Dr. Theresa Bullard

They used to call it junk. They don't call it junk anymore. They just call it non-coding. Yeah. So they have a less charged word for it now.

They used to call it junk. They don't call it junk anymore. They just call it non-coding. Yeah. So they have a less charged word for it now.

They used to call it junk. They don't call it junk anymore. They just call it non-coding. Yeah. So they have a less charged word for it now.

Yes, exactly. It shows once again, the arrogance of science, right? But what's fascinating is that in the human genome, there's more non-coding sections of the DNA than there is in like various animal species or a banana. You know, there's less of the non-coding sections. So there's clearly something important about these non-coding sections that

Yes, exactly. It shows once again, the arrogance of science, right? But what's fascinating is that in the human genome, there's more non-coding sections of the DNA than there is in like various animal species or a banana. You know, there's less of the non-coding sections. So there's clearly something important about these non-coding sections that

Yes, exactly. It shows once again, the arrogance of science, right? But what's fascinating is that in the human genome, there's more non-coding sections of the DNA than there is in like various animal species or a banana. You know, there's less of the non-coding sections. So there's clearly something important about these non-coding sections that

that is important to more intelligent and advanced forms of life. And so there's some alternative science that's happened like in Japan and in Europe and in Russia that is talked about, that's actually gone in to investigate these non-coding sections. And they've seen

that is important to more intelligent and advanced forms of life. And so there's some alternative science that's happened like in Japan and in Europe and in Russia that is talked about, that's actually gone in to investigate these non-coding sections. And they've seen

that is important to more intelligent and advanced forms of life. And so there's some alternative science that's happened like in Japan and in Europe and in Russia that is talked about, that's actually gone in to investigate these non-coding sections. And they've seen

that there is evidence that the non-coding sections of our DNA are used to transmit and receive coherent light that they call biophotons. And so they believe that this non-coding section is in charge of that, the generation, transmission, and reception of biophotons. And it's like this light, this coherent light is used like an information superhighway

that there is evidence that the non-coding sections of our DNA are used to transmit and receive coherent light that they call biophotons. And so they believe that this non-coding section is in charge of that, the generation, transmission, and reception of biophotons. And it's like this light, this coherent light is used like an information superhighway

that there is evidence that the non-coding sections of our DNA are used to transmit and receive coherent light that they call biophotons. And so they believe that this non-coding section is in charge of that, the generation, transmission, and reception of biophotons. And it's like this light, this coherent light is used like an information superhighway

that operates at the speed of light within the DNA to communicate and really send the signals rather than it just relying on chemical kind of signaling. So that's like Fritz Popp, Albert Fritz Popp kind of discovered biophotons and there's some Japanese scientists who looked into that as well.

that operates at the speed of light within the DNA to communicate and really send the signals rather than it just relying on chemical kind of signaling. So that's like Fritz Popp, Albert Fritz Popp kind of discovered biophotons and there's some Japanese scientists who looked into that as well.

that operates at the speed of light within the DNA to communicate and really send the signals rather than it just relying on chemical kind of signaling. So that's like Fritz Popp, Albert Fritz Popp kind of discovered biophotons and there's some Japanese scientists who looked into that as well.

And then there's a Russian scientist, Dr. Peter Garyev, who's, none of them are with us anymore, but, you know, they were alive in the last couple of decades. And Dr. Peter Garyev also looked at these non-coding sections and he saw that the DNA is able to almost like... receive language modulated upon coherent light into the DNA and respond to it.

And then there's a Russian scientist, Dr. Peter Garyev, who's, none of them are with us anymore, but, you know, they were alive in the last couple of decades. And Dr. Peter Garyev also looked at these non-coding sections and he saw that the DNA is able to almost like... receive language modulated upon coherent light into the DNA and respond to it.

And then there's a Russian scientist, Dr. Peter Garyev, who's, none of them are with us anymore, but, you know, they were alive in the last couple of decades. And Dr. Peter Garyev also looked at these non-coding sections and he saw that the DNA is able to almost like... receive language modulated upon coherent light into the DNA and respond to it.

And when linguists kind of analyze the code, the letter sequence of the DNA in the non-coding sections, there's actually more repetition. There's a little more order to it. There's more, you know, they used to call it a stutter. Like you'd have the same letter over and over and over again.

And when linguists kind of analyze the code, the letter sequence of the DNA in the non-coding sections, there's actually more repetition. There's a little more order to it. There's more, you know, they used to call it a stutter. Like you'd have the same letter over and over and over again.