eoe sub articles

EoE Sub Articles

All procedures involving animal models have been reviewed by the local institutional animal care committee and the JoVE veterinary review board.
1.FMT Imaging
NOTE: According to the experimental aim, the iRFP-tagged glioblastoma cells can be monitored in vivo before, during, or after treatment. For imaging purpose, anesthetize animals using an isoflurane induction chamber, maintain in an imaging cassette during the scanning, and image in the docking station of the FMT imager.
<ol>
	<li>Remove the animal from the cage and place in the isoflurane induction chamber. Close the chamber and turn on oxygen flow and vaporizer to 3&#8211;5%.</li>
	<li>Monitor the animal until it is completely anesthetized, usually within 1&#8211;2 min. Unconscious animals should not respond to external stimuli.</li>
	<li>Remove the anesthetized animal from the chamber and put the animal in the imaging cassette by placing the head adaptor first, followed by placing the animal facing down. Make sure that the head is located in the center of the cassette.</li>
	<li>Place the top plate of the cassette on top and tighten the adjustment knobs until 17 mm.</li>
	<li>Once the animal is secure in the imaging cassette, proceed to imaging by inserting the cassette into the internal docking station of the FMT imager, where the isoflurane is pumped to keep the animal anesthetized.</li>
	<li>Run the imager and analyzer software by double-clicking the software icon.</li>
	<li>In the &#34;Experimental tab&#34; window, select the &#34;Database&#34; and &#34;Study group&#34;.</li>
	<li>Go to the &#34;Scan tab&#34; window and select the subject to image by clicking &#34;select subject&#34;. Also, select the laser channel in the &#34;Laser channel&#34; panel. For the FP635-labeled cells, select &#34;laser channel 635 nm&#34;, and for FP720-labeled cells, select &#34;laser channel 680 nm&#34;.</li>
	<li>Acquire an image by clicking the &#34;Capture&#34; option in the &#34;Scan tab&#34; window. Then, adjust the scan field by clicking and dragging the scan field in the captured image to a determined number of source locations, usually within 20&#8211;25 sources for the ipsilateral side.</li>
	<li>Check the &#34;Add to reconstruction queue&#34; option and hit &#34;Scan&#34; in the &#34;Scan tab&#34; window.</li>
	<li>Wait until the scanning is completed and then remove the imaging cassette from the docking station.</li>
	<li>Remove the top plate of the cassette and place the animal back into the cage.</li>
	<li>Repeat steps 1.1&#8211;1.12 for the rest of the animals.</li>
</ol>
2. Image Analysis
<ol>
	<li>From the imager and analyzer software, select the &#34;Analysis tab&#34; window.</li>
	<li>Load the dataset and the subject to analyze by clicking the &#34;+&#34; button in the &#34;Dataset selection&#34; panel of the &#34;Analysis tab&#34; window.</li>
	<li>Once the image has been loaded in the &#34;Analysis tab&#34; window, perform the region of interest (ROI) analysis by selecting the ellipsoid icon, located in the upper left corner of the &#34;Analysis tab&#34; window.</li>
	<li>Adjust the threshold to zero in the &#34;statistic data&#34; panel by right clicking the &#34;threshold&#34; column in the &#34;Analysis tab&#34; window.</li>
	<li>The total value in the &#34;Statistic data&#34; panel represents the signal from the fluorescent-tagged glioblastoma cells implanted in the mouse brain.</li>
	<li>Repeat steps 2.2&#8211;2.4 for the rest of the animals. Load or remove a new subject by clicking the &#34;+&#34; or &#34;&#8722;&#34; button, respectively, in the &#34;Dataset selection&#34; panel of the &#34;Analysis tab&#34; window.</li>
</ol>

fluorescence molecular tomography: an imaging technique for in vivo imaging of fluorescent protein-tagged glioblastoma xenografts in mouse model

Source: Benitez, J. A. et al., <a href="https://www.jove.com/video/57448" target="_blank">Fluorescence Molecular Tomography for In Vivo Imaging of Glioblastoma Xenografts.</a> J. Vis. Exp. (2018)
In this video, we describe fluorescence molecular tomography or FMT for in vivo imaging of fluorescent protein-tagged glioblastoma xenografts in mouse models. The technique is useful for elucidating the effects of anti-tumor therapeutics at the molecular level.

Fluorescence Molecular Tomography: An Imaging Technique for In Vivo Imaging of Fluorescent Protein-tagged Glioblastoma Xenografts in Mouse Model

Source: Benitez, J. A. et al., Fluorescence Molecular Tomography for In Vivo Imaging of Glioblastoma Xenografts. J. Vis. Exp. (2018)
In this video, we ...

Fluorescence molecular tomography or FMT is an imaging technique that helps determine the distribution of fluorescent proteins present in tumors. To perform FMT, begin by taking an anesthetized mouse. This mouse model is engineered to express near-infrared fluorescent proteins in the glioblastoma cells - the cancerous cells of the brain.
Now, place the mouse in the prone position in the center of an imaging cassette. Fasten the cassette lid and insert it into the docking station of an FMT imager. Once inside, identify an appropriate tumor area containing labeled glioblastoma cells. The near-infrared light penetrates deeply through the brain tissue reaching the target cells.
These light waves scan the entire tumor area at multiple points. Consequently, the fluorescent proteins within the glioblastoma cells produce fluorescent emission signals. These signals are then detected by the transillumination system from above, which generates high-quality 2D images from various locations within the selected tumor area.
Finally, use the software algorithms to combine these images and reconstruct a 3D-tomographic model that indicates tumor localization in the brain. After scanning, remove the mouse from the imaging cassette and allow it to recover.

fluorescence-molecular-tomography-an-imaging-technique-for-vivo

Research

JoVE Encyclopedia of Experiments

Cancer Research

Cancers of the Nervous System

In vivo studies

1.1K Views. Source: Benitez, J. A. et al., Fluorescence Molecular Tomography for In Vivo Imaging of Glioblastoma Xenografts. J. Vis. Exp. (2018) In this video, we describe fluorescence molecular tomography or FMT for in vivo imaging of fluorescent protein-tagged glioblastoma xenografts in mouse models. The technique is useful for elucidating the effects of anti-tumor therapeutics at the molecular level. 

Video: Fluorescence Molecular Tomography: An Imaging Technique for In Vivo Imaging of Fluorescent Protein-tagged Glioblastoma Xenografts in Mouse Model - Concept

Computed Tomography-guided Time-domain Diffuse Fluorescence Tomography in Small Animals for Localization of Cancer Biomarkers

Small animal fluorescence molecular imaging (FMI) can be a powerful tool for preclinical drug discovery and development studies1. However, light absorption by tissue chromophores (e.g., hemoglobin, water, lipids, melanin) typically limits optical signal propagation through thicknesses larger than a few millimeters2. Compared to other visible wavelengths, tissue absorption for red and near-infrared (near-IR) light absorption dramatically decreases and non-elastic scattering becomes the dominant light-tissue interaction mechanism. The relatively recent development of fluorescent agents that absorb and emit light in the near-IR range (600-1000 nm), has driven the development of imaging systems and light propagation models that can achieve whole body three-dimensional imaging in small animals3.
Despite great strides in this area, the ill-posed nature of diffuse fluorescence tomography remains a significant problem for the stability, contrast recovery and spatial resolution of image reconstruction techniques and the optimal approach to FMI in small animals has yet to be agreed on. The majority of research groups have invested in charge-coupled device (CCD)-based systems that provide abundant tissue-sampling but suboptimal sensitivity4-9, while our group and a few others10-13 have pursued systems based on very high sensitivity detectors, that at this time allow dense tissue sampling to be achieved only at the cost of low imaging throughput. Here we demonstrate the methodology for applying single-photon detection technology in a fluorescence tomography system to localize a cancerous brain lesion in a mouse model.
The fluorescence tomography (FT) system employed single photon counting using photomultiplier tubes (PMT) and information-rich time-domain light detection in a non-contact conformation11. This provides a simultaneous collection of transmitted excitation and emission light, and includes automatic fluorescence excitation exposure control14, laser referencing, and co-registration with a small animal computed tomography (microCT) system15. A nude mouse model was used for imaging. The animal was inoculated orthotopically with a human glioma cell line (U251) in the left cerebral hemisphere and imaged 2 weeks later. The tumor was made to fluoresce by injecting a fluorescent tracer, IRDye 800CW-EGF (LI-COR Biosciences, Lincoln, NE) targeted to epidermal growth factor receptor, a cell membrane protein known to be overexpressed in the U251 tumor line and many other cancers18. A second, untargeted fluorescent tracer, Alexa Fluor 647 (Life Technologies, Grand Island, NY) was also injected to account for non-receptor mediated effects on the uptake of the targeted tracers to provide a means of quantifying tracer binding and receptor availability/density27. A CT-guided, time-domain algorithm was used to reconstruct the location of both fluorescent tracers (i.e., the location of the tumor) in the mouse brain and their ability to localize the tumor was verified by contrast-enhanced magnetic resonance imaging.
Though demonstrated for fluorescence imaging in a glioma mouse model, the methodology presented in this video can be extended to different tumor models in various small animal models potentially up to the size of a rat17.

Diffuse fluorescence tomography offers a relatively low-cost and potentially high-throughout approach to preclinical in vivo tumor imaging. The methodology of optical data collection, calibration, and image reconstruction is presented for a computed tomography-guided non-contact time-domain system using fluorescent targeting of the tumor biomarker epidermal growth factor receptor in a mouse glioma model.

Small animal fluorescence molecular imaging (FMI) can be a powerful tool for preclinical drug discovery and development studies1. However, light ...

JoVE Journal

Medicine

Hybrid &#181;CT-FMT imaging and image analysis

Fluorescence-mediated tomography (FMT) enables longitudinal and quantitative determination of the fluorescence distribution in vivo and can be used to assess the biodistribution of novel probes and to assess disease progression using established molecular probes or reporter genes. The combination with an anatomical modality, e.g., micro computed tomography (&#181;CT), is beneficial for image analysis and for fluorescence reconstruction. We describe a protocol for multimodal &#181;CT-FMT imaging including the image processing steps necessary to extract quantitative measurements. After preparing the mice and performing the imaging, the multimodal data sets are registered. Subsequently, an improved fluorescence reconstruction is performed, which takes into account the shape of the mouse. For quantitative analysis, organ segmentations are generated based on the anatomical data using our interactive segmentation tool. Finally, the biodistribution curves are generated using a batch-processing feature. We show the applicability of the method by assessing the biodistribution of a well-known probe that binds to bones and joints.

Hybrid  &amp;#181;CT-FMT imaging and image analysis

We describe a protocol for hybrid imaging, combining fluorescence-mediated tomography (FMT) with micro computed tomography (&#181;CT). After fusion and reconstruction, we perform interactive organ segmentation to extract quantitative measurements of the fluorescence distribution.

Fluorescence-mediated tomography (FMT) enables longitudinal and quantitative determination of the fluorescence distribution in vivo and can be used to ...

Bioengineering

Combined Near-infrared Fluorescent Imaging and Micro-computed Tomography for Directly Visualizing Cerebral Thromboemboli

Direct thrombus imaging visualizes the root cause of thromboembolic infarction. Being able to image thrombus directly allows far better investigation of stroke than relying on indirect measurements, and will be a potent and robust vascular research tool. We use an optical imaging approach that labels thrombi with a molecular imaging thrombus marker&#160;&#8212; a Cy5.5 near-infrared fluorescent (NIRF) probe that is covalently linked to the fibrin strands of the thrombus by the fibrin-crosslinking enzymatic action of activated coagulation factor XIIIa during the process of clot maturation. A micro-computed tomography (microCT)-based approach uses thrombus-seeking gold nanoparticles (AuNPs) functionalized to target the major component of the clot: fibrin. This paper describes a detailed protocol for the combined in vivo microCT and ex vivo NIRF imaging of thromboemboli in a mouse model of embolic stroke. We show that in vivo microCT and fibrin-targeted glycol-chitosan AuNPs (fib-GC-AuNPs) can be used for visualizing both in situ thrombi and cerebral embolic thrombi. We also describe the use of in vivo microCT-based direct thrombus imaging to serially monitor the therapeutic effects of tissue plasminogen activator-mediated thrombolysis. After the last imaging session, we demonstrate by ex vivo NIRF imaging the extent and the distribution of residual thromboemboli in the brain. Finally, we describe quantitative image analyses of microCT and NIRF imaging data. The combined technique of direct thrombus imaging allows two independent methods of thrombus visualization to be compared: the area of thrombus-related fluorescent signal on ex vivo NIRF imaging vs. the volume of hyperdense microCT thrombi in vivo.

This protocol describes the application of combined near-infrared fluorescent (NIRF) imaging and micro-computed tomography (microCT) for visualizing cerebral thromboemboli. This technique allows the quantification of thrombus burden and evolution. The NIRF imaging technique visualizes fluorescently labeled thrombus in excised brain, while the microCT technique visualizes thrombus inside living animals using gold-nanoparticles.

Direct thrombus imaging visualizes the root cause of thromboembolic infarction. Being able to image thrombus directly allows far better investigation of ...

Fluorescence Molecular Tomography: An Imaging Technique for In Vivo Imaging of Fluorescent Protein-tagged Glioblastoma Xenografts in Mouse Model

Transcript