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How to transform cell to the robot?

 

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How to transform cell to the robot?


The best way is to replace the nucleus of the cell by using a microchip, and then the microchip must connect to the cell membrane of the bacteria. The small-size batteries, what are using gold and iron (or some other metal) as battery are extremely multipurpose tools. And the microchip would control the movements of cells very easily. 

It would conduct the electricity to the membrane, and control the movements of the protein fibers. Or it can push the small electric wires to the fibers, which are moving bacteria if those fibers are rotating.  If the robot bacteria would be terminated and the cell-organs will remove which allows the covering of the bacteria by using silicone, and that makes it possible to create the nano-size terminator. 

If the creators of that kind of nanomachines want to transform things like helper T-cells into the robot, they must just remove the nucleus of the cell, and replace it with a microchip. That microchip might have the tank, where is stored the DNA (or RNA) sequences, what is activating the protein or antigen production when the operator wants. The idea is that when the cell is near its target, the tank will open, and then the cell-organelles start the chemical production. Those chemicals can mark every layer as removed, and then macrophages will release to that layer. 


The next-generation optical fibers have 10 000 times lower backscatter


The next-generation optical fibers can make it possible to transmit data without errors by using very small-size lasers. And that thing would give the possibility to use lasers for communicating between things like nanomachines. If we are thinking that we would use cells, what is turned to robots by implanting them by using microchips, the problem is the limits of the energy source. Those systems could use bioluminescence, where the nano-size laser would be made by using the shining bacteria by pushing laser elements in the bacteria. So there are two internal bacteria structures in the system that controls the cell. 

The laser element might have an overlapping tube where are the holes for light. When those tubes are turning the system can cut the entrance of light to the laser element, which can be the thin optical cable. The laser can communicate straight with other nanomachines, or it can send the laser ray to a small radio transmitter, which is on the microchip. That kind of system might make those nanomachines operate together as a team. But they can also be used in full-scale computers because the heat of the system would stay low, and that kind of system would also be energy-friendly. 


https://scitechdaily.com/next-generation-optical-fibers-with-10000-times-lower-backscatter/


Image I: https://thetechjournal.com/science/500-million-year-old-bacteria-resurrected-in-georgiatech-laboratory.xhtml

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