In vivo imaging in experimental preclinical tumor research–A review

The multiparametric molecular cell and tissue analysis in vitro and in vivo is characterized by rapid progress in the field of image generation technologies, sensor biotechnology, and computational modeling. Fascinating new potentials in unraveling the detailed functions of single cells, organs, and whole organisms are presently emerging and permit the close monitoring i.e. tumor development or basic cell development processes with an unprecedented multiplicity of promising investigative possibilities. To answer basic questions of in vivo tumor development and progression fluorescence based imaging techniques provide new insights into molecular pathways and targets. Genetic reporter systems (eGFP, DsRED) are available and high sensitive detection systems are on hand. These techniques could be used for in vitro assays and quantified e.g. by microscopy and CCD based readouts. The introduction of novel fluorescent dyes emitting in the near infrared range (NIR) combined with the development of sensitive detector systems and monochromatic powerful NIR‐lasers for the first time permits the quantification and imaging of fluorescence and/or bioluminescence in deeper tissues. Laser based techniques particularly in the NIR‐range (like two‐photon microscopy) offer superb signal to noise ratios, and thus the potential to detect molecular targets in vivo. In combination with flat panel volumetric computed tomography (fpVCT), questions dealing e.g. with tumor size, tumor growth, and angiogenesis/vascularization could be answered noninvasively using the same animal. The resolution of down to 150 μm/each direction can be achieved using fpVCT. It is demonstrated by many groups that submillimeter resolutions can be achieved in small animal imaging at high sensitivity and molecular specificity. Since the resolution in preclinical small animal imaging is down to ∼10 μm by the use of microCT and to subcellular resolutions using (∼1 μm) microscope based systems, the advances of different techniques can now be combined to “multimodal” preclinical imaging and the possibilities for in vivo intravital cytometry now become within one's reach. © 2007 International Society for Analytical Cytology

[1]  Wolfhard Semmler,et al.  Volumetric computed tomography (VCT): a new technology for noninvasive, high-resolution monitoring of tumor angiogenesis , 2004, Nature Medicine.

[2]  K. Yamauchi,et al.  Development of real-time subcellular dynamic multicolor imaging of cancer-cell trafficking in live mice with a variable-magnification whole-mouse imaging system. , 2006, Cancer research.

[3]  Sebastian Amigorena,et al.  In vivo imaging of cytotoxic T cell infiltration and elimination of a solid tumor , 2007, The Journal of experimental medicine.

[4]  Weibo Cai,et al.  Near-Infrared Fluorescence Imaging of Tumor Integrin αvβ3 Expression with Cy7-Labeled RGD Multimers , 2006, Molecular Imaging and Biology.

[5]  J. Zavadil,et al.  Single cell behavior in metastatic primary mammary tumors correlated with gene expression patterns revealed by molecular profiling. , 2002, Cancer research.

[6]  M. Funke,et al.  [Feasibility of flat-panel volumetric computed tomography (fpVCT) in experimental small animal imaging of osteoporosis - initial experience]. , 2006, Der Radiologe.

[7]  Michael L. Dustin,et al.  In vivo imaging of germinal centres reveals a dynamic open structure , 2007, Nature.

[8]  Wolfhard Semmler,et al.  Potential applications of flat-panel volumetric CT in morphologic and functional small animal imaging. , 2005, Neoplasia.

[9]  Dual-color, whole-body imaging in mice , 2005, Nature Biotechnology.

[10]  Meng Yang,et al.  In vivo color-coded imaging of the interaction of colon cancer cells and splenocytes in the formation of liver metastases. , 2006, Cancer research.

[11]  W. Kaiser,et al.  Autofluorescence spectroscopy in whole organs with a mobile detector system. , 2004, Academic radiology.

[12]  K. Eliceiri,et al.  Optimized temporal response in multichannel two‐photon fluorescence lifetime microscopy using a photonic crystal fibre , 2006, Journal of microscopy.

[13]  D L Farkas,et al.  Cyanine fluorochrome-labeled antibodies in vivo: assessment of tumor imaging using Cy3, Cy5, Cy5.5, and Cy7. , 1998, Cancer detection and prevention.

[14]  W. Denk,et al.  Two-photon laser scanning fluorescence microscopy. , 1990, Science.

[15]  V. Tuchin Handbook of Optical Biomedical Diagnostics , 2002 .

[16]  R. Hoffman Real-time subcellular imaging in live animals: new visible targets for cancer drug discovery. , 2006, IDrugs : the investigational drugs journal.

[17]  A. Maitra,et al.  Tumor Cells Genetically Labeled with GFP in the Nucleus and RFP in the Cytoplasm for Imaging Cellular Dynamics , 2006, Cell cycle.

[18]  R. Weissleder Molecular imaging: exploring the next frontier. , 1999, Radiology.

[19]  Robert M Hoffman,et al.  High correlation of whole-body red fluorescent protein imaging and magnetic resonance imaging on an orthotopic model of pancreatic cancer. , 2005, Cancer research.

[20]  M. Funke,et al.  Erste Erfahrungen mit einem Flächendetektor-Volumen-CT (fpVCT) in der experimentellen Osteoporosediagnostik am Kleintiermodell , 2006, Der Radiologe.

[21]  Steve M. Potter,et al.  Intravital imaging of green fluorescent protein using two-photon laser-scanning microscopy. , 1996, Gene.

[22]  Steven S Vogel,et al.  Quantitative linear unmixing of CFP and YFP from spectral images acquired with two‐photon excitation , 2006, Cytometry. Part A : the journal of the International Society for Analytical Cytology.