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10. Whole mouse cryo-imaging

Author

Wilson, David, primary, Roy, Debashish, additional, Steyer, Grant, additional, Gargesha, Madhusudhana, additional, Stone, Meredith, additional, and McKinley, Eliot, additional

Published
2008
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12. Calcium Imaging of Sonoporation of Mammalian Cells.

Author

Sabens, David, Aehle, Matthew, Steyer, Grant, Kourennyi, Dmitri, and Deng, Cheri X.

Subjects
CALCIUM ions, CELL membranes, GENETIC transformation, GENETIC recombination, APOPTOSIS, CELL death
Abstract

Ultrasound mediated delivery of compounds is a relatively recent development in drug delivery and gene transfection techniques. Due to the lack of methods for real-time monitoring of sonoporation at the cellular level, the efficiency of drug/gene delivery and sonoporation associated side effects, such as the loss of cell viability and enhanced apoptosis, have been studied only through post US exposure analyses, requiring days for cell incubation. Furthermore, because microporation appears to be transient in nature, it was not possible to correlate transfection with microporation on an individual cellular basis. By studying the role of calcium in the cell and using fluorescent calcium imaging to study sonoporation it is possible to quantify both cell porosity and sonoporation side effects. Since both post sonoporation cell survival and delivery efficiency are related to the dynamic process of the cell membrane poration, calcium imaging of sonoporation will provide important knowledge to obtain improved understanding of sonoporation mechanism. Our experimental results demonstrated the feasibility of calcium imaging of sonoporation in Chinese Hamster Ovary (CHO) cells. We have measured the changes in the intracellular calcium concentration using Fura-2, a fluorescent probe, which indicate influx or flow of Calcium across the cell membrane. Analysis of data identified key aspects in the dynamic sonoporation process including the formation of pores in the cell membrane, and the relative temporal duration of the pores and their resealing. These observations are obtained through the analysis of the rate the calcium concentration changes within the cells, making it possible to visualize membrane opening and repair in real-time through such changes in the intracellular calcium concentration. © 2006 American Institute of Physics [ABSTRACT FROM AUTHOR]

Published
2006
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13. Multi-Scale Characterization of the PEPCK-Cmus Mouse through 3D Cryo-Imaging.

Author

Roy, Debashish, Gargesha, Madhusudhana, Steyer, Grant J., Hakimi, Parvin, Hanson, Richard W., and Wilson, David L.

Subjects
TRANSGENIC mice, THREE-dimensional imaging, MULTISCALE modeling, PYRUVATE kinase, TRANSGENIC animals
Abstract

We have developed, for the Case 3D Cryo-imaging system, a specialized, multi-scale visualization scheme which provides colorrich volume rendering and multi-planar reformatting enabling one to visualize an entire mouse and zoom in to organ, tissue, and microscopic scales. With this system, we have anatomically characterized, in 3D, from whole animal to tissue level, a transgenic mouse and compared it with its control. The transgenic mouse over-expresses the cytosolic form of phosphoenolpyruvate carboxykinase (PEPCK-C) in its skeletal muscle and is capable of greatly enhanced physical endurance, and has a longer lifespan and reproductive life as compared to control animals. We semi-automatically analyzed selected organs such as kidney, heart, adrenal gland, spleen, and ovaries and found comparatively enlarged heart, much less visceral, subcutaneous and pericardial adipose tissue, and higher tibia-to-femur ratio in the transgenic animal. Microscopically, individual skeletal muscle fibers, fine mesenteric blood vessels, intestinal villi, among others, were clearly seen. [ABSTRACT FROM AUTHOR]

Published
2010
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14. IMAGING OF CARDIOVASCULAR CELLULAR THERAPEUTICS WITH A CRYO-IMAGING SYSTEM

Author

Steyer, Grant J.

Subjects
Biomedical Research, cryo-imaging, block face imaging, next image processing, model based processing, stem cell imaging, stem cell therapy
Abstract

The long term goal of this research is to use cryo-imaging to detect and spatially map nearly every stem cell in a mouse and quantify tissue specific, cell therapy PK. With this enabling technology, one will be able to quantitatively assess specificity of homing, quiescent survival in specific niches, emerging homing factors, delivery processes, cell engraftment dose response, etc., analyses which have, at best, been done qualitatively. To this end, we developed a cryo-imaging system, which alternates between sectioning (10-40 µm) and imaging bright field and fluorescence block-face image volumes with micron-scale-resolution. For applications requiring single-cell detection of fluorescently labeled cells anywhere in a mouse, we developed an algorithm, next-image processing, for reduction of subsurface fluorescence. Next-image processing greatly improves axial-resolution, enabling high quality 3D volume renderings, and improved automated enumeration of single cells by up to 24%. To answer many of the pressing questions in stem cell therapies, automated methods for quantification and detection of stem cells are required. We developed algorithms for the automated detection and quantification of fluorescently labeled cells. Our model based quantification algorithm was performed on low resolution images of fluorescently labeled stem cells and the results were compared to visual quantification of stem cells in high resolution images. In all cases but two, the algorithm was within ± 1 cells of the actual number present in a cluster. The total number of cells counted by the expert was 393 compared to 386 by the algorithm, giving an error rate of 1.7%. To estimate homing of stem cells to damaged tissues, quantification of stem cells in infracted mice hearts was compared to non-infarcted control mice hearts. The number of MSC’s detected in the heart was significantly higher for infarcted mice. The delivery ratio for infarcted mice was 8.0 ± 0.8 times larger than the delivery ratio for a control mouse on Day 4. This suggests that stem cells were homing to the damaged myocardium.

Published
2010

15. Imaging of Cardiovascular Cellular Therapeutics with a Cryo-imaging System

Author

Steyer, Grant

Subjects
Biomedical Research, cryo-imaging, cell quantification, episcopic imaging, block face imaging, subsurface fluorescence, model based processing, stem cell imaging
Abstract

The long term goal of this research is to use cryo-imaging to detect and spatially map nearly every stem cell in a mouse and quantify tissue specific, cell therapy PK. With this enabling technology, one will be able to quantitatively assess specificity of homing, quiescent survival in specific niches, emerging homing factors, delivery processes, cell engraftment dose response, etc., analyses which have, at best, been done qualitatively. To this end, we developed a cryo-imaging system, which alternates between sectioning (10-40 µm) and imaging bright field and fluorescence block-face image volumes with micron-scale-resolution. For applications requiring single-cell detection of fluorescently labeled cells anywhere in a mouse, we developed an algorithm, next-image processing, for reduction of subsurface fluorescence. Next-image processing greatly improves axial-resolution, enabling high quality 3D volume renderings, and improved automated enumeration of single cells by up to 24%. To answer many of the pressing questions in stem cell therapies, automated methods for quantification and detection of stem cells are required. We developed algorithms for the automated detection and quantification of fluorescently labeled cells. Our model based quantification algorithm was performed on low resolution images of fluorescently labeled stem cells and the results were compared to visual quantification of stem cells in high resolution images. In all cases but two, the algorithm was within ± 1 cells of the actual number present in a cluster. The total number of cells counted by the expert was 393 compared to 386 by the algorithm, giving an error rate of 1.7%. To estimate homing of stem cells to damaged tissues, quantification of stem cells in infracted mice hearts was compared to non-infarcted control mice hearts. The number of MSC’s detected in the heart was significantly higher for infarcted mice. The delivery ratio for infarcted mice was 8.0 ± 0.8 times larger than the delivery ratio for a control mouse on Day 4. This suggests that stem cells were homing to the damaged myocardium.

Published
2010

16. 3D cryo-imaging: a very high-resolution view of the whole mouse.

Author

Roy D, Steyer GJ, Gargesha M, Stone ME, and Wilson DL

Subjects
Actins genetics, Animals, Automation, Fluorescence, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Mice, Mice, Inbred C57BL, Mice, Transgenic, Muscle, Smooth, Promoter Regions, Genetic, Diagnostic Imaging, Image Processing, Computer-Assisted, Imaging, Three-Dimensional methods, Whole Body Imaging
Abstract

We developed the Case Cryo-imaging system that provides information rich, very high-resolution, color brightfield, and molecular fluorescence images of a whole mouse using a section-and-image block-face imaging technology. The system consists of a mouse-sized, motorized cryo-microtome with special features for imaging, a modified, brightfield/fluorescence microscope, and a robotic xyz imaging system positioner, all of which is fully automated by a control system. Using the robotic system, we acquired microscopic tiled images at a pixel size of 15.6 microm over the block face of a whole mouse sectioned at 40 microm, with a total data volume of 55 GB. Viewing 2D images at multiple resolutions, we identified small structures such as cardiac vessels, muscle layers, villi of the small intestine, the optic nerve, and layers of the eye. Cryo-imaging was also suitable for imaging embryo mutants in 3D. A mouse, in which enhanced green fluorescent protein was expressed under gamma actin promoter in smooth muscle cells, gave clear 3D views of smooth muscle in the urogenital and gastrointestinal tracts. With cryo-imaging, we could obtain 3D vasculature down to 10 microm, over very large regions of mouse brain. Software is fully automated with fully programmable imaging/sectioning protocols, email notifications, and automatic volume visualization. With a unique combination of field-of-view, depth of field, contrast, and resolution, the Case Cryo-imaging system fills the gap between whole animal in vivo imaging and histology., ((c) 2009 Wiley-Liss, Inc.)

Published
2009
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17. Cryo-Imaging of Fluorescently-Labeled Single Cells in a Mouse.

Author

Steyer GJ, Roy D, Salvado O, Stone ME, and Wilson DL

Abstract

We developed a cryo-imaging system to provide single-cell detection of fluorescently labeled cells in mouse, with particular applicability to stem cells and metastatic cancer. The Case cryo-imaging system consists of a fluorescence microscope, robotic imaging positioner, customized cryostat, PC-based control system, and visualization/analysis software. The system alternates between sectioning (10-40 μm) and imaging, collecting color brightfield and fluorescent block-face image volumes >60GB. In mouse experiments, we imaged quantum-dot labeled stem cells, GFP-labeled cancer and stem cells, and cell-size fluorescent microspheres. To remove subsurface fluorescence, we used a simplified model of light-tissue interaction whereby the next image was scaled, blurred, and subtracted from the current image. We estimated scaling and blurring parameters by minimizing entropy of subtracted images. Tissue specific attenuation parameters were found [u(T) : heart (267 ± 47.6 μm), liver (218 ± 27.1 μm), brain (161 ± 27.4 μm)] to be within the range of estimates in the literature. "Next image" processing removed subsurface fluorescence equally well across multiple tissues (brain, kidney, liver, adipose tissue, etc.), and analysis of 200 microsphere images in the brain gave 97±2% reduction of subsurface fluorescence. Fluorescent signals were determined to arise from single cells based upon geometric and integrated intensity measurements. Next image processing greatly improved axial resolution, enabled high quality 3D volume renderings, and improved enumeration of single cells with connected component analysis by up to 24%. Analysis of image volumes identified metastatic cancer sites, found homing of stem cells to injury sites, and showed microsphere distribution correlated with blood flow patterns.We developed and evaluated cryo-imaging to provide single-cell detection of fluorescently labeled cells in mouse. Our cryo-imaging system provides extreme (>60GB), micron-scale, fluorescence, and bright field image data. Here we describe our image pre-processing, analysis, and visualization techniques. Processing improves axial resolution, reduces subsurface fluorescence by 97%, and enables single cell detection and counting. High quality 3D volume renderings enable us to evaluate cell distribution patterns. Applications include the myriad of biomedical experiments using fluorescent reporter gene and exogenous fluorophore labeling of cells in applications such as stem cell regenerative medicine, cancer, tissue engineering, etc.

Published
2009
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18. Whole Mouse Cryo-Imaging.

Author

Wilson D, Roy D, Steyer G, Gargesha M, Stone M, and McKinley E

Abstract

The Case cryo-imaging system is a section and image system which allows one to acquire micron-scale, information rich, whole mouse color bright field and molecular fluorescence images of an entire mouse. Cryo-imaging is used in a variety of applications, including mouse and embryo anatomical phenotyping, drug delivery, imaging agents, metastastic cancer, stem cells, and very high resolution vascular imaging, among many. Cryo-imaging fills the gap between whole animal in vivo imaging and histology, allowing one to image a mouse along the continuum from the mouse → organ → tissue structure → cell → sub-cellular domains. In this overview, we describe the technology and a variety of exciting applications. Enhancements to the system now enable tiled acquisition of high resolution images to cover an entire mouse. High resolution fluorescence imaging, aided by a novel subtraction processing algorithm to remove sub-surface fluorescence, makes it possible to detect fluorescently-labeled single cells. Multi-modality experiments in Magnetic Resonance Imaging and Cryo-imaging of a whole mouse demonstrate superior resolution of cryo-images and efficiency of registration techniques. The 3D results demonstrate the novel true-color volume visualization tools we have developed and the inherent advantage of cryo-imaging in providing unlimited depth of field and spatial resolution. The recent results continue to demonstrate the value cryo-imaging provides in the field of small animal imaging research.

Published
2008
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