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Compactness regularization in the analysis of dipolar EPR spectroscopy data

Luis Fábregas Ibáñez, Gunnar Jeschke, Stefan Stoll

2022Journal of Magnetic Resonance17 citationsDOIOpen Access PDF

Abstract

Dipolar electron paramagnetic resonance (EPR) experiments, such as double electron-electron resonance (DEER), measure distributions of nanometer-scale distances between paramagnetic centers, which are valuable for structural characterization of proteins and other macromolecular systems. One challenge in the least-squares fitting analysis of dipolar EPR data is the separation of the inter-molecular contribution (background) and the intra-molecular contribution. For noisy experimental traces of insufficient length, this separation is not unique, leading to identifiability problems for the background model parameters and the long-distance region of the intra-molecular distance distribution. Here, we introduce a regularization approach that mitigates this by including an additional penalty term in the objective function that is proportional to the variance of the distance distribution and thereby penalizes non-compact distributions. We examine the reliability of this approach statistically on a large set of synthetic data and illustrate it with an experimental example. The results show that the introduction of compactness can improve identifiability.

Topics & Concepts

Electron paramagnetic resonanceIdentifiabilityStatistical physicsRegularization (linguistics)Tikhonov regularizationDipoleChemistryMeasure (data warehouse)Computational physicsBiological systemPhysicsMathematicsNuclear magnetic resonanceInverse problemStatisticsComputer scienceData miningMathematical analysisArtificial intelligenceBiologyOrganic chemistryElectron Spin Resonance StudiesElectrochemical Analysis and ApplicationsLanthanide and Transition Metal Complexes
Compactness regularization in the analysis of dipolar EPR spectroscopy data | Litcius