Michael Dobosz scite author profile

Classic histology still represents the gold standard in tumor tissue analytics. However, two-dimensional analysis of single tissue slides does not provide a representative overview of the inhomogeneous tumor physiology, and a detailed analysis of complex three-dimensional structures is not feasible with this technique. To overcome this problem, we applied multispectral fluorescence ultramicroscopy (UM) to the field of tumor analysis. Optical sectioning of cleared tumor specimen provides the possibility to three-dimensionally acquire relevant tumor parameters on a cellular resolution. To analyze the virtual UM tumor data sets, we created a novel set of algorithms enabling the fully automatic segmentation and quantification of multiple tumor parameters. This new postmortem imaging technique was applied to determine the therapeutic treatment effect of bevacizumab on the vessel architecture of orthotopic KPL-4 breast cancer xenografts at different time points. A significant reduction of the vessel volume, number of vessel segments, and branching points in the tumor periphery was already detectable 1 day after initiation of treatment. These parameters remained virtually unchanged in the center of the tumor. Furthermore, bevacizumab-induced vessel normalization and reduction in vascular permeability diminished the penetration behavior of trastuzumab-Alexa 750 into tumor tissue. Our results demonstrated that this newimaging method enables the three-dimensional visualization and fully automatic quantification of multiple tumor parameters and drug penetration on a cellular level. Therefore,UM is a valuable tool for cancer research and drug development. It bridges the gap between common macroscopic and microscopic imaging modalities and opens up new three-dimensional (3D) insights in tumor biology.

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Three-Dimensional Optical Mapping of Nanoparticle Distribution in Intact Tissues

Sindhwani

Syed

Wilhelm

et al. 2016

ACS Nano

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The role of tissue architecture in mediating nanoparticle transport, targeting, and biological effects is unknown due to the lack of tools for imaging nanomaterials in whole organs. Here, we developed a rapid optical mapping technique to image nanomaterials in intact organs ex vivo and in three-dimensions (3D). We engineered a high-throughput electrophoretic flow device to simultaneously transform up to 48 tissues into optically transparent structures, allowing subcellular imaging of nanomaterials more than 1 mm deep into tissues which is 25-fold greater than current techniques. A key finding is that nanomaterials can be retained in the processed tissue by chemical cross-linking of surface adsorbed serum proteins to the tissue matrix, which enables nanomaterials to be imaged with respect to cells, blood vessels, and other structures. We developed a computational algorithm to analyze and quantitatively map nanomaterial distribution. This method can be universally applied to visualize the distribution and interactions of materials in whole tissues and animals including such applications as the imaging of nanomaterials, tissue engineered constructs, and biosensors within their intact biological environment.

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Deep tissue imaging: a review from a preclinical cancer research perspective

Feuchtinger

Walch

Dobosz³

2016

Histochem Cell Biol

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This review delves into the rapidly evolving field of deep tissue imaging at cellular resolution, reviewing popular tissue clearing and staining methods in combination with light-sheet fluorescence microscopy (LSFM) including quantification and three-dimensional visualization tools, the field of applications and perspective, particularly with the focus on preclinical cancer research and drug development. The LSFM technique presented here allows an extremely fast optical sectioning for three-dimensional reconstruction of centimeter-sized tissue samples at cellular resolution. However, optical clearing methods are required to receive optical transparent tissue. Application of either tissue autofluorescence, in vivo fluorescence labeling, endogenous fluorescence or ex vivo whole-mount immunolabeling enables three-dimensional in situ visualization of morphological and functional features of unsectioned whole-mount tissue samples. This powerful and innovative imaging technique opens up a new dimension of tissue analysis providing detailed and comprehensive insights into biology. It enables the investigation of normal and pathological tissue features and disease progression and allows precise monitoring of potential therapeutic interventions in intact biological tissue on a cellular level.

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Intratumoral dendritic cell–CD4+ T helper cell niches enable CD8+ T cell differentiation following PD-1 blockade in hepatocellular carcinoma

Magen

Hamon

Fiaschi

et al. 2023

Nat Med

133

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Michael Dobosz

Multispectral Fluorescence Ultramicroscopy: Three-Dimensional Visualization and Automatic Quantification of Tumor Morphology, Drug Penetration, and Antiangiogenic Treatment Response

Three-Dimensional Optical Mapping of Nanoparticle Distribution in Intact Tissues

Deep tissue imaging: a review from a preclinical cancer research perspective

Intratumoral dendritic cell–CD4+ T helper cell niches enable CD8+ T cell differentiation following PD-1 blockade in hepatocellular carcinoma

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