A Potential Pitfall in the Interpretation of Microscope-Integrated Fluorescence Angiography: The Center-Periphery Effect.

Q1 Medicine

Medical sciences (Basel, Switzerland) Pub Date : 2025-05-03 DOI:10.3390/medsci13020054

Dieder Stolk, Paul Bloemen, Richard Martin van den Elzen, Martijn de Bruin, Caroline Driessen

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Abstract

Background/objectives: Indocyanine green fluorescence angiography (ICG-FA) enables the real-time visualization of tissue perfusion. However, objective research on microscope-integrated fluorescence angiography (FA) has not been conducted before. This study aims to evaluate the fluorescence light distribution in images formed by ICG-FA in two surgical microscopes using a phantom, and to provide recommendations for their application.

Methods: An 11.8 by 6.8 cm ICG and Intralipid phantom was made to evaluate overall spatial fluorescence sensitivity in two surgical microscopes in multiple working distances (WDs) and magnification factors (MFs). The signal was quantified using a tailor-made software in Python 3.8.10.

Results: A clear center-periphery effect was present in most settings in both microscopes, with the highest peripheral fluorescence signal loss in the lowest MF: 100% in the Tivato and 83% in the Pentero. Increasing the MF improved homogeneity, where the biggest difference was seen between the first and second MF. A 30 cm WD and 3.5× MF produced the most homogeneous images suitable for free-flap surgery. Manually opening the light beam diameter also reduced the center-periphery effect.

Conclusions: Peripheral signal loss in microscope-integrated ICG-FA must be considered during clinical interpretation and for the quantification of tissue perfusion. In clinical practice during reconstructive free-flap surgery, a 30 cm WD, 3.5 MF, and manually opened light beam diameter should be applied to achieve the most homogeneous image.

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显微镜集成荧光血管造影解释中的一个潜在缺陷：中心-外围效应。

背景/目的：吲哚菁绿荧光血管造影（ICG-FA）能够实时显示组织灌注。然而，显微镜集成荧光血管造影（FA）的客观研究尚未开展。本研究旨在评价ICG-FA成像在两种手术显微镜上的荧光分布，并对其应用提出建议。方法：制作11.8 × 6.8 cm的ICG和脂肪内影，评价两种手术显微镜在多工作距离（WDs）和放大倍数（MFs）下的整体空间荧光灵敏度。使用Python 3.8.10中定制的软件对信号进行量化。结果：两种显微镜在大多数情况下都存在明显的中心-外周效应，在最低MF下外周荧光信号损失最高：在Tivato中为100%，在Pentero中为83%。增加MF改善了均匀性，其中第一和第二MF之间的差异最大。30cm WD和3.5× MF产生最均匀的图像，适合自由皮瓣手术。手动打开光束直径也减少了中心-外围效应。结论：在临床解释和组织灌注定量时，必须考虑显微镜集成ICG-FA的外周信号丢失。在临床实践中，在自由瓣重建手术中，应采用30 cm WD， 3.5 MF，手动打开光束直径，以获得最均匀的图像。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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