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Imaging of mouse experimental melanoma in vivo and ex vivo by combination of confocal and nonlinear microscopy
Author(s) -
Chernyavskiy Oleksandr,
Vannucci Luca,
Bianchini Paolo,
Difato Francesco,
Saieh Mustafa,
Kubínová Lucie
Publication year - 2009
Publication title -
microscopy research and technique
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.536
H-Index - 118
eISSN - 1097-0029
pISSN - 1059-910X
DOI - 10.1002/jemt.20687
Subject(s) - autofluorescence , ex vivo , two photon excitation microscopy , in vivo , confocal microscopy , microscopy , pathology , melanoma , biomedical engineering , preclinical imaging , hyperthermia , confocal , materials science , biophysics , chemistry , biology , medicine , optics , fluorescence , cancer research , microbiology and biotechnology , paleontology , physics
Abstract We investigated possibilities of the combination of the one‐ and two‐photon excitation microscopy for examination of the experimental melanoma tissue in vivo, in mice under general anesthesia, and ex vivo on freshly harvested specimens. Our aim was to obtain sufficiently informative images of unstained tumor tissues and their modifications after hyperthermia treatment. The mouse experimental melanoma structure was studied and compared with normal tissue from the same animal by using confocal and nonlinear microscopy techniques based on (i) one‐photon excitation (1PE) fluorescence, (ii) 1PE reflectance, (iii) second harmonic generation imaging, and (iv) two‐photon excitation autofluorescence. We checked different spectral conditions and other settings of image acquisition, as well as combinations of the above imaging modalities, to fully exploit the potential of these techniques in the evaluation of treated and untreated cancer tissue morphology. Our approach enabled to reveal the collagen fiber network in relation with the other tissues, and to identify invasive tumor cells. It also proved to be useful for the examination of interrelationships between functional and morphological aspects based on optical properties of the tissues, especially in studies of changes between the tumor and control tissue, as well as changes induced by physical treatments, e.g., delivery of microwave hyperthermia treatment. These differences were also evaluated quantitatively, when we found out that the maximum Euler–Poincaré characteristic reflects well the melanoma morphological structure. The results showed that the proposed investigative approach could be suitable also for a direct evaluation of tissue modifications induced by clinical interventions. Microsc. Res. Tech., 2009. © 2009 Wiley‐Liss, Inc.