Interesting.

It is a hydrophobic molecule, based on a lack of H and OH in the extremities. That's a good thought: I hadn't realized that before.

So to visualize: think of the tactical memory of a magnet approaching another and they have similar polarities (NN or SS) - they repel each other. Hydrophobic surfaces basically repel water on a molecular level.

So this video shows the Ivermectin molecules attaching themselves to the protein bundle in nerve-cell pores (pores are channels that are regulated to convey minerals to the cell.). Because those pores are tubular structures, the Ivermectin forms a life-guard-like ring on those structures. And because the molecule is hydrophobic, the ring pulls outwards, (the molecules are effectively forcing water, and ions between them, into the pore).

Once the molecule attaches itself to proteins utilized by parasites in their cell make-up, the parasite's nerve and muscle response-system is destroyed (and they die) through hyperpolarization of the nerve-cells.

This also reinforces the idea that one must take zinc, magnesium etc. at the same time as dosing with Ivermectin, as it creates an ion-rich environment, to deal a fatal blow to the parasitic beings.

Thank you for posting that video. I was especially impressed with the visualization.

Interesting.

It is a hydrophobic molecule, based on a lack of H and OH in the extremities. That's a good thought: I hadn't realized that before.

So to visualize: think of the tactical memory of a magnet approaching another and they have similar polarities (NN or SS) - they repel each other. Hydrophobic surfaces basically repel water on a molecular level.

So this video shows the Ivermectin molecules attaching themselves to the protein bundle in nerve-cell pores (pores are channels that are regulated to convey minerals to the cell.). Because those pores are tubular structures, the Ivermectin forms a life-guard-like ring on those structures. And because the molecule is hydrophobic, the ring pulls outwards, (the molecules are effectively forcing water, and ions between them, into the pore).

Once the molecule attaches itself to proteins utilized by parasites in their cell make-up, the parasite's nerve and muscle response-system is destroyed (and they die) through hyperpolarization of the nerve-cells.

This also reinforces the idea that one must take zinc, magnesium etc. at the same time as dosing with Ivermectin, as it creates an ion-rich environment, to deal a fatal blow to the parasitic beings.

Thank you for posting that video. I was especially impressed with the visualization. I found another: https://www.youtube.com/watch?v=XTTuUa6Di-c

Interesting.

It is a hydrophobic molecule, based on a lack of H and OH in the extremities. That's a good thought: I hadn't realized that before.

So to visualize: think of the tactical memory of a magnet approaching another and they have similar polarities (NN or SS) - they repel each other. Hydrophobic surfaces basically repel water on a molecular level.

So this video shows the Ivermectin molecules attaching themselves to the protein bundle in nerve-cell pores (pores are channels that are regulated to convey minerals to the cell.). Because those pores are tubular structures, the Ivermectin forms a life-guard-like ring on those structures. And because the molecule is hydrophobic, the ring pulls outwards, (the molecules are effectively forcing water, and ions between them, into the pore).

Once the molecule attaches itself to proteins utilized by parasites in their cell make-up, the parasite's nerve and muscle response-system is destroyed (and they die) through hyperpolarization of the nerve-cells.

This also reinforces the idea that one must take zinc, magnesium etc. at the same time as dosing with Ivermectin, as it creates an ion-rich environment, to deal a fatal blow to the parasitic beings.

Thank you for posting that video. I was especially impressed with the visualization.

Interesting.

It is a hydrophobic molecule, based on a lack of H and OH in the extremities. That's a good thought: I hadn't realized that before.

So to visualize: think of the tactical memory of a magnet approaching another and they have similar polarities (NN or SS) - they repel each other. Hydrophobic surfaces basically repel water on a molecular level.

So this video shows the Ivermectin molecules attaching themselves to the protein bundle in nerve-cell pores (pores are channels that are regulated to convey minerals to the cell.). Because those pores are tubular structures, the Ivermectin forms a life-guard-like ring on those structures. And because the molecule is hydrophobic, the ring pulls outwards, (the molecules are effectively forcing water between them, into the pore).

Once the molecule attaches itself to proteins utilized by parasites in their cell make-up, the parasite's nerve and muscle response-system is destroyed (and they die) through hyperpolarization of the nerve-cells.

Thank you for posting that video. I was especially impressed with the visualization.