Electron Probe Microanalysis [electronic resource] : Applications in Biology and Medicine /

Electron Probe Microanalysis [electronic resource] : Applications in Biology and Medicine /

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The aim of electron probe microanalysis of biological systems is to identify, localize, and quantify elements, mass, and water in cells and tissues. The method is based on the idea that all electrons and photons emerging from an electron beam irradiated specimen contain information on its structure and composition. In particular, energy spectroscopy of X-rays and electrons after interaction of the electron beam with the specimen is used for this purpose. However, the application of this method in biology and medicine has to overcome three specific problems: 1. The principle constituent of most cell samples is water. Since liquid water is not compatible with vacuum conditions in the electron microscope, specimens have to be prepared without disturbing the other components, in parti­ cular diffusible ions (elements). 2. Electron probe microanaly­ sis provides physical data on either dry specimens or fully hydrated, frozen specimens. This data usually has to be con­ verted into quantitative data meaningful to the cell biologist or physiologist. 3. Cells and tissues are not static but dynamic systems. Thus, for example, microanalysis of physiolo­ gical processes requires sampling techniques which are adapted to address specific biological or medical questions. During recent years, remarkable progress has been made to overcome these problems. Cryopreparation, image analysis, and electron energy loss spectroscopy are key areas which have solved some problems and offer promise for future improvements.

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Bibliographic Details
Main Authors: Zierold, Karl. editor., Hagler, Herbert K. editor., SpringerLink (Online service)
Format: Texto biblioteca
Language:eng
Published: Berlin, Heidelberg : Springer Berlin Heidelberg, 1989
Subjects:Life sciences., Biochemistry., Cell biology., Biophysics., Biological physics., Biomedical engineering., Life Sciences., Biochemistry, general., Biophysics and Biological Physics., Cell Biology., Biomedical Engineering.,
Online Access:http://dx.doi.org/10.1007/978-3-642-74477-8
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id KOHA-OAI-TEST:205841
record_format koha
institution COLPOS
collection Koha
country México
countrycode MX
component Bibliográfico
access En linea
En linea
databasecode cat-colpos
tag biblioteca
region America del Norte
libraryname Departamento de documentación y biblioteca de COLPOS
language eng
topic Life sciences.
Biochemistry.
Cell biology.
Biophysics.
Biological physics.
Biomedical engineering.
Life Sciences.
Biochemistry, general.
Biophysics and Biological Physics.
Cell Biology.
Biomedical Engineering.
Life sciences.
Biochemistry.
Cell biology.
Biophysics.
Biological physics.
Biomedical engineering.
Life Sciences.
Biochemistry, general.
Biophysics and Biological Physics.
Cell Biology.
Biomedical Engineering.
spellingShingle Life sciences.
Biochemistry.
Cell biology.
Biophysics.
Biological physics.
Biomedical engineering.
Life Sciences.
Biochemistry, general.
Biophysics and Biological Physics.
Cell Biology.
Biomedical Engineering.
Life sciences.
Biochemistry.
Cell biology.
Biophysics.
Biological physics.
Biomedical engineering.
Life Sciences.
Biochemistry, general.
Biophysics and Biological Physics.
Cell Biology.
Biomedical Engineering.
Zierold, Karl. editor.
Hagler, Herbert K. editor.
SpringerLink (Online service)
Electron Probe Microanalysis [electronic resource] : Applications in Biology and Medicine /
description The aim of electron probe microanalysis of biological systems is to identify, localize, and quantify elements, mass, and water in cells and tissues. The method is based on the idea that all electrons and photons emerging from an electron beam irradiated specimen contain information on its structure and composition. In particular, energy spectroscopy of X-rays and electrons after interaction of the electron beam with the specimen is used for this purpose. However, the application of this method in biology and medicine has to overcome three specific problems: 1. The principle constituent of most cell samples is water. Since liquid water is not compatible with vacuum conditions in the electron microscope, specimens have to be prepared without disturbing the other components, in parti­ cular diffusible ions (elements). 2. Electron probe microanaly­ sis provides physical data on either dry specimens or fully hydrated, frozen specimens. This data usually has to be con­ verted into quantitative data meaningful to the cell biologist or physiologist. 3. Cells and tissues are not static but dynamic systems. Thus, for example, microanalysis of physiolo­ gical processes requires sampling techniques which are adapted to address specific biological or medical questions. During recent years, remarkable progress has been made to overcome these problems. Cryopreparation, image analysis, and electron energy loss spectroscopy are key areas which have solved some problems and offer promise for future improvements.
format Texto
topic_facet Life sciences.
Biochemistry.
Cell biology.
Biophysics.
Biological physics.
Biomedical engineering.
Life Sciences.
Biochemistry, general.
Biophysics and Biological Physics.
Cell Biology.
Biomedical Engineering.
author Zierold, Karl. editor.
Hagler, Herbert K. editor.
SpringerLink (Online service)
author_facet Zierold, Karl. editor.
Hagler, Herbert K. editor.
SpringerLink (Online service)
author_sort Zierold, Karl. editor.
title Electron Probe Microanalysis [electronic resource] : Applications in Biology and Medicine /
title_short Electron Probe Microanalysis [electronic resource] : Applications in Biology and Medicine /
title_full Electron Probe Microanalysis [electronic resource] : Applications in Biology and Medicine /
title_fullStr Electron Probe Microanalysis [electronic resource] : Applications in Biology and Medicine /
title_full_unstemmed Electron Probe Microanalysis [electronic resource] : Applications in Biology and Medicine /
title_sort electron probe microanalysis [electronic resource] : applications in biology and medicine /
publisher Berlin, Heidelberg : Springer Berlin Heidelberg,
publishDate 1989
url http://dx.doi.org/10.1007/978-3-642-74477-8
work_keys_str_mv AT zieroldkarleditor electronprobemicroanalysiselectronicresourceapplicationsinbiologyandmedicine
AT haglerherbertkeditor electronprobemicroanalysiselectronicresourceapplicationsinbiologyandmedicine
AT springerlinkonlineservice electronprobemicroanalysiselectronicresourceapplicationsinbiologyandmedicine
_version_ 1756268167104036864
spelling KOHA-OAI-TEST:2058412018-07-30T23:35:15ZElectron Probe Microanalysis [electronic resource] : Applications in Biology and Medicine / Zierold, Karl. editor. Hagler, Herbert K. editor. SpringerLink (Online service) textBerlin, Heidelberg : Springer Berlin Heidelberg,1989.engThe aim of electron probe microanalysis of biological systems is to identify, localize, and quantify elements, mass, and water in cells and tissues. The method is based on the idea that all electrons and photons emerging from an electron beam irradiated specimen contain information on its structure and composition. In particular, energy spectroscopy of X-rays and electrons after interaction of the electron beam with the specimen is used for this purpose. However, the application of this method in biology and medicine has to overcome three specific problems: 1. The principle constituent of most cell samples is water. Since liquid water is not compatible with vacuum conditions in the electron microscope, specimens have to be prepared without disturbing the other components, in parti­ cular diffusible ions (elements). 2. Electron probe microanaly­ sis provides physical data on either dry specimens or fully hydrated, frozen specimens. This data usually has to be con­ verted into quantitative data meaningful to the cell biologist or physiologist. 3. Cells and tissues are not static but dynamic systems. Thus, for example, microanalysis of physiolo­ gical processes requires sampling techniques which are adapted to address specific biological or medical questions. During recent years, remarkable progress has been made to overcome these problems. Cryopreparation, image analysis, and electron energy loss spectroscopy are key areas which have solved some problems and offer promise for future improvements.The history of electron probe microanalysis in biology -- 1. Specimen Preparation -- Specimen preparation and other limitations in quantitative electron probe X-ray microanalysis using ultrathin sections -- Freeze-substitution and low temperature embedding for analytical electron microscopy -- Ensuring the validity of results in biological X-ray microanalysis -- 2. Analytical Techniques -- a) X-ray microanalysis -- The subcellular accumulation of toxic heavy metals: Qualitative and quantitative X-ray microanalysis -- X-ray microanalysis of cryosections using image analysis -- Electron probe X-ray microanalysis in the silkmoth antenna — problems with quantification in ultrathin cryosections -- b) Electron energy loss spectroscopy -- Progress in electron energy loss spectroscopic imaging and analysing biological specimens with a field emission scanning transmission electron microscope -- Application of parallel-detection electron energy loss spectroscopy in biology -- Resin based standards for biological energy dispersive X-ray and electron energy loss microanalysis -- Imaging and microanalysis by electron spectroscopy -- 3. Biological Applications -- a) Intracellular element localization -- Application of X-ray microanalysis and electron energy loss spectroscopy to studies of secretory cell biology -- X-ray microanalysis of freshly isolated cells in suspension -- X-ray microanalysis and free calcium measurements in cultured neonatal rat ventricular myocytes -- b) Epithelial transport -- 1/um thick frozen hydrated/dried sections for analysing pericellular environment in transport epithelia; New results from old data -- Distribution of ions and water in epithelial cells and tissues -- Characterization of electrolyte transport mechanisms and compartments by the use of the markers Rb and Br -- Electron probe analysis of transport properties of cultured cells -- c) Dynamic processes -- Quantitative X-ray elemental mapping of dynamic physiologic events in skeletal muscle -- Single isolated cardiac myocytes frozen during voltage-camp pulses: A technique for correlating X-ray micro-analysis data on calcium distribution with calcium inward current in the same cell -- X-ray microanalysis of fast exocytotic processes -- 4. Medical Application -- Electron probe microanalysis in pathology -- Microprobe analysis in medicine — present practice and future trends.The aim of electron probe microanalysis of biological systems is to identify, localize, and quantify elements, mass, and water in cells and tissues. The method is based on the idea that all electrons and photons emerging from an electron beam irradiated specimen contain information on its structure and composition. In particular, energy spectroscopy of X-rays and electrons after interaction of the electron beam with the specimen is used for this purpose. However, the application of this method in biology and medicine has to overcome three specific problems: 1. The principle constituent of most cell samples is water. Since liquid water is not compatible with vacuum conditions in the electron microscope, specimens have to be prepared without disturbing the other components, in parti­ cular diffusible ions (elements). 2. Electron probe microanaly­ sis provides physical data on either dry specimens or fully hydrated, frozen specimens. This data usually has to be con­ verted into quantitative data meaningful to the cell biologist or physiologist. 3. Cells and tissues are not static but dynamic systems. Thus, for example, microanalysis of physiolo­ gical processes requires sampling techniques which are adapted to address specific biological or medical questions. During recent years, remarkable progress has been made to overcome these problems. Cryopreparation, image analysis, and electron energy loss spectroscopy are key areas which have solved some problems and offer promise for future improvements.Life sciences.Biochemistry.Cell biology.Biophysics.Biological physics.Biomedical engineering.Life Sciences.Biochemistry, general.Biophysics and Biological Physics.Cell Biology.Biomedical Engineering.Springer eBookshttp://dx.doi.org/10.1007/978-3-642-74477-8URN:ISBN:9783642744778

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