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Friday, February 27, 2015

Human head transplants could be a reality in just two years

Get ready, this might actually be happening.

A controversial new project to perform the world’s first human head transplant by 2017 will be launched later this year, amid a storm of ethical issues and questions over the actual science involved.
First proposed two years ago by neuroscientist Sergio Canavero from the Turin Advanced Neuromodulation Group in Italy, the idea came about in considering how to improve things for people who have experienced severe muscle and nerve damage because of cancer. The biggest challenges involved, such as connecting the severed spinal cord of the transplanted head to the recipient’s spinal cord, and figuring out how to introduce such a huge part without the body rejecting it, will be sorted over the next two years, Canavero predicts.

This month, he outlined the transplant technique he intends to follow in the journal Surgical Neurology International, and will announce his plan to get the project rolling at the annual conference of the American Academy of Neurological and Orthopaedic Surgeons (AANOS) in US in June, inviting other researchers to join him.

It's been almost five decades since the first ‘successful’ head transplant. And this experiment sure was a grisly one. In 1970, the head of one monkey was placed onto the body of another at the Case Western Reserve University School of Medicine in the US. While scientists weren’t able to fuse the spinal cords, which means the monkey recipient couldn’t move its new head, it was able to achieve assisted breathing, but it died in a mere nine days following the procedure.

But Canavero thinks we’ve got the technology and expertise to do a whole lot better than that now. He described the process to Helen Thomson at New Scientist, and it’s equal parts nuts and kinda genius. It starts with cooling both the body and head right down so the cells won’t die when deprived of oxgyen through the process. Next, the neck is severed and all the crucial blood vessels are hooked up to tubes while the spinal cord on both the head and the body are severed.

"The recipient's head is then moved onto the donor body and the two ends of the spinal cord – which resemble two densely packed bundles of spaghetti – are fused together,” says Thomson. "To achieve this, Canavero intends to flush the area with a chemical called polyethylene glycol, and follow up with several hours of injections of the same stuff. Just like hot water makes dry spaghetti stick together, polyethylene glycol encourages the fat in cell membranes to mesh.”

Canavero told Thomson the final step would be to stitch up the muscles and blood supply, and to induce a thre- or four-hour coma to let the body heal itself while embedded electrodes stimulate the spinal cord to strengthen the new nerve connections.

The recipient won’t be able to get up and walk around soon after the surgery, he says, telling New Scientist that the damage to the spinal cord would take about 12 months to heal fully. The recipient would retain their old voice, he adds.

Sounds simple, but is that really all there is to it? Not even a little bit, because we don’t even know if the plan to use polyethylene glycol to fuse the spinal cords is even going to work, in which case Canavero will be forced to use one of his other options. "There is no evidence that the connectivity of cord and brain would lead to useful sentient or motor function following head transplantation," Richard Borgens, director of the Centre for Paralysis Research at Purdue University in the US, told Thomson.

And then there's the whole 'how do you get the body to stop automatically rejecting the head?' issue. I'll let Helen Thomson explain that one over at New Scientist, because it's a doozy. Suffice it to say, this could be something that humans will have to prepare themselves for, if not in two years' time, perhaps within the next decade or five. We just have to figure out how to not end up like this in the process.

Source: New Scientist

Original link:  http://www.sciencealert.com/human-head-transplants-could-be-a-reality-in-just-two-years

This month, he outlined the transplant technique he intends to follow in the journal Surgical Neurology International, and will announce his plan to get the project rolling at the annual conference of the American Academy of Neurological and Orthopaedic Surgeons (AANOS) in US in June, inviting other researchers to join him.
It's been almost five decades since the first ‘successful’ head transplant. And this experiment sure was a grisly one. In 1970, the head of one monkey was placed onto the body of another at the Case Western Reserve University School of Medicine in the US. While scientists weren’t able to fuse the spinal cords, which means the monkey recipient couldn’t move its new head, it was able to achieve assisted breathing, but it died in a mere nine days following the procedure.
But Canavero thinks we’ve got the technology and expertise to do a whole lot better than that now. He described the process to Helen Thomson at New Scientist, and it’s equal parts nuts and kinda genius. It starts with cooling both the body and head right down so the cells won’t die when deprived of oxgyen through the process. Next, the neck is severed and all the crucial blood vessels are hooked up to tubes while the spinal cord on both the head and the body are severed.
"The recipient's head is then moved onto the donor body and the two ends of the spinal cord – which resemble two densely packed bundles of spaghetti – are fused together,” says Thomson. "To achieve this, Canavero intends to flush the area with a chemical called polyethylene glycol, and follow up with several hours of injections of the same stuff. Just like hot water makes dry spaghetti stick together, polyethylene glycol encourages the fat in cell membranes to mesh.”
Canavero told Thomson the final step would be to stitch up the muscles and blood supply, and to induce a thre- or four-hour coma to let the body heal itself while embedded electrodes stimulate the spinal cord to strengthen the new nerve connections.
The recipient won’t be able to get up and walk around soon after the surgery, he says, telling New Scientist that the damage to the spinal cord would take about 12 months to heal fully. The recipient would retain their old voice, he adds.
Sounds simple, but is that really all there is to it? Not even a little bit, because we don’t even know if the plan to use polyethylene glycol to fuse the spinal cords is even going to work, in which case Canavero will be forced to use one of his other options. "There is no evidence that the connectivity of cord and brain would lead to useful sentient or motor function following head transplantation," Richard Borgens, director of the Centre for Paralysis Research at Purdue University in the US, told Thomson.
And then there's the whole 'how do you get the body to stop automatically rejecting the head?' issue. I'll let Helen Thomson explain that one over at New Scientist, because it's a doozy. Suffice it to say, this could be something that humans will have to prepare themselves for, if not in two years' time, perhaps within the next decade or five. We just have to figure out how to not end up like this in the process:


Source: New Scientist

Brain signals turn into drone commands in Lisbon presentation


Original link:  http://phys.org/news/2015-02-brain-drone-lisbon.html

Credit: TEKEVER
Can we expect a time when aircraft will be directly controlled by the human brain? And what about mind-controlled drones? Imagine that, using an EEG (electroencephalogram) cap tracking neural activity, a man flies a drone with his brain.

"Amazing what you can do if you put your mind to it," said a BBC presenter, who recently witnessed such a feat. He visited an airstrip on the outskirts of Lisbon, Portugal, to see the technology in action. Brainflight is the name of the project. Brainflight is the result of an effort among four organizations – Tekever, the Champalimaud Foundation, Eagle Science and Technische Universität München in Germany. Tekever develops technologies for the enterprise, aerospace, defense and security markets. The effort involves a person's mental activity, detected through a cap, to pilot an unmanned vehicle. The person's cap monitors brain activity. Specifically, for this presentation in Lisbon, team members used EEG systems to measure brain waves noninvasively, and used algorithms to convert brain signals into commands. The electricity flowing through the pilot's brain acted as input to the drone's control system.

The demo signifies something bigger than mind-controlled drones. The technology could eventually be used in commercial flights. One might think the team is suggesting the new approach would mean there was no need for human pilots. That, however, is not part of the vision. The vision is not to replace them but to support them. It could be more a matter of de-risking missions rather than deposing human pilots. "If BCI [brain-computer interface] is adopted in the future as a method of control for aircraft (both manned and remotely piloted)," said the Tekever team, "then the project will potentially benefit the entire pilot community (from ultralight and general aviation to commercial aviation). Through the operant BCI approach, we believe people will be able to pilot aircraft just like they perform everyday activities like walking or running. This will mean that pilots will be able to focus on higher cognitive activities while still being able to operate such a complex system as an aircraft (akin to how professional sportsmen can focus on the tactical aspects of movement without worrying about maintaining proficiency on the basic game skills for example)."

The vision may seem far-fetched but, said BBC's Dave Lee, didn't we once say that about driverless cars? On Wednesday, Engadget's Jon Fingas said you probably won't be using Brainflight to fly anything larger than a small drone in the near future. Tekever is hopeful, though, that its technology will change how we approach transportation. The underlying technology, he added, would also let people with injuries and physical handicaps steer vehicles.

If and when the technology is ready, will people be ready to accept its capabilities? Questions would fall into the what-if category. What if someone were drowsy while wearing the cap and fell asleep? What if the person had a seizure? The BBC report quoted Ricardo Mendes, Tekever's chief operating officer. Mendes said the technology would incorporate safety measures to counteract the effects of someone having, for example, a seizure while piloting. He told the BBC that "There are algorithms on board that prevent bad things from happening."

Explore further: Using thoughts to control airplanes
  More information: tekevernews.blogspot.com/2015/… o-control-drone.html

Streaming algorithm

From Wikipedia, the free encyclopedia https://en.wikipedia.org/wiki/Streaming_algorithm ...