Epilepsy: Structural Imaging and Novel Contrasts

Question 1

What is the NICE guidelines on epilepsy (2012)?

Answer 1

1. MRI should be the imaging investigation of choice in children, young people and adults with epilepsy
2. Particularly onset before 2yr or in adulthood, focal onset seizures, pharmacoresistant epilepsy
3. Should be performed soon (within 4 weeks)
4. Not required for idiopathic generalised epilepsy
5. CT if MRI not available/contraindicated, in children who would need anaesthetic/sedation for MRI and in acute situation (e.g. bleed)

Question 2

When and why is imaging useful?

Answer 2

1. New onset focal seizures
   - identification of cause e.g. tumour
2. Refractor focal seizures
   - assessment for surgical treatment
   - what is nature of lesion?
   - what is extent of lesion?
   - what is relationship of lesion to eloquent cortex

Question 3

What is the acquisition protocol (ILAE, Bonn)?

Answer 3

1. 3D volumetric T1-weighted - grey/white matter contrast, cortical thickness, MCD
2. T2-weighted (axial,coronal) - hippocampal architecture (long axis), cystic tissue components
3. FLAIR (axial, coronal) - hippocampal sclerosis, FCD, tumours, inflammation, scars
4. T2* gradient echo echo/ SWI (axial) - calcifies or vascular e.g. caverns, AVM

Question 4

What is the imaging hardware/ scan interpretation?

Answer 4

1. Increased field strength, better coils, gradients
   - better SNR, resolution, hippocampal subfields (7T)
   - distortions/artefacts, patient tolerance, expense
2. Chalfont series of > 800 patients on 1.5T vs 3T
   - 37(5%) new diagnoses esp. HS, FCD, DNET
3. Diagnostic yield in presurgical epilepsy MRI
   - 1.5T standard - non-expert (39%), expert (50%)
   - 1.5T epilepsy protocol - expert (91%)

Question 5

What are example MRI findings?

Answer 5

1. Hippocampal sclerosis
2. Malformations of cortical development
   - focal cortical dysplasia
   - cortical neoplasms
3. Meningioma
4. Vascular malformations
5. Infectious (worldwide)

Question 6

What is Hippocampal Sclerosis?

Answer 6

1. Most common cause of refractory TLE
   - neuronal fell loss/gliosis esp. CA1, CA3, dentate gyrus
2. Visual analysis alone may fail to detect HS

Question 7

What are the imaging features of Hippocampal Sclerosis?

Answer 7

1. Hippocampal atrophy
2. Disrupted internal architecture
3. Decreased T1-weighted signal
4. Increased T2-weighted signal

Question 8

What is malformations of cortical development?

Answer 8

1. Updated classification scheme (>200 categories)
2. Neuronal/glial proliferation of apoptosis
3. Neuronal migration
4. Postmigrational development

Question 9

What are examples of abnormal neuronal/glial proliferation or apoptosis?

Answer 9

1. Microcephaly
2. Megalencephaly
3. Cortical dysgenesis with abnormal cell proliferation (e.g. FCD II, TS)
4. Cortical dysgenesis with abnormal cell proliferation and neoplasia (e.g. DNET, ganglioglioma)

Question 10

What is Hemimegalencephaly?

Answer 10

1. Unilateral cortical enlargement
2. Large, asymmetrical head
3. Epilepsy +/- learning disability
4. Large ventricle
5. Abnormal sulcation
6. Cortical thickening

Question 11

What are examples of abnormal neuronal migration?

Answer 11

1. Heterotopia
2. Lissencephaly
3. Subcortical heterotopia, sublobar dysgenesis
4. Cobblestone malformation

Question 12

What are examples of abnormal postmigrational development?

Answer 12

1. Polymicrogyria, schizencephaly
2. Cortical dysgenesis secondary to inborn errors of metabolism
3. Focal cortical dysplasia (including FCD I, III)
4. Postmigrational Microcephaly

Question 13

What is polymicrogyria ?

Answer 13

1. Excessive small gyri
   - focal or generalised
2. Epilepsy, learning disability, speech/swallowing/respiratory
3. Genetic
   - viral
   - nutritional deficits

Question 14

What are focal cortical dysplasia ?

Answer 14

1. Up to 42% of MRI-negative patients undergoing surgery have FCD
2. Disrupted laminar architecture and columnar organisation and abnormal cells, including dua moronic neurons and balloons cells

Question 15

What are imaging features of focal cortical dysplasia?

Answer 15

1. Cortical thickening and blurring grey/white matter boundary (T1-weighted)
2. Cortical/sub-cortical signal hyper intensity (T2-weighted)

Question 16

What are the different types of focal cortical dysplasia?

Answer 16

1. Prior classification system (Palmini 2004) updated 2011
2. Type I (abnormal cortical layering)
   - type Ia - abnormal RADIAL cortical Lamination
   - type Ib - abnormal TANGENITAL cortical lamination
   - type Ic - abnormal RADIAL + TANGENITAL
3. Type II (disrupted lamination + cytologic abnormalities)
   - type IIa - dysmorphic neurons
   - type IIb - dysmorphic neurons + balloon cells
4. Type III (disrupted lamination + primary lesions)

Question 17

Why is finding a lesion so important?

Answer 17

1. Surgical target!
2. Each type has varied MR findings
   - IIb associated with less wide spread abnormalities (both structural and functional)
   - more favourable seizure outcome after epilepsy surgery compared to types I and IIa

Question 18

What is the most common cortical neoplasms?

Answer 18

1. Ganglioglioma

2. Low grade astrocytoma

Question 19

What are less common cortical neoplasms?

Answer 19

1. Low-grade oligodendroglioma

2. DNET

Question 20

What is nearly exclusively seen in epilepsy?

Answer 20

1. Ganglioglioma

2. DNET

Question 21

What is Meningioma?

Answer 21

1. Commonest extra-axial tumour

2. 20-50% have epilepsy as presenting symptoms

Question 22

What is vascular abnormalities?

Answer 22

1. Cavernoma - heterogenous core depending on age of blood products, outer rim T2 hypointense
2. GRE (T2*) or SWI sequences useful for detection

Question 23

What is MRI negative epilepsy?

Answer 23

1. Around 30% of patients with focal epilepsy have normal conventional MRI (“MRI negative”)
   - undetected hippocampal sclerosis/ FCD
   - implications on surgery/planning/surgical outcome

Question 24

What are the possible solutions for MRI negative Epilepsy?

Answer 24

1. Quantitative analysis
2. Post-processing/computational techniques
3. Novel image contrasts
4. Varies from centre to centre

Question 25

What is Quantitative assessment of HS?

Answer 25

1. Hippocampal volumetric
   - manual
   - automated
2. Hippocampal T2 relaxometry
   - manual
   - automated
3. Quantitation improves sensitivity to detect HS
4. 28% in “MR Negative”

Question 26

What is automated Hippocampal segmentation?

Answer 26

1. Manual: time-consuming and subject to interrater/Intrarater variability
2. Automated: reduce time commitment, reproducible
   - some techniques perform poorly in abnormal atrophic hippocampi
3. Useful in identifying subtle or bilateral pathology

Question 27

What is Automated T2 mapping?

Answer 27

1. Dual-echo spin-echo sequence (PD,T2) - full brain coverage with sufficient sensitivity
2. Manual delineation is time consuming & samples part of hippocampus with CSF contamination
3. Can take Hippocampal segmentation, register to PD/T2 , erode, remove voxels with high T2(CSF)
4. Automated more reproducible than manual T2 relaxometry

Question 28

What are post-processing/computational methods?

Answer 28

1. Voxel-based approach
2. Surface-based approach
3. Combinations using machine learning models

Question 29

What are voxel-based approaches to FCD?

Answer 29

1. Investigate differences in brain anatomy statistically
2. Spatially normalise you group template + segment
3. Smooth + compare individual to controls on voxelwise basis
   - grey matter (from T1)
   - signal intensify (from FLAIR)
   - derivatives e.g. junction map
4. Main limitations is poor specificity

Question 30

What is surface-based approaches to FCD?

Answer 30

Morphometric measures from geometric surface models - individual curvature and folding

1. Extract cortical surface
   - Paul surface (CSF/dura + grey matter)
   - white surface (grey matter + white matter)
2. Represent as surface model (triangular mesh)
3. Morphometric measures
   - cortical thickness
   - cortical curvature
4. Surfaces can be inflated (match folding) to enable comparisons between groups

Question 31

What are free surfer parakeets for surface-based approaches to FCD?

Answer 31

1. Cortical thickness
2. GM/WM contrast
3. Local gyrification index
4. Sulcal depth
5. Mean curvature

Question 32

What is diffusion imaging?

Answer 32

1. In CSF, water diffuses equally in all directions
2. In white matter, water diffuses along length of nerves rather than perpendicular
3. Diffusion imaging is an MRI sequence that quantified water diffusion in different directions

Question 33

What are parameters of diffusion imaging?

Answer 33

FA (fractional anisotropy)

• quantifies degrees of directionality of diffusion
• ranges from 0 (isotropic) to 1 (fully anisotropic)
• often reduced in disease (e.g. hippocampal sclerosis)

MD (mean diffusivity)

• quantified average rate of diffusion in all directions
• often increased in disease

Question 34

What is magnetisation transfer imaging?

Answer 34

1. Protons exist in two pools - free and bound
   - magnetisation pulse applied to exclusively bound pool (macromolecules)
   - energy transferred to free pool
   - contrast generated from magnetisation exchange
   - quantified as MTR (magnetisation transfer ratio)
   - reduced due to loss of macromolecules

Question 35

What are the results of MTR?

Answer 35

1. 15/42 MRI-negative epilepsy
   - changes concord ant with electro clinical syndromes
   - minor structural disorganisation

Question 36

What is double inversion recovery?

Answer 36

1. Two inversion pulses to bull signal from CSF (like FLAIR) and from normal white matter
2. Useful to visualise cortical ribbon with minimisation of CSF/WM partial volume effects

Question 37

What are limitations of techniques?

Answer 37

1. Limited sensitivity and different sequences perform differently
2. Problem of lack of specificity so many false positives
3. Never really introduced into clinical practice
4. Future approaches
   - computational post-processing of multiple contrasts
   (E.g. machine learning)

Question 38

What is ASL?

Answer 38

1. Non-invasive, ionisation free measure of tissue perfusion
2. Magnetically labelled arterial blood eater protons as an endogenous tracer

Question 39

What do areas of low perfusion correspond to in ASL?

Answer 39

Areas of reduced glucose metabolism (on FDG-PET)

Question 40

What is NODDI?

Answer 40

1. Neurotransmission orientation dispersion and density imaging
   - special type of diffusion-weighted scan and modelling, provides estimates of tissue microstructure
2. May identify reduced intracellular volume fraction, marker of neurite density - FCD

Question 41

What is the principle of multimodal imaging?

Answer 41

1. Co-register and display multiple imaging sources in a common space to understand the 3D relationship between different metabolites
2. Useful for planning of the 20-30% of patients who require intracranial EEF
3. Increasing move towards SEEG (12-29 depth)
   - practice targeting (entry,destination) increases grey matter sampling and reduced risk (arteries,veins)