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14 - MR perfusion imaging in the body: kidney, liver, and lung

from Section 2 - Clinical applications

Published online by Cambridge University Press:  05 May 2013

By
Pottumarthi V. Prasad  and
Robert R. Edelman
Edited by
Peter B. Barker ,
Xavier Golay  and
Gregory Zaharchuk
Peter B. Barker
Affiliation:
The Johns Hopkins University School of Medicine
Xavier Golay
Affiliation:
National Hospital for Neurology and Neurosurgery, London
Gregory Zaharchuk
Affiliation:
Stanford University Medical Center
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Summary

Introduction

This chapter will discuss body perfusion MRI applications, specifically related to three organs: kidneys, liver, and lungs. Each section begins with a short description of the scientific and/or clinical rationale for perfusion imaging and then describes what is known to date regarding the feasibility and/or status of performing these measurements, along with their potential significance. Unlike neurological and oncological applications described in Chapters 8–13, perfusion MRI in the body is still evolving, and so no specific, standardized methods of data acquisition and analysis have yet emerged. However, a brief description of all methods available to date and relevant references are provided. The perfusion MRI techniques discussed fall under two primary categories, either those based on exogenous contrast agent administration, or those based on endogenous contrast mechanisms.

Kidney

Scientific/clinical rationale

In 1938, Goldblatt [1, 2] demonstrated a relationship between hypertension and renal ischemia. He was able to consistently produce elevations in systolic blood pressure by producing renal ischemia with a constricting clamp in an animal model. Removal of the clamp restored blood pressure to the reference range. Based on this finding, Burkland et al. performed nephrectomy of a unilateral ischemic kidney as a cure for hypertension [3]. This remained the method of surgical treatment until 1960 when Lambeth et al. reported resolving hypertension by correction of renal artery stenosis (RAS) [4]. In the 1960s, the delineation of the renin–angiotensin system and its relation to hypertension [5] also had a large impact on the medical therapy and diagnostic studies used in renovascular hypertension.

Type
Chapter
Information
Clinical Perfusion MRI
Techniques and Applications
 , pp. 281 - 301
Publisher: Cambridge University Press
Print publication year: 2013

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