Versatile whole-organ/body staining and imaging based on electrolyte-gel properties of biological tissues

Susaki, Etsuo A.; Shimizu, Chika; Kuno, Akihiro; Tainaka, Kazuki; Li, Xiang; Nishi, Kengo; Morishima, Ken; Ono, H.; Ode, Koji L.; Saeki, Yasutake; Miyamichi, Kazunari; Isa, Kaoru; Yokoyama, Chihiro; Kitaura, Hiroki; Ikemura, Masako; Ushiku, Tetsuo; Shimizu, Yoshihiro; Saito, Takashi; Saido, Takaomi C.; Fukayama, Masashi; Onoe, Hirotaka; Touhara, Kazushige; Isa, Tadashi; Kakita, Akiyoshi; Shibayama, Mitsuhiro; Ueda, Hiroki R.

doi:10.1038/s41467-020-15906-5

Cited by 179 publications

(213 citation statements)

References 61 publications

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“…While transgenic strategies are currently not applicable to nonhuman primates (NHP), viral approaches like RAM could be, in principle, switched to map-activated neurons in different animals (Sørensen et al, 2016). Indeed, large-scale clearing and imaging methods have been demonstrated in small NHP like the marmoset (Seiriki et al, 2017;Susaki et al, 2020). When coupled with standard neuroimaging like functional magnetic resonance imaging (fMRI) or positron-emission tomography (PET), single-cell activation mapping in NHP could provide a unique framework to better understand the relationship between neuronal activity and imaging data.…”

Section: Discussionmentioning

confidence: 99%

“…Anyhow, whatever optical improvement must rely on a good optical clearing, which is an essential prerequisite for the use of high-resolution LSM. The group of Hiroki Ueda has pioneered IEG mapping at subcellular resolution, demonstrating the potential of this approach to quantify neuronal activation across the entire murine brains without excluding any areas (Murakami et al, 2018;Matsumoto et al, 2019;Susaki et al, 2020).…”

Section: Imagingmentioning

confidence: 99%

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Dissecting Neuronal Activation on a Brain-Wide Scale With Immediate Early Genes

Franceschini¹,

Costantini

Pavone

et al. 2020

Front. Neurosci.

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Visualizing neuronal activation on a brain-wide scale yet with cellular resolution is a fundamental technical challenge for neuroscience. This would enable analyzing how different neuronal circuits are disrupted in pathology and how they could be rescued by pharmacological treatments. Although this goal would have appeared visionary a decade ago, recent technological advances make it eventually feasible. Here, we review the latest developments in the fields of genetics, sample preparation, imaging, and image analysis that could be combined to afford whole-brain cell-resolution activation mapping. We show how the different biochemical and optical methods have been coupled to study neuronal circuits at different spatial and temporal scales, and with celltype specificity. The inventory of techniques presented here could be useful to find the tools best suited for a specific experiment. We envision that in the next years, mapping of neuronal activation could become routine in many laboratories, allowing dissecting the neuronal counterpart of behavior.

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Section: Discussionmentioning

confidence: 99%

Section: Imagingmentioning

confidence: 99%

Dissecting Neuronal Activation on a Brain-Wide Scale With Immediate Early Genes

Franceschini¹,

Costantini

Pavone

et al. 2020

Front. Neurosci.

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“…This type of tissue is the most widely studied using tissue clearing methods ( Kim et al., 2018 ; Wan et al., 2018 ). In principle, it is essential for any method that aims at clearing neural tissue to perform a prior delipidation step to remove the myelin sheets that enclose neuronal axons ( Susaki et al., 2020 ), as their high lipidic content causes a large amount of scattering. An approach combining CLARITY with double photon microscopy enabled visualization of gray matter in the intact brain ( Chang et al., 2017 ).…”

Section: Translational Applications Of Tissue Clearing and 3d Imagingmentioning

confidence: 99%

“…CUBIC was proposed as a new brain clearing method that obviates electrophoresis, in contrast to CLARITY ( Susaki et al., 2014 ). CUBIC's clearing capability of neural tissue has been quantitatively proved by means of a small-angle X-ray scattering analysis (SAXS), which showed that CUBIC reagent 1 is capable of effectively removing the myelin sheet and, therefore, reducing scattering ( Susaki et al., 2020 ). Chicken embryo brains have been successfully cleared with an optimized CUBIC method ( Gómez-Gaviro et al., 2017 ).…”

Section: Translational Applications Of Tissue Clearing and 3d Imagingmentioning

confidence: 99%

“…The authors demonstrated the electrolyte-hydrogel behavior of fixed, delipidated tissues, what supports the application of the Lorentz-Lorenz equation (which was stated in 1880 for polymers) to tissues, as mentioned in the introduction ( Ueda et al., 2020 ). They used this resemblance to optimize electrostatic interactions between the dye or immunolabel and the gel, and improve their penetration by regulating pH, salt concentration, temperature, and other environmental and chemical conditions ( Susaki et al., 2020 ).…”

Section: Translational Applications Of Tissue Clearing and 3d Imagingmentioning

confidence: 99%

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Biomedical Applications of Tissue Clearing and Three-Dimensional Imaging in Health and Disease

et al. 2020

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Summary Three-dimensional (3D) optical imaging techniques can expand our knowledge about physiological and pathological processes that cannot be fully understood with 2D approaches. Standard diagnostic tests frequently are not sufficient to unequivocally determine the presence of a pathological condition. Whole-organ optical imaging requires tissue transparency, which can be achieved by using tissue clearing procedures enabling deeper image acquisition and therefore making possible the analysis of large-scale biological tissue samples. Here, we review currently available clearing agents, methods, and their application in imaging of physiological or pathological conditions in different animal and human organs. We also compare different optical tissue clearing methods discussing their advantages and disadvantages and review the use of different 3D imaging techniques for the visualization and image acquisition of cleared tissues. The use of optical tissue clearing resources for large-scale biological tissues 3D imaging paves the way for future applications in translational and clinical research.

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Volumetric imaging of the tumor microvasculature reflects outcomes and genomic states of clear cell renal cell carcinoma

Kaneko,

Masuda,

Takamatsu

et al. 2024

The Journal of Pathology CR

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Tumor structure is heterogeneous and complex, and it is difficult to obtain complete characteristics by two‐dimensional analysis. The aim of this study was to visualize and characterize volumetric vascular information of clear cell renal cell carcinoma (ccRCC) tumors using whole tissue phenotyping and three‐dimensional light‐sheet microscopy. Here, we used the diagnosing immunolabeled paraffin‐embedded cleared organs pipeline for tissue clearing, immunolabeling, and three‐dimensional imaging. The spatial distributions of CD34, which targets blood vessels, and LYVE‐1, which targets lymphatic vessels, were examined by calculating three‐dimensional density, vessel length, vessel radius, and density curves, such as skewness, kurtosis, and variance of the expression. We then examined those associations with ccRCC outcomes and genetic alteration state. Formalin‐fixed paraffin‐embedded tumor samples from 46 ccRCC patients were included in the study. Receiver operating characteristic curve analyses revealed the associations between blood vessel and lymphatic vessel distributions and pathological factors such as a high nuclear grade, large tumor size, and the presence of venous invasion. Furthermore, three‐dimensional imaging parameters stratified ccRCC patients regarding survival outcomes. An analysis of genomic alterations based on volumetric vascular information parameters revealed that PI3K‐mTOR pathway mutations related to the blood vessel radius were significantly different. Collectively, we have shown that the spatial elucidation of volumetric vasculature information could be prognostic and may serve as a new biomarker for genomic alterations. High‐end tissue clearing techniques and volumetric immunohistochemistry enable three‐dimensional analysis of tumors, leading to a better understanding of the microvascular structure in the tumor space.

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Versatile whole-organ/body staining and imaging based on electrolyte-gel properties of biological tissues

Cited by 179 publications

References 61 publications

Dissecting Neuronal Activation on a Brain-Wide Scale With Immediate Early Genes

Dissecting Neuronal Activation on a Brain-Wide Scale With Immediate Early Genes

Biomedical Applications of Tissue Clearing and Three-Dimensional Imaging in Health and Disease

Volumetric imaging of the tumor microvasculature reflects outcomes and genomic states of clear cell renal cell carcinoma

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