Quantitative active super-resolution thermal imaging: The melanoma case study

Q2 Biochemistry, Genetics and Molecular Biology

Biomolecular Concepts Pub Date : 2022-01-01 DOI:10.1515/bmc-2022-0015

M. Marini, M. Bouzin, R. Scodellaro, L. D’alfonso, L. Sironi, F. Granucci, F. Mingozzi, G. Chirico, M. Collini

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引用次数: 2

Abstract

Abstract Super-resolution image acquisition has turned photo-activated far-infrared thermal imaging into a promising tool for the characterization of biological tissues. By the sub-diffraction localization of sparse temperature increments primed by the sample absorption of modulated focused laser light, the distribution of (endogenous or exogenous) photo-thermal biomarkers can be reconstructed at tunable ∼10−50 μm resolution. We focus here on the theoretical modeling of laser-primed temperature variations and provide the guidelines to convert super-resolved temperature-based images into quantitative maps of the absolute molar concentration of photo-thermal probes. We start from camera-based temperature detection via Stefan–Boltzmann’s law, and elucidate the interplay of the camera point-spread-function and pixelated sensor size with the excitation beam waist in defining the amplitude of the measured temperature variations. This can be accomplished by the numerical solution of the three-dimensional heat equation in the presence of modulated laser illumination on the sample, which is characterized in terms of thermal diffusivity, conductivity, thickness, and concentration of photo-thermal species. We apply our data-analysis protocol to murine B16 melanoma biopsies, where melanin is mapped and quantified in label-free configuration at sub-diffraction 40 µm resolution. Our results, validated by an unsupervised machine-learning analysis of hematoxylin-and-eosin images of the same sections, suggest potential impact of super-resolved thermography in complementing standard histopathological analyses of melanocytic lesions.

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定量主动超分辨率热成像:黑色素瘤病例研究

超分辨率图像采集使光激活远红外热成像成为表征生物组织的一种有前途的工具。通过对样品吸收调制聚焦激光引发的稀疏温度增量的亚衍射定位，(内源性或外源性)光热生物标志物的分布可以在可调的~ 10−50 μm分辨率下重建。我们专注于激光引发温度变化的理论建模，并提供将超分辨温度图像转换为光热探针绝对摩尔浓度定量图的指导方针。我们从基于相机的温度检测出发，通过斯特凡-玻尔兹曼定律，阐明了相机点扩展函数和像素化传感器尺寸与激发束腰的相互作用，以确定被测温度变化的幅度。这可以通过在样品上存在调制激光照射的情况下三维热方程的数值解来实现，样品的特征是热扩散率、电导率、厚度和光热物质的浓度。我们将我们的数据分析方案应用于小鼠B16黑色素瘤活检，在亚衍射40µm分辨率下，在无标记配置下绘制和量化黑色素。通过对同一切片的苏木精和伊红图像进行无监督机器学习分析，我们的结果得到了验证，表明超分辨率热成像在补充黑素细胞病变的标准组织病理学分析方面具有潜在的影响。

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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来源期刊

Biomolecular Concepts Biochemistry, Genetics and Molecular Biology-Biochemistry, Genetics and Molecular Biology (all)

CiteScore

5.30

自引率

0.00%

发文量

审稿时长

12 weeks

期刊介绍： BioMolecular Concepts is a peer-reviewed open access journal fostering the integration of different fields of biomolecular research. The journal aims to provide expert summaries from prominent researchers, and conclusive extensions of research data leading to new and original, testable hypotheses. Aspects of research that can promote related fields, and lead to novel insight into biological mechanisms or potential medical applications are of special interest. Original research articles reporting new data of broad significance are also welcome. Topics: -cellular and molecular biology- genetics and epigenetics- biochemistry- structural biology- neurosciences- developmental biology- molecular medicine- pharmacology- microbiology- plant biology and biotechnology.