Researchers at Kyushu University and Institute of Science Tokyo have developed a new computational model that can simulate the transport of oxygen by red blood cells (RBCs) through tiny blood ...

Obtaining clearer and more detailed microscopic images deep within tissue has become a rich area of research in fields ranging from adaptive optics to photodynamic therapy. Visualising biological ...

Our brain is a complex organ. Billions of nerve cells are wired in an intricate network, constantly processing signals, enabling us to recall memories or to move our bodies. Making sense of this ...

Unlike other modes of microscopy that employ sophisticated optical equipment to acquire high-resolution images, expansion microscopy enlarges biological specimens physically enabling nanoscale image ...

There is a growing demand for non-invasive insights into the complex three-dimensional subcellular dynamics within living tissues on the frontier of biological research. To achieve simultaneous ...

Until today, skin, brain, and all tissues of the human body were difficult to observe in detail with an optical microscope, since the contrast in the image was hindered by the high density of their ...

This flexibility enables the fabrication of composite structures that best replicate the physiological conditions that surround the tissue, such as mechanical properties and topographical cues. 10 Due ...

Researchers developed a large-scale, dynamic imaging technique using mesoscopic oblique plane microscopy, which can capture 3D images of entire organisms and maintain cellular resolution. A new ...

Researchers have developed a new microscopy technology called decrowding expansion pathology (dExPath) to analyze brain tissue. By pulling proteins apart with dExPath, researchers can stain proteins ...

There is a growing demand for non-invasive insights into the complex three-dimensional subcellular dynamics within living tissues at the frontier of biological research. Professor Xi Peng's group at ...