Pager Plays MindPong

The Link amplifies and digitizes the voltage recorded from each of its 1024 electrodes. These tiny voltage traces contain signatures of the activity of nearby neurons (called action potentials or “spikes”). Custom algorithms running aboard the Link automatically detect spikes on each electrode, which are then aggregated into vectors of spike counts [1 count every 25 ms x 1024 channels]. Every 25 milliseconds, the Link transmits these spike counts over bluetooth to a computer running custom decoding software. First, this software re-aggregates the spike counts at several timescales, from the most recent 25 ms to the past 250 ms, to account for differing temporal properties in the activity of the motor neurons. Next, the weighted sum of these current and recent spike counts are computed for each dimension of control by passing their firing rates through a decoding model. The output of the decoder is a set of velocity signals for each 25 ms bin, which are integrated over time to direct the movement of a cursor (or MindPong paddle) on a computer screen.

The video below shows the spatial pattern of directional tuning on each of the electrodes in Pager’s implant while playing a 2D target acquisition game.

With monkeys, we calibrate the decoder by mapping neural activity patterns to actual (joystick) movements. However, we won't be able to use such a strategy for people with paralysis. Prior research by the BrainGate consortium have shown that neurons in the motor cortex remain directionally tuned to movement intention even in people with paralysis, and that it is possible to calibrate a decoder as the person simply imagines moving a mouse on a mousepad or a finger on a trackpad to guide a cursor that automatically moves to presented targets. After the decoder is calibrated, the person is able to type emails and text messages, browse the web, or anything else that can be done with a computer, just by thinking about how they want the cursor to move.

Neuralink's technology builds on decades of research. The BCI systems used in previous studies have no more than a few hundred electrodes, with connectors that pass through the skin, requiring a technician or caregiver to "connect" the BCI. Our mission is to build a safe and effective clinical BCI system that is wireless and fully implantable that users can operate by themselves and take anywhere they go; to scale up the number of electrodes for better robustness and higher information throughput; and to automate the implant surgery to make it as rapid and safe as possible. Recent engineering advances in the field and new technologies developed at Neuralink are paving the way for progress on each of these key technical hurdles.

Our first goal is to give people with paralysis their digital freedom back: to communicate more easily via text, to follow their curiosity on the web, to express their creativity through photography and art, and, yes, to play video games. After that, we intend to use the Link to help improve the lives of those with neurological disorders and disabilities in other ways. For example, for people with paralysis the Link could also potentially be used to restore physical mobility. To achieve this, we'd use the Link to read signals in the brain and use them to stimulate nerves and muscles in the body, thereby allowing the person to once again control their own limbs.

As you can see, MindPong is an initial demonstration of the potential capabilities of the N1 Link. However, it's important to remember that it is a small slice of what our device is intended to achieve. If you'd like to be a part of making a brighter future through neural devices, we'd love to hear from you.

To make Neuralink implants a reality, the robot is absolutely necessary on two fronts: first, the threads are smaller than a human hair and cannot be grasped, manipulated, and accurately inserted by a human surgeon. Doing this requires micron precision for the grasp, tens of microns of precision for localizing and tracking the moving brain during insertion, and high speed in order to get hundreds of threads in quickly. Second, scaling to hundreds of thousands then millions of patients means that not only must the thread insertion be automated but also the planning and execution of the rest of the surgery.

Like all animals, pigs and non-human primates deserve our utmost respect and appreciation. Every aspect of their care is thoroughly evaluated by a team of veterinarians and behaviorists, ensuring access to high quality nutrition, socialization, and enriched spaces to perform species-specific behaviors. For example, Pager lives with his best mate, Code. They enjoy swinging from their treehouse and napping in their hammocks after an engaging gaming session. All of the behavioral tasks that Pager and his friends participate in are voluntary, and trained using positive reinforcement. Pager’s first choice in a preference test is often banana smoothie, and some days it is strawberries!