Advanced Motion Compensation Methods for Intravital Optical Microscopy

Authors
Vinegoni, ClaudioLee, SungonFumene Feruglio, PaoloWeissleder, Ralph
Issue Date
2014-03
Publisher
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
Citation
IEEE JOURNAL OF SELECTED TOPICS IN QUANTUM ELECTRONICS, v.20, no.2
Abstract
Intravital microscopy has emerged in the recent decade as an indispensible imaging modality for the study of the microdynamics of biological processes in live animals. Technical advancements in imaging techniques and hardware components, combined with the development of novel targeted probes and new mice models, have enabled us to address long-standing questions in several biology areas such as oncology, cell biology, immunology, and neuroscience. As the instrument resolution has increased, physiological motion activities have become a major obstacle that prevents imaging live animals at resolutions analogue to the ones obtained in vitro. Motion compensation techniques aim at reducing this gap and can effectively increase the in vivo resolution. This paper provides a technical review of some of the latest developments in motion compensation methods, providing organ specific solutions.
Keywords
MOUSE SPINAL-CORD; IN-VIVO; 2-PHOTON MICROSCOPY; HIGH-SPEED; FLUORESCENCE MICROSCOPY; CHAMBER TECHNIQUE; IMAGING WINDOW; RESOLUTION; MICE; ANIMALS; MOUSE SPINAL-CORD; IN-VIVO; 2-PHOTON MICROSCOPY; HIGH-SPEED; FLUORESCENCE MICROSCOPY; CHAMBER TECHNIQUE; IMAGING WINDOW; RESOLUTION; MICE; ANIMALS; Intravital microscopy; image stabilization; in vivo imaging; motion artifact and motion compensation
ISSN
1077-260X
URI
https://pubs.kist.re.kr/handle/201004/127073
DOI
10.1109/JSTQE.2013.2279314
Appears in Collections:
KIST Article > 2014
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