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Title: NEUROLOGY SUBSPECIALTY SEMINAR -SEP 29/2006


1
  • NEUROLOGY SUBSPECIALTY SEMINAR -SEP 29/2006

2
  • CEREBELLAR DISEASES

3
  • ANATOMY
  • Derived from the somatic afferent portion of the
    alar plate
  • acts as a monitor or modulator of motor activity
    "originating" in other brain centers.
  • One of the major cerebellar functions is
    automatic excitation of antagonist muscles at the
    end of a movement with simultaneous inhibition of
    the agonist muscles that initiated the movement.
  • cerebellum is located in the posterior fossa of
    the skull, dorsal to pons and medulla oblongata
    and separated from the occipital lobes by the
    tentorium cerebelli.
  • On coronal planes has two portions the midline,
    vermis and cerebellar hemispheres.
  • vermis - older- receives mainly spinocerebellar
    afferents
  • Hemispheres have more complex fiber connections

4
  • Histologically. the cerebellar cortex has 3
    layers
  • the outer - molecular layer , the middle -
    Purkinje cell layer , the inner most - granule
    cell layer
  • - five cell types are distributed in these layers
  • outer basket cell and inner stellate cells in
    the molecular layer purkinjie cells arranged in
    a single row , granule and Golgi cells in granule
    cell layer
  • - The white matter of the cerebellum is made up
    of intrinsic, afferent, and efferent fibers.
  • - 4 pairs of nuclei on each side of the midline
    with in the white matter core of the cerebellum
    receive input from the cerebellar cortex and
    incoming afferents and cerebellar efferent.
  • Fastgial nucleus,nucleus globose, nucleus emboli
    form and dentate (lateral cerebellar) nucleus.

5
  • considering connections of these nuclie and
    sagital organization, the cerebellum can be
    divided longitudinally
  • a) midline (vermal ) zone - contain
    cerebellar neurons
  • projecting to the fastigial nucleus.
    Abnormal stance,gait,truncal titubation,disturbanc
    e of extraoccular movement
  • b) an intermediate (paravermal) zone contain
    neuron
  • projecting to the nucleus interposed
  • c) the lateral (hemisphere) zone contain
    neuron projecting to the dentate
    nucleus. Similar Sx plus decomposition of
    movement,dysdiaokinesia,dysarthria,tremer,hypotoni
    a,excessive rebound
  • - Each nucleus controls a different type
    of mode of movements.

6
  • connections
  • inferior and superior cerebellar peduncles are
    afferents and efferents.
  • Inferior cerebellar peduncle connects cerebellum
    to medulla oblongata.
  • afferents
  • dorsal spinocerbellar tract (T1-L2) ,
    cuneocerebellar tract , vestibulocerbillar tract
    , reticulo cerebellar tract , trigeminocerebellar
    tract
  • Efferent fastigiobulbar,cerebelloreticular,
  • Middle cerebellar pudnclecotcopontocerebellar
    tracts
  • Superior cerebellar pud-cerebellum to midbrain
  • mainly efferents

7
  • CLINICAL MANIFSTATIONS OF CEREBELLAR DYSFUNCTION
  • Hypotonia
  • - accompanies acute, less often in chronic
  • - ipsilateral
  • - more noticeable in the upper limbs- proximal
    muscles
  • - decreased resistance to passive stretch of
    muscles
  • - Occurs in neocerebellar lesions.

8
  • Ataxia or Dystaxia
  • - result from defective timing of sequential
    contractions of agonist and antagonist muscles.
  • - due to disturbance in the smooth performance of
    voluntary motor acts.
  • - movements errantic in speed, range, force, and
    timing
  • - due to absence of cerbellar inhibitory and
    modulating influences.
  • - ataxia may affect limbs, trunk, gait, may be
    acute onset ,episodic or progressive - ataxia
    includes asynergia (dysdiadokinesia, past
    pointing, excessive rebound phenomenon.
  • - Wide based stance and gait characterized by
    staggering and impaired tandem walking.
  • - Truncal instability -falls in any directions.
  • - Titubation or truncal ataxia suggest midline
    cerebella lesion

9
  • cerebellar dysarthria
  • abnormality in articulation and prosody
  • described as scanning, slurring, staccato,
    explosive, hesistant, garbled.
  • Tremor
  • specially lesion of dentate nucleus gives
    kinetic (intention) tremor. because intrupt
    rubro-olivo-cerebellar circuit
  • static (postral) tremor also may ccur.
  • Nystagmus
  • frequently
  • gaze evoked, upbeat, rebound nystagmus

10
  • Nonmotor manifestations.
  • cerebellar cognitive affective syndrome-
    characterized by impaired executive functioning,
    personality changes associated with blunted
    affect or disinherited and inappropriate behavior
    , visuospatial disorganization, impaired
    visual-spatial memory, mild anomia, agrammatism
    and dysprosodia
  • macrographia

11
  • Rostral vermis syndrome
  • - Wide based stance and gait
  • - ataxia of gait- little ataxia on heel to shin
    manuever
  • - Normal or only slightly impaired arm
    coordination
  • - Infrequent presence of hypotonia, nustagmus,
    and dysarthria.
  • in chronic alcoholic patients.
  • - remarkable purikinje cell loss
  • caudal vermis syndrome
  • - axial disequilibrium and staggering gait,
  • - little or no limb ataxia,
  • - spontaneous nystagmus and rotated postures or
    head.
  • - seen in damage of flocculondular lobe
    especially medulloblastoma in children as it
    grows superimposed neocerebellum
  • cerbellar hemispheric syndrome
  • - typically incoordination of ipsilateral
    appendicular movements.
  • - affects muscles involved in speech and finger
    movements etiologies- in farcts, neoplasm and
    abscess
  • pancerbellar syndrome
  • - combination of all other cerebellar syndromes
  • - characterized by bilateral signs of cerebellar
    dysfunction affecting the trunck, limbs, and
    cranial musculature.
  • etilogy - ifections, parainfections, hypogycemia,
    hyperthermia, paraneoplastic disorders, toxic
    metabolic disorder.

12
  • APPROACH TO PATIENTS WITH ATAXIC DISORDERS
  • Careful Hx/P/E accurate Dx and appropriate Mx
  • Age of onset
  • Tempo of progression,associated neurologic and
    systemic signs
  • Family Hx,ethinic origin, country
  • True cerebellar ataxia Vs ataxia associated with
    vestibular or labyrinthine disease- associated
    with dizziness or vertigo , sensory disturbance
    (Roberg sign)
  • Rate and pattern of development of cerebellar
    symptoms help to narrow ddx
  • Gradual, progressive, bilateral, symmetric -
    Biochemical, metabolic, immune, or toxic
    etiology.
  • Focal, unilateral Sx with headache and impaired
    level of consciousness with ipisilateral cranial
    nerve palsy and cotralateral weakness imply a
    space-occupying cerebellar lesion.

13
  • symmetric ataxia
  • progressive, symmetiric reclassified with respect
    to onset as acute (over hours or days) subacute
    (weeks or months) or chronic (months of yrs.)
  • acute /Reversible ataxia intoxication with
    alcohol, phenytoin, lithium, barbiturates.
  • subacute degeneration of cerebellar vermis due
    to combined effect of alcoholism and
    malnutrition. deficiency of B1 and B12 vitamins,
    hyponatremia ,paraneoplastic, CJD,
  • Chronic symmetric inherited ataxia metabolic
    disorder hypothyroidism, chronic infections
    meningovascular syphilis

14
  • Focal ataxia
  • acute focal- ischemic infarction, cerebellar
    hemorrhage
  • - ipsilateral to the injury
  • - may be associated with impaired level of
    consciousness due to BS compression or ? ICP
  • ipsilateral pontine sugns (CN, VI and VII palsy)
  • - posterior fossa subdural hematoma, bacterial
    abcess, primary or metastatic cerebellar tumor.
  • - CT or MRI
  • - most true neurologic emergencies / sudden
    herniation
  • - acute surgical decompression may be required
  • - acute or subacute focal cerebellar syndrome in
    AIDS are lymphoma or PML.
  • - chronic focal - MS, Chiari malfo, congenital
    cyst of posterior fossa (Dandy -Walker syndrome)

15
Symmetric and Progressive Signs
Focal and Ipsilateral Cerebellar Signs
16
  • INVESTIGATION
  • CBC
  • ESR,U/A,CXR,
  • CSF-
  • protein,VDRL,oligoclonal,PCR,cultu
    re,cytology,
  • Serology-HIV,toxo,AntiYo,Ri,Hu,GAD,gladi
    an
  • ChemistryOFT,TFT,Parathyroid,RB
    S,electrolyte,Vitamins,special test
  • Toxicology-matals,drugs(blood,urine)
  • ECG,ECHO,NCS
  • IMAGING-CT,MRI,U/S,
  • Genetics

17
  • CEREBELLAR ATAXIAS
  • result of insult to the cerebellum and its
    connecting pathways.
  • - Acquired, Inherited, Sporadic ataxia
  • Acquired ataxias
  • - In many progressive ataxia result from
    environmental insults
  • Hypothyroidism - occasionally -mild gait ataxia
    in conjunction with
  • - its systemic symptoms
  • - TFT needed in patient with progressive ataxia
  • Dx - clinical TFT
  • Rx replacement
  • Hypoparathyroidism
  • Hypoglycemia
  • Hypoxia damages Purkinje cells-ataxi ,myoclonus
    may result
  • Hyperthermia damage purknije cells
  • Hyperammonia in child
  • Wilsons dx-tremor,dystonia Rx is copper
    restriction ,chelation

18
  • Toxic
  • Alcohol-
  • -The major exogenous agent causing ataxia
    significant proportion f alcoholics have midline
    cerebellar degeneration at autopsy.
  • - characterized by progressive gait disturbance
    of a cerebellar type with little in the way of
    upper limb ataxia, speech difficulties, or eye
    movements abnormalities (relative sparing of
    cerebellar hemispheres
  • - Imaging- typical vermial atrophy.
  • -Chronic alcoholism - significant cerebellar
    atrophy (1 severe alcoholics)

19
  • Chemotherapy
  • - Adverse effect of 5- FU (used in breast and GI
    cancer)
  • - Conventional dose of 5-FV may cause cerebellar
    ataxia if there is an abnormality of pyrimidine
    dehydrogenase deficiency.
  • - Higher dose 5-FU - pancerebellar syndrome
    (acute or sub acute coarse)
  • - cytosine arabinoside in high dose ( 3 gm/m2
    for 8-12 doses- conventional dose 1000-2000 mg/m2
    for 5-7 days) significant pts develop cerebellar
    syndrome. Pathologically characterized by loss of
    Purkinje cells, gliosis , loss of dentate
    neurons, and spongiform changes.

20
  • Metals
  • Organic mercury contamination from mercury
    -containg fungicides.
  • - Mercury toxic cerebellar granule cells and
    visual cortex.
  • - causes parasthesia, ataxia, restricted visual
    field.
  • Manganese- Parkinson ataxia
  • Bismuth- gait ataxia, confusion. mycoclonus
  • Solvents
  • - chronic solvents abuse (esp. toluene)
  • - spray paint
  • - paint thinners
  •  

21
  • Anticonvulsants
  • - Issue of cerebellar atrophy and anticonvulsant
    (phenytoin) is controversial.
  • - Transient cerebellar signs in supratherapetic
    dose many anticonvulsants seen.
  • - Persistent ataxia and purkinje cell loss seen
    prolonged phenytoin use
  • - Pathogenesis is unclear - Hypothesis direct
    toxic effect of phenytoin, a result of repeated
    hypoxia related seizures, the effect of seizure
    related electrical discharge on cerebellar
    Purkinje cells.
  • - avoid phenytoin in an epileptic patient if
    ataxia /cerebellar atrophy present.

22
  • Infections
  • may be feature of post infectious
    encephalomyelitis but usually accompanies more
    diffuse cerebral process.
  • In children restricted cerebellar syndromes seen
    when acute ataxic disorder that is not associated
    with a more diffuse process reflected by
    seizures, meningismus or obtundation.
  • In most children preceded by a non specific
    viral syndrome or varicella-peak incidence 5-6yr.
  • similar picture from EBV in teenage years.
  • Dx CSF protein elevation and modest mononuclear
    pleocytosis and MRI -signal density changes in
    the cerebellum.
  • Px - excellent.
  • Brain stem encephalitis - ataxia ophtalmoplegia
    and other lower cranial nerve palsies- resemble
    MFS of GBS

23
  • HIV
  • - Many neurologic syndrome - ataxia
  • - Most pts have focal lesions, like lymphoma,
    chronic meningeal infection, PML or
    toxoplasmosis.
  • - 30 ADC - have ataxia prior dementia
  • - MRI - cerebellar atrophy
  • - Pathology - marked granule cell loss.

24
  • CJD
  • - progressive ataxia.
  • Rapidly progressive dementing illness.
  • - Due to accumulation of mutant prion protein
    (result from post translational modification of
    normal prion protein)
  • Among CJD - 17 early ataxia 60 cerebellar
    pathology at autopsy.
  • Upper motor neuron signs are common,
  • - myclonus -25 and dementia evolves late.
  • - Survival 7wk - 8 years
  • - Pathological- cerebellum shows striking granule
    cell loss
  • - Dx - protein 14-3-3 in CSF and coden 29
    homozygosisty tall-by ELISA

25
  • Autoimmune causes of ataxia
  • Paraneoplastic cerebellar degeneration syndrome
  • that reaches its nadir with in a few months of
    onset.
  • Produces severe ataxia wit dysarthria and
    oscillopsia, diplopia, vertigo other neurologic
    sn-dementia, extra pyramidal signs, hearing loss,
    dysphagia.
  • MRI- typically-cerebellar atrophy and high
    density signal in deep white matter.
  • CSF- mononuclear pleocytosis and oligoclonal
    bands.
  • The syndrome results from autoimmune process
    triggered by the cancer.
  • Anti Yo in ovarian ca
  • Anti-Hu. Ab. in SCLC.
  • Purkinjec cell degeneration in 25 with
    Anti.Hu.Ab.
  • Anti Ri Ab - truncal ataxia and opsoclonus in
    breast cancer.

26
  • Ataxia with Gluten Sensitivity
  • Seen as neurological complication in celiac
    disease 68 had antigliadin Ab.
  • Slowly progressing ataxia associated with brisk
    tendon reflexes, peripheral neuropathy, cognitive
    changes, mycolonus.
  • Pathology - cerebellar Purkinje cell loss,
    infiltration by Tcell lymphocyte, posterior
    column degeneration
  • Variable proportion show celiac sprue on
    duodenal Bx.
  • Whether gluten -free diet or other
    immunomodulation will improve gliadin Ab-
    associated ataxia is unclear.

27
  • Ataxia and antiglutamate decarboxylase
    antibodies.
  • - Recently reported Anti GAD in progressive
    ataxia.
  • - Usually middle aged women - associated with
    peripheral neuropathy, slow saccades, stiff-
    person syndrome.
  • - Many pts had multiple organ specific Ab
    including Ab to thyroid cell, pancreatic islet
    cell,
  • Abs are seen in higher titers in adult onset
    diabetes and cerebellar purkinje cells.
  • Nutritional vit E deficiency
  • Rare
  • In some lipid malabsorption eg. In cystic
    fibrosis,cholestatic dx
  • Demyelinating (ms)
  • - clinical feature other CNS involvement CSF
    findings

28
  • Vascular
  • Lesions cerebellum or pathways
  • Infarction - thrombotic or embolic occlusion of
    cerbellar vessels
  • clinical manifestation depends on specific
    vessels involved and extent of collateral
    circulation
  • main symptoms vertigo dizziness, nausea,
    vomitting gait unsteadiness, limb clumsiness,
    headache dysarthria, diplopia and decreased
    alertness, nystagmus.
  • 2 clinical syndromes - cerebellar infarcts with
    fourth ventricular and brainstem compression and
    those without.
  • Large cerebellar infarcts - cause brainstem
    compression with onset of occipital headache,
    vertigo, nausea, vomiting gait, and dysarthria
    impaired consciousness. Obstructive
    hydrocephalus, upward or down ward hernia tion.
  • small (border zone) infarcts specific boundaries
    causes cardiac arrest4 atheroma or
    hypercoagulable 20 focal cerebellar hypo
    perfusion occlusion of vertebrobasilar occlusive
    disease (34), brain embolism (23)

29
  • Mass lesions
  • Most common is hemorrhage near dentate nucleus in
    HTN,edema in large infarct, tumors in
    children-medduloblastoma, astrocytoma, ependymoma
    and
  • Adults,-Metastasis of tumor, hemangioblastoma,
    abscess, tuberculomas,other granulomas,
    toxoplasmosis
  • Cerebellar hemorrhages with headache,nausae,vomitt
    ing,gait ataxia,vertigo are common but variable.
  • are emergency devastating.
  • Abscesses
  • notorious for paucity and variability of
    signs,may present with headache alone
  • infections are in or near adjacent
    structures(OM,mastoditis)
  • Hydrocephalus

30
  • INHERITED ATAXIAS
  • Autosomal dominant, autosomal recessive or
    maternal (mitochondrial) modes
  • Genomic classification superseded the previous
    clinical expression based
  • Even though cerebellar manifestations dominate,
    changes may occur in BS, SC, optic nerves, retina
    and peripheral nerves.
  • So manifestations range from purely cerebellar
    to mixed syndromes of these structural
    abnormalities. Rarely dementia.
  • Homogenous in dominantly inherited family but
    different phenotypes may occur

31
  • Autosomal Dominant Ataxia
  • - Onset usually in 3rd - 5th decade but variable
    onset of age.
  • - Disease occurs in each generation of the
    pedigree, the offspring of affected parents 50
    risk.
  • - The progressive dominant ataxias are labeled
    SCA, followed by a number to denote the
    chromosomal locus.
  • Some differently named are MJD(SCA3), DRPLA
    (Dentatorubropallidolusysian atrophy),Episodic
    ataxias (EA1, and EA2)
  • - Absence of Sx in either parents is rare.
  • But possible because early onset in child and
    late in parent, death of parent early, wrong
    paternity.

32
  • Clinical Features of Dominant Ataxia
  • Overall have overlapping clinical features.
  • Genetic study is gold standard for Dx
    classification
  • - Gradually progressive ataxia associated with an
    array of cerebellar signs forms the core features
    of the Dx.
  • - ataxic gait, dysmetria, dysdiadokinesia,
    dysarhria, abnormal persuit and inaccurate
    saccades of the eyes, nystagmus.
  • - Many, not all Dx are associated with clinical
    signs referable to pathology in CNS structures.
  • - Occulomotor abnormality - ptosis, gaze palsy,
    blepharospasm
  • - some- bulbar deficts- facial atrophy, facial
    fasciculation, toungue atrophy and fasciculation,
    unable to cough.
  • - UMN sign - DTR, spasticity, Babniski sign
  • - Extrapyramidal sign- akinetic rigidity, chorea,
    athetosis, dystonia
  • - PN- distal sensory loss and DTR , amyotrophy
  • - In some cognitive decline and seizure, retinal
    disease and visual loss.
  • - loss of ambulation over 10-15 yrs.

33
  • Imaging and other lab studies in dominat Ataxia
  • MRI/CT - to exclude many disorders causing
    ataxia - stroke, tumors, ms
  • atrophy of cerebellum, /- atrophy of pons,
    medulla, middle cerebellar peduncles, and upper
    cervical cord.
  • Hyperintensity of middle cerebellar atrophy and
    SCA6 isolated cerebellar atrophy
  • NCS -axonal polyneuropathy

34
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35
  • Neuropathology SCA1, SCA2, SCA7 wide spread
    pathology loss of Purkinje cells pontine neurons,
    olivary neruons.
  • /- dorsal root ganglion cell, cranial and LMN
    and tracts may be affected.
  • Both unstable expansions of repeated nucleotide
    sequences and point mutations seen (CAG repeats
    inherited in heterozygous fashion)
  • CAG encodes for glutamine - polyglutamine protein

36
  • Pathogenesis.
  • CAG repeats - polyglutamine disorders (ataxin
    proteins)
  • Nuclear accumulation of these proteins (normally
    in cytoplasm)
  • Ataxins with gt40 glutamines toxic to the neurons.
  • Ataxin1,2,3,7,atrophin
  • EA1 potassium channel gene mutation on chromsome
    12
  • EA2-calcium channel mutaton on chromosmome 19
  • In some chromosomes or the loci not known

37
  • Autosomal Recessive Ataxia
  • Most common form of inherited ataxia (50)
  • Most of disease begin in childhood or early
    adult life.
  • Late onset possible
  • Singleton pt- may occur in families.
  • Typically parents don't manifest any Sx because
    they are heterozygous for mutation.
  • Affects both males and females.

38
  • Some of autosomal recessive ataxia
  • Frederichs ataxia
  • Ataxia telangectasia
  • Ataxia with isolated vit E deficiency
  • Abetalipoproteinemia
  • ARA of Charlovox-Sanguenay

39
  • Friendreich's Ataxia
  • Clinicla Features prevalence 2/100,000 .
  • Age of onset lt25 yr. typically early adolescent.
  • Onset ?ing gait difficulty, gait ataxia, loss of
    proprioceptive sense in lower limbs, absent DTR
    (generalized or lower limb) because early
    involvement of dorsal root ganglion cell,
    dysarthria, UMN sign.
  • Pts loose ambulation by 9-15 yrs after onset.
    (at this stage increasing ataxia in both upper
    and lower extremities profound proprioceptive
    loss, areflexia, weakness of lower limb muscles,
    dystonia ,flexor spasm and increasing dysarthria,
    dysphagia. Optic athrophy, hearing loss in many

40
  • ECG abnormality and HCMP- 50 pts,
  • Diabetis (10-20)- insulin resistance and B cell
    dysfunction,
  • skeletal and spinal deformity common. pescavus,
    pes equinovarus, scoliosis
  • Mean age at death 4th decade (cause- cardiac/
    respiratory)
  • NCS early absence or reduction of sensory nerve
    potentials in diffuse fashion reflecting loss of
    large sensory axons of PN
  • Sural nerve Bx loss of myelinated fibers.
  • MRI upper cervical spinal cord atrophy nonmal
    cerebellum
  • Pathology- loss of Dorsal root ganglion cell,
  • - degeneration of dorsal
    column,
  • -degeneration of
    spinocerebellar and corticospinal tracts,
  • -loss of dentate nuclei in
    cerebellum.

41
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42
  • Mutation in FA is unstable expansion of a
    repeated trinucleotide(GAA) sequence within the
    first intron of the gene X25 on chromosome 9
  • or point mutation of the gene (5 heterozygous)
  • Pathogenesis
  • presence expanded GAA sequence-
    reduced transcription and translational
    efficiency leading to partial deficiency of the
    protein frataxin.
  • the exact function of ftataxin not clear- is
    mitochondrial iron availability heme synthesis.

43
  • Ataxia Telangiectasia
  • 3 in million frequency
  • Sx/Sn- Present in the first decade of life with
    progressive telangiectatic lesions associated
    with deficits in cerebellar function and
    nystagmus
  • neurologic manifestations correspond to FA so
    ddx.
  • High incidence of pulmonary infections and
    lymphatic and RES neoplasms.
  • Thymic hypoplasia (Cellular and humoral
    immunodefinciency)
  • Premature aging, endocrine disorders type 1 Dm.
  • Increased incidence of lymphomas, HD ,acute
    leukemias of T-cells, and breast cancer.
  • Most striking neurologic change - loss of
    purkingje, granule and basket cells in the cortex
    and neurons in the deep cerebellar nuclei,
    neuronal loss in olive, loss of anterior horn
    cells, dorsal root ganglion.
  • Gene- ATM gene mutation product protein may
    result in DNA damage

44
  • Mitochondrial Ataxias.
  • Each mitochondrion contains several copies of
    circular chromosomes
  • mtDNA small and encodes 13 proteins component
    of respiratory chain in oxidative
    phosphorylation ATP generation
  • Mt genome inherited maternally
  • 30 pathogenic mtDNA point mutations and 60
    different types of mtDNA deletions are known,
    several of which cause or are associated with
    ataxia
  • Alterations result in reduction in ATP
    supply,free radical production,apoptosis
  • Clinical spectrum involves cardiomyophathy and
    enchephalopathy

45
  • Sporadic/ Idiopathic Ataxia
  • No primary cause known or no gene identified
  • Progressive cerebellar ataxia resemble IA
  • Etiopathogenesis not well known
  • Dx is by exclusion of other genetic or acquired
    ataxias
  • Eg.sporadic cortical cerebellar atrophy
  • spradic ataxia with added noncerebellar
  • deficits

46
  • Treatments
  • Most important goal in management of Pts with
    ataxia is to identify treatable disease entities
  • Mass lesions should be ruled out and treated
    appropriately.
  • Paraneoplastic disorders can often be identified
    by the clinical patterns of the disease that they
    produce ,measurements of specific autoantibody
    and uncovering the primary cancer. (Usually
    refractory but some may respond to tumor removal
    or chemotherapy)
  • A number of single case reports improvement after
    tumor removal, plasma exchange, IVIG,
    cyclophosphamide or glucocoticoids.

47
  • Avoid phenytoin and alcohol.
  • No proven therapy for autosomal dominant ataxia
  • (SCA1 - 22 ) - Preliminary evidences that
    idebenone a free radical scavenger, can improve
    myocardial hypertrophy in pts with classic FA.
    (Not known whether improves neuropathy)
  • Anticholinergic,serotoninergics,GABAergic tried
    but not effective
  • Acetazolamide - reduce the duration of Sx of
    episodic ataxia
  • Identifying at risk person's genotype together
    with appropriate family and genetic counseling
    can reduce the incidence of these cerebellar
    syndromes in future generations.
  • Supportive care of patients with FA include
    adequate rehabilitation efforts aimed at mobility
    using appropriate device and Monitoring and
    caring of the systemic complications are also
    important. (Skeletal deformty, cardiomyopathy,
    and dialetes)

48
  • Avoid Exposure to metals or chemotherapy
  • Gluten free diet
  • Vit E therapy.
  • Vit B1 and Vit B12 Supplementation in
    deficiencies
  • Replace hypothyroidism.
  • CSF VDRL (CNS syphilis) Rx
  • Ab titer to Leigionella and Lyme- appropriate
    Antibiotics
  • Surgery-thalamic stimulation for tremer and brain
    tumor
  • chemotherapy and radiation for other neoplasms
  • Chelating agents,hemodialysis

49
  • THANK YOU!!
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