In vivo imaging in experimental preclinical tumor research–A review

Wessels, Johannes T.; Busse, Ann-Christin; Mahrt, J.; Dullin, Christian; Grabbe, E.; Muêller, G.

doi:10.1002/cyto.a.20419

Cited by 94 publications

(78 citation statements)

References 19 publications

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“…One solution may be the incorporation of spectral deconvolution into the methodology described here, leading to improvement of imaging quality through the highly specific discrimination between overlapping fluorescent signals (i.e. real and autofluorescence) (10).…”

Section: Discussionmentioning

confidence: 99%

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Quantification of green fluorescent protein by in vivo imaging, PCR, and flow cytometry: Comparison of transgenic strains and relevance for fetal cell microchimerism

et al. 2008

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Animal models are increasingly being used for the assessment of fetal cell microchimerism in maternal tissue. We wished to determine the optimal transgenic mouse strain and analytic technique to facilitate the detection of rare transgenic microchimeric fetal cells amongst a large number of maternal wild-type cells. We evaluated two strains of mice transgenic for the enhanced green fluorescent protein (EGFP): a commercially available, commonly used strain (C57BL/6-Tg(ACTB-EGFP)10sb/J) (CAG) and a newly created strain (ROSA26-EGFP) using three different techniques: in vivo and ex vivo fluorescent imaging (for whole body and dissected organs, respectively), PCR amplification of gfp, and flow cytometry (FCM). By fluorescent imaging, organs from CAG mice were 10-fold brighter than organs from ROSA26-EGFP mice (P < 0.0001). By PCR, more transgene from CAG mice was detected compared to ROSA26-EGFP mice (P 5 0.04). By FCM, ROSA26-EGFP cell fluorescence was more uniform than CAG cells. A greater proportion of cells from ROSA26-EGFP organs were positive for EGFP than cells from CAG organs, but CAG mice had a greater proportion of cells with the brightest fluorescent intensity. Each transgenic strain possesses characteristics that make it useful under specific experimental circumstances. The CAG mouse model is preferable when experiments require brighter cells, whereas ROSA26-EGFP is more appropriate when uniform or ubiquitous expression is more important than brightness. Investigators must carefully select the transgenic strain most suited to the experimental design to obtain the most consistent and reproducible data. In vivo imaging allows for phenotypic evaluation of whole animals and intact organs; however, we did not evaluate its utility for the detection of rare, fetal microchimeric cells in the maternal organs. Finally, while PCR amplification of a paternally inherited transgene does allow for the quantitative determination of rare microchimeric cells, FCM allows for both quantitative and qualitative evaluations of fetal cells at very high sensitivity in a plethora of maternal organs. '

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Section: Discussionmentioning

confidence: 99%

“…We assessed each of these two strains using three different techniques: PCR, in vivo imaging (9,10) as well as the imaging of explanted organs using the same technique (ex vivo imaging), and flow cytometry (FCM). We compared transgenic strains to each other and to their respective wild-type background.…”

mentioning

confidence: 99%

Quantification of green fluorescent protein by in vivo imaging, PCR, and flow cytometry: Comparison of transgenic strains and relevance for fetal cell microchimerism

et al. 2008

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“…Thus the last decades saw the development of a vast number of methods for creating 3D information of cell, tissue, and organ morphology, 3D information of gene expression and gene product patterns, or both. Examples for techniques capable of analyzing small specimens, such as tissue samples or embryos are: in vivo microscopy [7][8][9][10], microcomputed tomography ( CT) [11][12][13], micro-magnetic resonance imaging ( MRI) [9,[14][15][16][17][18], ultrasound biomicroscopy (UBM) [19][20][21], optical projection tomography (OPT) [22,23], confocal microscopy [24][25][26][27][28], atomic force microscopy [29][30][31], 3D electron tomography [32,33], histological or macroscopic section based 3D reconstruction methods [34][35][36][37][38], and 3D episcopic imaging methods (see below). This paper does not compare all the different methods for volume data generation and gene expression analysis.…”

Section: In Situ Gene Expression Analysismentioning

confidence: 99%

Episcopic 3D Imaging Methods: Tools for Researching Gene Function

2013

Advances in Genome Science: Changing Views on Living Organisms

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This work aims at describing episcopic 3D imaging methods and at discussing how these methods can contribute to researching the genetic mechanisms driving embryogenesis and tissue remodelling, and the genesis of pathologies. Several episcopic 3D imaging methods exist. The most advanced are capable of generating high-resolution volume data (voxel sizes from 0.5x0.5x1 m upwards) of small to large embryos of model organisms and tissue samples. Beside anatomy and tissue architecture, gene expression and gene product patterns can be three dimensionally analyzed in their precise anatomical and histological context with the aid of whole mount in situ hybridization or whole mount immunohistochemical staining techniques. Episcopic 3D imaging techniques were and are employed for analyzing the precise morphological phenotype of experimentally malformed, randomly produced, or genetically engineered embryos of biomedical model organisms. It has been shown that episcopic 3D imaging also fits for describing the spatial distribution of genes and gene products during embryogenesis, and that it can be used for analyzing tissue samples of adult model animals and humans. The latter offers the possibility to use episcopic 3D imaging techniques for researching the causality and treatment of pathologies or for staging cancer. Such applications, however, are not yet routine and currently only preliminary results are available. We conclude that, although episcopic 3D imaging is in its very beginnings, it represents an upcoming methodology, which in short terms will become an indispensable tool for researching the genetic regulation of embryo development as well as the genesis of malformations and diseases.

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“…They are either optimised for diagnosing pathologies in humans (computed tomography (CT), magnetic resonance imaging (MRI), ultrasound (US), single photon emission computed tomography (SPECT), positron emission tomography (PET)), for in vivo analysis of -often transparent -model animals [23][24][25][26][27][28][29][30][31][32], or for post-mortem analyses of entire biological specimens and biological tissue samples, on the molecular, subcellular, cellular, tissue, and organ system level (atomic force microscopy, electron microscopy, confocal imaging, optical projection tomography (OPT), episcopic imaging techniques, histological sectioning, micro-MRI, micro-CT, near infrared imaging techniques, polarised light spectroscopy, optical coherence tomography (OCT)). Not all of these techniques permit 3D imaging of the developing cardiovascular system of unborn mice.…”

Section: Modern 3d Imagingmentioning

confidence: 99%

Three-Dimensional (3D) Visualisation of the Cardiovascular System of Mouse Embryos and Fetus

Weninger¹,

Geyer²

2009

TOCARIJ

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Abstract:The mouse is the most appropriate biomedical model organism for researching the mechanistic function of genetic factors in normal embryogenesis and in the genesis of cardiovascular malformations. Three-dimensional (3D) visualisation of the developing organs of wild type and genetically modified mouse embryos is essential for such research. This paper aims at discussing imaging methods that permit the generation of digital volume data sets, which fit for the virtual 3D visualisation and 3D analysis of the cardiovascular system of mouse embryos and mouse fetus. To cover the spectrum of imaging methods comprehensively, we will start with a short overview about early 3D-reconstruction techniques. This will be followed by a brief discussion why in vivo imaging techniques, such as ultrasound (US) or optical coherence tomography (OCT) do not fit for constructing volume data sets that permit virtual 3D visualisation of the cardiovascular system of mouse embryos/fetus. We will then briefly introduce techniques, which permit 3D analysis of the cardiovascular system but do not fit for creating digital volume data (corrosion casts, scanning electron microscopy). Finally, we will focus on describing the advantages and disadvantages, the spectrum of application and the limitations of important modern digital volume data generation methods, such as micro-computed tomography ( CT), micro-magnetic resonance imaging ( MRI), optical projection tomography (OPT), confocal microscopy, histological section based volume data generation methods, and 3D episcopic imaging methods.

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In vivo imaging in experimental preclinical tumor research–A review

Cited by 94 publications

References 19 publications

Quantification of green fluorescent protein by in vivo imaging, PCR, and flow cytometry: Comparison of transgenic strains and relevance for fetal cell microchimerism

Quantification of green fluorescent protein by in vivo imaging, PCR, and flow cytometry: Comparison of transgenic strains and relevance for fetal cell microchimerism

Episcopic 3D Imaging Methods: Tools for Researching Gene Function

Three-Dimensional (3D) Visualisation of the Cardiovascular System of Mouse Embryos and Fetus

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