An anonymous reader sends this story about medical research in zero-gravity environments. Many earth-based treatments need to be adapted for use in space, and anatomical behaviors can change in subtle and unpredictable ways as well. This research aims to protect astronauts and future generations of space-goers from conditions that are easily treatable on the ground. The ultrasound machine the students are testing would be well suited for space missions. It is light and compact, requires very little medical training to use, and the probe can stay in the body for 72 hours at a time. But the technology has only ever been used on Earth, and no one knows whether it would function correctly in zero gravity. The most significant concern is that microgravity will cause the probe to drift out of position. The team's mentor, cardiac surgeon and space medicine specialist Peter Lee, tells me that an ultrasound probe that sits in the esophagus is an ideal diagnostic tool for extended spaceflights. "If an astronaut far from Earth were to have a cardiovascular event, or for some reason became incapacitated and had to be on a ventilator, there's no imaging currently available [in space] that provides continuous images of the heart," he says. "You can use [external] ultrasound, but the technician has to be there the whole time to hold it on the chest."

KentuckyFC writes: In the early hours of the morning on 24 February 1987, a neutrino detector deep beneath Mont Blanc in northern Italy picked up a sudden burst of neutrinos. Three hours later, neutrino detectors at two other locations picked up a second burst. These turned out to have been produced by the collapse of the core of a star in the Large Magellanic Cloud that orbits our galaxy. And sure enough, some 4.7 hours after this, astronomers noticed the tell-tale brightening of a blue supergiant in that region, as it became a supernova, now known as SN1987a. But why the delay of 7.7 hours from the first burst of neutrinos to the arrival of the photons? Astrophysicists soon realized that since neutrinos rarely interact with ordinary matter, they can escape from the star's core immediately. By contrast, photons have to diffuse through the star, a process that would have delayed them by about 3 hours. That accounts for some of the delay but what of the rest? Now one physicist has the answer: the speed of light through space requires a correction.

An anonymous reader writes: National Geographic has a detailed article about efforts underway to search for life in the oceans of Europa, which are buried beneath miles of ice. A first mission would have a spacecraft orbit just 16 miles over the moon's surface, analyzing the material ejected from the moon, measuring salinity, and sniffing out its chemical makeup. A later mission would then deploy a rover. But unlike the rovers we've built so far, this one would be designed to go underwater and navigate using the bottom surface of the ice over the oceans. An early design was just tested successfully underneath the ice in Alaska. "[It] crawls along under a foot of ice, its built-in buoyancy keeping it firmly pressed against the frozen subsurface, sensors measuring the temperature, salinity, pH, and other characteristics of the water."

Astronomers and astrobiologists are hopeful that these missions will provide definitive evidence of life on other worlds. "Europa certainly seems to have the basic ingredients for life. Liquid water is abundant, and the ocean floor may also have hydrothermal vents, similar to Earth's, that could provide nutrients for any life that might exist there. Up at the surface, comets periodically crash into Europa, depositing organic chemicals that might also serve as the building blocks of life. Particles from Jupiter's radiation belts split apart the hydrogen and oxygen that makes up the ice, forming a whole suite of molecules that living organisms could use to metabolize chemical nutrients from the vents."

MTorrice (2611475) writes "Despite cocaine's undeniable destructiveness, there are no antidotes for overdoses or medications to fight addiction that directly neutralize cocaine's powerful effects. A natural bacterial enzyme, cocaine esterase, could help by chopping up cocaine in the bloodstream. But the enzyme is unstable in the body, losing activity too quickly to be a viable treatment. Now, using computational design, researchers tweaked the enzyme (full paper, PDF) to simultaneously increase stability and catalytic efficiency. Mice injected with the engineered enzyme survive daily lethal doses of cocaine for an average of 94 hours."