成像质谱中的无标记组织虚拟染色。

ArXiv Pub Date : 2024-11-20
Yijie Zhang, Luzhe Huang, Nir Pillar, Yuzhu Li, Lukasz G Migas, Raf Van de Plas, Jeffrey M Spraggins, Aydogan Ozcan
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引用次数: 0

摘要

成像质谱(IMS)是生物医学研究中对组织进行非靶向、高度复用分子绘图的强大工具。IMS 提供了一种绘制生物组织中分子物种空间分布图的方法,具有无与伦比的化学特异性和灵敏度。然而,大多数 IMS 平台无法达到显微镜级别的空间分辨率,也缺乏细胞形态对比度,因此需要进行后续的组织化学染色、显微成像和高级图像配准步骤,才能将分子分布与特定的组织特征和细胞类型联系起来。在这里,我们介绍了一种虚拟组织学染色方法,该方法利用扩散模型提高了空间分辨率,并以数字方式将细胞形态对比度引入无标记人体组织的质谱图像中。对人体肾脏组织的盲测结果表明,无标记样本的虚拟染色图像与组织化学染色的对应图像(采用周期性酸-希夫染色)非常吻合,尽管使用的是像素尺寸大 10 倍的 IMS 数据,但在识别关键的肾脏病理结构方面却显示出高度的一致性。此外,我们的方法在扩散模型的推理过程中采用了优化的噪声采样技术,以减少生成图像的差异,从而获得可靠且可重复的虚拟染色。我们相信,这种虚拟染色方法将极大地扩展 IMS 在生命科学领域的应用,并为基于质谱的生物医学研究开辟新的途径。
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Virtual Staining of Label-Free Tissue in Imaging Mass Spectrometry.

Imaging mass spectrometry (IMS) is a powerful tool for untargeted, highly multiplexed molecular mapping of tissue in biomedical research. IMS offers a means of mapping the spatial distributions of molecular species in biological tissue with unparalleled chemical specificity and sensitivity. However, most IMS platforms are not able to achieve microscopy-level spatial resolution and lack cellular morphological contrast, necessitating subsequent histochemical staining, microscopic imaging and advanced image registration steps to enable molecular distributions to be linked to specific tissue features and cell types. Here, we present a virtual histological staining approach that enhances spatial resolution and digitally introduces cellular morphological contrast into mass spectrometry images of label-free human tissue using a diffusion model. Blind testing on human kidney tissue demonstrated that the virtually stained images of label-free samples closely match their histochemically stained counterparts (with Periodic Acid-Schiff staining), showing high concordance in identifying key renal pathology structures despite utilizing IMS data with 10-fold larger pixel size. Additionally, our approach employs an optimized noise sampling technique during the diffusion model's inference process to reduce variance in the generated images, yielding reliable and repeatable virtual staining. We believe this virtual staining method will significantly expand the applicability of IMS in life sciences and open new avenues for mass spectrometry-based biomedical research.

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