Neuralink has implanted its chip in a human for the first time and is detecting electrical signals from the patient’s brain, startup leader Elon Musk said Monday. It’s one step on a very long path to making the technology safe and useful.
“The first human received an implant from Neuralink yesterday and is recovering well,” Musk said on his X social network. The initial results are showing the implant, which Musk said is named Telepathy, is registering spikes of brain cell activity.
The first device installed is part of a clinical trial Neuralink announced in 2023 testing how well the device works on people with quadriplegia because of a spinal cord injury or amyotrophic lateral sclerosis, also known as Lou Gehrig’s disease. The idea is to intercept the brain’s neural signals to move limbs then retransmit those signals elsewhere in the body so the patient can control their limbs again.
Watch this: Neuralink Explained: Elon Musk Plans to Tap Our Minds With Brain Implants
Neuralink got approval from the US Food and Drug Administration for the medical test in 2023, but Musk wants to go far beyond that, building what he’s called “generalized input-output device that could interface with every aspect of your brain.” In other words, something everybody would use to connect their minds directly to the digital realm.
It’s radical sci-fi by the standards of today’s computing technology. When Musk first announced Neuralink, he floated the idea of sending messages directly to another person’s mind — “consensual telepathy,” as he called it in 2017. His ultimate objective: “a full brain-machine interface where we can achieve a sort of symbiosis with AI,” Musk said.
Big barriers to Neuralink’s success
Don’t expect that anytime soon. It’s easier to get approval for limited medical studies in people whose health problems show no signs of improving than it is to persuade people to implant a nonmedical product inside their bodies. On top of proving the technology and gaining medical approval, there are serious ethical and social barriers to adoption.
Adoption could be held back by Musk himself, a polarizing figure. He became a tech hero to many when he led Tesla to create competitive electric vehicles and SpaceX to build more affordable rockets and satellite-based internet access. But his chaotic takeover of Twitter, now called X, has alienated many who view him as antisemitic or racist.
Another obstacle: people’s squeamishness. Telepathy sounds cool, but there’s no getting around the fact that a Neuralink implant replaces a piece of your skull, and getting one installed will be a lot more significant than a dentist drilling out a cavity. Neuralink has has problems with infections and implant attachment screws coming loose in tests in monkeys that have drawn criticism from animal rights activists.
Neuralink also wants to let patients control computing devices solely with their minds with an app it’s working on. “Imagine if Stephen Hawking could communicate faster than a speed typist or auctioneer. That is the goal,” Musk said.
Neuralink is one of many brain implant efforts
The human trial is years late. Neuralink had wanted to begin human tests in 2020.
Meanwhile, rivals are also making progress in the field, called brain-machine interface or brain-computer interface technology, including an experiment that already has helped a man walk again.
BlackRock Neurotech has tested implants in humans for years. Paradromics is working on an implant, too. Synchron Medical published test results of a communications implant in 2023. Precision Neuroscience is working on less invasive implants, and Nuro hopes to succeed with noninvasive approaches that require no surgery at all.
Academic researchers have produced a steady stream of research papers, too.
What Neuralink is up to
Neuralink is founded on the idea that modern electronics and computing technology can register and interpret the electrical signs of brain cells, called neurons. That computing technology can then communicate back to the body by generating its own signals. The hope is to eventually connect to computers, for example sending signals from a camera to a blind person’s visual cortex to enable sight.
An implant works by inserting 64 threads with a total of 1,024 very small electrodes into the brain. Each electrode can sense the brain’s electrical signals. Part of Neuralink’s sales pitch is its R1 robot, designed to install these wires without disturbing blood cells in the brain.
The Telepathy unit is roughly coin-sized, though much thicker, and fits inside a hole bored in a patient’s skull. It carries a processor that oversees the communications with the brain and the outside world. It communicates and charges wirelessly.
The Neuralink human trial should last about six years, according to a brochure about the test.