We describe a novel method (FLICS, FLow Image Correlation Spectroscopy) to extract flow speeds in complex vessel networks from a single raster-scanned optical xy-image, acquired in vivo by confocal or two-photon excitation microscopy. Fluorescent flowing objects produce diagonal lines in the raster-scanned image superimposed to static morphological details. The flow velocity is obtained by computing the Cross Correlation Function (CCF) of the intensity fluctuations detected in pairs of columns of the image. The analytical expression of the CCF has been derived by applying scanning fluorescence correlation concepts to drifting optically resolved objects and the theoretical framework has been validated in systems of increasing complexity. The power of the technique is revealed by its application to the intricate murine hepatic microcirculatory system where blood flow speed has been mapped simultaneously in several capillaries from a single xy-image and followed in time at high spatial and temporal resolution.

Sironi, L., Bouzin, M., Inverso, D., D'Alfonso, L., Pozzi, P., Cotelli, F., et al. (2014). In vivo flow mapping in complex vessel networks by single image correlation. SCIENTIFIC REPORTS, 4, 7341 [10.1038/srep07341].

In vivo flow mapping in complex vessel networks by single image correlation

SIRONI, LAURA
Primo
;
BOUZIN, MARGAUX
Secondo
;
D'ALFONSO, LAURA;POZZI, PAOLO;COLLINI, MADDALENA
Penultimo
;
CHIRICO, GIUSEPPE
Ultimo
2014

Abstract

We describe a novel method (FLICS, FLow Image Correlation Spectroscopy) to extract flow speeds in complex vessel networks from a single raster-scanned optical xy-image, acquired in vivo by confocal or two-photon excitation microscopy. Fluorescent flowing objects produce diagonal lines in the raster-scanned image superimposed to static morphological details. The flow velocity is obtained by computing the Cross Correlation Function (CCF) of the intensity fluctuations detected in pairs of columns of the image. The analytical expression of the CCF has been derived by applying scanning fluorescence correlation concepts to drifting optically resolved objects and the theoretical framework has been validated in systems of increasing complexity. The power of the technique is revealed by its application to the intricate murine hepatic microcirculatory system where blood flow speed has been mapped simultaneously in several capillaries from a single xy-image and followed in time at high spatial and temporal resolution.
Articolo in rivista - Articolo scientifico
permeation,transport, microscopy, blood, flowfluorescence, imaging
English
2014
4
7341
none
Sironi, L., Bouzin, M., Inverso, D., D'Alfonso, L., Pozzi, P., Cotelli, F., et al. (2014). In vivo flow mapping in complex vessel networks by single image correlation. SCIENTIFIC REPORTS, 4, 7341 [10.1038/srep07341].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10281/57489
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