Imagine performing an MRI on a single cell rather than the entire body – taking a molecule or group of molecules within a cell, identifying and examining problem areas within the DNA, and presenting more accurate diagnoses and patient treatments. Today, this is possible with the precision of quantum computing and nanotechnology built into MRI devices.

In a recent press release, IBM claims that they are very close to making breakthroughs in quantum computing. Because of some experimental success, they are closer to building the first quantum computer, which can take advantage of the peculiarities of quantum physics and can solve certain problems in a matter of seconds, otherwise it will take billions of years to solve today's computers.

Quantum computing is a computing system based on qubits rather than bits; where qubits [qubits] are the basic unit of information in quantum computers. Although a little can represent one of two possibilities, such as 0 or 1, or yes or no, Qubits can represent more options: 0 or 1, 1 and 0, the appearance of multiple combinations of Qubits, and also in this way. Therefore, Qubit represents a set of possibilities, all of which can be calculated while considering the probability.

The Qubit concept deals with very small particles [subatomic particles]. It has been shown that subatomic particles can have different states at the same time because the particles are never static. This is obvious because they move very fast and approach the speed of light. Therefore, the particle state of a particle [Qubit] appears to be different from that of a different observer, and the particle has several states at the same time. This is why a subatomic particle can have different states and probabilities at the same time. We can use it to replace bits and get better performance: better performance! Then, when you use Qubits in combination, the amount of information in this combination is much larger than the index. Subatomic logic is much more powerful than binary logic used in ordinary computing.

As a result, you can process complex information faster. Its main applications are encryption, decryption, modeling, database, speech recognition, structure recognition, simulation and artificial intelligence, as well as many other applications that do not exist.

Imagine its application and effectiveness in the healthcare field, especially in the field of electronic health. Electronically available patient data, structuring, modeling, simulation and processing in seconds – AI for diagnostic and conditional predictability is almost 100% accurate and will increase millions of times over unconstrained limits.

Quantum computing also proves that two entangled particles coexist. That is, when one modifies its state, the other also modifies its own state, no matter how far they are in the universe. This means that we can "transfer" information from one place to another without modifying the state of an entangled particle without physical movement.

In e-health, this may mean automatic remote and reliable diagnosis, electronic patient information through instant communication with entangled subatomic particles. Moreover, for nanoscale precision applications, this is just the tip of the iceberg.

Quantum Computing and Healthcare Technology was originally published on Spring