A bioengineer and geneticist at Harvard’s Wyss Institute have successfully stored 5.5 petabits of data— around 700 terabytes — in a single gram of DNA, smashing the previous DNA data density record by a thousand times.
The work, carried out by George Church and Sri Kosuri, basically treats DNA as just another digital storage device. Instead of binary data being encoded as magnetic regions on a hard drive platter, strands of DNA that store 96 bits are synthesized, with each of the bases (TGAC) representing a binary value (T and G = 1, A and C = 0).
To read the data stored in DNA, you simply sequence it — just as if you were sequencing the human genome — and convert each of the TGAC bases back into binary. To aid with sequencing, each strand of DNA has a 19-bit address block at the start (the red bits in the image below) — so a whole vat of DNA can be sequenced out of order, and then sorted into usable data using the addresses.
Scientists have been eyeing up DNA as a potential storage medium for a long time, for three very good reasons: It’s incredibly dense (you can store one bit per base, and a base is only a few atoms large); it’s volumetric (beaker) rather than planar (hard disk); and it’s incredibly stable — where other bleeding-edge storage mediums need to be kept in sub-zero vacuums, DNA can survive for hundreds of thousands of years in a box in your garage.
It is only with recent advances in microfluidics and labs-on-a-chip that synthesizing and sequencing DNA has become an everyday task, though. While it took years for the original Human Genome Project to analyze a single human genome (some 3 billion DNA base pairs), modern lab equipment with microfluidic chips can do it in hours. Now this isn’t to say that Church and Kosuri’s DNA storage is fast — but it’s fast enough for very-long-term archival.
Just think about it for a moment: One gram of DNA can store 700 terabytes of data. That’s 14,000 50-gigabyte Blu-ray discs… in a droplet of DNA that would fit on the tip of your pinky. To store the same kind of data on hard drives — the densest storage medium in use today — you’d need 233 3TB drives, weighing a total of 151 kilos. In Church and Kosuri’s case, they have successfully stored around 700 kilobytes of data in DNA — Church’s latest book, in fact — and proceeded to make 70 billion copies (which they claim, jokingly, makes it the best-selling book of all time!) totaling 44 petabytes of data stored.
Looking forward, they foresee a world where biological storage would allow us to record anything and everything without reservation. Today, we wouldn’t dream of blanketing every square meter of Earth with cameras, and recording every moment for all eternity/human posterity — we simply don’t have the storage capacity. There is a reason that backed up data is usually only kept for a few weeks or months — it just isn’t feasible to have warehouses full of hard drives, which could fail at any time. If the entirety of human knowledge — every book, uttered word, and funny cat video — can be stored in a few hundred kilos of DNA, though… well, it might just be possible to record everything (hello, police state!)
It’s also worth noting that it’s possible to store data in the DNA of living cells — though only for a short time. Storing data in your skin would be a fantastic way of transferring data securely…
by Lauren O’Neil from cbc.ca
If Dmitry Itskov’s 2045 initiative plays out as planned, humans will have the option of living forever with the help of machines in only 33 years.
It may sound ridiculous, but the 31-year-old Russian mogul is dead serious about neuroscience, android robotics, and cybernetic immortality.
He has already pulled together a team of leading Russian scientists intent on creating fully functional holographic human avatars that house artificial brains which contain a person’s complete consciousness – in other words, a humanoid robot.
Together, they’ve laid out an ambitious course of action that would see the team transplant a human brain into an artificial body (or ‘avatar’) in as little as seven years time.
Now, Itskov is asking the world’s richest people for help in financing the project.
In exchange, he’s offered to coordinate their own personal immortality projects for free.
“I urge you to take note of the vital importance of funding scientific development in the field of cybernetic immortality and the artificial body,” he writes in an open letter to members of the Forbes World’s Billionaires List.
“Such research has the potential to free you, as well as the majority of all people on our planet, from disease, old age and even death.”
Itskov goes on to offer skeptics a meeting with “a team of the world’s leading scientists working in this field ” to prove the viability of the concept of cybernetic immortality.
And while many are skeptical that such a plan could ever come to fruition, Popular
Science Magazine points that phase one — creating a robot controlled by a human brain — is already well within reach.
“DARPA is already working on it via a program called “Avatar” (which, incidentally, is also the name of Itskov’s project) through which the Pentagon hopes to create a brain-machine interface that will allow soldiers to control bipedal human surrogate machines remotely with their minds,” writes PopSci’s Clay Dillow.
“And of course there are all the ongoing medical prosthesis projects that have shown that the human nervous system can interface with prosthetic enhancements, manipulating them via thought. Itskov draws a clear arc from what we have now to the consciousness-containing holograms that he envisions. All we have to do is attack the technological obstacles in between, one at a time, until we get there.”
Discovery’s Alyssa Danigelis takes an opposing stance to the very idea.
“There’s a world of difference between pursuing a brain-controlled exoskeleton to help paraplegics regain control and wanting to essentially upload a human brain into an artificial body,” she writes.
“I read a sci-fi novel involving disembodied live brains once. It didn’t turn out well”
The second annual God Debate features atheist neuroscientist Sam Harris and Evangelical Christian apologist William Lane Craig as they debate the topic: “Is Good From God?” The debate was sponsored in large part by the Notre Dame College of Arts and Letters: The Henkels Lecturer Series, The Center for Philosophy of Religion and the Institute for Scholarship in the Liberal Arts.
This one is interesting too, the Cardinal ends up making no sense, and Dawkins gets pissed. A few comedic moments as well.
We all love mushrooms here! This is one of the coolest ideas I have heard recently, and it makes a lot of sense. The proposal is that, when we die, we allow our bodies to naturally decay in the earth with the help of an Infinity Mushroom that will cleanse our bodies of all accumulated toxins that would otherwise enter back into the natural environment and cause further pollution of the planet. This is fascinating and makes you think about your own responsibility to mother Earth even after death of the physical body. Plus… the suit just looks awesome.
In 1974 Arthur C. Clarke told the ABC that every household in 2001 will have a computer and be connected all over the world. Courtesy of Australian Broadcasting Corporation.
Quoted from original article here at wired.com
“About 40 percent of red dwarf stars may have Earth-sized planets orbiting them that have the right conditions for life.
Red dwarfs – which are smaller and cooler than our sun – are extremely common, making up 80 percent of stars in the galaxy. Their ubiquity suggests that there are tens of billions of possible places to look for life beyond Earth, with at least 100 such planets located nearby.
The new estimate comes from a team of astronomers using the European Southern Observatory’s HARPS planet-hunting telescope to look at a sample of 102 nearby red dwarfs over a six-year period. The telescope checked for a characteristic wobble from the star, indicating that at least one planet was tugging on it while orbiting around.
The search found nine planets with between one and 10 Earth masses, including two in the habitable zone, possibly giving them the right temperature to have liquid water. Because red dwarfs don’t produce as much heat as our sun, their habitable zones occur much closer to the star.
Larger planets, about the size of Jupiter, were found around less than 12 percent of red dwarfs, suggesting they are rarer than small rocky worlds.
Until recently, astronomers could only guess at the number of stars with planets around them. Now, with the more than 700 confirmed exoplanets, researchers finally have enough data to begin homing in on the true number.
A previous team suggested that one quarter of sun-like stars have an Earth-sized planet around them, while another group estimated that one planet exists for each of the hundred billion stars in our galaxy.
Astronomers hope to someday build a telescope capable of directly imaging the light from an extrasolar planet and see if they contain the telltale chemicals of life, such as oxygen or methane.”