Christian Drapeau

It will stimulate mitochondrial function because these stem cells now, one stem cells migrate into your muscle, That stem cell is irrelevant. What is one stem cell among the 10 billion cells in your muscle right now? It's irrelevant.

It will stimulate mitochondrial function because these stem cells now, one stem cells migrate into your muscle, That stem cell is irrelevant. What is one stem cell among the 10 billion cells in your muscle right now? It's irrelevant.

But if that one stem cell becomes a million stem cells, and let's say a million stem cells have migrated in that tissue and they all become 100,000 tissue cells, now you've got robust repair. So going from one stem cell to many tissue cells, that process of expansion and amplification requires massive genesis of mitochondria, mitochondrial biogenesis. So massive.

But if that one stem cell becomes a million stem cells, and let's say a million stem cells have migrated in that tissue and they all become 100,000 tissue cells, now you've got robust repair. So going from one stem cell to many tissue cells, that process of expansion and amplification requires massive genesis of mitochondria, mitochondrial biogenesis. So massive.

So as you support your mitochondria, you're going to support the amplification of these stem cells and you fully support the repair process. But it's the stem cells that did the process. So you can think of almost like anything that is supporting repair like mitochondrial function. And it's because it's going to leverage stem cell function.

So as you support your mitochondria, you're going to support the amplification of these stem cells and you fully support the repair process. But it's the stem cells that did the process. So you can think of almost like anything that is supporting repair like mitochondrial function. And it's because it's going to leverage stem cell function.

I am, and I don't have an answer because they're too recent now in science. So I'm not aware of how the two are working together. But if I were to gamble, I would bet on this way more than I would bet on the Super Bowl. I would bet without hesitation. It has to be related. It has to be that BPC-157 or any of those peptides.

I am, and I don't have an answer because they're too recent now in science. So I'm not aware of how the two are working together. But if I were to gamble, I would bet on this way more than I would bet on the Super Bowl. I would bet without hesitation. It has to be related. It has to be that BPC-157 or any of those peptides.

There's no doubt in my mind that somewhere they leverage stem cell function.

There's no doubt in my mind that somewhere they leverage stem cell function.

It's probably one of the conditions. So we have studies now with the plants that I use to stimulate stem cell release. We have one study ongoing on congestive heart failure, one on Parkinson's. We're starting one on COPD emphysema. We're starting one on liver failure and one on colitis. And the reason why we're targeting this condition is just because of what we have seen historically.

It's probably one of the conditions. So we have studies now with the plants that I use to stimulate stem cell release. We have one study ongoing on congestive heart failure, one on Parkinson's. We're starting one on COPD emphysema. We're starting one on liver failure and one on colitis. And the reason why we're targeting this condition is just because of what we have seen historically.

So the gut is a really good example because... Organs that have a very rapid turnover rate, like the liver, for example, a fairly rapid turnover rate. If you don't have enough stem cells, but you have a degenerative process that is affecting that tissue, the decline can be fairly quick. But the repair can also be fairly quick.

So the gut is a really good example because... Organs that have a very rapid turnover rate, like the liver, for example, a fairly rapid turnover rate. If you don't have enough stem cells, but you have a degenerative process that is affecting that tissue, the decline can be fairly quick. But the repair can also be fairly quick.

You just suddenly provide more stem cells and the tissue will suck up these stem cells. And that's where colitis comes in. You have a new lining of the intestinal layer just about every five days. So your fine, fine intestinal layer is epithelial layer of the mucosal, intestinal mucosa is one cell thick layer. And it's filled with stem cells.

You just suddenly provide more stem cells and the tissue will suck up these stem cells. And that's where colitis comes in. You have a new lining of the intestinal layer just about every five days. So your fine, fine intestinal layer is epithelial layer of the mucosal, intestinal mucosa is one cell thick layer. And it's filled with stem cells.

These stem cells are going to constantly replenish and renew the lining of the intestine. So if you've got an insult in one area of the intestine where you have an inflammatory process that is going to overcome or overwhelm, I should say, the speed and efficiency at which the intestine can renew itself, then there's a place where the tissue is degraded and now you have an acute phase.

These stem cells are going to constantly replenish and renew the lining of the intestine. So if you've got an insult in one area of the intestine where you have an inflammatory process that is going to overcome or overwhelm, I should say, the speed and efficiency at which the intestine can renew itself, then there's a place where the tissue is degraded and now you have an acute phase.

You bleed, you have pain, you have everything that is associated with colitis or poor gut. I'm not talking about flora here. I'm talking about the lining of the gut. If you put more stem cells in circulation, stem cells in circulation can replenish tissue stem cells, and now the tissue stem cells will renew the tissue.

You bleed, you have pain, you have everything that is associated with colitis or poor gut. I'm not talking about flora here. I'm talking about the lining of the gut. If you put more stem cells in circulation, stem cells in circulation can replenish tissue stem cells, and now the tissue stem cells will renew the tissue.