Litcius/Paper detail

Estimating computational limits on theoretical descriptions of biological cells

Roland R. Netz, William A. Eaton

2021Proceedings of the National Academy of Sciences20 citationsDOIOpen Access PDF

Abstract

There has been much success recently in theoretically simulating parts of complex biological systems on the molecular level, with the goal of first-principles modeling of whole cells. However, there is the question of whether such simulations can be performed because of the enormous complexity of cells. We establish approximate equations to estimate computation times required to simulate highly simplified models of cells by either molecular dynamics calculations or by solving molecular kinetic equations. Our equations place limits on the complexity of cells that can be theoretically understood with these two methods and provide a first step in developing what can be considered biological uncertainty relations for molecular models of cells. While a molecular kinetics description of the genetically simplest bacterial cell may indeed soon be possible, neither theoretical description for a multicellular system, such as the human brain, will be possible for many decades and may never be possible even with quantum computing.

Topics & Concepts

Simple (philosophy)Multicellular organismComputer scienceComputational complexity theoryComputational modelTheoretical computer scienceBiological systemComputational biologyAlgorithmBiologyCellGeneticsEpistemologyPhilosophyGene Regulatory Network AnalysisProtein Structure and DynamicsBioinformatics and Genomic Networks
Estimating computational limits on theoretical descriptions of biological cells | Litcius