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MRI is basically a huge magnet that emits energy (Radio Frequency pulse) into the body. | ==Overview== | ||
Radiofrequency pulse causes the protons in H+ atoms to spin in different directions from which it used to spin. | *MRI is basically a huge magnet that emits energy (Radio Frequency pulse) into the body. | ||
When the pulse stops .. the protons go back to spinning in the normal direction .. it releases energy. | *Radiofrequency pulse causes the protons in H+ atoms to spin in different directions from which it used to spin. | ||
As | *When the pulse stops .. the protons go back to spinning in the normal direction .. it releases energy. | ||
Interpreting this energy using certain techniques enables us to represent every tissue in a unique density. | *As tissues vary in a number of protons in it .. the energy emitted differ from tissue to tissue. | ||
*Interpreting this energy using certain techniques enables us to represent every tissue in a unique density. | |||
MRI | ==MRI Sequence== | ||
An MRI sequence is a number of radio-frequency pulses (from the machine) and gradients that result (from protons in the body) in a set of images with a particular appearance. | *An MRI sequence is a number of radio-frequency pulses (from the machine) and gradients that result (from protons in the body) in a set of images with a particular appearance. | ||
Each sequence gives tissues different intensities and best used in diagnosing specific pathology/ies. | *Each sequence gives tissues different intensities and best used in diagnosing specific pathology/ies. | ||
T1 weighted imaging: | ===T1 weighted imaging:=== | ||
When using T1 weighted imaging .. the tissues take the following densities: | When using T1 weighted imaging .. the tissues take the following densities: | ||
Fat: bright | *Fat: bright | ||
Muscle: gray | *Muscle: gray | ||
Fluid: dark | *Fluid: dark | ||
Moving blood: dark | *Moving blood: dark | ||
Bone: dark | *Bone: dark | ||
Air: dark | *Air: dark | ||
Brain : | *Brain: | ||
-Gray matter: gray | -Gray matter: gray | ||
-White matter: bright | -White matter: bright | ||
| Line 25: | Line 26: | ||
T1 is best used in assessing the anatomy as the picture resembles the tissue macroscopically. | T1 is best used in assessing the anatomy as the picture resembles the tissue macroscopically. | ||
T1+C (gadolinium) | ====T1+C (gadolinium)==== | ||
*Tissues have the same densities as in T1 except that moving blood is bright. | |||
*Useful in assessing hypervascular lesions (e.g. hemangiomas, lymphangiomas) | |||
===T2 weighted imaging:=== | |||
When using T1 weighted imaging .. the tissues take the following densities: | |||
Fat: bright | *Fat: bright | ||
Muscle: gray | *Muscle: gray | ||
Fluid: dark | *Fluid: dark | ||
Moving blood: dark | *Moving blood: dark | ||
Bone: dark | *Bone: dark | ||
Air: dark | *Air: dark | ||
Brain : | *Brain: | ||
-Gray matter: gray | -Gray matter: gray | ||
-White matter: bright | -White matter: bright | ||
Most pathologies have increased fluid content of the tissue as a part of the inflammatory process. Thus, tissues become brighter | *Most pathologies have increased fluid content of the tissue as a part of the inflammatory process. Thus, tissues become brighter | ||
*Used as in T1 in assessing the anatomy & most lesions in the body. | |||
====Important note:==== | |||
*T2 weighted imaging is not the best sequence for assessing lesions close to brain ventricles both will appear bright. | |||
DWI | ===Diffusion weighted imaging (DWI):=== | ||
*DWI specifically detects the motion of protons in water molecules. | |||
Fat: | When using T1 weighted imaging .. the tissues take the following densities: | ||
Muscle | *Fat: low signal | ||
Fluid | *Muscle: gray | ||
*Fluid: dark | |||
*Brain: | |||
-Gray matter: gray | |||
Brain : | -White matter: hypodense compared to gray matter | ||
-Gray matter: | |||
-White matter: | |||
Fluid restricted areas appear bright. So, it’s most useful in assessing ischemia (e.g. stroke) | Fluid restricted areas appear bright. So, it’s most useful in assessing ischemia (e.g. stroke) | ||
Revision as of 14:05, 11 April 2017
Overview
- MRI is basically a huge magnet that emits energy (Radio Frequency pulse) into the body.
- Radiofrequency pulse causes the protons in H+ atoms to spin in different directions from which it used to spin.
- When the pulse stops .. the protons go back to spinning in the normal direction .. it releases energy.
- As tissues vary in a number of protons in it .. the energy emitted differ from tissue to tissue.
- Interpreting this energy using certain techniques enables us to represent every tissue in a unique density.
MRI Sequence
- An MRI sequence is a number of radio-frequency pulses (from the machine) and gradients that result (from protons in the body) in a set of images with a particular appearance.
- Each sequence gives tissues different intensities and best used in diagnosing specific pathology/ies.
T1 weighted imaging:
When using T1 weighted imaging .. the tissues take the following densities:
- Fat: bright
- Muscle: gray
- Fluid: dark
- Moving blood: dark
- Bone: dark
- Air: dark
- Brain:
-Gray matter: gray -White matter: bright
T1 is best used in assessing the anatomy as the picture resembles the tissue macroscopically.
T1+C (gadolinium)
- Tissues have the same densities as in T1 except that moving blood is bright.
- Useful in assessing hypervascular lesions (e.g. hemangiomas, lymphangiomas)
T2 weighted imaging:
When using T1 weighted imaging .. the tissues take the following densities:
- Fat: bright
- Muscle: gray
- Fluid: dark
- Moving blood: dark
- Bone: dark
- Air: dark
- Brain:
-Gray matter: gray -White matter: bright
- Most pathologies have increased fluid content of the tissue as a part of the inflammatory process. Thus, tissues become brighter
- Used as in T1 in assessing the anatomy & most lesions in the body.
Important note:
- T2 weighted imaging is not the best sequence for assessing lesions close to brain ventricles both will appear bright.
Diffusion weighted imaging (DWI):
- DWI specifically detects the motion of protons in water molecules.
When using T1 weighted imaging .. the tissues take the following densities:
- Fat: low signal
- Muscle: gray
- Fluid: dark
- Brain:
-Gray matter: gray -White matter: hypodense compared to gray matter
Fluid restricted areas appear bright. So, it’s most useful in assessing ischemia (e.g. stroke)
FLAIR:
Same as T2 except that fluid is dark. Fat Muscle Fluid Moving blood Bone Air Brain : -Gray matter: -White matter:
Best used in assessing lesions near ventricles the lesion can be easily discriminated from CSF.
Proton density weighted sequences:
Fat Muscle Fluid Moving blood Bone Air Hyaline cartilage fibrocartilage
Excellent in assessing joints as they can discriminate between fluid, hyaline cartilage & fibrocartilage