Validation of a White Light and Fluorescence Augmented Panoramic Endoscopic Imaging System on a Bimodal Bladder Wall Experimental Model

Moskalev, Arkadii; Kalyagina, Nina; Kozlikina, Elizaveta; Kustov, Daniil; Loshchenov, Maxim; Amouroux, Marine; Daul, Christian; Blondel, Walter

doi:10.3390/photonics11060514

Cited by 1 publication

(1 citation statement)

References 54 publications

(70 reference statements)

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“…The utilization of a three-dimensional tumor model, previously obtained through computed tomography or magnetic resonance imaging (MRI) with Monte Carlo simulation, permits the simulation of PDT within the tumor volume [104], and the walls of hollow organs [100,106]. An optical scanning method represents a low-cost and effective alternative to CT and MRI for the construction of a model of organ walls [142,143]. For example, the results of PDT modeling using an individual 3D model of metastatically affected vertebrae obtained from three patients demonstrated the potential for the treatment of 90% of metastatic lesions with less than 17% spinal cord damage [113].…”

Section: Discussionmentioning

confidence: 99%

Devices and Methods for Dosimetry of Personalized Photodynamic Therapy of Tumors: A Review on Recent Trends

Alekseeva,

Makarov,

Efendiev

et al. 2024

Cancers

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Significance: Despite the widespread use of photodynamic therapy in clinical practice, there is a lack of personalized methods for assessing the sufficiency of photodynamic exposure on tumors, depending on tissue parameters that change during light irradiation. This can lead to different treatment results. Aim: The objective of this article was to conduct a comprehensive review of devices and methods employed for the implicit dosimetric monitoring of personalized photodynamic therapy for tumors. Methods: The review included 88 peer-reviewed research articles published between January 2010 and April 2024 that employed implicit monitoring methods, such as fluorescence imaging and diffuse reflectance spectroscopy. Additionally, it encompassed computer modeling methods that are most often and successfully used in preclinical and clinical practice to predict treatment outcomes. The Internet search engine Google Scholar and the Scopus database were used to search the literature for relevant articles. Results: The review analyzed and compared the results of 88 peer-reviewed research articles presenting various methods of implicit dosimetry during photodynamic therapy. The most prominent wavelengths for PDT are in the visible and near-infrared spectral range such as 405, 630, 660, and 690 nm. Conclusions: The problem of developing an accurate, reliable, and easily implemented dosimetry method for photodynamic therapy remains a current problem, since determining the effective light dose for a specific tumor is a decisive factor in achieving a positive treatment outcome.

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