Neuroimaging

Question 1

What are some of the uses of brain imaging techniques and factors to consider?

Answer 1

• Locating cysts and tumours
• finding oedema and haemorrhage
• Identifying the facts of a stroke
• some show structure, function and some both

Factors to consider;
- Availability
- Practicality and cost
- Side effects

Question 2

What are the different orientations/slices of the brain that we can get?

Answer 2

Sagittal
Transverse
Coronal

Question 3

What are the features of CT (computerised tomography)?

Answer 3

Uses x-rays and a computer to create detailed images of the body

Advantages;
Fast - takes about 0.3 seconds to image a single slice, get up to 64 slices pr rotation with 64 slice CT scanner

Widely available !

Disadvantages;
- Ionizing radiation

Question 4

Why is radiation an issue in CT and what its the radiation risk factor?

Answer 4

CT head dose = 200 x CXR dose

Radiation risk factor = total lifetime risk of radiation-induced fatal cancer for the general population

0.05% per mSv (1 in 20,000)

There is also new photon-counting CT which reduces radiation and gives better imaging - not been made into routine yet

Question 5

What plane are CT images given in?

Answer 5

Orbitomeatal plane, now in the supraorbitomeatal plane.

Images are acquired in the axial plane but can be reconstructed

Caudal view: axial slices viewed ‘as if from the foot of the bed’ - Right side of image is the Left side of the patient and vice versa

Question 6

What colours would you see in CT images?

Answer 6

Grey scale from black to white (opposite of MRI)

Generated by absorption;
- Tissues differ in absorption of x-rays
- Corresponds to ‘shade of grey’ on image
- Narrow range for soft tissues - poor differentiation

Bone absorbs so white, air doesn’t so black

Question 7

How does MRI work?

Answer 7

Clinical MRI relies on hydrogen;
- Has a single proton in its atom
- Found in abundance in the body -> good source of signal

Uses a combination of magnetic fields and radio waves to produce images

RF pulse used in MRI is non-ionising but may cause heating effect (same radiation as phones)

Question 8

What planes can you acquire MRI’s in?

Answer 8

Oblique

Axial: Viewed as if from the foot of the bed - Right side of image is left side of patient vice versa

Coronal images: Viewed as if you are looking at the face of the patient - Right side of image is left side of patient vice versa

Question 9

What are the different MRI scans that you can get?

Answer 9

Contrast between different tissues/structures/pathologies is needed

Three properties of tissue affect contrast:
- T1 time (T1 recovery)
- T2 time (T2 decay)
- Proton density (PD)

A series of RF and magnetic field applications is called a pulse (MR) sequence

Pulse sequence, therefore the images can be T1-, T2- or PD-weighted

Question 10

What are the different weighted images good for?

Answer 10

T1-weighted image: good for anatomy and contrast
- Water (CSF) is dark, grey matter is dark grey, white matter is off white, fat is white

T2 - weighted image: good for identifying pathology - inflammation, oedema
- Water is white, white matter is darker than grey matter
(WW2 - Water is White on T2)

Question 11

What is magnetic resonance angiography ?

Answer 11

Makes vessel visible for scan

Can be done with our without contrast - Might not want to use contrast in patients who are allergic or have kidney disease will struggle to eliminate as heavy

Inflow angiography (aka time-of-flight) and phase contrast

Can over-exaggerate stenoses, underestimate true lumen size

Question 12

When else can contrast agents be used?

Answer 12

Not only for angiography but also to enhance contrast between tissues

Positive contrast agents produce an increase in signal intensity in affected tissues

Gadolinium - Most commonly used - not easily eliminated from body but some instances is needed
- Potential to build up in body

Negative contrast agents produce a decrease in signal intensity in affects tissues - contain iron oxide

Question 13

What do diffusion wighted imaging (DWI) rely on and what can these show?

Answer 13

Diffusion weighted imaging (DWI) relies on diffusion of water molecules. (T2)

Areas of cerebral infarction t(issue death or necrosis due to inadequate blood supply to the affected area) have decreased diffusion, which results in increased signal intensity (more white)

Is now the standard imaging for early detection of ischemia / infarct / stroke, differentiation of brain tumours and intracranial infections

Question 14

What is the apparent diffusion coefficient (ADC)?

Answer 14

The apparent diffusion coefficient (ADC) is a measure of the magnitude of diffusion of water molecules within the tissue.

Commonly calculated using diffusion-weighted imaging (DWI)

ADC values are calculated automatically by the software and then displayed as a parametric map

The images contrast on ADC maps is opposite to that of DWI (water was white now black)

Question 15

What is tractography?

Answer 15

A 3D reconstruction technique to show / assess axons / tracts using data related to diffusion of water collected by diffusion MRI

Question 16

What is function MRI and its use (fMRI)?

Answer 16

Used to obtain functional information buy visualising cortical activity

Detects subtle alteration in blood flow or blood oxygen in response to stimuli or actions

There are limitations

Question 17

What are the contraindications of using MRI?

Answer 17

Projectiles (attraction of metal objects)

Implanted devices;
- Pacemakers, cochlear implants, non-MRI compatible heart valves, stents
- Foreign bodies (shrapnel) - torque or malfunction

Claustrophobia

Question 18

What is nuclear imaging: SPECT and PET

Answer 18

Perfusion techniques that requires intravenous contrast agent

They show the metabolic or biochemical function by measuring radio tracer uptake (usually glucose) by the tissues (cancer, infection, coronary artery disease, brain disorders)

PET offers better spatial resolution, higher diagnostic accuracy and lower dosimetry then SPECT but it is very expensive

Question 19

What is the system we use for interpreting images?

Answer 19

ABC’S

A;
- Adequacy
- Alignment
- Artefact

B;
- Bones
- Blood
- Brain

C;
- CSF filled spaces (cisterns & ventricles)

S;
- Subcutaneous
- Surfaces
- Symmetry

Question 20

What does part A in ABC’s cover?

Answer 20

Adequacy - Can you see all 7 cervical vertebrae + the top of T1 (as well as occipital bone)

Alignment - Draw three vertical “parallel” lines along the anterior + posterior border of the 7 vertebral bodies and a third line through the base of each spinous process

Asymmetry - Look for abnormal asymmetry between the 7 cervical vertebrae

Artefact;
- Motion/confused patient, children
- Beam hardening - posterior fossa
- Medical - metal clips, intraventricular shunts
- Aliasing

Question 21

What does part B in ABC’s cover?

Answer 21

Bones;
- Bone window on CT when parameters are preset correctly
- MRI shows bones indirectly by showing structures around bone to give bone appearance

Blood; (white in T2, not as white as bone tho)

Subdural hematoma;
- Crescent-shaped
- blood collection between dura and arachnoid matter
- Tear in bridging veins
- Alcoholics and elderly are prone

Epidural hematoma;
- Biconvex (lens) shaped
- Blood between dura and skull
- Tearing of middle meningeal artery
- Adolescents and young adults (Trauma)

Subarachnoid haemorrhage;
- blood in circle of Willis, cisterns, and fissures
- Rupture of berry aneurysm
- polycystic kidney disease is a risk factor
- Rupture of cerebral arteries

Intracerebral haemorrhage;
- Blood in parenchyma and ventricles
- Hypertensive vasculopathy
- Terriotry between penetrator arteries (between brain mass)

Brain;
- Mass
- Poor grey-white matter differentiation
- Loss of sulci / atrophy

Question 22

What does part C in ABC’s cover?

Answer 22

CSF - filled spaces;

Check cisterns, has blood collected in them? - Subarachnoid haemorrhage

Obstructive hydrocephalus - blockage in ventricular system leads to enlargement of lateral ventricles - very large black cross shape

Question 23

What does part S in ABC’s cover?

Answer 23

Subcutaneous and soft tissues;

• Skin / subcutaneous lesions (or mass)
• Orbit
• Sinuses
• Nasopharynx and oropharynx

Question 24

What type of heamorrhage is this? (See image)

Answer 24

Subdural hematoma;
- Crescent shapd
- Blood collection between dura and arachnoid matter
- Tear in briding veins
- Alcohlics and elderly are prone

Question 25

What would a Subdural haematoma look like ?

Answer 25

Subdural hematoma;
- Crescent shaped
- Blood collection between dura and arachnoid matter
- Tear in briding veins
- Alcohlics and elderly are prone

(See image)

Question 26

What type of haemorrhage is this? (See image)

Answer 26

Subarachnoid Haemorrhage;
- Blood in circle of Willis, cisterns and fissures
- Rupture of berry aneurysm
- Polycistic kidney disease (risk factor)

Question 27

What type of heamorrhage is this? (See image)

Answer 27

Epidural haematoma;
- Biconvex (lens) shaped
- Blood between dura and skull
- Tearing of middle meningeal artrey (hit in pterion?)
- Adolescents and young adults (trauma)

Question 28

What type of heamorrhage is this? (See image)

Answer 28

Intracerebral haemorrhage;
- Blood in parenchyma and venticles
- Hypertensive vasculopathy
- Territory of penetrator arteries

Question 29

What would a Subarachnoid Haemorrhage look like?

Answer 29

Subarachnoid Haemorrhage;
- Blood in circle of Willis, cisterns and fissures
- Rupture of berry aneurysm
- Polycistic kidney disease (risk factor)

(See image)

Question 30

What would a Epidural haematoma look like?

Answer 30

Epidural haematoma;
- Biconvex (lens) shaped
- Blood between dura and skull
- Tearing of middle meningeal artrey (hit in pterion?)
- Adolescents and young adults (trauma)

(See image)

Question 31

What would a Intracerebral Haemorrhage look like ?

Answer 31

Intracerebral haemorrhage;
- Blood in parenchyma and venticles
- Hypertensive vasculopathy
- Territory of penetrator arteries

(See image)