The work is divided into two main parts: a conceptual/enabling component that takes the form of a unified software library (GlobalBioIm) which is common to all sub-projects; and an application-oriented part that is devoted to the development of specialized reconstruction algorithms for a variety of imaging modalities.
Our methods are made available to the community as part of an integrative software framework (GlobalBioIm) for the reconstruction of biomedical images (
https://biomedical-imaging-group.github.io/GlobalBioIm/(odnośnik otworzy się w nowym oknie)). The leading idea of our system is to decouple the physical aspect of the problem, which is application-specific, from the so-called “regularization” of the solution. Regularization dictates how to properly constrain the reconstruction and is often the same across modalities. Once equipped with these two components, the user has to specify a suitable cost functional, together with an adequate method of optimization. The desired image-reconstruction algorithm can then be automatically assembled by GlobalBioIm. Since the critical part of this approach is the choice of the regularization, we have also performed a theoretical investigation of its effect on image reconstruction. As an alternative to regularization, we have also made use of convolutional neural networks, which has enabled us to improve the quality of the reconstructed images, and this, far beyond the state of the art.
On the application side, our contributions include
- high-end reconstruction methods for x-ray CT and optical projection tomography;
- a new algorithm for structured-illumination microscopy that uses computational sectioning;
- a comparative assessment of the resolution of various forms of superresolution microscopies;
- a multiresolution framework for 3D reconstruction with joint refinement of the poses;
- a novel paradigm (CryoGAN) for the 3D reconstruction of single particles in cryo-EM without pose estimation;
- the improvement of the axial resolution of fluorescence microscopy through the combination of multiple views of particle replicates that differ by their orientation;
- a novel method for diffraction tomography based on the solution of the inverse scattering problem;
- a novel reconstruction framework for dynamic MRI based on deep prior that produces images of astonishing quality.