Time-resolved blood flow measurement in the in vivo mouse model by optical frequency domain imaging

Julia Walther; Gregor Mueller; Sven Meissner; Peter Cimalla; Hanno Homann; Henning Morawietz; Edmund Koch

doi:10.1364/ECBO.2009.7372_0J

Optical Coherence Tomography and Coherence Techniques IV
Proceedings of SPIE-OSA Biomedical Optics (Optica Publishing Group, 2009),
paper 7372_0J
•https://doi.org/10.1364/ECBO.2009.7372_0J

Time-resolved blood flow measurement in the in vivo mouse model by optical frequency domain imaging

Julia Walther, Gregor Mueller, Sven Meissner, Peter Cimalla, Hanno Homann, Henning Morawietz, and Edmund Koch

European Conference on Biomedical Optics 2009

Munich Germany
14–18 June 2009
ISBN: 9780819476487

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J. Walther, G. Mueller, S. Meissner, P. Cimalla, H. Homann, H. Morawietz, and E. Koch, "Time-resolved blood flow measurement in the in vivo mouse model by optical frequency domain imaging," in Optical Coherence Tomography and Coherence Techniques IV, P. Anderson and B. Bouma, eds., Vol. 7372 of Proceedings of SPIE-OSA Biomedical Optics (Optica Publishing Group, 2009), paper 7372_0J.

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Abstract

In this study, we demonstrate that phase-resolved Doppler optical frequency domain imaging (OFDI) is very suitable to quantify the pulsatile blood flow within a vasodynamic measurement in the in vivo mouse model. For this, an OFDI-system with a read-out rate of 20 kHz and a center wavelength of 1320 nm has been used to image the time-resolved murine blood flow in 300 μm vessels. Because OFDI is less sensitive to fringe washout due to axial sample motion, it is applied to analyze the blood flow velocities and the vascular dynamics in six-week-old C57BL/6 mice compared to one of the LDLR knockout strain kept under sedentary conditions or with access to voluntary wheel running. We have shown that the systolic as well as the diastolic phase of the pulsatile arterial blood flow can be well identified at each vasodynamic state. Furthermore, the changes of the flow velocities after vasoconstriction and -dilation were presented and interpreted in the entire physiological context. With this, the combined measurement of time-resolved blood flow and vessel diameter provides the basis to analyze the vascular function and its influence on the blood flow of small arteries of different mouse strains in response to different life styles.

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