Mike Adams highlights Cornell's Andrej Odryzwolek's breakthrough showing all elementary math functions derive from a single NAND gate, unifying microprocessor logic with biological systems like E. coli and yeast. This discovery suggests light-based computing could revolutionize AI efficiency while supporting Adams' theory that the universe is a self-computing simulation where natural intelligence, driven by light rather than artificial constructs, performs real-time calculations to collapse probability fields. Ultimately, this implies darkness represents ignorance while light serves as the fundamental source of wisdom and life within our cosmic construct. [Automatically generated summary]
Transcriber: CohereLabs/cohere-transcribe-03-2026, sat-12l-sm, and large-v3-turbo
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Why I Left Engineering00:02:46
Well, we are sure on a weird timeline.
That's for real.
Welcome.
Mike Adams here.
I've got a number of important things to share with you.
One of them comes from a breakthrough science paper today that you may or may not care about, but it's something that blew my mind.
And it's a science paper that shows that all elementary functions of math sine, cosine, tangent, Exponentials, log functions, powers, roots,
hyperbolic functions, pi, etc., can be derived from one binary operator, which in computer hardware is called a NAND operator.
That's N A N D, which is a not AND, by the way, in case you're wondering, or a NAND gate.
And this really blew my mind because this is one of the most important and profound discoveries.
Frankly, in the history of computer science and computer hardware, and I'll explain it a little more in a second.
But the reason this matters is because this is going to revolutionize the design and the scaling and the ease of manufacturing things like GPUs for AI inference, as well as microprocessors, all kinds of electronics will be impacted by this.
Now, a NAND gate, as I said, it's a not.
And gate.
Now, the reason this intrigued me is because you may or may not know this, but I originally went to college to study electrical engineering.
I was going to be a double E.
Yeah, because, well, you know, I aced all the math of the college entrance exams and I was given numerous scholarships and opportunities.
I was actually invited to attend MIT, but I didn't have a I didn't have a full ride to MIT.
And so I met with an MIT advisor.
And I don't know if it's still the case, but there were MIT advisors, you know, alumni all over the country.
And so I actually visited and met with an MIT alumni who looked at my scores and said, yeah, you should go to MIT, but you're going to need about $50,000 a year to pay for room and board and food.
you know, whatever, plus the tuition that you need, because again, I didn't have Fulbright scholarships there.
The MIT Money Problem00:04:39
So I didn't have that kind of money.
This was in the 1980s.
I lived in the Midwest, middle class family.
My parents didn't have that kind of money.
I was mowing lawns, you know, for a couple of dollars.
So no, I did not go to MIT.
But I did initially my first semester of college, I was actually studying to be an electrical engineer.
But it turns out that, as fate would have it, just because you're good at something doesn't mean that you love doing it.
I was really great at math, but it wasn't what I loved doing.
And I ended up doing a lot of other things, more arts kinds of things, writing, actually a lot of creative writing and things like that, and also learned how to juggle.
That was, oh, I'm sorry, that was my second semester in college.
I learned juggling flaming pins and also.
I think it was my second year in college.
I learned how to juggle seven rings with a homeless British man who would hang out on campus.
I mean, his name was Andrew, by the way.
His name was Andrew.
And he was homeless, long hair.
And he just would hang out on campus.
And he was a juggler.
So he would juggle in the commons area.
And he would juggle rings and pins and stuff.
And one day I had time between classes.
And I said, hey, I wouldn't mind, because I learned how to juggle a couple of semesters ago with some pins, flaming pins.
And you want to throw some pins around here?
Let's just do some juggling.
And he was like, hell yeah, I've been waiting for that.
Well, with a British accent.
And so he first taught me how to juggle six pins between two people.
And that's actually pretty easy, it turns out.
Six is not a problem because the rhythm works.
If you know anything about juggling, you juggle three pins, and it's one, two, three, one, two, three, one, two, three.
It's just like juggling three balls or three beanbags or whatever.
It's one, two, three, one, two, three.
So if you're juggling six pins between two people, it's the same thing.
Three, but it's like one to throw or one to pass, one to pass, one to pass.
Or you can increase the passing if you can pass more than one at a time.
But anyway, when you want to go to seven pins or seven rings, things get crazy because then you have an extra pin in the pattern.
Now you got to do some funk, some funky rhythms and things.
And that was extremely difficult, but over the period of the semester, While mostly skipping class, I did learn how to juggle seven pins and I did some amazing creative writing.
The problem was I wasn't enrolled in any creative writing classes, and so I ended up changing my major to becoming a well, we called it technical writing.
It was an interdisciplinary degree.
And my college advisor, who was it?
His first name was Doug.
What was his last name?
He was like a very well known writer, a PhD.
I mean, obviously, PhD.
He was like, I don't know, he was a very successful writer.
Anyway, he became my advisor and he advised me through the rest of my college education with a degree in technical writing, which combined, interestingly, mathematics and economics.
I ended up with a minor in economics.
I think I ended up with a minor in math, too, come to think of it, but.
Pretty much forgotten those classes.
That was not the fun stuff.
And then I did a lot of writing, and I ended up graduating with this degree, and I ended up being a technical writer.
And I got my start out of college writing software manuals for antivirus security companies.
And actually, one of the main companies I worked for in its early days, I lived in Taiwan, and I wrote the documentation for the company now known as Trend Micro.
So, you've heard of Trend, you know, they're one of the biggest antivirus software companies and security companies in the world.
And they had a major investment from SoftBank, which is a Japanese venture capital company.
And I was actually there when that investment came in.
Light Gives Rise To Math00:15:18
And I was part of a team of like, I don't know, 20 people or something that we had.
And, you know, used to hang out with the engineers and we would talk about antivirus security and talk about heuristics and everything.
And then I would write up the manuals.
I did all the documentation for antivirus security software.
So, that.
I explain all that to share with you that yes, I actually got my start in electrical engineering.
And so.
I had classes in circuit design, and so we would do logic gates, and we would do like, you know, OR and AND, obviously, and then NOT AND, which is NAND.
Or, of course, there's NOR, and, you know, there's a bunch of different logic gates.
And you put billions of these together, and you have a microprocessor.
I mean, I'm oversimplifying it, but that's basically how it works.
And then, you know, we studied what is a transistor, how do transistors work, and, you know, you have the control that comes in and allows the.
Allows the signal, the high voltage signal, to either pass or to be stopped based on the control signal.
So that's how transistors work, but they're actually little quantum devices.
Nobody exactly knows entirely how they work, but whatever.
We know how to harness them and make microprocessors.
So I don't mean to geek out on you here, but I have to explain why I got so excited about this paper.
Because, you know, if you want to build a microprocessor that does things like, let's say, addition.
You know, you could do that.
You can do that with just logic gates.
You can do it with, you know, ands and ors and whatever.
And you have to have enough registers of the bits to store the current status.
And of course, all of this is happening in binary, which is later translated into either hexadecimal or decimal.
And you have to have a clock with a cycle timer.
And that's what it means when you have a CPU that's got like, You know, five gigahertz or whatever, that's five billion cycles a second.
So there are five billion clock steps happening per second that allow each of the logic gates to process one incoming, what do you even call it?
I don't know, one like one pending little operation at that logic gate.
So, you know, a clock determines the cycling, how quickly things move through the logic gates.
But if you combine enough of these gates, then you can create addition.
You can create subtraction.
If you get more complex, you can create multiplication, et cetera.
And this is all like really old school circuit design from the 1970s, let's say.
But then, as time went on, and the circuit designs and the microprocessors had multiple cores and multiple pipelines, and then the CPU to memory bandwidth and the speed of that bandwidth became very important, the speed of communication between memory and the CPU became critically important, especially now in the age of AI inference.
And that's why high bandwidth memory is in such short supply right now.
And that's why GPUs are expensive because they have to use very high speed memory because they have to shuttle all of the storage states back and forth between the CPU on the GPU, which I guess technically you just call it a GPU.
But anyway, so this paper comes out and says you can do everything with just one logic type, and that's called the NAND or the NOT AND.
And I'm like, whoa, are you kidding me?
You know, you're giving me chills.
Is this for real?
This is crazy.
Yes, you can do almost, well, nearly everything with a NAND gate plus the number one.
So you need the NAND gate and you need the integer of one, which kind of makes sense.
So you might wonder what is a not AND gate?
Well, let's start with an AND gate.
So an AND gate.
It has two inputs and one output.
So, an AND gate means that if input 1 and input 2 are both true, let's say, although it's represented by higher voltage, but whatever, they're both true, then the output is set to true.
Or you could say if both of the inputs are equal to 1, then the output is 1.
That's called an AND gate.
Like A and B have to be true for the answer to be true.
That makes sense.
That's reasonable.
Well, a NOT AND is a little bit different.
What it means is that a not AND gate is only, well, let me say it this way.
When the inputs are both true, then the not AND gate produces false on the output.
Okay?
So it's the opposite of AND.
And if one of the inputs is true and one of the inputs is false, then the output of the NAND gate is true.
Okay?
So in other words, both of the inputs have to be true for the NAND gate to produce a false or a zero.
or a low voltage.
That kind of gate actually can be built in physics.
Just like a transistor can be built, or an AND gate, or an OR gate, etc.
These can be built in physics, and they are.
They're built in physics all the time.
And what this means is that since this is now a fundamental physical phenomenon that is consistent with the laws of physics and the way the universe works, what this means is.
That this is part of sort of God's logic.
This is part of the logic of the cosmos.
And it can be scaled very easily with the same component just massively scaled over and over and over and over and over again, billions of times or trillions of times, even potentially, but just arranged in a certain way.
And if you arrange them in a certain way, then you can produce almost all math.
So, And there are, and I simplified, it's not just two inputs of NAND gates.
There are also three input NAND gates.
And then you can kind of cobble these together.
You can do four input functions, which begins to be groups of NAND gates.
And then you can put NAND gates with NOT gates.
And you could create any kind of logic you want.
Anyway, those of you who are electrical engineers, you know exactly what I'm talking about.
And those of you who aren't electrical engineers, you probably don't care what I'm talking about.
But the reason you should care is because.
This is kind of like the equivalent of finding the God particle in physics.
Or this is the equivalent of discovering the unified field theory of, let's say, electromagnetism or something.
That's what this is.
This is such a big deal to find.
It's a unified logic gate.
The NAND gate, or not AND, is the unified logic gate behind almost all math that is physically imprinted into the structure of the cosmos.
That's a big deal.
It's almost like if you're going to find this funny, but you know how I've said like carbon dioxide is God's molecule?
The NAND gate would be God's logic, or God's logic function, let's say, NAND.
It's the basis of all math and all AI, or nearly all, not exactly all, but most of it.
So, That's a pretty big deal, folks.
So I'm actually reading from the paper here.
It says, a single two input gate suffices for all of Boolean logic in digital hardware.
Wow!
Wow!
And the paper goes on, no comparative primitive has been known for continuous mathematics.
Computing elementary functions such as sine, cosine, square root, and log has always required multiple distinct operations.
But here, in this paper, I show that a single binary operator, together with the constant 1, generates the standard repertoire of a scientific calculator.
This includes constants such as e, pi, and i, or, you know, imaginary.
Arithmetic operations including addition, subtraction, multiplication, division, and exponentiation, as well as the usual transcendental and algebraic functions.
Wow!
The paper goes on and says that such an operator exists was not anticipated.
I found it by systematic exhaustive search and established constructively that it suffices for the concrete scientific calculator basis.
So every such expression becomes a binary tree of identical nodes, yielding a grammar, like a hardware grammar, a structure of how these are put together that is simple.
This uniform structure also enables gradient based symbolic regression using EML trees as trainable circuits with standard optimizers.
It goes on, I demonstrate the feasibility of exact recovery of closed form elementary functions.
From numerical data at shallow tree depths up to four, the same architecture can fit arbitrary data.
Anyway, he goes on and obviously gets a little bit more technical here.
And this is from Andrej Odryzwolek.
Okay, I'm guessing that's either Ukrainian or Russian or something similar.
All right, so this is being published in the symbolic computation category of, oh, it's from Cornell University, I think.
All elementary functions from a single binary operation.
That's the name of the paper.
Holy cow.
Again, I'm sorry, I can't cover up my excitement about this.
I mean, it would be like finding a subatomic particle that was.
Responsible for all mass, or something like that.
You know, it's that big.
I think it's that big of a deal.
This is a big deal.
What will we do with this knowledge?
Who knows?
I mean, there's so many applications of this, but I want to add that I bet you we can find this in nature.
I bet you this is all over nature.
I bet this is in plants.
I bet it's in different ways of processing light.
I bet you that optoelectronics or optics as computational devices.
I bet you there are NAND gates when it comes to light processing.
And so you could actually end up with optoelectronic light computers that use a fraction of the power of the current electron based systems and also don't generate much heat at all.
And I bet you we could take AI inference and we could make it a million times faster and a million times cheaper with a million times less heat, et cetera.
By using NAND gates in light circuits or light Boolean logic.
I'm just guessing.
Actually, you know what?
Now I got to look that up.
Let's see.
All right, so I'm asking Are there NAND gates in optoelectronics and light based computing?
Here's the answer yes.
NAND gates are fundamental components in both optoelectronics and all optical logic systems.
Okay, well, I guess that's not such a huge realization then because.
The answer is basically saying, well, of course there are NAND gates.
Yeah, obviously.
Serving as universal building blocks capable of cascading to perform any complex logical operation.
Yes, that's what we're saying.
Recent research has successfully demonstrated these gates using diverse mechanisms, including diffractive neural networks.
Holy cow.
Gallium arsenic heterostructures.
Wow, that's interesting.
And nanowire networks.
Wow, okay.
Gallium arsenic heterostructures?
Man, that would be like you could turn solar panels into machine consciousness.
I don't know.
Let's see.
Semiconductor heterostructures.
What are the novel structures based on gallium arsenic quantum wells?
There you go, quantum wells and zinc oxide ITO devices have realized NAND gates that operate at room temperature, offering advantages such as polarity independent operation and radiant emission.
Whoa.
Wow, what a great way to get rid of heat in space.
That's awesome.
Nanowire systems?
All optical NAND gates have been constructed using aligned nanowire networks, where logic inputs are defined by laser wavelength and polarization, enabling arithmetic functions like binary addition.
No way!
By polarization?
So, polarization would indicate zeros or ones instead of voltage differences.
So, that way you would conduct the computation at maybe six to nine orders of magnitude less energy.
Oh my God.
Well, clearly, maybe I should have been an electrical engineer because to me, this is really fascinating stuff.
Okay, look, I'm not going to keep hammering you with this, but I just want to emphasize.
That, you know, to those of us who are interested in the way things work, which I assume includes most of you listening to this, this is a very big deal.
And what it means is that we are nowhere near the peak of computational efficiency or scalability.
Now, we have achieved, let's say, the end of Moore's Law, named after, you know, what was the co founder of Intel, which said, I believe that the number of transistors on any microprocessor would double every, what did he say?
Life As A Cosmic Simulation00:14:57
Was it 18 months?
Roughly 18 months, give or take.
But that has reached a physical limit because of the physics of transistors.
You can't just keep squeezing more and more transistors onto a computational platter because you start getting into, I think, not just nanometers, but picometers.
And you get to the limit of.
Of how physics can function in a working transistor.
And we're very close to that limit right now.
But we are nowhere near such limits when it comes to optoelectronics and light processing.
And since I guess you can polarize light to be zeros or ones and you can use NAND gates in optoelectronics, then based on this paper, we now know that light gives rise to all math.
And that's kind of biblical.
That's kind of like God said, let there be light, and then it gave rise to everything.
You know?
I mean, I'm saying that kind of poetically, let's say.
I'm not saying that light created, you know, mass or the rules of mass and space time distortions and all of that.
But I am saying that light is far more functional than most people have ever probably understood.
And this brings me to my conclusion of this podcast.
And you may find that a relief if you think I've been nerding out here, so I apologize.
But.
I believe, you know this, I believe that we live in a simulation.
And this simulation is a self-computing simulation.
We live in a cosmos that is a giant computer.
And everything that's happening around us in real time is constantly recomputing its state.
So that's not just spin states of subatomic particles or what have you, protons.
It's more than that.
The entire fabric of reality is actually only being projected into existence and actually, let's say, collapsing the probability fields by doing computations when you are observing it.
And so, we as observers, we're living in a computational simulation that is efficient because it only does the math when it needs to.
When you're noticing things, it doesn't have to do the math all the time for things that people aren't looking at, you know.
But when you look at it, then the, you know, all the probabilities collapse into the calculated current state, you know, Heisenberg principle and all that.
Quantum mechanics, right?
I mean, it gets into many interesting areas.
But light is the key computational backbone.
Light is the computational infrastructure of our cosmos.
That's what I believe.
And I know that lots of people have all kinds of fun blowing their minds with the double slit experiments and, like, does it go back in time if you use a mirror over here and then it reflects half of them over this way?
And then, oh my God, you know.
Have you seen those experiments?
They're all kinds of fun.
And if you try to think about it rationally as if light is a particle, then it makes no sense.
And also if you try to think about, oh, light is a wave, then it makes sense sometimes, but not other times.
The real way to look at light is that light is math.
And the computation of the math isn't actually completed until it needs to be.
And the math will be completed at the most efficient possible path of the light based on you as the observer also taking that into account.
So, I mean, I could go into more detail, but this is why the double-slit experiment is so baffling to people, because they don't realize that they are part of it, that they as the observers are part of the experiment.
And if you're not observing, if you're not looking, if you're not tied in, I mean, they have remote instruments that do the counting, but that still requires a human observer.
To be aware of what's happening.
Anyway, there are different kinds of ways to test all of this and go back in time, things like that.
But we are part of the experiment, and light is doing math.
That's my point.
Just that light is doing math.
And yes, I'm oversimplifying a lot of stuff, just in the interest of time.
But light is doing math.
And think about what that means in your body.
You know how, like earlier today, I was out getting sunlight.
You know what I like to do?
I've said it many times here.
You know, I get as naked as possible and I run around the forest with sunlight.
That's called exercise and sunbathing at the same time.
I mean, I'm not actually naked.
I have shorts on, but I'm shirtless, right?
So I'm running around with no shirt and shorts and tennis shoes and getting sunlight.
Well, what do you think that that light is doing in your body?
It's doing math in your body, okay?
It's not just warmth, it's not just making vitamin D.
The light is actually activating an intelligence in your body's.
Cells.
This is why red light therapy is so amazingly healing, by the way.
And all the different wavelengths matter so much.
And you know, if you get sunlight more midday, you're getting the shorter, more yellower wavelengths.
And then if you get sunlight in the afternoon or closer to sunset, you're getting the deeper red, more reddish wavelengths that are longer wavelengths that penetrate your body more.
And each of these different frequencies of light has a different kind of math that comes with it.
And it interacts with your body and your cells and the.
innate intelligence of your cells in different ways based on what your cells need, what you're lacking, you know, what you're trying to get rid of disease or whatever.
So light is not just math.
It's not just the mathematical backbone of the universe.
Light is also medicine.
Light is medicine, yes.
And when you understand that, you know, then you understand why there's evil in the world.
That is always talking about darkness.
And like Israel, they launched a bombing campaign of Lebanon and they called the campaign Eternal Darkness.
Like that was their actual name.
And it makes perfect sense because if you're evil and you're dark, you're going to be talking about darkness.
If you're good and positive and loving and compassionate, you're going to be talking about light.
Whereas, you know, darkness is ignorance and darkness doesn't do any math.
Darkness can't solve any problems.
You know, it's the light.
It's the living light.
It's the energy of light.
It's the wisdom of light.
It's the backbone of the entire construct in which we live, which is, again, a computational simulation.
And it's funny because sometimes people ask me, well, if this is a simulation, where are the computers that run it?
And I'm like, dude, we're living in the computer.
We are in it.
This whole system is the computer.
You look around.
I mean, again, the light is doing math all the time.
Photons, or, you know. make believe photons, electrons, which aren't even real exactly, but you can call them that.
It's doing math all the time, all the time.
Spin states, orbital patterns, whatever.
It's doing math.
Everything around us is doing math.
So the computational infrastructure of the simulation is not only all around us, it's also within us.
It's in our cells.
It's in our neurology.
It's in our voice.
It's in our consciousness.
We are part of the computational infrastructure of the cosmos.
Understand?
So it's not like, oh, there's a computer out there above all of us somewhere, like there's a giant server room in another dimension that is rendering this reality.
No, we are co rendering this reality as we also experience it.
We are interacting with the light, we are beings of light.
We are beings made of atomic matter that ultimately is an expression of light, you know, the conversion of matter to energy, et cetera.
So I don't want to get too carried away here, but yes, when I saw the science paper, it reminded me of all this stuff.
It's like, oh my God, this is proof of the simulation yet again, or at least another demonstration of the simulation that.
The fundamental logic of the cosmos.
I mean, you can derive almost all math from one fundamental logical function that we now know, since I just looked it up, is also part of optoelectronics.
Isn't that interesting?
Isn't that interesting?
And again, I bet you we would find this throughout nature.
We would find it in animal physiology, we would find it in plants.
There might be something like this in.
I mean,.
At the chemical level, you know, I'm talking chemistry, I'm talking proteins, protein folding perhaps, you know, I bet you, I bet you there are NAND operations in biology.
Okay, now I got to look that one up too.
Okay.
All right, I typed in, are there NAND logic operations found in biology?
And here's the answer.
My God, blow my mind again.
Yes, NAND logic operations have been successfully engineered and validated in living biological systems, including E. coli and yeast.
You didn't know that, huh?
So the E. coli in your peanut butter, it's actually microprocessors in there.
These gates are typically constructed by combining AND and NOT gates or by utilizing protein-protein interactions coupled with DNA looping to produce a high output whenever at least one input is low.
That's the NAND logic.
So, yeah, you can do it in yeast, which is Saccharomyces cerevisiae.
Okay, I'm not familiar, obviously.
You can do it in E. coli, which means there's probably NAND logic in your gut.
Because you have E. coli in your gut, probably.
I mean, hopefully.
If you don't, you're in trouble.
There's NAND gates across Bacillus, Clousey, and humans.
What?
Confirming their existence as functional components in synthetic biology.
There are 10 experimentally validated NAND gates across different species.
Oh, oh my God.
So NAND operations have been performed using DNA translocations through biological nanopores in droplet networks.
Yeah, that wasn't on my bingo card for today.
But there we go.
See, I mean, I knew it.
I knew it.
Looked it up.
It's true.
Of course it's in biology because it's a basic function of the cosmos.
NAND gates.
Not Bill Gates, but NAND gates.
It's amazing.
It's amazing.
So what does that mean?
What if, think about it, if it's in E. coli and it's probably in your gut bacteria, what if your gut bacteria are freaking doing math?
Like, they're probably doing more math than most of us do on a daily basis.
There's a lot of math going on in your gut.
Yeah, you might be crapping integers at any moment.
Who knows?
Or, you know, hurling fractions.
I don't know.
This is up to you.
But, okay, anyway, I'm going to end it there before this gets completely out of control.
Wow, wow, we live in an amazing universe, and I would say God is everywhere.
God, I mean, God, the designer, the engineer of this entire simulation, our creator, has built the entire computational infrastructure into literally everything into the elements, into the rocks, the dirt, the microbes, the freaking light rays, the water, the biology, neurology, everything.
Everywhere you look, there's intelligence.
This is why I've said to people, you've heard me say this, if you've listened for very long, I've said there's no such thing as artificial intelligence.
All intelligence is natural.
And it's a natural part of the construct of the simulation.
All intelligence is natural.
Even microchips.
It's all natural.
Wow.
Bottom line, I'm so glad that the darkness isn't going to win.
Because there's light and wisdom and intelligence everywhere.
You know, the ultimate love of the Creator is found in the fact that our Creator infused life into every single thing that makes up the universe around us, including electromagnetic propagation, as we call it in certain frequencies, light.
But, you know, It goes way beyond what we can see, obviously.
So, most light is invisible to humans, obviously, or what we would call electromagnetic propagation is invisible to us, which means that most of the mathematics is taking place in the universe is also invisible to us.
It's a great unseen computational backbone of the cosmic simulation that we are inhabiting.
Vitamin D For Optimal Health00:04:47
So I'll just leave you with that thought for today.
Hopefully, that'll kind of pull you out of the doldrums of all the Iran war and the Strait of Hormuz and gas shortage and all that garbage.
Think about the fact that the universe is an amazing simulation infused with incredible gifts of computational infrastructure and that you are part of it and that it's part of you.
It's in your cells, it's in your gut, it's in your neurology, it's in your perception, it's in your consciousness, and you interact with it, and you can even sort of hack it.
You can change it by changing your perceptions and changing your intentions, changing your speech.
You can actually sort of reform the entire system around you because it responds to your consciousness.
Anyway, I'll cover that another time in more detail, but what an incredible day, an incredible science paper.
And an incredible realization about the world or the universe in which we live.
So I'm Mike Adams.
Thank you for listening.
If you want to hear more of my podcast, you can track me at brightvideos.com and also naturalnews.com.
And I am an AI developer and I'm working on some really interesting AI projects right now, specifically about generating documentaries with nothing but local open source AI.
Hopefully, I'll bring you some of those results pretty soon.
Thank you for listening.
Take care.
We now have vitamin D3 plus K2 plus Aquaman, which is a seaweed calcium available at healthrangerstore.com.
Here, I've got it up on my site.
This is the GroovyBee brand that we have, which is our in house brand, healthrangerstore.com.
Again, vitamin D3 plus K2 with Aquaman.
That's the brand of the seaweed calcium in a capsule format.
Of course, It's laboratory tested for heavy metals and glyphosate and microbiology and so much more.
And it's certified ingredients, of course.
And, you know, everything that we build for you in terms of a product is meticulously sourced.
And one of the most difficult products to source is actually vitamin D3.
It's extremely difficult because it turns out in the supply chain, almost all vitamin D has a bunch of sort of unnamed ingredients in it.
And that's what our sourcing people found after.
A couple of years of trying to source a clean version of vitamin D3 that we finally found and nailed and put it in the formula and did all the lab testing and certification.
So now it's available.
So, this synergistic combination, if you think about natural bone support, for example, or you think about the fact that so many people may not have sufficient levels of vitamin D for just optimal health and immune support and many other reasons to have vitamin D levels, this product can help you supplement that.
And so it's available now, healthrangerstore.com, vitamin D3 plus K2 with Aquaman, 60 capsules available, shipping right now while supplies last.
And in this environment where global supply chains are getting wrecked, if this is something you want, get it now while we have supplies, because it's becoming more difficult and more expensive to source literally everything at this point.
So, anyway, thank you for your support.
You can also find many other products, of course, hundreds of different products at healthrangerstore.com, including storable food.
And right here, we have our organic powdered chicken bone broth in a number 10 can, our turmeric root powder, and so much more.
We've got so many amazing products for you to choose from, including tinctures, superfoods, storable foods, as well as freeze dried fruits and vegetables in sealed number 10 cans.
That's great for long term storage.
Plus, we have iodine, and that's a product that's moving very quickly because of concerns about global nuclear war, unfortunately.
But you can find all of this, it's all laboratory tested.
Certified, it's all meticulously sourced at healthrangerstore.com.
And yeah, there we go.
That's what the vitamin D3 looks like there.
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I'm Mike Adams, the Health Ranger for healthrangerstore.com.