Above this text is the image of the lipid molecule. If the hydrogen atom at the end of the molecules is replaced by using iron or germanium. Those parts of molecules can pull to the right point. So that thing allows making intelligent and very small-size structures. Or when the main molecule is traveling past the bacteria colony, those side-parts can be pulled to the unwanted cells.
And that makes it possible to use nanomachines as the tools of medicines. But as I have written before this thing is the most horrible weapon in the wrong hands. The fact is that by using modern ion technology. Into those structures is possible to connect many other atoms like carbon, iron, silicon, or other molecules.
Those molecules can be used to clean water or they can use as medicals. In the cytostatic, the ends of lipid molecules are equipped with nutrients. That cheats the cell open the ion pump for those molecules. When a cell is accessing that molecule it fills the cell. Or it can simply leave some part of it outside the ion pump.
Lipids or more specifically fat molecules are an important part of nanotechnology. Those molecules can equip with carbon and iron atoms, which allows use for cleaning water. During that process, Those molecule-sized machines can pull back and forth. Those nanomachines travel Between two magnets, and those lipids can clean water very effectively.
If the parts of the molecule have been replaced using magnetic reacting atom. Or carrier enzyme that makes certain cells moving it in a certain direction. That is giving the new ability for that thing. In the wildest visions, the nanomachine is equipped with ion pumps that are taken from the cells. Those ion pumps act as the ion motors, which are transporting those molecules. And the iron-based molecule is making it possible to adjust the direction where that molecule is moving.
That is making it follow the magnet field or homing specific position or make certain things that turn the molecule to the machine. That are turning to make certain things.
Those long-chain molecules are suitable, for example, as nanorobots. So these robots are just molecules to which some kind of enzyme is attached. Those lipid nanomachines can be used, for example, to mark a tumor site or bacterial colony. Or to destroy individual cells.
Those lipids can equip with antibodies, which are making immune cells transport to the bacteria or tumor. When the cell is eating the nanomachine by using its ion channel, the tail of that molecule can stay outside the ion pump. That thing causes the death of the cell. The nanorobots can also connect to small microchips, which are reaching the RFID-sensors. That are marking the unwanted cells.
Then those nanomachines can attack those cells themselves, or they can be connected to the marking antigens, which activate immune defense to attack against those cells. But the use of lipid nanorobots can be even more wide-ranging than people think. By connecting that thing to biotechnology is possible to transport single cells to a specific point in the human body. The idea is that the point. Where a new cell must be taken is marked by the transmitter.
Then the immune cell is turned to the robot by removing its nucleus and implanting it with a microchip, which allows driving that cell to the right position. The lipid molecule is acting as the rope, which pulls the wanted cell behind the nanorobot. When the nanorobot is in the right position, it will put the cell in the right place. And after that, the nanorobot will be destroyed. That helps to fix the things like damages in the blood veins and neural structures.
At first, those lipid molecules will send to the veins, and if there are iron atoms in those molecules, they can be pulled to the walls of the veins. That allows them to make the vein stronger. And then the nanorobots can pull the living cells to the right places for making the new tissue for veins. These nanorobots can also move cloned neurons in the points, where the neurons are destroyed.
Image:()https://www.visionlearning.com/img/library/modules/mid207/Image/VLObject-7483-141201121200.gif
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