Helfrich Monte Carlo Flexible Fitting: physics-based, data-driven cell-scale simulations

Simulating entire cells represents the next frontier of computational biology. Achieving this goal requires methods that accurately reconstruct and simulate cellular membranes across spatial and temporal scales. Although three-dimensional electron microscopy enables detailed membrane visualization, dose limitations and restricted field-of-view often result in fragmented membrane representations incompatible with simulations. To resolve this, here we introduce Helfrich Monte Carlo Flexible Fitting (HMFF), a novel approach that integrates experimental density data into membrane simulations. Together with the accompanying Mosaic software ecosystem, HMFF translates static imaging data into complete and physically regularized simulation-ready models at micrometer scales. We demonstrate the versatility of HMFF across diverse biological systems, including influenza virus particles, Mycoplasma pneumoniae cells, and entire eukaryotic organelles. These models enable multi-scale simulations involving millions of lipids, incorporate proteins at experimentally determined positions, and allow for quantitative morphological analysis of cellular compartments. HMFF thus establishes a foundation for data-driven whole-cell simulations.