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Powerhouse-pruning protein may also help make energy rapidly available for growing new blood vessels
A protein that helps keep our cell powerhouses working at a premium appears to also help make energy rapidly available when it's time to make new blood vessels. 
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The 3D printed blood vessel was not rejected by the immune system because it came from the subject’s own body.
BigField GEG Tech's insight:
Chinese scientists have successfully implanted a 3D printed blood vessel into rhesus monkeys, which could pave the way for printing human organs for transplants. An estimated 1.8 billion people affected with cardiovascular disease can benefit from this medical breakthrough.
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NIH-funded pre-clinical study links gut microbes and the immune system to a genetic disorder that can cause stroke and seizures
BigField GEG Tech's insight:
A study in mice and humans suggests that bacteria in the gut can influence the structure of the brain’s blood vessels, and may be responsible for producing malformations that can lead to stroke or epilepsy. The research, published in Nature, adds to an emerging picture that connects intestinal microbes and disorders of the nervous system. The study was funded by the National Institute of Neurological Disorders and Stroke (NINDS), a part of the National Institutes of Health (NIH).
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‘Groundbreaking’ move marks step towards mass printing of organs for human transplant
BigField GEG Tech's insight:
Chinese scientists have successfully implanted 3D printed blood vessels made from stem cells into rhesus monkeys, marking an important step towards printing blood vessels and other organs for human transplants.
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Ushio-Fukai and Dr. Tohru Fukai reported in Nature Cell Biology that ROS rapidly modifies CTR1, a cell surface receptor that usually allows essential mineral copper to enter the interior, where its tasks include aiding angiogenesis. Modification of CTR1 prompts it to bind to the VEGF receptor, VEGFR2, also on the cell surface, and the united pair dives inside. This movement enables the sustained VEGFR2 signaling that is essential for making new blood vessels. The researchers also have evidence that Drp1 is also modified by ROS, prompting it to move from a passive state in the fluid part of the cell, or cytosol, to the mitochondria where it still promotes fission, which also produces the powerful hydrogen peroxide ROS. She says that active mitochondria are high users of oxygen and therefore, like NADPH oxidase, high producers of ROS in endothelial cells. The researchers showed that the ROS generated by mitochondria in turn activates AMPK, a key enzyme for regulating energy levels in cells and known to use glucose to rapidly generate enough energy to support important biological work such as making new blood vessels.