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Books on the topic 'T1-weighted magnetic resonance imaging'

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Author: Grafiati

Published: 10 December 2022

Last updated: 29 January 2023

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1

Glockner, James F., Kazuhiro Kitajima, and Akira Kawashima. Magnetic resonance imaging. Edited by Christopher G. Winearls. Oxford University Press, 2018. http://dx.doi.org/10.1093/med/9780199592548.003.0015_update_001.

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Magnetic resonance imaging (MRI) provides excellent anatomic detail and soft tissue contrast for the evaluation of patients with renal disease. MRI needs longer scan time than computed tomography (CT); however, no radiation is involved. Gadolinium-based contrast agents (GBCAs) are used to help provide additional image contrast during MRI. MRI is indicated for characterization of renal mass, staging of malignant renal neoplasms, and determination of vena cava involvement by the renal tumour. Magnetic resonance (MR) angiography is widely accepted as a non-invasive imaging work-up of renal artery stenosis. MR urography is an alternative to CT urography to assess the upper urinary tract but does not identify urinary calculi. Diffusion-weighted imaging is a functional MR technique being used to characterize parenchymal renal disease and renal tumours. Nephrogenic systemic fibrosis is a rare but debilitating and potentially life-threatening condition which has been linked to exposure of GBCAs in patients with severe renal insufficiency. The risk versus benefit must be assessed before proceeding.

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2

Taouli, Bachir. Extra-Cranial Applications of Diffusion-Weighted MRI. Cambridge University Press, 2010.

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3

Taouli, Bachir. Extra-Cranial Applications of Diffusion-Weighted Mri. Cambridge University Press, 2010.

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4

Taouli, Bachir. Extra-Cranial Applications of Diffusion-Weighted MRI. Cambridge University Press, 2010.

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5

Extra-Cranial Applications of Diffusion-Weighted MRI. Cambridge: Cambridge University Press, 2010.

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6

Moritani, Toshio, Sven Ekholm, and Per-Lennart A. Westesson. Diffusion-Weighted MR Imaging of the Brain. Springer London, Limited, 2009.

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7

Diffusion-Weighted MR Imaging of the Brain. Springer, 2004.

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8

Thoeny, Harriet C., and Dow-Mu Koh. Diffusion-Weighted MR Imaging: Applications in the Body. Springer, 2012.

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9

Diffusion-Weighted MR Imaging: Applications in the Body (Medical Radiology). Springer, 2010.

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10

Das, Raj, Susan Heenan, and Uday Patel. Magnetic resonance imaging in urology. Edited by Michael Weston. Oxford University Press, 2017. http://dx.doi.org/10.1093/med/9780199659579.003.0134.

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Magnetic resonance imaging is essential for urological imaging. It offers excellent soft tissue contrast and resolution, allowing manipulation of tissue contrast with different image weighting and sequences. The multiplanar aspect of MRI allows image acquisition in different planes and degrees of obliquity to best exhibit pathology. The basic physics of MRI is explored initially with explanation of image weighting, sequences, and diffusion-weighted imaging. The chapter is then divided into renal, bladder, and prostate MRI imaging. The paragraphs on renal MRI outline renal mass analysis and include characterization and assessment of cystic and fat-containing lesions. Staging of renal carcinoma with MRI is also discussed, along with its advantages compared with CT staging. Throughout the text, the key diagnostic MRI features with each disease and organ, and the pitfalls and caveats of MRI imaging are emphasized.

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11

MRI Susceptibility Weighted Imaging: Basic Concepts and Clinical Applications. Wiley, 2007.

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12

Moritani, Toshio, Sven Ekholm, and Per-Lennart A. Westesson. Diffusion-Weighted MR Imaging of the Brain. Springer, 2010.

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13

Diffusion-Weighted MR Imaging of the Brain. Springer, 2009.

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14

Castillo, Mauricio, and Claudia da Costa Leite. Diffusion Weighted and Diffusion Tensor Imaging: A Clinical Guide. Thieme Medical Publishers, Incorporated, 2016.

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15

Özarslan, Evren. Developments in diffusion weighted Magnetic Resonance Imaging (MRI) with applications to neural tissue. 2004.

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16

Ferrari, Victor. The EACVI Textbook of Cardiovascular Magnetic Resonance. Edited by Massimo Lombardi, Sven Plein, Steffen Petersen, Chiara Bucciarelli-Ducci, Emanuela Valsangiacomo Buechel, and Cristina Basso. Oxford University Press, 2018. http://dx.doi.org/10.1093/med/9780198779735.001.0001.

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Cardiovascular magnetic resonance imaging (CMR) has become one of the great pillars of cardiac imaging. Modern CMR, as we now practise it, is the result of an enormous method and application development effort that has occurred over the past 25 years and has taken CMR from its humble beginnings of anatomical T₁- and T₂-weighted imaging to the extremely versatile, accurate, and robust technique it is now. The main developments over this time, building on the anatomical imaging, were the establishment of cine imaging for assessment of cardiac function, first-pass perfusion imaging for measurement of perfusion reserve, as well as myocardial blood flow (in millilitres per minute and gram), late gadolinium enhancement for imaging of scar and patchy fibrosis, and two-dimensional flow velocity imaging for assessment of valve and shunt lesions. This textbook intends to explore and evaluate all areas of this fascinating subject.

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17

Gardner, Andrew, Grant L. Iverson, Paul van Donkelaar, Philip N. Ainslie, and Peter Stanwell. Magnetic Resonance Spectroscopy, Diffusion Tensor Imaging, and Transcranial Doppler Ultrasound Following Sport-Related Concussion. Edited by Ruben Echemendia and Grant L. Iverson. Oxford University Press, 2015. http://dx.doi.org/10.1093/oxfordhb/9780199896585.013.12.

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Sport-related concussion has been referred to as a functional rather than a structural injury with neurometabolic and microstructural alterations reported in several studies. Accordingly, conventional neuroimaging techniques, such as computed tomography (CT) and structural magnetic resonance imaging (MRI), have limited value beyond ruling out structural injury such as a contusion or hemorrhage. This chapter presents a review of three neuroimaging techniques that offer insight into the connectivity and neurometabolic consequences of concussion. A number of studies have now been published using magnetic resonance spectroscopy (MRS), diffusion tensor imaging (DTI)/diffusion-weighted imaging, and transcranial Doppler ultrasound (TCD) with varying findings. The results of these studies will be presented, together with current and possible future application of these techniques within the field of sport-related concussion.

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18

Diaz, Roberto Jose, Gregory W. Basil, and Ricardo J. Komotar. Primary CNS Lymphoma. Oxford University Press, 2018. http://dx.doi.org/10.1093/med/9780190696696.003.0008.

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Central nervous system (CNS) lymphoma must be considered in the differential diagnosis of any immunocompromised patient with a solid brain lesion. In such patients, diagnosis can be made via a careful review of important signs, symptoms, and classic radiologic findings. While there is no single physical exam finding classic for lymphoma, the clinician must carefully evaluate patients for the presence or absence of findings that may suggest an alternative diagnosis. Such findings include the stigmata of endocarditis, symptoms suggestive of pneumonia, or additional non-CNS mass lesions. Additionally, several imaging modalities including magnetic resonance imaging, diffusion-weighted magnetic resonance imaging, susceptibility weighted imaging, and dynamic contrast-enhanced imaging can be useful in identifying this condition. While steroids can be helpful in reducing the disease burden and decreasing edema, they may also hinder diagnosis. Surgery may be indicated for either diagnostic or decompressive purposes; however, the mainstay of treatment is chemotherapeutic and immunotherapeutic agents with radiation reserved for refractory cases.

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19

Chappell, Michael, Bradley MacIntosh, and Thomas Okell. Introduction to Perfusion Quantification using Arterial Spin Labelling. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198793816.001.0001.

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Arterial spin labeling (ASL) magnetic resonance imaging (MRI) is unique in being a completely non-invasive method for imaging perfusion in the brain. Relying upon a blood-borne tracer that is created by the MRI scanner itself, ASL is becoming a popular tool to study cerebral perfusion, as well as how this perfusion changes in response to neuronal activity or in disease. This primer provides an introduction to perfusion quantification using ASL MRI, focusing both on the methods needed to extract perfusion-weighted images and on how to quantify perfusion and other hemodynamic parameters. Starting with the simplest implementation of ASL, the primer details all the common acquisition methods, as well as the subsequent analysis steps required to quantify perfusion in an individual, detect changes in perfusion in response to neural activity or pharmacological intervention, and examine perfusion variations across groups of individuals. This is supported with examples from real data illustrating all the major steps in the analysis process, linked to online material where the reader can undertake the same analysis for themselves.

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