Immunohistochemistry and mass spectrometry for highly multiplexed cellular molecular imaging

Levenson, Richard M.; Borowsky, Alexander D.; Angelo, Michael

doi:10.1038/labinvest.2015.2

Cited by 95 publications

(90 citation statements)

References 44 publications

(44 reference statements)

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“…These isotopes are not found in normal tissue, eliminating problems with tissue background signal and resulting in high sensitivity. However, this technology is limited by the availability of metal tags (only ~32) and validated antibody conjugates (34). Furthermore, the latter approach requires sample ablation for isotope release, rendering samples unsuitable for additional downstream analysis such as FISH.…”

Section: Discussionmentioning

confidence: 99%

Multiplexed immunofluorescence delineates proteomic cancer cell states associated with metabolism

Sood¹,

Miller²,

Brogi³

et al. 2016

JCI Insight

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The phenotypic diversity of cancer results from genetic and nongenetic factors. Most studies of cancer heterogeneity have focused on DNA alterations, as technologies for proteomic measurements in clinical specimen are currently less advanced. Here, we used a multiplexed immunofluorescence staining platform to measure the expression of 27 proteins at the single-cell level in formalin-fixed and paraffin-embedded samples from treatment-naive stage II/III human breast cancer. Unsupervised clustering of protein expression data from 638,577 tumor cells in 26 breast cancers identified 8 clusters of protein coexpression. In about one-third of breast cancers, over 95% of all neoplastic cells expressed a single protein coexpression cluster. The remaining tumors harbored tumor cells representing multiple protein coexpression clusters, either in a regional distribution or intermingled throughout the tumor. Tumor uptake of the radiotracer 18F-fluorodeoxyglucose was associated with protein expression clusters characterized by hormone receptor loss, PTEN alteration, and HER2 gene amplification. Our study demonstrates an approach to generate cellular heterogeneity metrics in routinely collected solid tumor specimens and integrate them with in vivo cancer phenotypes.

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Section: Discussionmentioning

confidence: 99%

Multiplexed immunofluorescence delineates proteomic cancer cell states associated with metabolism

Sood¹,

Miller²,

Brogi³

et al. 2016

JCI Insight

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“…Samples are ionized either with a laser or ion beam, the metal tags are quantified, and then the images are computationally reconstructed based on known raster positions of the laser or ion beams. 93, 102, 103 These approaches are still developing, but have already enabled quantification of >40 parameters at the single cell level, 103, 104105 and have been used to detect heterogeneity in breast cancer tissues 93, 106 …”

Section: Methods For Single Cell Evaluation In Cell Populationsmentioning

confidence: 99%

Biologically Relevant Heterogeneity: Metrics and Practical Insights

et al. 2017

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Heterogeneity is a fundamental property of biological systems at all scales that must be addressed in a wide range of biomedical applications including basic biomedical research, drug discovery, diagnostics and the implementation of precision medicine. There are a number of published approaches to characterizing heterogeneity in cells in vitro and in tissue sections. However, there are no generally accepted approaches for the detection and quantitation of heterogeneity that can be applied in a relatively high throughput workflow. This review and perspective emphasizes the experimental methods that capture multiplexed cell level data, as well as the need for standard metrics of the spatial, temporal and population components of heterogeneity. A recommendation is made for the adoption of a set of three heterogeneity indices that can be implemented in any high throughput workflow to optimize the decision-making process. In addition, a pairwise mutual information method is suggested as an approach to characterizing the spatial features of heterogeneity, especially in tissue-based imaging. Furthermore, metrics for temporal heterogeneity are in the early stages of development. Example studies indicate that the analysis of functional phenotypic heterogeneity can be exploited to guide decisions in the interpretation of biomedical experiments, drug discovery, diagnostics and the design of optimal therapeutic strategies for individual patients.

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“…It is also worth to mention that alternative staining (e.g., fluorescence) and microscopy methods (multi-spectral imaging) have been proposed and studied in order to overcome the fundamental limitations/challenges in tissue histology (Stack et al, 2014; Levenson et al, 2015; Rimm, 2014; Huang et al, 2013; Ghaznavi et al, 2013); however, H&E stained tissue sections are still the gold standard for the assessment of tissue neoplasm. Furthermore, the efficient and effective representation and interpretation of H&E tissue histology sections in large cohorts (e.g., The Cancer Genome Atlas dataset) have the potential to provide predictive models of genomics and clinical outcome, and are therefore urgently required.…”

Section: Introductionmentioning

confidence: 99%

When machine vision meets histology: A comparative evaluation of model architecture for classification of histology sections

Zhong

Han

Borowsky

et al. 2017

Medical Image Analysis

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Classification of histology sections in large cohorts, in terms of distinct regions of microanatomy (e.g., stromal) and histopathology (e.g., tumor, necrosis), enables the quantification of tumor composition, and the construction of predictive models of genomics and clinical outcome. To tackle the large technical variations and biological heterogeneities, which are intrinsic in large cohorts, emerging systems utilize either prior knowledge from pathologists or unsupervised feature learning for invariant representation of the underlying properties in the data. However, to a large degree, the architecture for tissue histology classification remains unexplored and requires urgent systematical investigation. This paper is the first attempt to provide insights into three fundamental questions in tissue histology classification: I. Is unsupervised feature learning preferable to human engineered features? II. Does cellular saliency help? III. Does the sparse feature encoder contribute to recognition? We show that (a) in I, both Cellular Morphometric Feature and features from unsupervised feature learning lead to superior performance when compared to SIFT and [Color, Texture]; (b) in II, cellular saliency incorporation impairs the performance for systems built upon pixel-/patch-level features; and (c) in III, the effect of the sparse feature encoder is correlated with the robustness of features, and the performance can be consistently improved by the multi-stage extension of systems built upon both Cellular Morphmetric Feature and features from unsupervised feature learning. These insights are validated with two cohorts of Glioblastoma Multiforme (GBM) and Kidney Clear Cell Carcinoma (KIRC).

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Immunohistochemistry and mass spectrometry for highly multiplexed cellular molecular imaging

Cited by 95 publications

References 44 publications

Multiplexed immunofluorescence delineates proteomic cancer cell states associated with metabolism

Multiplexed immunofluorescence delineates proteomic cancer cell states associated with metabolism

Biologically Relevant Heterogeneity: Metrics and Practical Insights

When machine vision meets histology: A comparative evaluation of model architecture for classification of histology sections

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