PT - JOURNAL ARTICLE AU - M. Caroline Müllenbroich AU - Ludovico Silvestri AU - Antonino P. Di Giovanna AU - Giacomo Mazzamuto AU - Irene Costantini AU - Leonardo Sacconi AU - Francesco S. Pavone TI - High-Fidelity Imaging in Brain-Wide Structural Studies Using Light-Sheet Microscopy AID - 10.1523/ENEURO.0124-18.2018 DP - 2018 Nov 01 TA - eneuro PG - ENEURO.0124-18.2018 VI - 5 IP - 6 4099 - http://www.eneuro.org/content/5/6/ENEURO.0124-18.2018.short 4100 - http://www.eneuro.org/content/5/6/ENEURO.0124-18.2018.full SO - eNeuro2018 Nov 01; 5 AB - Light-sheet microscopy (LSM) has proven a useful tool in neuroscience to image whole brains with high frame rates at cellular resolution and, in combination with tissue clearing methods, is often employed to reconstruct the cyto-architecture over the intact mouse brain. Inherently to LSM, however, residual opaque objects, always present to some extent even in extremely well optically cleared samples, cause stripe artifacts, which, in the best case, severely affect image homogeneity and, in the worst case, completely obscure features of interest. Here, demonstrating two example applications in intact optically cleared mouse brains, we report how Bessel beams reduce streaking artifacts and produce high-fidelity structural data for the brain-wide morphology of neuronal and vascular networks. We found that a third of the imaged volume of the brain was affected by strong striated image intensity inhomogeneity and, furthermore, a significant amount of information content lost with Gaussian illumination was accessible when interrogated with Bessel beams. In conclusion, Bessel beams produce high-fidelity structural data of improved image homogeneity and might significantly relax demands placed on the automated tools to count, trace, or segment fluorescent features of interest.