical Skin Model improves drug and cosmetic testing by accurately mimicking human skin for efficient compound screening.

Root hair growth slows under force, confirming a model of cell wall mechanics.

A new method using a microfluidic device can prepare hair follicle germs efficiently for potential use in hair loss treatments.

Innovative methods are reducing animal testing and improving biomedical research.

In vitro skin models are improving but still need more innovation to fully replicate human skin.

Bioprinting is improving skin models for better testing of skin diseases without using animals.