Submicrometer tomographic resolution examined using a micro-fabricated test object

TL;DR

This study evaluates the submicrometer spatial resolution of microtomographs using a microfabricated test object, demonstrating the importance of zoom reconstruction for detailed visualization of human tissue microstructures.

Contribution

It introduces a method to accurately measure 3D spatial resolution of microtomographs at submicrometer scales, highlighting the benefits of zoom reconstruction.

Findings

In-plane resolution estimated at 1.2 μm without zoom, 0.8 μm with zoom

Through-plane resolution also around 0.8 μm, comparable to in-plane resolution

Microtomography visualizes subcellular structures in human cerebral tissue

Abstract

To estimate the spatial resolution of microtomographs, a test object on the submicrometer scale was prepared by focused ion beam milling and subjected to microtomographic analysis. Since human tissues are composed of cells and extracellular matrices with micrometer and submicrometer structures, it is important to investigate the three-dimensional spatial resolution of microtomographs used to visualize microstructures of human tissues. The resolutions along the direction within the tomographic slice plane (in-plane resolution) and perpendicular to it (through-plane resolution) were determined from the modulation transfer function of square-wave patterns. The in-plane resolution was estimated to be 1.2 um from the modulation transfer function of the non-zoom image. In contrast, the zoom image gave the in-plane resolution of 0.8 um. This in-plane resolution is comparable to the through-plane resolution, which was estimated to be 0.8 um. Although the two-dimensional radiographs were taken with the pixel width of half the x-ray optics resolution, these three-dimensional resolution analyses indicated that the zoom reconstruction should be performed to achieve the in-plane resolution comparable to the x-ray optics resolution. The submicrometer three-dimensional analysis was applied in the structural study of human cerebral tissue stained with high-Z elements and the obtained tomograms revealed that the microtomographic analysis allows visualization of the subcellular structures of the cerebral tissue.