High-fidelity functional and structural whole-brain imaging with Bessel-beam light-sheet microscopy

Year: 2017

Authors: Mullenbroich MC., Silvestri L., Turrini L., Di Giovanna AP., Alterini T., Gheisari A., Ricci P., Sacconi L., Vanzi F., Pavone FS.

Autors Affiliation: Univ Firenze, Lab Europeo Spettroscopie Nonlineari, Florence, Italy; CNR, Ist Nazl Ott, Rome, Italy;‎ Univ Firenze, Florence, Italy

Abstract: Light-sheet microscopy (LSM) has proven a useful tool in neuroscience and is particularly well suited to image the entire brain with high frame rates at single cell resolution. On the one hand, LSM is employed in combination with tissue clearing methods like CLARITY which allows for the reconstruction of neuronal or vascular anatomy over cm-sized samples. On the other hand, LSM has been paired with intrinsically transparent samples for real-time recording of neuronal activity with single cell resolution across the entire brain, using calcium indicators like GCaMP6. Despite its intrinsic advantages in terms of high imaging speed and reduced photobleaching, LSM is very sensitive to residual opaque objects present in the sample, which cause dark horizontal stripes in the collected images. In the best case, these artefacts obscure the features of interest in structural imaging; in the worst case, dynamic shadowing introduced by red blood cells significantly alters the fluorescence signal variations related to neuronal activity. We show how the use of Bessel beams in LSM can dramatically reduce such artefacts even in conventional one-sided illumination schemes, thanks to their “self-healing” properties. On the functional side, Bessel-beam LSM allows recording neuronal activity traces without any disturbing flickering caused by the movement of red blood cells. On the structural side, our proposed method is capable of obtaining anatomical information across the entire volume of whole mouse brains allowing tracing blood vessels and neuronal projections also in poorly cleared specimens.

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KeyWords: Medical Imaging; sensor