Nanoscopic X-ray Tomography for Correlative Microscopy of a Small Meiofaunal Sea-cucumber

Overview

Journal Sci Rep

Specialty Science

Date 2020 Mar 5

PMID 32127610

Citations 3

Authors

Simone Ferstl

Thomas Schwaha

Bernhard Ruthensteiner

Lorenz Hehn

Sebastian Allner

Mark Muller

Martin Dierolf

Klaus Achterhold

Franz Pfeiffer

Affiliations

Soon will be listed here.

Abstract

In the field of correlative microscopy, light and electron microscopy form a powerful combination for morphological analyses in zoology. Due to sample thickness limitations, these imaging techniques often require sectioning to investigate small animals and thereby suffer from various artefacts. A recently introduced nanoscopic X-ray computed tomography (NanoCT) setup has been used to image several biological objects, none that were, however, embedded into resin, which is prerequisite for a multitude of correlative applications. In this study, we assess the value of this NanoCT for correlative microscopy. For this purpose, we imaged a resin-embedded, meiofaunal sea cucumber with an approximate length of 1 mm, where microCT would yield only little information about the internal anatomy. The resulting NanoCT data exhibits isotropic 3D resolution, offers deeper insights into the 3D microstructure, and thereby allows for a complete morphological characterization. For comparative purposes, the specimen was sectioned subsequently to evaluate the NanoCT data versus serial sectioning light microscopy (ss-LM). To correct for mechanical instabilities and drift artefacts, we applied an alternative alignment procedure for CT reconstruction. We thereby achieve a level of detail on the subcellular scale comparable to ss-LM images in the sectioning plane.

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