Single-Pixel Photoacoustic Microscopy with Speckle Illumination

IF 2.2 Q3 COMPUTER SCIENCE, CYBERNETICS
A. Caravaca-Aguirre, F. Poisson, D. Bouchet, N. Stasio, P. Moreau, I. Wang, E. Zhang, P. Beard, C. Prada, C. Moser, D. Psaltis, O. Katz, E. Bossy
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引用次数: 0

Abstract

Wide-field optical-resolution microscopy with structured illumination and single-pixel detection has been the topic of a number of research investigations. Its advantages over point scanning approaches are many and include a faster acquisition rate for sparse samples, sectioning, and super-resolution features. Initially introduced for fluorescence imaging, structured illumination approaches have been adapted and developed for many other imaging modalities. In this paper, we illustrate how speckle illumination, as a particular type of structured illumination, can be exploited to perform optical-resolution photoacoustic microscopy with a single-pixel imaging approach. We first introduce the principle of single-pixel detection applied to photoacoustic imaging and then illustrate in 2 different situations how photoacoustic images may be computationally reconstructed from speckle illumination: In the first situation where the speckle patterns are known through a prior calibration, various reconstruction approaches may be implemented, which are demonstrated experimentally through both scattering layers and multimode optical fibers; in the second situation where the speckle patterns are unknown (blind structured illumination), the so-called memory effect can be harnessed to produce calibration-free photoacoustic images, following the approach initially proposed for fluorescence imaging through thin scattering layers.
带有散斑照明的单像素光声显微镜
具有结构照明和单像素检测的宽视场光学分辨率显微镜已经成为许多研究调查的主题。它比点扫描方法有很多优点,包括对稀疏样本、切片和超分辨率特征的更快采集速率。最初引入荧光成像,结构照明方法已经适应和发展了许多其他成像模式。在本文中,我们说明了如何散斑照明,作为一种特殊类型的结构化照明,可以利用单像素成像方法来执行光学分辨率光声显微镜。我们首先介绍了应用于光声成像的单像素检测原理,然后在两种不同的情况下说明了如何从散斑照明中计算重建光声图像:在第一种情况下,通过事先校准知道散斑图案,可以实现各种重建方法,这些方法通过散射层和多模光纤进行实验证明;在第二种情况下,散斑模式是未知的(盲结构照明),所谓的记忆效应可以利用产生不需要校准的光声图像,遵循最初提出的通过薄散射层进行荧光成像的方法。
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
CiteScore
6.80
自引率
4.70%
发文量
26
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