The triumph of nanotechnology.

In some visions, the medicines of tomorrow are things like nanocrystals. When the medicine or those nanocrystals are in targeted cells, the acoustic system will resonate with those crystals. And that resonance will destroy those cells.

The other version is that the nano-size microchip there is electrical resistant. And would slip into the cell. Then the radio wave activates the system. And the resistance causes the temperature in the cells to start to rise.

The precise, super-resolution DNA analysis is one of the most remarkable things in history. In the future, the super-resolution DNA scanner that uses nanopore and scanning ion-conducting microscopes can install in the nano-size submarine. The system can search for things like cells that are infected by some virus.

And if that system has a certain system like precisely targeted ultrasound systems that kind of thing can be useful in medical work. The system can destroy targeted cells with very high accuracy. And it also can detect some non-wanted mutations. Nanotechnology allows the removal of non-wanted sequences of DNA and replacing them with non-mutated DNA sequences.

The same system that scans the DNA can use to scan other molecules. And that thing makes it possible to create more complicated nanostructures than ever before. The ability to see molecules and its participant is one of the most vital things in nanotechnology. Nanotechnology allows researchers to create the sharpest tools in the world. Nanomachines can use as common medicines against bacteria and cancer cells.

The same machines can remove blocks from veins. The work of nanomachines is mechanical. And that means they just cut the membrane of the targeted cell. Or they can just cut things like fibrine fibers from the veins. Those systems can use things like nano-lasers, ultrasound, or mechanic cutters for that mission. The problem with that technology is how to control those extremely small-size robots.

"EPFL researchers led by Dr. Aleksandra Radenovic have advanced nanopore technology by integrating it with scanning ion conductance microscopy. The resultant technique, scanning ion conductance spectroscopy, offers unprecedented precision in controlling molecular transit speed, yielding a significant signal-to-noise ratio increase. This versatile method could greatly impact DNA analysis, proteomics, and clinical research. Credit: Samuel Leitão / EPFL" (ScitechDaily.com/Super-Resolution DNA Analysis: Multi-Scanning Individual Molecules for Extreme Precision)

Maybe in the future, we have a pill that makes everything.

There is already a soft, silicon-core robot, that can travel through the alimentary canal and search things like what kind of bacteria is there. Those robots also can take samples from the alimentary channel or can have a microscope that allows the system to search things like blood or some parasites.

Those robots are used to search for what kind of food things like sharks are eating. When we are thinking of robots that travel in the human body, those robots can communicate with cell phones. They can transmit information on how stomach and stomach nerves are functioning.

In some security versions, the pill that person eats is the GPS and maybe a system that observes also vital signs. And it could be useful in military operations. When a person eats this emergency pill it sends location and warning signs to their troops. And it can tell if the person is under heavy stress.

But nanotechnology makes those things even more powerful. And maybe everything that we need is in pills like the song In the Year 2525 predicts. The pills are excellent tools for transferring sensors and nano-size machines in the human body. Intelligent nanomachines can destroy cancer cells or bacteria.

Maybe the vision of the pill can drive information in our nervous system or make the diagnosis and give treatment for multiple diseases closer than we think. That kind of pill can base on a nano-size robot submarine that we can eat inside the pill. When we are eating that small robot submarine. It will take a touch to the stomach nerve.

And then it can follow our nerve signals. The submarine can also deliver small sensors in the human body or it can have a nano-optical microscope that it can use to find non-wanted cells. Then the system can release nanorobots that can attack those cells. When this submarine will need to load information into the nervous system it just transmits electric impulses to the stomach nerve. And that thing makes this kind of pill a very multi-use system.

https://scitechdaily.com/super-resolution-dna-analysis-multi-scanning-individual-molecules-for-extreme-precision/?expand_article=1

https://scitechdaily.com/the-future-of-medical-diagnostics-all-purpose-biosensor-chip-with-10000-fold-increase-in-detection-range/

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