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Computers often use statistical models alone, risking bias and errors. Combining mechanistic and statistical models, like digital twins, offers a path to reliable precision cardiology.

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Area of Science:

  • Cardiology
  • Computational Biology
  • Data Science

Background:

  • Clinical decisions integrate experience-based statistical models and physiology-based mechanistic models.
  • Computers excel at inductive data pattern discovery but rarely combine it with deductive reasoning.
  • Current trends emphasize big data and inductive methods, leading to potential pitfalls.

Purpose of the Study:

  • To review the risks and limitations of purely inductive computational approaches in medicine.
  • To recommend strategies for mitigating common flaws in data-driven predictions.
  • To highlight the potential of integrating mechanistic and statistical models for precision cardiology.

Main Methods:

  • Review of risks associated with inductive computational methods.
  • Discussion of biases (selection, confounding), overfitting, and spurious correlations.
  • Exploration of causality, statistical technique selection, and research transparency.

Main Results:

  • Purely inductive computational approaches carry significant risks, including lack of generality and spurious correlations.
  • Overfitting and various biases can lead to unreliable predictions.
  • Integrating mechanistic and statistical models addresses these limitations.

Conclusions:

  • A purely inductive approach in computational cardiology is prone to errors and biases.
  • Recommendations include causal examination of data, careful statistical methods, and transparency.
  • The synergy of mechanistic and statistical models (digital twins) promises a future for precision cardiology.