Microfluids, acoustic systems, and nanotechnology are the ultimate combination.

 Microfluids, acoustic systems, and nanotechnology are the ultimate combination. 

The new types of advanced robots combine microfluidics and acoustic technologies. The small-size molecular propellers making possible to move single atoms or molecules. Extremely small nano-size whips that operators use under very powerful microscopes make it possible to create new types of 3D- and 2D nanostructures. 

The new CAD/CAM (Computer Aided Design/ Computer Aided Manufacturing) technology makes it possible to connect the new acoustic manipulators to computers and AI-based technology. 

In this kind of semi-automatic system, the operators move the images of the atoms and molecules on the screen. Then the highly advanced CAM system makes the physical molecule in the reaction chamber. This type of system allows mass-producing complicated nanomachines. The idea of this kind of system is that there are lots of manipulators in some laboratories. 

In the first, operators make models for the wanted nano-system by using one actor. In that model, the mass spectrometers are following the chemical environment in the reaction chamber. If the result satisfies the system scales, that model is through the system to other manipulators. 

The acoustic systems can also offer new cures against bacteria and viruses. The nanomachine can just put manipulators over cells that the system wants to destroy. Then the nanomachine pressure impulses to that cell. That system can give resonance by using an outside sound source or internal sound circuit. 

The best way to destroy non-wanted cells is just to inject some crystals into those cells. Then the system puts that crystal to resonate. That resonance can destroy the internal structure of the cell. The resonance-based systems are brand new things in medical work. 

The high-pressure microfluid injector uses nano-size pumps like DNA molecules that transport blood plasma through the robot as the Archimedes' screw can inject a microfluid shower into the targeted cell. That shower can cut its protein shell open. 

If the robot can make microfluidics, it can inject those materials into the materials that wanted to remove. Microfluidics means the fluid that the system injects through a thin tube that has a micro-size diameter. 

The nanorobots can turn fluids, like water around them into microfluidics simply by pumping that fluid through them. That means the system can clean surfaces. But it also can remove things like cancer cells and tumors. In that system nanorobot just injects blood plasma into the targeted cells. 

https://www.elveflow.com/microfluidic-reviews/general-microfluidics/a-general-overview-of-microfluidics/

https://scitechdaily.com/combining-robotics-and-microfluidics-a-precision-arm-for-miniature-robots/

https://en.wikipedia.org/wiki/Microfluidics