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Alternating Hemiplegia

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PHASE 2: Hemiplegic attacks and psychomotor delay/regression. ... et al 1993 suggested that Hemiplegic Attacks could be an intermittent paroxysmal ... – PowerPoint PPT presentation

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Title: Alternating Hemiplegia


1
U.O. di Neuropsichiatria Infantile Ospedale
Maggiore C.A. Pizzardi Bologna-Italy
Long term neurological outcome in AHCFunctional
MRI (Arterial spin labeling-perfusion
imaging-ASL-PI) study
2
AHC The Course of the illness
  • PHASE1 Abnormal ocular movements and dystonic
    attacks
  • PHASE 2 Hemiplegic attacks and psychomotor
    delay/regression.
  • PHASE 3 persistent/chronic psychomotor delay and
    chronic non paroxysmal neurological deficits.
    (Mikati et al 2000)

3
Chronic Neurological Disturbances
  • Postural Dystonia, Choreoathetosis, Tremor
  • Ataxia, Hypotonia
  • Spasticity
  • Epilepsy
  • Cognitive impairment
  • Learning Disabilities
  • Behavioural Disorder
  • Psychomotor Delay

4
Postural Dystonia and Choreoathetosis
  • Frequent
  • Onset after 2-5 yrs
  • Variable intensity
  • Prevented fine hand movements (writing) and gait
  • Progressive course with successive stabilization
    (after 2-3 yrs or after 20 yrs of age)

5
Ataxia and Hypotonia
  • Marked hypotonia more frequent at onset
  • Ataxia
  • Early or late onset
  • Mild or moderate degree
  • Quite significant functional impairment (walking)

6
Spasticity
  • Rare
  • Progressive onset
  • At times replaced marked hypotonia that may be
    present at onset
  • Acquired mild hemiparesis on the side most
    frequently involved by the paroxysmal attack

7
Research projectIntroduction
  • One of the major and unresolved issue is whether
    AHC is a static encephalopathy or a progressive
    condition.
  • To date, there isnt any specific study about
    chronic non paroxysmal neurological disorders in
    AHC

8
Research projectAim
  • We propose to study the chronic non
  • paroxysmal neurological disorders by
  • functional neuroimaging.

9
What are we looking for?
  • Several clinical observation suggest impairment
    of several cortical and subcortical structures in
    patients with Alternating Hemiplegia

10
Alternating Hemiplegia
Paroxysmal Oculomotor features (nystagmus and
ophtalmoplegia) Autonomic features Sleep EEG
pattern (slow waves)
Hypothalamus and brainstem nuclei
Ataxia and hypotonia
cerebellum
Paroxysmal and chronic Dystonia Choreoathetosis tr
emor
Basal ganglia
Attention Disturbances Behavioural
Problems Learning Disabilities Mental Retardation
Frontal cortex Orbitofrontal circuit
Fronto-cerebellar circuit?
11
  • Wong et al 1993 suggested that Hemiplegic Attacks
    could be an intermittent paroxysmal disorder of
    vascular origin

FRONTAL, PARIETAL, TEMPORAL LOBE PLEGIA APHASIA
DECREASED BLOOD SUPPLY TO THE MIDDLE CEREBRAL
ARTERY
DECREASED BLOOD SUPPLY TO THE POSTERIOR CEREBRAL
ARTERY
BASAL GANGLIA EXTRAPYRAMIDAL SIGNS
12
  • Since Magnetic Resonance Imaging scans of
    patients with AHC are normal or not
    informative/significative, at least at the
    current resolution level of this technology,
    further attempts at functional neuroimaging have
    been made with
  • Single-Photonemission Computed Tomography
    (SPECT)
  • Positron Emission Tomography (PET)
  • Magnetic Resonance Spettroscopy.

13
SPECT
  • Conflicting set of data
  • Blood flow changes are not always present, while
    present may be there hyper or hypoperfusion
  • Different reports of regional or hemispheric
    blood flow changes anatomically linked or not to
    the side of hemiplegia.
  • SPECT images were conducted at different stages
    of hemiplegic attacks and thus cannot be directly
    compared, so that it is difficult to understand
  • Where changes in cerebral blood flow initially
    occur
  • How it evolves both in space and time

14
PET
  • PET offers greater resolution and the potential
    for measuring local and regional biochemical
    changes.
  • 2-Deoxy-2 18 F-fluoro-D-glucose (FDG)single
    or multiple areas of relative hypometabolism
    suggestive of local or regional damage.
  • Older children were more likely to show discrete
    areas of hypometabolism as compared to young
    children (Da Silva, Chugani 1996).

15
PET
  • 11-C-flumazenil (measures BDZ receptor binding)
    In one patient there was increasing in flumazenil
    binding in the controlateral hemisphere. (Chugani
    et al. unpublished data 1997)
  • 11-C-?-methyltryptophan PET allows regional
    serotonin synthesis to be estimated (Chaturvedi
    et al unpublished data 1997).
  • Patients with AHC studied in the ictal or
    postictal state showed increased serotonin
    synthesis capacity in the frontoparietal cortex,
    lateral and medial temporal structures, striatum,
    and thalamus when compared to controls and
    interictally studied AHC subjects (Chugani el
    al.2002)

16
MAGNETIC RESONANCE SPETTROSCOPY
  • Magnetic Resonance Spettroscopy has demonstrated
    consistent metabolic abnormalities indicative of
    neural damage or dysfunction
  • Decreased levels of N-acetyl-aspartate
  • Abnormally high-level of inorganic phosphate
  • Decreased phosphocreatine
  • Low cytosolic phosphorilation
  • Relatively increased in glutammate and decreased
    N-acetyl-asportate levels in cerebellum

17
Functional MRI(Blood oxygenation level
dependent-BOLD)
  • The functional MRI locates neural activity by
    examining regional blood flow in the brain.
  • In a region of neural activity the supply of
    oxygenated is greater than its consumption,
    leading to a higher than normal ratio to
    deoxygenated blood.
  • Because the two forms of haemoglobin have
    different effects on the dephasing of protons
    they produce different magnetic resonance
    signals.

18
Functional MRI
UNSTIMULATED CONDITION Minimal visual/motor
information Little neuron activation Blood flow
is not increased Large proportion of
deoxyhemoglobin
STIMULATED CONDITION Increased visual/motor
information Neurons activation Blood flow is
increased Decrease of deoxyhaemoglobin
WEAK MAGNETIC SIGNAL
STRONGER MAGNETIC SIGNAL
19
Why Functional MRI in AHC?
  • fMRI, like PET scanning, is sensitive to the
    increased blood flow, which is associated with
    neural activity
  • This tecnique has several advantages over PET
    scanning
  • - greater spatial and temporal resolution
  • - no injection of foreign material into the
    bloodstream (fMRI uses endogenous hemoglobin for
    a marker)
  • In literature theres no mention of study with
    fMRI in Patients with Alternating Hemiplegia

20
Functional MRI
  • fMRI is an emerging non-invasive methodology
    which provides various approaches to visualizing
    regional brain activity.
  • Although the exact mechanism underlying the
    coupling between neural function and fMRI signal
    changes remain unclear, fMRI studies have been
    successful in confirming task-specific activation
    in a variety of brain regions, providing
    converging evidence for functional localization.

21
Functional MRI
  • In particular, fMRI methods based on Blood
    Oxygenation Level Dependent (BOLD) contrast and
    arterial spin labeling (ASL) have enabled imaging
    of changes in blood oxygenation and cerebral
    blood flow.

22
Functional MRI
  • While BOLD contrast has been widely used as the
    surrogate marker of neural activation and can
    provide reliable information on the neuroanatomy
    underlying transient sensorimotor and cognitive
    functions, recent evidence suggests perfusion
    contrast (ASL-PI) is suitable for studying
    relatively long term effects on CBF both at rest
    or during activation.

23
  • Potential anatomical site or sites of brain
    dysfunction underlying chronic neurological
    symptoms in AHC may be identified with these
    tecniques.

24
Research projectMethods
  • Phase 1
  • Clinical and data-base evaluation of patient with
    chronic neurological signs
  • Phase 2
  • Review of all patients structural neuroimaging
    (MRI)
  • New MRI investigation aimed to a specific
    cerebral region, depending on patients main
    chronic disorder (dystonia? basal ganglia).

25
Research project
  • Phase 3
  • Study in depth with
  • perfusion maps (CBF maps)
  • spettroscopy MRI (Hydrogen or Phosphorus).
  • Phase 4
  • Possible ictal study.

26
Results
  • Phase 1and 2 results are expected in
  • 6 months.
  • Further investigation
  • (depending on phase 1 results)
  • will be developed later.

27
Budget
  • Travelling
  • Meetings
  • Workshop

5.000 US ds
Equipment (ASL-PI MRS) Workstation Silicon
Graphic for post processing of Mapping perfusion
Max 10.000 US ds
TOTAL
Max 15.000 US ds
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