On the possibility of implementing a quantum entanglement distribution in a biosystem: Microtubules.

The paper considers the possibility of implementing a quantum entanglement distribution in the cell microtubule. It has been shown that a quantum entanglement distribution proposed in the paper determines the process of quantum state teleportation through microtubule tryptophan chain. The work shows that the system of tryptophans in a microtubule essentially is a quantum network that consists of: spatially spaced nodes - tryptophans, quantum communication channels connecting tryptophans and qubits transmitted through these communication channels.

Modeling of the quantum entangled state transfer protocol in the cell microtubules.

In the work based on the quantum gates representation, the modeling of the quantum entangled state transfer protocol in the cell microtubules is carried out. It has been proved that considered data transmission can be determined as a mechanism that ensures the transfer of information through a quantum channel in microtubule tryptophans chain. The influence of external factors on the formation of entangled states is investigated.

Simulation of the charge migration in DNA under irradiation with heavy ions.

A computer model to simulate the processes of charge injection and migration through DNA after irradiation by a heavy charged particle was developed. The most probable sites of charge injection were obtained by merging spatial models of short DNA sequence and a single 1 GeV/u iron particle track simulated by the code RITRACKS (Relativistic Ion Tracks). Charge migration was simulated by using a quantum-classical nonlinear model of the DNA-charge system.