Electron tomography of biological samples is used to study the organization and the
structure of the whole cell and subcellular complexes. We achieve isotropic resolution with a …

Electron tomography (ET) of biological samples is used to study the organization and the
structure of the whole cell and subcellular complexes in great detail. However, projections …

The 3D reconstruction of a tilt series for electron tomography is mostly carried out using the
weighted backprojection (WBP) algorithm or using one of the iterative algorithms such as the …

Iterative reconstruction algorithms pose tremendous computational challenges for 3D
Electron Tomography (ET). Similar to X-ray Computed Tomography (CT), graphics …

Electron tomography (ET) combining subsequent sub-volume averaging has been
becoming a unique way to study the in situ 3D structures of macromolecular complexes …

Despite much progress in electron tomography, quantitative assessment of resolution has
remained a problematic issue. The criteria that are used in single particle analysis, based on …

Electron tomography is now established as a powerful tool to image complex structures with
nanometer resolution in 3D. In the life sciences, electron tomography is used to study …

Electron tomography is an underdetermined inverse problem that suffers from missing
wedges of information in reciprocal space. Even with a 180 specimen tilt range, small …

Electron tomography is currently the highest resolution imaging modality available to study
the 3D structures of pleomorphic macromolecular assemblies, viruses, organelles and cells …

Electron tomography (ET) is a key technique for examining the three-dimensional
morphologies of nanostructures. ET involves the reconstruction of a set of 2D projection …