The application of DNA computing in medicine is explored, focusing on models regulating parallel computations, self-replication, and efficient data distribution. The results of the research allowed to identify the main modes of system behavior: trivial attractor, stationary mode, Poincare-type limit cycles, dynamic chaos, destructive changes - the «black hole» effect. The region of stable periodic oscillations (self-oscillations) can be identified with the region of normal coordination and synchronization of computing operations. The region of dynamic chaos can be identified with the region of irregular, chaotic behavior for organizing complex calculations through nonlinear interactions of molecules and modeling highly adaptive, optimal behavior.

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A DNA-Based Computational Framework Inspired by Mathematical Model of Cell Division

  • Mohiniso Hidirova,
  • Anvar Abduvaliev,
  • Margarita Gildieva,
  • Abrorjon Turgunov,
  • Zaynab Yusupova,
  • Adhamjon Hasanov,
  • Alisher Shakarov,
  • Nodira Khalbaeva

摘要

The application of DNA computing in medicine is explored, focusing on models regulating parallel computations, self-replication, and efficient data distribution. The results of the research allowed to identify the main modes of system behavior: trivial attractor, stationary mode, Poincare-type limit cycles, dynamic chaos, destructive changes - the «black hole» effect. The region of stable periodic oscillations (self-oscillations) can be identified with the region of normal coordination and synchronization of computing operations. The region of dynamic chaos can be identified with the region of irregular, chaotic behavior for organizing complex calculations through nonlinear interactions of molecules and modeling highly adaptive, optimal behavior.