Nanotechnology and artificial intelligence are the ultimate combinations in medical work.

If medicines are equipped with nano-size sensors. That thing makes the system able to observe how chemicals are affecting cells. 

AI can follow the effect of medicine in real-time. That thing requires that researchers will inside put inside medicines the nano-size microchips that can measure things like the electric load of the cells. And those nano-size microchips can also search for things, like changes in the metabolism of the cells and other kinds of things. The nano-size submarines are even more powerful than those medicals. 

The UV-LED can destroy viruses. But it can also destroy bacteria. If the UV-LED slip into the cell it can give radiation to the DNA. And that thing can destroy bacteria as well as it destroys viruses. 

The nano-size submarines can take the miniature UV-LEDs near harmful cells. And those UV-LEDs can destroy the cell. There is the possibility that nano-size UV sources will put in the microchips that are slipping into the cells. And then the UV light will destroy the DNA of the targeted cell. That system can use a battery where iron and gold atoms are given electricity. 

That kind of system can make it possible to destroy bacteria and other harmful cells by using the WLAN or BlueTooth technology. But the nano-size submarines can also transmit images of the cells. And they can search how UV light affects cells that are under radiation. 

Or maybe the futuristic microtechnology can get its energy from the ion pumps. In that kind of system, the nanomachine will touch positive and negative ion pumps at the same time. And that thing can deliver energy to those machines. 

There is also the possibility that the nanomachine puts a small tube in the ion pumps. And that tube will lock those ion pumps open. Or nano-size robot can conduct all electricity from the surface of the targeted cell to itself. And that thing denies the ion pump's ability to work. There are billions of ways how the nanomachine can destroy its target. 

It can slip into the cell and destroy its internal organelles. The nanomachine can simply pull the internal organelles of the cell away. And that kills the cell immediately. Or it can pump the cell full of DNA or fibrine fiber. That thing can make the cell unable to operate. 

https://scitechdaily.com/uv-led-lights-can-destroy-coronaviruses-and-hiv-with-the-flip-of-a-switch/

https://scitechdaily.com/artificial-intelligence-can-accurately-predict-human-response-to-new-drug-compounds/amp/

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New nanocoating destroys bacteria very fast.

"The coating only needed one hour to kill 99.7% of a common pathogen called Staphylococcus aureus." (ScitechDaily.com/99.7% in Only One Hour – New Nanocoating Kills More Bacteria Faster)

The problem with bacteria is that they are turning resistant to antibiotics. Antibiotic-resistant bacteria cause epidemics in hospitals. So researchers must create other methods to use against those things. 

When bacteria are covered by using a nano-size "rivet jacket", it turns to terminate other bacteria. The effect of this "rivet jacket" is simply to make holes in other bacteria membranes. 

The term "nanocoating" means that the bacteria or part of it is covered by using a "plastic bag" or nanotechnical spikes. This thing denies the bacteria's ability to get nutrients. 

That new nanocoating destroys 99% of bacteria in less than an hour. The problem with nano-coating has been that there are lots of bacteria that the layer must cover. So the nanospikes are more effective tools for that thing. 

But there is another way to think. The medicine can cover bacteria by using nanospikes. In that version, the nano spikes will not kill the bacteria that carry them. When another bacteria comes near that bacteria which is covered by using that rivet jacket will destroy other bacteria. The idea is that those spikes that bacteria carry destroy other bacteria by making holes in its membrane. 

There are also plans to use things like genetically engineered bacteria to destroy other bacteria. The idea is that when bacteria are changing genomes the genetically engineered bacteria will split the genome that causes programmed cell death to targeted bacteria. 

And in some other versions, the bacteria can have the genome that makes cancer cells able to steal mitochondria from immune cells. In that model, the bacteria will steal mitochondria from another bacteria that comes to change genomes with that. This kind of thing can use to fight against bacteria that are resistant to antibiotics. 

Image and sources:

https://scitechdaily.com/99-7-in-only-one-hour-new-nanocoating-kills-more-bacteria-faster/