TY - JOUR
T1 - In vivo high-resolution structural imaging of large arteries in small rodents using two-photon laser scanning microscopy
AU - Megens, Remco T A
AU - Reitsma, Sietze
AU - Prinzen, Lenneke
AU - oude Egbrink, Mirjam G A
AU - Engels, Wim
AU - Leenders, Peter J A
AU - Brunenberg, Ellen J L
AU - Reesink, Koen D
AU - Janssen, Ben J A
AU - ter Haar Romeny, Bart M
AU - Slaaf, Dick W
AU - van Zandvoort, Marc A M J
PY - 2010/3/10
Y1 - 2010/3/10
N2 - In vivo (molecular) imaging of the vessel wall of large arteries at subcellular resolution is crucial for unraveling vascular pathophysiology. We previously showed the applicability of two-photon laser scanning microscopy (TPLSM) in mounted arteries ex vivo. However, in vivo TPLSM has thus far suffered from in-frame and between-frame motion artifacts due to arterial movement with cardiac and respiratory activity. Now, motion artifacts are suppressed by accelerated image acquisition triggered on cardiac and respiratory activity. In vivo TPLSM is performed on rat renal and mouse carotid arteries, both surgically exposed and labeled fluorescently (cell nuclei, elastin, and collagen). The use of short acquisition times consistently limit in-frame motion artifacts. Additionally, triggered imaging reduces between-frame artifacts. Indeed, structures in the vessel wall (cell nuclei, elastic laminae) can be imaged at subcellular resolution. In mechanically damaged carotid arteries, even the subendothelial collagen sheet (approximately 1 microm) is visualized using collagen-targeted quantum dots. We demonstrate stable in vivo imaging of large arteries at subcellular resolution using TPLSM triggered on cardiac and respiratory cycles. This creates great opportunities for studying (diseased) arteries in vivo or immediate validation of in vivo molecular imaging techniques such as magnetic resonance imaging (MRI), ultrasound, and positron emission tomography (PET).
AB - In vivo (molecular) imaging of the vessel wall of large arteries at subcellular resolution is crucial for unraveling vascular pathophysiology. We previously showed the applicability of two-photon laser scanning microscopy (TPLSM) in mounted arteries ex vivo. However, in vivo TPLSM has thus far suffered from in-frame and between-frame motion artifacts due to arterial movement with cardiac and respiratory activity. Now, motion artifacts are suppressed by accelerated image acquisition triggered on cardiac and respiratory activity. In vivo TPLSM is performed on rat renal and mouse carotid arteries, both surgically exposed and labeled fluorescently (cell nuclei, elastin, and collagen). The use of short acquisition times consistently limit in-frame motion artifacts. Additionally, triggered imaging reduces between-frame artifacts. Indeed, structures in the vessel wall (cell nuclei, elastic laminae) can be imaged at subcellular resolution. In mechanically damaged carotid arteries, even the subendothelial collagen sheet (approximately 1 microm) is visualized using collagen-targeted quantum dots. We demonstrate stable in vivo imaging of large arteries at subcellular resolution using TPLSM triggered on cardiac and respiratory cycles. This creates great opportunities for studying (diseased) arteries in vivo or immediate validation of in vivo molecular imaging techniques such as magnetic resonance imaging (MRI), ultrasound, and positron emission tomography (PET).
KW - Animals
KW - Carotid Artery, Common/anatomy & histology
KW - Collagen/analysis
KW - Image Processing, Computer-Assisted/methods
KW - Mice
KW - Mice, Inbred C57BL
KW - Microscopy, Confocal/methods
KW - Microscopy, Fluorescence, Multiphoton/methods
KW - Movement/physiology
KW - Rats
KW - Renal Artery/anatomy & histology
U2 - https://doi.org/10.1117/1.3281672
DO - https://doi.org/10.1117/1.3281672
M3 - Article
C2 - 20210434
SN - 1083-3668
VL - 15
SP - 011108
JO - Journal of biomedical optics
JF - Journal of biomedical optics
IS - 1
ER -