Background: Two-photon excitation (TPE) fluorescence microscopy is a high-resolution laser-scanning imaging technique enabling deep imaging inside biological tissues. TPE microscopy has the triple advantage of offering high spatial resolution (250 nm radially, 800 nm axially), high penetration depth inside skin (200mm), and low photodamage effects. Further, cells and extracellular matrix intrinsically contain a variety of fluorescent molecules (NADH, tryptophan, keratins, melanin, elastin, cholecalciferol and others), so that biological tissues can be imaged by TPE microscopy without any exogenous probe. The time-resolved analysis of the fluorescence signal, known as fluorescence lifetime imaging microscopy (FLIM), is an additional non-invasive microscopy technique useful to characterize endogenous fluorescence species and their surrounding medium by measuring the mean lifetime of fluorescent emission. Finally, multispectral (MTPE) tissue imaging can also be used to identify different endogenous fluorescent species by measuring their two photon emission spectra. Those techniques offer functional information about the relative quantities of fluorescent molecules, which are correlated with tissue structure in physiological and pathological states. Objective: We have decided to apply these three methods at the same time for cutaneous tumors in order to evaluate their possible future use. Method: We have analyzed a melanoma and a basal cell carcinoma, with their surrounding healthy skin, to evaluate any difference in healthy skin and neoplasia. The samples were excised during dermatological surgery, then cut, saving some healthy skin in both, to obtain a regular shape, allowing its positioning either with the skin surface parallel to the optical axis (horizontal optical sectioning), or perpendicular (vertical optical sectioning). Conclusion: This first result demonstrates that FLIM is effective in discriminating healthy skin from MM, while MTPE is effective in discriminating healthy skin from BCC
Combined non-linear laser imaging (two-photon excitation fluorescence microscopy, fluorescence lifetime imaging microscopy, multispectral multiphoton microscopy) in cutaneous tumours: first experiences / V. De Giorgi;D. Massi;S. Sestini;R. Cicchi;F. S. Pavone;T. Lotti. - In: JOURNAL OF THE EUROPEAN ACADEMY OF DERMATOLOGY AND VENEREOLOGY. - ISSN 0926-9959. - ELETTRONICO. - 23:(2009), pp. 314-316. [10.1111/j.1468-3083.2008.03045.x]
Combined non-linear laser imaging (two-photon excitation fluorescence microscopy, fluorescence lifetime imaging microscopy, multispectral multiphoton microscopy) in cutaneous tumours: first experiences
MASSI, DANIELA;R. Cicchi;PAVONE, FRANCESCO SAVERIO;
2009
Abstract
Background: Two-photon excitation (TPE) fluorescence microscopy is a high-resolution laser-scanning imaging technique enabling deep imaging inside biological tissues. TPE microscopy has the triple advantage of offering high spatial resolution (250 nm radially, 800 nm axially), high penetration depth inside skin (200mm), and low photodamage effects. Further, cells and extracellular matrix intrinsically contain a variety of fluorescent molecules (NADH, tryptophan, keratins, melanin, elastin, cholecalciferol and others), so that biological tissues can be imaged by TPE microscopy without any exogenous probe. The time-resolved analysis of the fluorescence signal, known as fluorescence lifetime imaging microscopy (FLIM), is an additional non-invasive microscopy technique useful to characterize endogenous fluorescence species and their surrounding medium by measuring the mean lifetime of fluorescent emission. Finally, multispectral (MTPE) tissue imaging can also be used to identify different endogenous fluorescent species by measuring their two photon emission spectra. Those techniques offer functional information about the relative quantities of fluorescent molecules, which are correlated with tissue structure in physiological and pathological states. Objective: We have decided to apply these three methods at the same time for cutaneous tumors in order to evaluate their possible future use. Method: We have analyzed a melanoma and a basal cell carcinoma, with their surrounding healthy skin, to evaluate any difference in healthy skin and neoplasia. The samples were excised during dermatological surgery, then cut, saving some healthy skin in both, to obtain a regular shape, allowing its positioning either with the skin surface parallel to the optical axis (horizontal optical sectioning), or perpendicular (vertical optical sectioning). Conclusion: This first result demonstrates that FLIM is effective in discriminating healthy skin from MM, while MTPE is effective in discriminating healthy skin from BCC
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