Bliss Chapman

So once we kind of changed the algorithm for the implant to not just give you the boss output, but also these spike band power output, that helped us sort of refine the model with the new set of inputs. And that was the thing that really ultimately gave us the performance back. In terms of

And obviously, the thing that we want, ultimately, and the thing that we are working towards is figuring out ways in which we can keep those threads intact for as long as possible so that we have many more channels going into the model. That's by far the number one priority that the team is currently embarking on to understand how to prevent that from happening.

And obviously, the thing that we want, ultimately, and the thing that we are working towards is figuring out ways in which we can keep those threads intact for as long as possible so that we have many more channels going into the model. That's by far the number one priority that the team is currently embarking on to understand how to prevent that from happening.

And obviously, the thing that we want, ultimately, and the thing that we are working towards is figuring out ways in which we can keep those threads intact for as long as possible so that we have many more channels going into the model. That's by far the number one priority that the team is currently embarking on to understand how to prevent that from happening.

The thing that I will say also is that As I mentioned, this is the first time ever that we're putting these threads in a human brain. And human brain, just for size reference, is 10 times that of the monkey brain or the sheep brain. And it's just a very, very different environment. It moves a lot more. It actually moved a lot more than we expected when we did Nolan's surgery. And...

The thing that I will say also is that As I mentioned, this is the first time ever that we're putting these threads in a human brain. And human brain, just for size reference, is 10 times that of the monkey brain or the sheep brain. And it's just a very, very different environment. It moves a lot more. It actually moved a lot more than we expected when we did Nolan's surgery. And...

The thing that I will say also is that As I mentioned, this is the first time ever that we're putting these threads in a human brain. And human brain, just for size reference, is 10 times that of the monkey brain or the sheep brain. And it's just a very, very different environment. It moves a lot more. It actually moved a lot more than we expected when we did Nolan's surgery. And...

It's just a very, very different environment than what we're used to. And this is why we do clinical trial. We want to uncover some of these issues and failure modes earlier than later. So in many ways, it's provided us with this enormous amount of data and information to be able to solve this. And this is something that Neuralink is extremely good at.

It's just a very, very different environment than what we're used to. And this is why we do clinical trial. We want to uncover some of these issues and failure modes earlier than later. So in many ways, it's provided us with this enormous amount of data and information to be able to solve this. And this is something that Neuralink is extremely good at.

It's just a very, very different environment than what we're used to. And this is why we do clinical trial. We want to uncover some of these issues and failure modes earlier than later. So in many ways, it's provided us with this enormous amount of data and information to be able to solve this. And this is something that Neuralink is extremely good at.

Once we have set of clear objective and engineering problem, we have enormous amount of talents across many, many disciplines to be able to come together and fix the problem very, very quickly.

Once we have set of clear objective and engineering problem, we have enormous amount of talents across many, many disciplines to be able to come together and fix the problem very, very quickly.

Once we have set of clear objective and engineering problem, we have enormous amount of talents across many, many disciplines to be able to come together and fix the problem very, very quickly.

It is. And, and I mean, I think, I mean, as a company, we're extremely vertically integrated. You know, we make these thin film arrays in our own microfab and,

It is. And, and I mean, I think, I mean, as a company, we're extremely vertically integrated. You know, we make these thin film arrays in our own microfab and,

It is. And, and I mean, I think, I mean, as a company, we're extremely vertically integrated. You know, we make these thin film arrays in our own microfab and,

That's a whole thing that we can get into.

That's a whole thing that we can get into.

That's a whole thing that we can get into.

This is the needle that's engaging with the loops in the thread. So they're the ones that... you know thread the feather loop um and then peel it from the silicon backing and then this is the thing that gets inserted into the tissue and then this pulls out leaving the thread and this kind of a notch or the shark tooth that we used to call uh is the thing that actually is um grasping the loop.