Lifeboat Foundation: Safeguarding Humanity
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Quantum communication is a strange beast, but one of the weirdest proposed forms of it is called counterfactual communication — a type of quantum communication where no particles travel between two recipients.

Theoretical physicists have long proposed that such a form of communication would be possible, but in 2017, for the first time, researchers were able to experimentally achieve it — transferring a black and white bitmap image from one location to another without sending any physical particles.

If that sounds a little too out-there for you, don’t worry, this is quantum mechanics, after all. It’s meant to be complicated. But once you break it down, counterfactual quantum communication actually isn’t as bizarre as it sounds.

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In air-breathing vertebrates, the circulatory and pulmonary systems contain separate networks of channels that intertwine but do not intersect with each other. Recreating such structures within cell-compatible materials has been a major challenge; even a single vasculature system can be a burden to create. Grigoryan et al. show that natural and synthetic food dyes can be used as photoabsorbers that enable stereolithographic production of hydrogels containing intricate and functional vascular architectures. Using this approach, they demonstrate functional vascular topologies for studies of fluid mixers, valves, intervascular transport, nutrient delivery, and host engraftment.

Science, this issue p. 458

Solid organs transport fluids through distinct vascular networks that are biophysically and biochemically entangled, creating complex three-dimensional (3D) transport regimes that have remained difficult to produce and study. We establish intravascular and multivascular design freedoms with photopolymerizable hydrogels by using food dye additives as biocompatible yet potent photoabsorbers for projection stereolithography. We demonstrate monolithic transparent hydrogels, produced in minutes, comprising efficient intravascular 3D fluid mixers and functional bicuspid valves. We further elaborate entangled vascular networks from space-filling mathematical topologies and explore the oxygenation and flow of human red blood cells during tidal ventilation and distension of a proximate airway. In addition, we deploy structured biodegradable hydrogel carriers in a rodent model of chronic liver injury to highlight the potential translational utility of this materials innovation.

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I’m not going to venture a guess as to what percentage of the population regularly cracks their necks, but I have to imagine it’s pretty high. A quick bend left and right is all it normally takes to produce the satisfying “pop,” and for most of us it seems like little more than a harmless habit.

Apparently that’s not the case, and the story of one 28-year-old Oklahoma man is a strong reminder that toying with one’s own spine can be a dangerous thing. A simple neck crack is all it took to turn Josh Hader’s life upside down, and he knew within moments that he had accidentally done some serious damage.

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As we dive into the brave new world of gene editing, CRISPR technologies are undoubtedly becoming increasingly precise, but alongside enhanced precision is also the necessity for developing ways to inhibit or block the process – an anti-CRISPR molecule, if you will. New work from the Broad Institute and Brigham and Women’s Hospital has presented a study that homes in on small molecules that may have the ability to safely block the CRISPR gene editing process.

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