In sample preparation of biological samples for electron microscopy, many types of embedding media are widely used. Unfortunately, none of them is perfectly resistant to beam induced damage. The article is focused on mass loss measuring of pure epoxy resin EMbed 812 that replaced Epon - the most widely used embedding resin for biological electron microscopy, in a form of ultrathin sections with thicknesses ranging from 30 to 100 nm. The STEM imaging was performed in a quantitative way which allowed us to estimate the mass loss directly up to the total dose of 3000 e-/nm2. For data acquisition we used SEM equipped with a commercial STEM detector working at a relatively low acceleration voltage of 30 kV. In this study we estimated the influence of various factors which can affect the endurance of the epoxy resin EMbed 812 ultrathin sections under an electron beam, such as the sample aging, differences between storing the samples in forms of ultrathin sections and whole blocks, ultrathin sections thicknesses, temperature of the sample, probe current, and one or two-sided carbon coating of ultrathin sections. The aim of this work is to investigate beam induced mass loss at electron energies of SEM and find out how to reduce the mass loss.

Institute of Macromolecular Chemistry of the Czech Academy of Sciences Heyrovsky Sq 2 162 06 Prague 6 Czech Republic

Institute of Parasitology Biology Centre of the Czech Academy of Sciences Branisovska 31 370 05 Ceske Budejovice Czech Republic; Faculty of Science Charles University Prague Vinicna 7 128 44 Prague 2 Czech Republic

Institute of Scientific Instruments of the Czech Academy of Sciences Kralovopolska 147 612 64 Brno Czech Republic

Citace poskytuje Crossref.org

An advanced fast method for the evaluation of multiple immunolabelling using gold nanoparticles based on low-energy STEM

High Resolution Powder Electron Diffraction in Scanning Electron Microscopy

Powder Nano-Beam Diffraction in Scanning Electron Microscope: Fast and Simple Method for Analysis of Nanoparticle Crystal Structure

Nanoscale Estimation of Coating Thickness on Substrates via Standardless BSE Detector Calibration