A cube of healthy bone is anything but solid. Inside it, countless tiny channels carry fluid and help cells move, feed, and ...

Researchers in Sweden have engineered a cell-free cartilage scaffold that can guide the body to rebuild damaged bone. By removing the cells but preserving the structure and natural growth signals, the ...

Human cells can possibly sense far beyond surfaces they touch, with cancer cells being able to probe about 10 microns ahead, ...

Rotator cuff tears often heal with stiff, dysfunctional scar tissue, limiting recovery. A new study reveals why tendon ...

Researchers in EPFL’s School of Engineering have now created a room‑temperature 3D printing process that uses enzymes to rapidly mineralise HA‑based scaffolds.

Researchers reveal TGF-β1 promotes scar tissue formation and restricts recovery CHINA, March 19, 2026 /EINPresswire.com/ — Fibrotic scarring is a major challenge in recovery post spinal cord injury ...

Researchers at EPFL 3D printed porous bone scaffolds to support bone regeneration. Learn about the process here.

A new study reveals that human cells, including cancer cells, possess the ability to sense their environment far beyond their immediate point of contact, potentially influencing cell movement and ...

Spinal cord injury (SCI) often leads to long-term loss of motor and sensory function, with limited available treatment options to restore the lost ...

A bone-like composite developed at EPFL uses naturally occurring enzymes to accelerate mineralization through an ...

The arterial vasculature is the second most frequently calcified structure in the human body after the skeleton. Calcification of the aorta and aortic valves occurs in most individuals in westernized ...