15
Magnetic Resonance Magnetic Resonance Imaging (MRI) Imaging (MRI)

Magnetic Resonance Imaging (MRI)

Embed Size (px)

DESCRIPTION

Magnetic Resonance Imaging (MRI). The Components:. A magnet which produces a very powerful uniform magnetic field. Gradient Magnets which are much lower in strength. Equipment to transmit radio frequency (RF). - PowerPoint PPT Presentation

Citation preview

Page 1: Magnetic Resonance Imaging (MRI)

Magnetic Resonance Magnetic Resonance Imaging (MRI)Imaging (MRI)

Page 2: Magnetic Resonance Imaging (MRI)
Page 3: Magnetic Resonance Imaging (MRI)
Page 4: Magnetic Resonance Imaging (MRI)

The Components:The Components: A magnet which produces a very powerful A magnet which produces a very powerful

uniform magnetic field.uniform magnetic field.

Gradient Magnets which are much lower in Gradient Magnets which are much lower in strength.strength.

Equipment to transmit radio frequency (RF).Equipment to transmit radio frequency (RF).

A very powerful computer system, which A very powerful computer system, which translates the signals transmitted by the coilstranslates the signals transmitted by the coils . .

Page 5: Magnetic Resonance Imaging (MRI)

The MagnetThe Magnet

The most important component of the MRI scanner is the magnet: The magnets currently used in scanners

today are in the .5-tesla to 2.0-tesla range (5,000 to 20,000-gauss).

Higher values are used for research.

Earth magnetic field: 0.5-gauss

Page 6: Magnetic Resonance Imaging (MRI)

The Magnet (cont.)The Magnet (cont.)

There are three types of magnets used in MRI systems: Resistive magnets Permanent magnets Super conducting magnets (the most commonly used type

in MRI scanners).

The most commonly used imaging planes in MRI are The most commonly used imaging planes in MRI are axial, sagittal and coronal.axial, sagittal and coronal.

Page 7: Magnetic Resonance Imaging (MRI)

The main uses of MRI The main uses of MRI NEUROLOGYNEUROLOGY Brain (early detection of cerebral white Brain (early detection of cerebral white

matter disease, posterior fossa and brain matter disease, posterior fossa and brain stem pathology, intracranial arterial and stem pathology, intracranial arterial and venous abnormalities )venous abnormalities )

Spinal cord (spinal cord lesions)Spinal cord (spinal cord lesions) Brachial plexusBrachial plexus ORTHOPAEDICSORTHOPAEDICS Lumber spineLumber spine KneeKnee ShoulderShoulder

Page 8: Magnetic Resonance Imaging (MRI)

Advantages of MRIAdvantages of MRI No ionizing radiation.No ionizing radiation. Superior soft tissue contrast than CT.Superior soft tissue contrast than CT. Can select any plane Can select any plane

e.g coronal,sagittal,oblique.e.g coronal,sagittal,oblique. More sensitive to tissue changesMore sensitive to tissue changes No bone artifacts No bone artifacts No iodinated contrast media used. No iodinated contrast media used.

IV contrast (gadolinium) has a lower IV contrast (gadolinium) has a lower risk of death compared with risk of death compared with iodinated contrast used with CT.iodinated contrast used with CT.

Page 9: Magnetic Resonance Imaging (MRI)

DisadvantagesDisadvantages Limited slice thickness 3mm(CT-1mm)Limited slice thickness 3mm(CT-1mm) Bone imaging limited to display of marrowBone imaging limited to display of marrow Claustrophobia(due to the confined space in Claustrophobia(due to the confined space in

the scanner).the scanner). Cannot use with pacemaker or ferromagnetic Cannot use with pacemaker or ferromagnetic

implantimplant Longer imaging times 20-30 minsLonger imaging times 20-30 mins Cardiac scan upto 1hr.Cardiac scan upto 1hr. MRI equipment is expensive to purchase, MRI equipment is expensive to purchase,

maintain, and operatemaintain, and operate

Page 10: Magnetic Resonance Imaging (MRI)

Contraindication to MRIContraindication to MRI Cardiac pacemakerCardiac pacemaker Implanted cardiac defibrillatorsImplanted cardiac defibrillators Cochlear implantsCochlear implants PregnancyPregnancy marked obesity marked obesity

Page 11: Magnetic Resonance Imaging (MRI)

Tissue contrast Tissue contrast The relaxation times T1 and T2 are The relaxation times T1 and T2 are

times related to the nuclei returning to times related to the nuclei returning to their original alignment in the their original alignment in the longitudinal axis (T1) and in the transverse axis (T2) of the magnetic of the magnetic field.field.

There are 2 basic types of relaxation T1 There are 2 basic types of relaxation T1 and T2.and T2.

To define a tissue or pathology To define a tissue or pathology accurately a radiologist often compare accurately a radiologist often compare its appearance on both T1 and T2. its appearance on both T1 and T2.

Page 12: Magnetic Resonance Imaging (MRI)

T1 weighted images T1 weighted images T1 MRI is known as T1 MRI is known as Spin-lattice

relaxation time. T1 shows anatomy very well.T1 shows anatomy very well. Water is black on T1.-low signalWater is black on T1.-low signal Fat subacute blood melanin Fat subacute blood melanin

proteinaceous fluid and contrast proteinaceous fluid and contrast media- high signalmedia- high signal

Page 13: Magnetic Resonance Imaging (MRI)

T2 weighted images T2 weighted images

T2 MRI is known as T2 MRI is known as spin-spin relaxation time

T2shows pathology or inflammation T2shows pathology or inflammation wellwell

Water and inflammation are white-Water and inflammation are white-high signalhigh signal

Fat is high signal on T2.Fat is high signal on T2.

Page 14: Magnetic Resonance Imaging (MRI)
Page 15: Magnetic Resonance Imaging (MRI)

Low signal or no signal Low signal or no signal tissuestissues

Cortical boneCortical bone CalcificationCalcification Tendons/ligamentsTendons/ligaments MetalMetal GasGas