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Книги з теми "Quantitative imaging analysis"

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Автор: Grafiati
Опубліковано: 10 грудня 2022
Оновлено: 28 січня 2023

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1

Zaidi, Habib, ed. Quantitative Analysis in Nuclear Medicine Imaging. Boston, MA: Springer US, 2006. http://dx.doi.org/10.1007/b107410.

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2

Brandt, Roland, and Lidia Bakota. Laser scanning microscopy and quantitative image analysis of neuronal tissue. New York: Humana Press, 2014.

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3

Rozenblat, Céline. Methods for Multilevel Analysis and Visualisation of Geographical Networks. Dordrecht: Springer Netherlands, 2013.

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4

Miller, James G. Physical interpretation and development of ultrasonic nondestructive evaluation techniques applied to the quantitative characterization of textile composite materials: Semiannual progress report, September 15, 1994 - March 14, 1995. St. Louis, Mo. : Washington University, Dept. of Physics, Laboratory for Ultrasonics: National Aeronautics and Space Administration, 1995.

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5

Miller, James G. Physical interpretation and development of ultrasonic nondestructive evaluation techniques applied to the quantitative characterization of textile composite materials: Semiannual progress report : March 15, 1992-September 14, 1992. St. Louis, Mo: Washington University, Dept. of Physics, Laboratory for Ultrasonics, 1992.

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6

Xavier, Ronot, and Usson Yves, eds. Imaging of nucleic acids and quantitation in photonic microscopy. Boca Raton, FL: CRC Press, 2001.

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7

Dolgov, I., Mihail Volovik, and Andrey Mahnovskiy. Thermographic signs of certain diseases of the respiratory system (acute sinusitis, pneumonia) Thermography Atlas. ru: INFRA-M Academic Publishing LLC., 2021. http://dx.doi.org/10.12737/textbook_61b1ab7de6b1f9.69203696.

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The present issue focuses on the practice of medical thermal imaging in patients with paranasal sinusitis and pneumonia. The description of thermograms is based on a quantitative analysis of temperature gradients and trends in temperature of different body regions (Projection «head front» for paranasal sinusitis, «breast front» and «back», in a defined layout formed in «cloud» thermograms analysis program "Tvision" of «Dignosis», Russia) with values of thermographic markers that demonstrated their differentiating capabilities when compared with reference methods. Thus, the thermographic conclusion is formed not simply by thermal phenomenon «hot-cold», but on the basis of numerical values of markers, which indicate hypothetical nosological diagnosis and significantly simplifies the algorithm for those physicians who use this method as an additional. The publication is intended for doctors of any speciality who, in their daily clinical practice, treat the patients with suspicions disease of respiratory system
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8

Zaidi, Habib. Quantitative Analysis in Nuclear Medicine Imaging. Springer, 2005.

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9

Zaidi, Habib. Quantitative Analysis in Nuclear Medicine Imaging. Springer, 2010.

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10

Zaidi, Habib. Quantitative Analysis in Nuclear Medicine Imaging. Springer, 2006.

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11

Quantitative und strukturelle Bildanalyse in der Medizin: Quantitative and structural image analysis in medicine. Darmstadt: GIT Verlag, 1987.

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12

Coherent Light Microscopy Imaging And Quantitative Phase Analysis. Springer, 2011.

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13

Ferraro, Pietro, Zeev Zalevsky, and Adam Wax. Coherent Light Microscopy: Imaging and Quantitative Phase Analysis. Springer, 2013.

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14

Ferraro, Pietro, Zeev Zalevsky, and Adam Wax. Coherent Light Microscopy: Imaging and Quantitative Phase Analysis. Springer, 2011.

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15

(Editor), H. A. Schmidt, and J. Chambron (Editor), eds. Nuclear Medicine: Quantitative Analysis in Imaging and Function. John Wiley & Sons, 1990.

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16

Ferraro, Pietro, Zeev Zalevsky, and Adam Wax. Coherent Light Microscopy: Imaging and Quantitative Phase Analysis. Springer, 2011.

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17

Habib, Zaidi, ed. Quantitative analysis of nuclear medicine images. New York: Springer, 2005.

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18

1949-, Frost J. James, and Wagner Henry N. 1927-, eds. Quantitative imaging: Neuroreceptors, neurotransmitters, and enzymes. New York: Raven Press, 1990.

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19

Quantitative Imaging: Neuroreceptors Neurotransmitters and Enzymes. Raven Pr, 1990.

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20

Quantitative analysis in nuclear medicine images. New York: Springer, 2006.

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21

Brandt, Roland, and Lidia Bakota. Laser Scanning Microscopy and Quantitative Image Analysis of Neuronal Tissue. Humana Press, 2016.

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22

Hillmer, Ansel T., Kelly P. Cosgrove, and Richard E. Carson. PET Brain Imaging Methodologies. Edited by Dennis S. Charney, Eric J. Nestler, Pamela Sklar, and Joseph D. Buxbaum. Oxford University Press, 2017. http://dx.doi.org/10.1093/med/9780190681425.003.0009.

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While quantitative and pharmacologically specific aspects distinguish molecular imaging, they also impose the need for considerable expertise to design, conduct, and analyze molecular imaging studies. Positron emission tomography (PET) brain imaging provides a powerful noninvasive tool for quantitative and pharmacologically specific clinical research. This chapter describes basic methodological considerations for PET brain imaging studies. First the physiological interpretation of the most common outcome measures of binding potential (BPND) and volume of distribution (VT) are described. Next, aspects of acquisition of PET imaging data and blood measurements for analysis are discussed, followed by a summary of standard data analysis techniques. Finally, various applications for the study of mental illness, including group differences, measurements of drug occupancy, and assay of acute neurotransmitter release are discussed.
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23

Callen, David James Anthony. Quantitative analysis of changes in limbic structures in probable Alzheimer's disease using coregistered spect and magnetic resonance imaging. 2000.

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24

Rozenblat, Céline, and Guy Melançon. Methods for Multilevel Analysis and Visualisation of Geographical Networks. Springer, 2013.

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25

Rozenblat, Céline, and Guy Melaçon. Methods for Multilevel Analysis and Visualisation of Geographical Networks. Springer, 2013.

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26

Rozenblat, Céline, and Guy Melancon. Methods for Multilevel Analysis and Visualisation of Geographical Networks. Ingramcontent, 2014.

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27

United States. National Aeronautics and Space Administration., ed. Physical interpretation and development of ultrasonic nondestructive evaluation techniques applied to the quantitative characterization of textile composite materials: Semiannual progress reprt, March 15, 1993 - September 14, 1993. St. Louis, Mo. : Washington University , Dept. of Physics, Laboratory for Ultrasonics: National Aeronautics and Space Administration, 1993.

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28

United States. National Aeronautics and Space Administration., ed. Physical interpretation and development of ultrasonic nondestructive evaluation techniques applied to the quantitative characterization of textile composite materials: Semiannual progress reprt, March 15, 1993 - September 14, 1993. St. Louis, Mo. : Washington University , Dept. of Physics, Laboratory for Ultrasonics: National Aeronautics and Space Administration, 1993.

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29

United States. National Aeronautics and Space Administration., ed. Physical interpretation and development of ultrasonic nondestructive evaluation techniques applied to the quantitative characterization of textile composite materials: Semiannual progress report : March 15, 1992-September 14, 1992. St. Louis, Mo: Washington University, Dept. of Physics, Laboratory for Ultrasonics, 1992.

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30

United States. National Aeronautics and Space Administration., ed. Physical interpretation and development of ultrasonic nondestructive evaluation techniques applied to the quantitative characterization of textile composite materials: Semiannual progress report, September 15, 1994 - March 14, 1995. St. Louis, Mo. : Washington University, Dept. of Physics, Laboratory for Ultrasonics: National Aeronautics and Space Administration, 1995.

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31

Sicari, Rosa, Edyta Płońska-Gościniak, and Jorge Lowenstein. Stress echocardiography: image acquisition and modalities. Oxford University Press, 2016. http://dx.doi.org/10.1093/med/9780198726012.003.0013.

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Stress echocardiography has evolved over the last 30 years but image interpretation remains subjective and burdened by the operator’s experience. The objective operator-independent assessment of myocardial ischaemia during stress echocardiography remains a technological challenge. Still, adequate quality of two-dimensional images remains a prerequisite to successful quantitative analysis, even using Doppler and non-Doppler based techniques. No new technology has proved to have a higher diagnostic accuracy than conventional visual wall motion analysis. Tissue Doppler imaging and derivatives may reduce inter-observer variability, but still require a dedicated learning curve and special expertise. The development of contrast media in echocardiography has been slow. In the past decade, transpulmonary contrast agents have become commercially available for clinical use. The approved indication for the use of contrast echocardiography currently lies in improving endocardial border delineation in patients in whom adequate imaging is difficult or suboptimal. Real-time three-dimensional echocardiography is potentially useful but limited by low spatial and temporal resolution. It is possible that these technologies may serve as an adjunct to expert visual assessment of wall motion. At present, these quantitative methods require further validation and simplification of analysis techniques.
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32

Hunter, David J., Frank W. Roemer, and Ed Riordan. Imaging: magnetic resonance imaging. Oxford University Press, 2016. http://dx.doi.org/10.1093/med/9780199668847.003.0018.

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Magnetic resonance imaging (MRI) overcomes many of the limitations associated with conventional radiography, the technique historically regarded as the gold standard in imaging of osteoarthritis (OA). MRI allows visualization of changes and pathologies in joint tissues including cartilage and the menisci, the two tissue components responsible for the indirect radiographic marker of joint space narrowing, decreasing the length of time that must elapse before disease progression can be detected. Other elements of the joint can also be analysed simultaneously: a key development in the understanding of OA. This chapter focuses on the utility of MRI in observational studies and clinical trials, detailing the available MRI techniques and quantitative/qualitative measurements, and their correlation with tissue damage. The possible future directions of MRI in OA are also discussed, with a view to its potential utility in identifying disease-modifying interventions.
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33

(Editor), Xavier Ronot, and Yves Usson (Editor), eds. Imaging of Nucleic Acids and Quantitation in Photonic Microscopy. CRC, 2001.

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34

Ronot, Xavier, and Yves Usson. Imaging of Nucleic Acids and Quantitation in Photonic Microscopy. Taylor & Francis Group, 2001.

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35

Chen, C. Julian. Introduction to Scanning Tunneling Microscopy. 3rd ed. Oxford University Press, 2021. http://dx.doi.org/10.1093/oso/9780198856559.001.0001.

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The scanning tunnelling microscope (STM) was invented by Binnig and Rohrer and received a Nobel Prize of Physics in 1986. Together with the atomic force microscope (AFM), it enables non-destructive observing and mapping atoms and molecules on solid surfaces down to a picometer resolution. A recent development is the non-destructive observation of wavefunctions in individual atoms and molecules, including nodal structures inside the wavefunctions. STM and AFM have become indespensible instruments for scientists of various disciplines, including physicists, chemists, engineers, and biologists to visualize and utilize the microscopic world around us. Since the publication of the first edition in 1993, this book has been recognized as a standard introduction for everyone that starts working with scanning probe microscopes, and a useful reference book for those more advanced in the field. After an Overview chapter accessible for newcomers at an entry level presenting the basic design, scientific background, and illustrative applications, the book has three Parts. Part I, Principles, provides the most systematic and detailed theory of its scientific bases from basic quantum mechancis and condensed-metter physics in all available literature. Quantitative analysis of its imaging mechanism for atoms, molecules, and wavefunctions is detailed. Part II, Instrumentation, provides down to earth descriptions of its building components, including piezoelectric scanners, vibration isolation, electronics, software, probe tip preparation, etc. Part III, Related methods, presenting two of its most important siblings, scanning tunnelling specgroscopy and atomic force miscsoscopy. The book has five appendices for background topics, and 405 references for further readings.
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36

Delgado Martín, Jordi, Andrea Muñoz-Ibáñez, and Ismael Himar Falcón-Suárez. 6th International Workshop on Rock Physics: A Coruña, Spain 13 -17 June 2022: Book of Abstracts. 2022nd ed. Servizo de Publicacións da UDC, 2022. http://dx.doi.org/10.17979/spudc.000005.

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[Abstract] The 6th International Workshop on Rock Physics (6IWRP) was held A Coruña, Spain, between 13th and 17th of June, 2022. This meeting follows the track of the five successful encounters held in Golden (USA, 2011), Southampton (UK, 2013), Perth (Australia, 2015), Trondheim (Norway, 2017) and Hong Kong (China, 2019). The aim of the workshop was to bring together experiences allowing to illustrate, discuss and exchange recent advances in the wide realm of rock physics, including theoretical developments, in situ and laboratory scale experiments as well as digital analysis. While rock physics is at the core of the oil & gas industry applications, it is also essential to enable the energy transition challenge (e.g. CO2 and H2 storage, geothermal), ensure a safe and adequate use of natural resources and develop efficient waste management strategies. The topics of 6IWRP covered a broad spectrum of rock physics-related research activities, including: • Experimental rock physics. New techniques, approaches and applications; Characterization of the static and dynamic properties of rocks and fluids; Multiphysics measurements (NMR, electrical resistivity…); Deep/crustal scale rock physics. • Modelling and multiscale applications: from the lab to the field. Numerical analysis and model development; Data science applications; Upscaling; Microseismicity and earthquakes; Subsurface stresses and tectonic deformations. • Coupled phenomena and rock properties: exploring interactions. Anisotropy; Flow and fractures; Temperature effects; Rock-fluid interaction; Fluid and pressure effects on geophysical signatures. • The energy transition challenge. Applications to energy storage (hydrogen storage in porous media), geothermal resources, energy production (gas hydrates), geological utilization and storage of CO2, nuclear waste disposal. • Rock physics templates: advances and applications. Quantitative assessment; Applications to reser voir characterization (role of seismic wave anisotropy and fracture networks). • Advanced rock physics tools. Machine learning; application of imaging (X-ray CT, X-ray μCT, FIB-SEM…) to obtain rock proper ties. This book compiles more than 50 abstracts, summarizing the works presented in the 6IWRP by rock physicists from all over the world, belonging to both academia and industry. This book means an updated overview of the rock physics research worldwide.
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37

Stålberg, Erik. Electromyography. Oxford University Press, 2016. http://dx.doi.org/10.1093/med/9780199688395.003.0007.

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Electromyography (EMG) has been used since the 1940s in the diagnosis of neuromuscular disorders. It has particularly developed with the advent of computers and recording equipment with integrated software. This has made methods of analysis fast, robust, and precise, helping to deal with increasing numbers of patients. Indications have changed dynamically over the years, with the development of new EMG methods themselves and complementary methods used in this field for diagnosis such as histochemistry, genetics, and imaging techniques. This chapter focuses mainly on the routine methods based on recordings with concentric or monopolar needle electrodes, but will also briefly review some of the other EMG methods. There is an increasing understanding of the relationship between the generators (muscle fibres) and the recorded signal that helps interpretation of the recordings. The parameters used for quantitation of the EMG signal are discussed. The findings in pathological conditions are discussed and some practical hints on EMG studies given.
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