Bio-Inspired Material Interacts With Surrounding Tissue To Promote Healing.

Studying DNA Breaks to Protect Future Space Travelers

Genes in Space logo. May 9, 2019 Earth’s atmosphere shields life on the ground from cosmic radiation that can damage DNA.  Astronauts in space have no such protection, and that puts them at risk. An investigation on the International Space Station examines DNA damage and repair in space in order to help protect the long-term health of space travelers. An organism carries all of its genetic information in its deoxyribonucleic acid or DNA. This blueprint for life takes the form of specific sequences of nitrogen bases: adenine, cytosine, guanine, and thymine, represented by the letters A, C, G and T.

Image above: The miniPCR device, used to make multiple copies of a particular strand of DNA in space. Image Credit: NASA. One type of DNA damage is double strand breaks, essentially a cut across both strands of DNA. Cells repair these breaks almost immediately, but can make errors, inserting or deleting DNA bases and creating mutations. These mutations may result in diseases such as cancer. Genes in Space-6 looks at the specific mechanism cells use to repair double strand breaks in space. The investigation takes cells of the yeast Saccharomyces cerevisiae to the space station, where astronauts cause a specific type of damage to its DNA using a genome editing tool known as CRISPR-Cas9. The astronauts allow the cells to repair this damage, then make many copies of the repaired section using a process called polymerase chain reaction (PCR) with an onboard device, the miniPCR. Another device, MinION, is then used to sequence the repaired section of DNA in those copies. Sequencing shows the exact order of the bases, revealing whether the repair restored the DNA to its original order or made errors. The investigation represents a number of firsts, including the first use of CRISPR-Cas9 genetic editing on the space station and the first time scientists evaluate the entire damage and repair process in space.

Image above: The student team that developed the Genes in Space 6 experiment. From left to right: David Li, Aarthi Vijayakumar, Michelle Sung, and Rebecca Li. Image Credit: Boeing. “The damage actually happens on the space station and the analysis also happens in space,” said one of the investigators from miniPCR Bio, Emily Gleason. “We want to understand if DNA repair methods are different in space than on Earth.” This investigation is part of the Genes in Space program. Founded by miniPCR and Boeing, the program challenges students to come up with DNA experiments in space that involve using the PCR technique and the miniPCR device on the station. Students submit ideas online, and the program chooses five finalists. These finalists are paired with a mentor scientist who helps them turn their idea into a presentation for the ISS Research and Development Conference. A panel of judges selects one proposed experiment to fly to the space station. “We want to inspire students to think like scientists and give them the opportunity for an authentic science experience that doesn’t cost them anything,” says Gleason. More than 550 student teams submitted ideas last year. The Genes in Space-6 investigation student team includes Michelle Sung, Rebecca Li, and Aarthi Vijayakumar at Mounds View High School in Arden Hills, Minnesota, and David Li, now a freshman at the Massachusetts Institute of Technology (MIT) in Cambridge, Massachusetts. Their mentor is Kutay Deniz Atabay at MIT.

Image above: The Genes in Space 6 student team. Image Credit: GENES IN SPACE. Other investigators include Sarah E. Stahl and Sarah Wallace with NASA’s Johnson Space Center Microbiology group in Houston; G. Guy Bushkin, Whitehead Institute for Biomedical Research, Cambridge; Melissa L. Boyer, Teresa K. Tan, Kevin D. Foley, and D. Scott Copeland at Boeing; and Ezequiel Alvarez Saavedra, Gleason, and Sebastian Kraves at Amplyus LLC, in Cambridge. Amplyus is the parent company of miniPCR Bio. “One thing the investigation will tell us is yes, we can do these things in space,” said Gleason. “We expect to see the yeast use the error-free method of repair more frequently, which is what we see on Earth; but we don’t know for sure whether it will be the same or not. Ultimately, we can use this knowledge to help protect astronauts from DNA damage caused by cosmic radiation on long voyages and to enable genome editing in space.” The procedures used in this investigation may have applications for protecting people from radiation and other hazards in remote and harsh locations on Earth as well. Related links: Genes in Space-6: https://www.nasa.gov/mission_pages/station/research/experiments/explorer/Investigation.html?#id=7893 miniPCR: https://www.minipcr.com/ MinION: https://www.nasa.gov/mission_pages/station/research/news/biomolecule_sequencer Genes in Space program: https://www.genesinspace.org/ Space Station Research and Technology: https://www.nasa.gov/mission_pages/station/research/index.html International Space Station (ISS): https://www.nasa.gov/mission_pages/station/main/index.html Images (mentioned), Text, Credits: NASA/Michael Johnson/JSC/International Space Station Program Science Office/Melissa Gaskill. Greetings, Orbiter.ch Full article

Organic Pigment Photocapacitors May Restore Sight to Blind People

A simple retinal prosthesis is being developed in collaboration between Tel Aviv University in Israel and LiU. Fabricated using cheap and widely-available organic pigments used in printing inks and cosmetics, it consists of tiny pixels like a digital camera sensor on a nanometric scale. Researchers hope that it can restore sight to blind people.

Researchers led by Eric Glowacki, principal investigator of the organic nanocrystals subgroup in the Laboratory of Organic Electronics, Linköping University, have developed a tiny, simple photoactive film that converts light impulses into electrical signals. These signals in turn stimulate neurons (nerve cells). The research group has chosen to focus on a particularly pressing application, artificial retinas that may in the future restore sight to blind people. The Swedish team, specializing in nanomaterials and electronic devices, worked together with researchers in Israel, Italy and Austria to optimise the technology. Experiments in vision restoration were carried out by the group of Yael Hanein at Tel Aviv University in Israel. Yael Hanein’s group is a world-leader in the interface between electronics and the nervous system.

The results have recently been published in the prestigious scientific journal Advanced Materials.

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What doesn't tear you makes you doper

Substitutional defects ( 2 ) are point defects in which an impurity atom takes the place of a native atom within the crystal lattice. Semiconductors often intentionally add substitional defects through doping, such as adding boron or phosphorous to silicon to create an n- or p-type semiconductor, and certain alloys include extraneous elements to create substitional defects for solution hardening purposes.

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Apply independently produced drug to the burnt area

Fed Up With Drug Companies, Hospitals Decide to Start Their Own

"A group of large hospital systems plans to create a nonprofit generic drug company to battle shortages and high prices.

Mars Surface Is Looking Much Deadlier Than We Previously Thought

So much for those space potatoes.

A new study has revealed that compounds present in the Martian soil can wipe out whole bacterial cultures within minutes.

Researchers have had their suspicions over whether microorganisms can actually survive on the surface of the Red Planet, and now lab tests are spelling doom for any potential little green bacteria. And yeah, growing potatoes on Mars might be more difficult than we thought.

The problem here lies with perchlorates - chlorine-containing chemical compounds that we first detected on Mars back in 2008. These salty compounds are also what makes water on the Martian surface stay liquid, essentially turning it into brine.

Perchlorates are considered toxic for people, but they don’t necessarily pose a problem for microbes. And because they keep surface water liquid, on Mars the presence of these compounds could even be beneficial for life - or so we thought.

Researchers from the University of Edinburgh have now confirmed that when you pair the compounds with intense ultraviolet (UV) light exposure, things become grim for any life forms.

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Eric Magnus Lensherr-sphere

Magnetospheres: How Do They Work?

The sun, Earth, and many other planets are surrounded by giant magnetic bubbles.

Space may seem empty, but it’s actually a dynamic place, dominated by invisible forces, including those created by magnetic fields.  Magnetospheres – the areas around planets and stars dominated by their magnetic fields – are found throughout our solar system. They deflect high-energy, charged particles called cosmic rays that are mostly spewed out by the sun, but can also come from interstellar space. Along with atmospheres, they help protect the planets’ surfaces from this harmful radiation.

It’s possible that Earth’s protective magnetosphere was essential for the development of conditions friendly to life, so finding magnetospheres around other planets is a big step toward determining if they could support life.

But not all magnetospheres are created equal – even in our own backyard, not all planets in our solar system have a magnetic field, and the ones we have observed are all surprisingly different.

Earth’s magnetosphere is created by the constantly moving molten metal inside Earth. This invisible “force field” around our planet has an ice cream cone-like shape, with a rounded front and a long, trailing tail that faces away from the sun. The magnetosphere is shaped that way because of the constant pressure from the solar wind and magnetic fields on the sun-facing side.

Earth’s magnetosphere deflects most charged particles away from our planet – but some do become trapped in the magnetic field and create auroras when they rain down into the atmosphere.

We have several missions that study Earth’s magnetosphere – including the Magnetospheric Multiscale mission, Van Allen Probes, and Time History of Events and Macroscale Interactions during Substorms (also known as THEMIS) – along with a host of other satellites that study other aspects of the sun-Earth connection.

Mercury, with a substantial iron-rich core, has a magnetic field that is only about 1% as strong as Earth’s. It is thought that the planet’s magnetosphere is stifled by the intense solar wind, limiting its strength, although even without this effect, it still would not be as strong as Earth’s. The MESSENGER satellite orbited Mercury from 2011 to 2015, helping us understand our tiny terrestrial neighbor.

After the sun, Jupiter has by far the biggest magnetosphere in our solar system – it stretches about 12 million miles from east to west, almost 15 times the width of the sun. (Earth’s, on the other hand, could easily fit inside the sun.) Jupiter does not have a molten metal core like Earth; instead, its magnetic field is created by a core of compressed liquid metallic hydrogen.

One of Jupiter’s moons, Io, has intense volcanic activity that spews particles into Jupiter’s magnetosphere. These particles create intense radiation belts and the large auroras around Jupiter’s poles.

Ganymede, Jupiter’s largest moon, also has its own magnetic field and magnetosphere – making it the only moon with one. Its weak field, nestled in Jupiter’s enormous shell, scarcely ruffles the planet’s magnetic field.

Our Juno mission orbits inside the Jovian magnetosphere sending back observations so we can better understand this region. Previous observations have been received from Pioneers 10 and 11, Voyagers 1 and 2, Ulysses, Galileo and Cassini in their flybys and orbits around Jupiter.

Saturn’s moon Enceladus transforms the shape of its magnetosphere. Active geysers on the moon’s south pole eject oxygen and water molecules into the space around the planet. These particles, much like Io’s volcanic emissions at Jupiter, generate the auroras around the planet’s poles. Our Cassini mission studies Saturn’s magnetic field and auroras, as well as its moon Enceladus.

Uranus’ magnetosphere wasn’t discovered until 1986 when data from Voyager 2’s flyby revealed weak, variable radio emissions. Uranus’ magnetic field and rotation axis are out of alignment by 59 degrees, unlike Earth’s, whose magnetic field and rotation axis differ by only 11 degrees. On top of that, the magnetic field axis does not go through the center of the planet, so the strength of the magnetic field varies dramatically across the surface. This misalignment also means that Uranus’ magnetotail – the part of the magnetosphere that trails away from the sun – is twisted into a long corkscrew.

Neptune’s magnetosphere is also tilted from its rotation axis, but only by 47. Just like on Uranus, Neptune’s magnetic field strength varies across the planet. This also means that auroras can be seen away from the planet’s poles – not just at high latitudes, like on Earth, Jupiter and Saturn.

Does Every Planet Have a Magnetosphere?

Neither Venus nor Mars have global magnetic fields, although the interaction of the solar wind with their atmospheres does produce what scientists call an “induced magnetosphere.” Around these planets, the atmosphere deflects the solar wind particles, causing the solar wind’s magnetic field to wrap around the planet in a shape similar to Earth’s magnetosphere.

What About Beyond Our Solar System?

Outside of our solar system, auroras, which indicate the presence of a magnetosphere, have been spotted on brown dwarfs – objects that are bigger than planets but smaller than stars.

There’s also evidence to suggest that some giant exoplanets have magnetospheres. As scientists now believe that Earth’s protective magnetosphere was essential for the development of conditions friendly to life, finding magnetospheres around exoplanets is a big step in finding habitable worlds.  

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Don't drink dihydrogen monoxide. Everybody dies who does!

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Self-healing material a breakthrough for bio-inspired robotics

Many natural organisms have the ability to repair themselves. Now, manufactured machines will be able to mimic this property. In findings published this week in Nature Materials, researchers at Carnegie Mellon University have created a self-healing material that spontaneously repairs itself under extreme mechanical damage.

This soft-matter composite material is composed of liquid metal droplets suspended in a soft elastomer. When damaged, the droplets rupture to form new connections with neighboring droplets and reroute electrical signals without interruption. Circuits produced with conductive traces of this material remain fully and continuously operational when severed, punctured, or had material removed.

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Do 5s often develop complexes about being fuckups or incompetent over small things, like not understanding something they weren't taught, or being forgetful, etc (I ask because I believe I have adhd and am a 5 core, and some of the difficulties from the disorder have given me a complex, which is one of the main reasons I typed myself as a 5, along with my really annoying tendency to need to show off my intelligence)

Yes, but it also sounds like you have a strong 3 fix. 5s hate this on a gut level because they can’t keep up their self image as completely competent and intelligent. 3s hate this because others see them failing at a task and 3s have trouble contextualizing that everyone fails at stuff and no one really cares. 

Plus “annoying tendency to show off my intelligence” is the hallmark of 3+5