Photodynamic therapy in fibrosarcoma BALB/c animal model: Observation of the rebound effect

Photodynamic therapy in fibrosarcoma BALB/c animal model: Observation of the rebound effect

•One-point fluorescence is employed to follow the photosensitizer during the photodynamic treatment of an animal model.•For certain tumor sites the "rebound effect" is observed: fluorescence signal increases 24h after illumination.•The “rebound effect” is used to perform a second illuminat...

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Published in:Photodiagnosis and photodynamic therapy Vol. 21; pp. 98 - 107
Main Authors: Eugenia, Etcheverry María, Ángel, Pasquale Miguel, Anabella, Gutiérrez, Solange, Bibé, Carlos, Ponzinibbio, Horacio, Poteca, Mario, Garavaglia
Format: Journal Article
Language:English
Published: Netherlands Elsevier B.V 01-03-2018
Subjects:
Animals
Disease Models, Animal
Fibrosarcoma
Fibrosarcoma - drug therapy
Fluorescence spectra
Mesoporphyrins - pharmacokinetics
Mesoporphyrins - therapeutic use
Mice
Mice, Inbred BALB C
Photochemotherapy - methods
Photodynamic therapy
Photosensitizer accumulation
Photosensitizing Agents - pharmacokinetics
Photosensitizing Agents - therapeutic use
Fibrosarcoma
Photodynamic therapy
Photosensitizer accumulation
Fluorescence spectra
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Summary:•One-point fluorescence is employed to follow the photosensitizer during the photodynamic treatment of an animal model.•For certain tumor sites the "rebound effect" is observed: fluorescence signal increases 24h after illumination.•The “rebound effect” is used to perform a second illumination and improve the outcome of the photodynamic treatment. In vivo spectrofluorometric analysis during photodynamic therapy (PDT) is a fundamental tool to obtain information about drug bleaching kinetics. Using a portable spectrofluorometer with an excitation source emitting at 400nm wavelength and a spectral analyzer ranging from 500nm to 800nm, the evolution of the meta-tetra(hydroxyphenyl) chlorin (m-THPC) photosensitizer fluorescence spectrum at the tumoral tissue of BALB/c murines with fibrosarcoma located at their flank was followed up. Ex vivo fluorescence measurements of the tumor and skin were also performed with the aim of better characterizing the in vivo signal at different parts of the tumor. PDT was performed employing a LED 637nm light source. Fluorescence at different parts of the tumor and at the tail and armpit of mice was measured immediately after injection and followed daily. The average fluorescence intensity in the tumor reached a maximum after 24–72h. Subsequently, illuminations 24, 48, 72 and 96h post-injection were performed, and the fluorescence was measured immediately before and after each illumination. Eventually, 24h post-illumination, the fluorescence at certain parts of the tumor increased in comparison with that measured immediately after illumination. This effect, named “rebound effect”, was due to the new local accumulation of the drug, and was used to perform a second illumination on some mice to increase the amount of photodynamic reaction and significantly improve the PDT outcome. These results are encouraging to optimize PDT in the proposed animal model, thinking about the possible translation to humans.
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ISSN:1572-1000
1873-1597
DOI:10.1016/j.pdpdt.2017.11.006