Gregg Braden

So they take an egg, take the DNA out of the original, take that DNA out. Now they take the DNA from another sheep, for example, and put it into that egg, and then they electrically stimulate it, and it begins to grow. Here's what they've missed. The DNA does not only exist in the nucleus of the cell. There is DNA there, we all know that.

And the nucleus, there's also DNA outside of the nucleus in what's called the cytoplasm. This is where the information technology is now blurring the lines with biology. Because IT, information technology, says the DNA is a resonant fractal antenna, all right? So in the original egg, the DNA inside the nucleus is in communication with the DNA outside the nucleus.

And the nucleus, there's also DNA outside of the nucleus in what's called the cytoplasm. This is where the information technology is now blurring the lines with biology. Because IT, information technology, says the DNA is a resonant fractal antenna, all right? So in the original egg, the DNA inside the nucleus is in communication with the DNA outside the nucleus.

And the nucleus, there's also DNA outside of the nucleus in what's called the cytoplasm. This is where the information technology is now blurring the lines with biology. Because IT, information technology, says the DNA is a resonant fractal antenna, all right? So in the original egg, the DNA inside the nucleus is in communication with the DNA outside the nucleus.

They're having a conversation so they can support one another. You pull that original DNA out, you put another DNA in, it's tuned to a different station. It can no longer communicate with the DNA outside of the nucleus. That is where the breakdown happens. That is why the functions begin to... begin to fail at about 50% of the lifespan.

They're having a conversation so they can support one another. You pull that original DNA out, you put another DNA in, it's tuned to a different station. It can no longer communicate with the DNA outside of the nucleus. That is where the breakdown happens. That is why the functions begin to... begin to fail at about 50% of the lifespan.

They're having a conversation so they can support one another. You pull that original DNA out, you put another DNA in, it's tuned to a different station. It can no longer communicate with the DNA outside of the nucleus. That is where the breakdown happens. That is why the functions begin to... begin to fail at about 50% of the lifespan.

And I think the only way they'll have that successful long-term cloning is they will have to acknowledge that and allow those two pieces of DNA to communicate. And there are a number, I hesitate, I don't know how deep I want to get into that. There are a number of ways to go about doing that.

And I think the only way they'll have that successful long-term cloning is they will have to acknowledge that and allow those two pieces of DNA to communicate. And there are a number, I hesitate, I don't know how deep I want to get into that. There are a number of ways to go about doing that.

And I think the only way they'll have that successful long-term cloning is they will have to acknowledge that and allow those two pieces of DNA to communicate. And there are a number, I hesitate, I don't know how deep I want to get into that. There are a number of ways to go about doing that.

But the key is they've got to acknowledge that there is information being shared between nuclear and cytoplasmic DNA. And to the best of my knowledge, they haven't done that yet. Isn't that interesting?

But the key is they've got to acknowledge that there is information being shared between nuclear and cytoplasmic DNA. And to the best of my knowledge, they haven't done that yet. Isn't that interesting?

But the key is they've got to acknowledge that there is information being shared between nuclear and cytoplasmic DNA. And to the best of my knowledge, they haven't done that yet. Isn't that interesting?

Yeah, and so they want to apply this to humans. Ultimately, they want to apply it to organs. They want to clone organs so that we don't have to have someone die before we get an organ, you know, from someone else. They've got... Right now, we can 3D print key organs. You can 3D print a kidney. You can 3D print a heart.

Yeah, and so they want to apply this to humans. Ultimately, they want to apply it to organs. They want to clone organs so that we don't have to have someone die before we get an organ, you know, from someone else. They've got... Right now, we can 3D print key organs. You can 3D print a kidney. You can 3D print a heart.

Yeah, and so they want to apply this to humans. Ultimately, they want to apply it to organs. They want to clone organs so that we don't have to have someone die before we get an organ, you know, from someone else. They've got... Right now, we can 3D print key organs. You can 3D print a kidney. You can 3D print a heart.

You can 3D print ears, nose, and skin, which is awesome for burn victims and things like that, so you don't have to take your own skin grafts. How successful will those organs be in the body? And these are all considerations that we have to think about.

You can 3D print ears, nose, and skin, which is awesome for burn victims and things like that, so you don't have to take your own skin grafts. How successful will those organs be in the body? And these are all considerations that we have to think about.

You can 3D print ears, nose, and skin, which is awesome for burn victims and things like that, so you don't have to take your own skin grafts. How successful will those organs be in the body? And these are all considerations that we have to think about.

All under the umbrella of this transhumanistic movement, we're trying, this is a generation, we're trying to replace our natural biology with synthetics.