The initial objective was to explore machine learning methods that have been successful in other imaging modalities, like computed tomography, to produce more informative priors for cryo-EM structure determination. In cryo-EM data processing, the aim is to reconstruct an unknown 3D molecular structure from 2D projection images, which view the structure from unknown relative orientations. From a mathematical point of view, cryo-EM structure determination belongs to the field of ill-posed inverse problems. It is ill-posed because the high levels of noise and the many unknown parameters result in a situation where the data alone does not provide sufficient information to determine a unique solution. I proposed to use the regularization by denoising (RED) framework to inject prior knowledge into cryo-EM reconstruction to better handle the ill-posedness. The denoiser would be a deep neural network that is trained on cryo-EM data from publica databases.
By tapping into the vast amounts of prior knowledge about protein structures available in public databases, the proposed methods have the potential to not only make existing cryo-EM applications better, but also to enhance the scope of cryo-EM structure determination to many more targets than currently possible. This includes important drug targets, like GPCRs, that currently are outside the size limit of what can be resolved by cryo-EM to high resolution.