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Stiffer hydrogels better promote stem cells turning into hair follicle cells.

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

A small 3D skin model helps study how immune cells move in the skin.

The new biomaterial helps grow blood vessels and hair for skin repair.

3D-printed mesoporous scaffolds show promise for personalized drug delivery with controlled release.

Different levels of shear stress affect where cells move and gather in a 3D-printed model, helping to better understand cell behavior in blood vessels.

A single robotic system can accurately harvest and implant hair grafts, showing promise for real-world use.

A new 3D-printed hydrogel scaffold helps regenerate corneas and prevent scarring.

A new tool allows easier long-term imaging of live skin cells, helping study diseases like skin cancer.

Bioinspired polymers are promising for advanced medical treatments and tissue repair.

Virtual surgical planning improves efficiency, coordination, and precision in complex surgeries.

A new 3-D bioreactor system improves drug screening and reduces animal testing.

Researchers created a 3D-printed skin model that grew human hair when grafted onto mice by improving blood supply to the grafts.

4D scaffolds made with melt electrowriting can change shape for use in medicine.

New methods for growing skin cells can improve skin grafts by building blood vessels within them.

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

New cell sources for bone tissue engineering are promising due to easier harvesting and availability.

Standardizing and engineering organoids can improve their use in medicine and drug testing.

The new system makes hair transplants faster and more precise.

Printable templates improve hair transplant accuracy and efficiency.

3D human skin models show promise for dermatology but face challenges in standardization and cost.

A single medium, PRIME AIRLIFT, supports better human hair follicle formation in grafts.

New technologies like AI, robotics, and stem cells have made hair transplants more effective and natural-looking.

Magnetic fields help create complex 3D soft structures for biomedical use.

Researchers developed a method to grow human hair follicles using 3D-printed skin models and modified cells.

The smart bandage improved healing in diabetic mice by delivering drugs directly into wounds.

3D skin bioprinting and "BioMask" offer promising new ways to treat facial skin injuries.

The scaffold with polydopamine and bioactive glass effectively promotes bone regeneration.