Abstract
Zebrafish has rapidly evolved as a powerful vertebrate model organism for studying human diseases. Here we first demonstrate a new label-free approach for in vivo imaging of microvasculature, based on the recent discovery and detailed characterization of the two-photon excited endogenous fluorescence in the blood plasma of zebrafish. In particular, three-dimensional reconstruction of the microvascular networks was achieved with the depth-resolved two-photon excitation fluorescence (TPEF) imaging. Secondly, the blood flow images, obtained by perpendicularly scanning the focal point across the blood vessel, provided accurate information for characterizing the hemodynamics of the circulatory system. The endogenous fluorescent signals of reduced nicotinamide adenine dinucleotide (NADH) enabled visualization of the circulating granulocytes (neutrophils) in the blood vessel. The development of acute sterile inflammation could be detected by the quantitative counting of circulating neutrophils. Finally, we found that by utilizing a short wavelength excitation at 650 nm, the commonly used fluorescent proteins, such as GFP and DsRed, could be efficiently excited together with the endogenous fluorophores to achieve four-color TPEF imaging of the vascular structures and blood cells. The results demonstrated that the multi-color imaging could potentially yield multiple view angles of important processes in living biological systems.
Highlights
Microvasculature, the distal function unit of the cardiovascular system, plays an important role in the fundamental activities of various organs [1,2]
Zebrafish has rapidly evolved as a powerful vertebrate model organism for studying human diseases
Three-dimensional reconstruction of the microvascular networks was achieved with the depth-resolved two-photon excitation fluorescence (TPEF) imaging
Summary
Microvasculature, the distal function unit of the cardiovascular system, plays an important role in the fundamental activities of various organs [1,2]. Noninvasive imaging of microcirculatory networks and the dynamics of blood cells is invaluable for the prevention, diagnosis and treatment of related diseases. The major shortcomings of these imaging technologies are: (1) lack of sufficient spatial resolution for resolving individual capillaries, let alone a single blood cell; (2) many of them often involve external contrast agents to enhance image quality. Label-free in vivo imaging of the microvasculature and blood cells trafficking in mouse and hamster models has been achieved by using two-photon excited endogenous fluorescence of tryptophan and hemoglobin [11,12]. Our previous study reported a newly discovered endogenous fluorescence signal from zebrafish blood plasma. With two-photon excited plasma and NADH fluorescence, we measured the dynamics of red and white blood cells in vivo [13]
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