On the last day of March, surgeons at Massachusetts General Hospital began surgery that they hoped would lead to lasting changes in the way the kidneys are implanted in people.
The patient that morning was not a human. It was a pig and was anesthetized on the table. The pig had one kidney missing and needed an implant.
Kidneys usually need to be transplanted within 24-36 hours, but the kidneys that enter the pig were removed 10 days before and frozen earlier that morning.
No one ever transplanted frozen organs into large animals. There were a lot of things that didn’t work out.
“I think there’s about a 50% chance that it will work,” said Kolkout Wygun, a surgical professor and team leader, before the surgery. Dr. Uygun is on the Scientific Advisory Committee of Sylvatica Biotech Inc., a company that develops freezing methods for organ maintenance.
But the promise from the organs of freezing and storage is fantastic.
There is a severe and continuous shortage of kidneys for transplants – That’s all 92,000 People are on the waiting list. One reason is that the 24-36 hour window is very short, so limit the number of recipients that are good matches.
How good is it to have a bank of stored frozen organs, as organ transplants can be like an elective surgery?
At least, it was a decades-long dream of a transplant surgeon.
However, the medical researchers’ attempts to freeze organs were thwarted at every turn. In many cases, ice crystals formed organs and destroyed them. The material was also intended to stop the crystals from forming, the anti-freeze agent was toxic and killed cells. Or the frozen organs became very brittle and cracked.
A device has been created by scientists that can translate speech ideas into spoken words in real time.
Although still in the experimental stage, the goal is to develop a Brain Computer Interface that can give voice to individuals unable to speak.
In a recent study, the device was tested on a 47-year-old woman with quadriplegia who had been speech-impaired for 18 years since experiencing a stroke. The device was implanted in her brain during surgery as part of a clinical trial.
According to Gopala Anumanchipalli, co-author of the study published in Nature Neuroscience, the device “translates the intent to speak into fluent text.”
Most brain computer interfaces for speech experience a delay between thought and speech, which can disrupt conversations and cause misunderstandings. However, this new device is considered a significant advancement in the field.
The device works by recording brain activity using electrodes and generating speech based on this activity. An AI model is then trained to translate this neural activity into spoken words.
The UCSF Clinical Research Coordinator will connect a neural data port to the head of the ANN, a participant in El Cerrito, California, on May 22, 2023.Noah Berger/UCSF, via AP files via UC Berkeley
Anumanchipalli of the University of California, Berkeley, explains that the device operates similarly to existing systems used for transcribing meetings and phone calls in real time.
Located in the brain’s speech center, the implant translates signals into spoken sentences as they are heard. This “streaming approach” ensures a constant flow of audio to the recorder without waiting for the sentence to finish.
Rapid speech decoding enables the device to keep up with natural speech pace, enhancing language naturalness according to Brumberg.
Funded in part by the National Institutes of Health, further research is necessary before the technology can be widely available. Anumanchipalli suggests that with sustained investment, the device could potentially be accessible to patients within the next decade.
A virtual drone was steered through an obstacle course by imagining moving a finger.
Wilsey et al.
A paralyzed man with electrodes implanted in his brain can pilot a virtual drone through an obstacle course just by imagining moving his fingers. His brain signals are interpreted by an AI model and used to control a simulated drone.
Research on brain-computer interfaces (BCI) has made great progress in recent years, allowing people with paralysis to write speech on a computer by precisely controlling a mouse cursor or imagining writing words with a pen. It became. However, so far it has not yet shown much promise in complex applications with multiple inputs.
now, Matthew Wilsey Researchers at the University of Michigan created an algorithm that allows users to trigger four discrete signals by imagining moving their fingers and thumbs.
The anonymous man who tried the technique is a quadriplegic due to a spinal cord injury. He was already fitted with Blackrock Neurotech's BCI, which consists of 192 electrodes implanted in the area of the brain that controls hand movements.
An AI model was used to map the complex neural signals received by the electrodes onto the user's thoughts. Participants learned how to think about moving the first two fingers of one hand to generate electrical signals that can be made stronger or weaker. Another signal was generated by the next two fingers, and another two by the thumb.
These are enough to allow the user to control the virtual drone with just their head, and with practice they will be able to expertly maneuver it through obstacle courses. Wilsey said the experiment could have been done using a real drone, but was done virtually for simplicity and safety.
“The goal of building a quadcopter was largely shared by our lab and the participants,” Wilsey says. “For him, it was a kind of dream come true that he thought was lost after he got injured. He had a passion and a dream to fly. He felt so empowered and capable. He instructed us to take a video and send it to a friend.
Although the results are impressive, Willsey says there is still much work to be done before BCIs can be reliably used for complex tasks. First, AI is required to interpret the signals from the electrodes, but this depends on individual training for each user. Second, this training must be repeated over time as function declines. This could be due to slight misalignment of the electrodes in the brain or changes in the brain itself.
Noland Arbor can play chess using Neuralink implant
Neuralink
Neuralink, the brain-computer interface company founded by Elon Musk, has revealed the identity of its first patient who says its implant “changed his life.” But experts say it’s not yet clear whether Neuralink has done more than replicate existing research efforts.
Who was Neuralink’s first patient?
Musk announced in January that the first human patient had received a Neuralink implant, but few details were released at the time. We now know from something. Live stream video by company – Who is that person and how will the test be done?
Noland Arbaugh explains in the video that an accident eight years ago dislocated his fourth and fifth vertebrae, leaving him a quadriplegic. He previously controlled the computer with a mouth interface, and is shown moving the cursor with just his thoughts, apparently using a Neuralink implant.
“Once I started imagining the cursor moving, it became intuitive,” Arbaugh says in the video. “Basically, it was like using ‘force’ on the cursor, and I was able to move the cursor anywhere I wanted. I could just look anywhere on the screen and the cursor would move where I wanted it. It was a very wild experience.”
He uses the device for reading, language learning, and computer games such as chess, and claims he uses it for up to eight hours at a time, at which point he needs to charge the device. “It’s not perfect, I’ve run into some problems. But it’s already changed my life,” he says.
What does the implant contain?
Neuralink did not respond to requests for an interview, but its website says the current generation coin-sized implant, called N1, generates neural activity through 1,024 electrodes distributed across 64 threads that extend into the user’s brain. It is said that it records. These are so fine that they must be placed by a surgical robot.
In a livestream video, Arbaugh said he was discharged from the hospital the day after his implant surgery, and that from his perspective the surgery was a relatively simple process.
The implant uses a small battery that is charged through the skin by an inductance charger and communicates wirelessly with an app on your smartphone.
Does this mean the first human trials were successful?
Reinhold Scherrer Researchers at the University of Essex in the UK will decide whether Neuralink’s first human trial was a success because the company “has not released enough information to form an informed opinion” He said it was too early.
“While the video is impressive and there is no doubt that it took a lot of research and development work to get to this stage, it is unclear whether what is being shown is new or groundbreaking,” he said. Masu. “Although control appears to be stable, most of the studies and experiments presented so far are primarily replications of past studies. Replication is good, but major challenges still remain. ”
Who else is working on brain implants?
Neuralink isn’t the only group exploring this idea. A number of academic organizations and commercial startups have already conducted human experiments that have successfully interpreted brain signals and produced some sort of output.
A team at Stanford University in California placed two small sensors just below the surface of the brain of a man who was paralyzed from the neck down. Researchers may be able to interpret the brain signals when a man decides to put pen to paper and translate them into text that can be read on a computer.
When will Neuralink be available and how much will it cost?
It’s too early to tell, as this has a long way to go before it becomes a commercial product, with much testing and certification to come. But Musk has made it clear that he intends to commercialize the technology.of The first product planned was named Telepathy.allows users to take control of their mobile phones and computers.
The first human patient implanted with Neuralink’s brain chip appears to have made a full recovery and is now able to use his thoughts to control a computer mouse, according to Neuralink founder Elon Musk, who shared the news late Monday.
“Things are going well, the patient appears to have made a full recovery, and there are no adverse effects that we are aware of. The patient can move the mouse on the screen just by thinking,” Musk said on the social media platform during the X Spaces event.
Musk said Neuralink is currently trying to get as many mouse button clicks from patients as possible. Neuralink did not immediately respond to a request for further details.
The company successfully implanted the chip in its first human patient last month after receiving approval to recruit for a clinical trial in September.
The study will use robots to surgically place brain-computer interface implants in areas of the brain that control locomotion intentions, Neuralink said, with the initial goal of helping people use their thoughts to interact with computers. He added that the idea was to be able to control the cursor and keyboard.
Musk has grand ambitions for Neuralink, saying it will facilitate rapid surgical insertion of chip devices to treat conditions such as obesity, autism, depression and schizophrenia.
Neuralink, valued at about $5 billion last year, has faced repeated calls for scrutiny over its safety protocols. The company was fined for violating U.S. Department of Transportation regulations regarding the movement of hazardous materials.
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