Magnetic resonance angiography (MRA) and Flow MRI
Objetivos de aprendizaje
After reading this chapter, you should be able:
- To describe the different flow phenomena in MRI
- Explain the principle of flow compensation gradients
- Present non-contrast magnetic resonance angiography methods (technique, results, advantages and disadvantages:
- Time-of-flight (TOF) MRA
- Phase contrast (PCA) MRA
- 3D MRA with ultrafast spin echo and ECG synchronization (FBI)
- Describe the Contrast-enhanced MRA technique, its constraints related to the injection of a contrast agent, and its advantages
Flow and MRI
Phenomena associated with flow in MRI
- The inflow effect: flow of nonsaturated blood into the explored zone (vascular hypersignal)
- The outflow effect: the excited blood flows out of the explored zone (loss of vascular signal)
- Dephasing of moving spins in a gradient
This last phenomenon, used in phase contrast MRA, produces artifacts in the other imaging methods. The artifacts caused by flows at constant velocity can be overcome by means of flow compensation gradients.
Time of Flight
- Saturation of stationary spins
- Maximization of inflow effect and minimization of outflow effect
- GE, TR and TE
- Orientation of slices perpendicular to flow
- Slow flow: 2D;
- Fast flow: 3D, MOTSA, TONE
- Magnetization transfer, Fat suppression, Saturation band
- Good visualization of fast flow, Less good for in-plane or turbulent slow flow
- Poor suppression of background signal if short T1 (fat, hematoma, thrombus)
- Velocity phase encoding gradient in 3 directions
- Subtraction from a non- encoding gradient acquisition
- Choice of encoding speed +++
- 2D: fast, encoding speed test
- 3D: reduction in the number of phase encoding steps to accelerate the sequence
- Data on flow velocity and direction
- Poor visualization of complex or turbulent flows
- Slow in 3D
- 3D half Fourier fast spin echo
- Prospective ECG synchronization
- STIR preparation
- Short TE, coronal plane, phase encoding in the direction of the vessels
- Calibration of time interval between R wave and acquisition ++
- Double acquisition to subtract the venous signal
- Possible for thorax/abdomen
- Loss of signal for fast flows (alternative: diastolic acquisition)
- Fast 3D GE, short TR and TE, T1 weighted with destruction of residual magnetization
- Gadolinium bolus injection
- Filling of center of k-space when vasculair contrast is at it's peak +++: bolus test, real-time tracking, 4D angioMR
- Fat suppression
- Increase of vascular signal. Exploration of large volumes, Turbulent flow imaging
- Risks and drawbacks of injection
- Ozsarlak, Van Goethem. MR angiography of the intracranial vessels: technical aspects and clinical applications. Neuroradiology. 2004 Dec;46(12):955-72.
- Miyazaki, Sugiura. Non-contrast-enhanced MR angiography using 3D ECG-synchronized half-Fourier fast spin echo. J Magn Reson Imaging. 2000 Nov;12(5):776-83.
- Zhang, Maki. 3D contrast-enhanced MR angiography. J Magn Reson Imaging. 2007 Jan;25(1):13-25.
- Gauvrit, Trystram. [Advanced vascular imaging techniques of supra-aortic, encephalic and medullary vessels.]. Journal de radiologie. 2007 Mar;88(3 Pt 2):472-82.
- Wilson, Hoogeveen. Parallel imaging in MR angiography. Top Magn Reson Imaging. 2004 Jun;15(3):169-85.
- Foo, Polzin. MR angiography physics: an update. Magnetic resonance imaging clinics of North America. 2005 Feb;13(1):1-22, v.
- Madhuranthakam, Hu. Contrast-enhanced MR angiography of the peripheral vasculature with a continuously moving table and modified elliptical centric acquisition. Radiology. 2006 Jul;240(1):222-9.
- Ersoy, Zhang. Peripheral MR angiography. J Cardiovasc Magn Reson. 2006;8(3):517-28.
The first fully digital C-arm
Increasing interventional radiology capacity while reducing patient radiation
A healthy dose of radiation monitoring
Patient-Specific Radiation Dose Estimation in Breast Cancer Screening
Ensuring performance of x-Ray equipment: a holistic approach