OBJECTIVE: Diffusion-weighted MRI is increasingly applied in the body. It has been recognized for some time, on the basis of scientific experiments and studies in the brain, that the calculation of apparent diffusion coefficient by simple monoexponential relationship between MRI signal and b value does not fully account for tissue behavior. However, appreciation of this fact in body diffusion MRI is relatively new, because technologic advancements have only recently enabled high-quality body diffusion-weighted images to be acquired using multiple b values. There is now increasing interest in the radiologic community to apply more sophisticated analytic approaches, such as those based on the principles of intravoxel incoherent motion, which allows quantitative parameters that reflect tissue microcapillary perfusion and tissue diffusivity to be derived. CONCLUSION: In this review, we discuss the principles of intravoxel incoherent motion as applied to body diffusion-weighted MRI. The evidence for the technique in measuring tissue perfusion is presented and the emerging clinical utility surveyed. The requisites and challenges of quantitative evaluation beyond simple monoexponential relationships are highlighted.
OBJECTIVE: Diffusion-weighted MRI is increasingly applied in the body. It has been recognized for some time, on the basis of scientific experiments and studies in the brain, that the calculation of apparent diffusion coefficient by simple monoexponential relationship between MRI signal and b value does not fully account for tissue behavior. However, appreciation of this fact in body diffusion MRI is relatively new, because technologic advancements have only recently enabled high-quality body diffusion-weighted images to be acquired using multiple b values. There is now increasing interest in the radiologic community to apply more sophisticated analytic approaches, such as those based on the principles of intravoxel incoherent motion, which allows quantitative parameters that reflect tissue microcapillary perfusion and tissue diffusivity to be derived. CONCLUSION: In this review, we discuss the principles of intravoxel incoherent motion as applied to body diffusion-weighted MRI. The evidence for the technique in measuring tissue perfusion is presented and the emerging clinical utility surveyed. The requisites and challenges of quantitative evaluation beyond simple monoexponential relationships are highlighted.
Authors: Moti Freiman; Stephan D Voss; Robert V Mulkern; Jeannette M Perez-Rossello; Michael J Callahan; Simon K Warfield Journal: Med Phys Date: 2012-08 Impact factor: 4.071
Authors: Behzad Ebrahimi; Ahmed Saad; Kai Jiang; Christopher M Ferguson; Hui Tang; John R Woollard; James F Glockner; Stephen C Textor; Lilach O Lerman Journal: Invest Radiol Date: 2017-11 Impact factor: 6.016
Authors: Hadrien A Dyvorne; Nicola Galea; Thomas Nevers; M Isabel Fiel; David Carpenter; Edmund Wong; Matthew Orton; Andre de Oliveira; Thorsten Feiweier; Marie-Louise Vachon; James S Babb; Bachir Taouli Journal: Radiology Date: 2012-12-06 Impact factor: 11.105