1. Neuroscience Lectures�Child Neurology November 12, 2009
Gail I. Schuman, DO
Department of Neurology
2. Objectives Know normal development
Learn about Neural Tube Defects and associated conditions
Learn about some common conditions that can lead to abnormal development:
before birth
at birth
due to genetic/metabolic abnormalities
3. Initial Development The part that is important for neural development is the ectoderm
All neural tissue arises from the ectoderm
Process is very complex
4. Neural Tube Formation Gastrulation
Formation of 3 primary germ layers needed for induction (ecto-, endo- mesoderm)
Primary Neurulation
Formation of Brain and Spinal Cord
Secondary Neurulation
Formation of Lower Sacral Segments of the Spinal Cord
5. Gastrulation Formation of primary germ layers needed for the inductive processes to follow
Formation of neural tube
at 3rd and 4th weeks of gestation
6. Gastrulation Induction of neural plate by notochord
Folding into neural tube
Joining of edges
Neural tube is ectoderm
Neural crest cells form dorsal root ganglia
Neural tube forms nervous system
7. Primary Neurulation First fusion of neural fold occurs at the level of the medulla (upper cervical region) at about 22 days so the tube fusion doesnt occur all along the tube all at once
Closure proceeds both rostrally and caudally
Anterior end closes at about 24 days
Caudal end closes at about 26 days
Lower end closure is at the lumbosacral level, more caudal cord segments are formed during secondary neurulation
8. Primary Neurulation Process is dependent on a variety of cellular and molecular and signaling mechanisms
Most important cellular mechanisms involve the function of the cytoskeletal network of microtubules and microfilaments - movement
Microtubules are involved in development of neural plate
Microfilaments lead to formation of neural folds and then the neural tube
Molecular mechanisms involve cell-cell recognition and adhesive interactions
9. PROLIFERATIVE ZONE Ventricular or Proliferative zone starts as a single layer of ectodermal cells that lines the inner margin of the neural tube.
Proliferative zone begins to divide at Embryonic Day (ED) 28.
Both neurons and glial cells are produced in the proliferative zone.
10. Proliferative Zone This development of zones occurs along the length of the neural tube
Different parts of the neural tube will form different parts of the nervous system
Upper level brain
Lower level spinal cord
11. PROLIFERATIVE ZONE�- symmetric division - Symmetric division = each cell gives rise to two identical daughter cells.
Each round of mitosis doubles the number of cells in the proliferative zone.
ED 28 ED 42 (a 2 week time period!!)
Cells produced during this period are called progenitor cells.
Progenitor cells are multipotent cells that give rise to both neuronal and glial lineages.
12. PROLIFERATIVE ZONE�- asymmetric division - Asymmetric division = each cell gives rise to one identical daughter cell and one more differentiated (committed) cell.
Begins after ED 42
Committed cells migrate away from the proliferative zone.
13. PROLIFERATION Most neurons are produced in the first half of the pregnancy between Embryonic Day (ED) 42 and 125
Within a region most neurons are produced before most glial cells
Without cell signaling causing inhibitory signals, all the cells would become neurons
14. A SINGLE CELL UNDERGOING DIVISION Interactions between adjacent cells direct what type of neuronal cell will be formed
Asymmetric division of cells occurs
Cells divide to become two identical cells (glia) or two different cells (one glia, one neuron)
15. BIRTHDAY OF A NEURON Cell birthday is a day on which an individual cell stops dividing and migrates out of the proliferative zone.
On its birthday the cell is considered to be a Primitive Neuron.
16. MIGRATION The Primitive Neuron moves out of the proliferative zone, but only for a small distance.
It is pushed out by newly born neurons.
So, the earliest formed neurons are furthest from the proliferative zone.
17. JOURNEY THROUGH RADIAL GLIA Radial glia form a scaffold that extends from the proliferative zone to the outer edges of the brain.
When primitive neuron is pushed by newly born neurons, it attaches to the radial glia and propels itself along.
It recognizes its final destination and detaches from radial glia.
19. What happens when things go wrong?
20. Primary Neurulation Disorders Craniorachischisis - total failure of neurulation
Anencephaly - failure of anterior tube closure
Myeloschisis - failure of posterior tube closure
Encephalocele - restricted disorder of neurulation involving anterior tube closure
Myelomeningocele - Restricted failure of posterior tube closure
21. Neural Tube Defects Epidemiology
Incidence 3-6/10000 in US decreasing due to folate supplementation as preventative measure
F>M
Whites > Blacks, Asians
Higher incidence in poorer socioeconomic class
Genetics
Familial tendency, non-Mendelian, multiple genes involved.
Risk of one child with spina bifida is 0.05%. If one sibling is affected, risk increases to 5%, if two sibs affected, risk rises to 12-15%
22. Anencephaly Complete failure of anterior closure
Worst case is level of Foramen Magnum up (holoanencephaly)
If not to foramen magnum then called meroanencephaly
Usually involves forebrain & part of brainstem
23. Anencephaly Exposed neural tissue is a hemorrhagic, fibrotic, degenerated mass of neurons and glia
No defined structure
Frontal bones, parietal bones and squamous part of occipital bones are usually absent
Gives patient a frog-like appearance when viewed from the front
Timing onset is no later than 24 days gestation
Associated with polyhydramnios in mother
24. Anencephaly 75% are stillborn, remainder die as neonates, 60% die by 24 hrs, 85% dead at 48 hrs, 98% at 7 days, nearly all by 14 days
More common in whites than blacks, in Irish more than any other ethnic group
Most often female (F:M = 37:1)
More common in very young mother or very old mother
0.2 per 1000 in US
25. Encephalocele Restricted/Partial failure of anterior tube closure
Pathogenesis unknown
Occipital region 70-80% of cases
Occasionally frontal with protrusion into nasal cavity
Protruding brain tissue is usually from occipital lobe with normal gyri and subcortical white matter (i.e., brain tissue is normal)
50% of cases have associated hydrocephalus
26. Encephalocele Onset no later than 26 days GA
Later onset causes cases involving overlying meninges or skull
Associated with subependymal nodular heterotopia
1/5000 live births worldwide
60-70% require shunts for hydrocephalus
27. Partial Failure of �Anterior Closure
28. Myelomeningocele Restricted failure of posterior tube closure
80% of lesions occur in lumbar region, the last area to close
Many associated with dorsal displacement of neural tissue creating a sac on the back
Onset no later than 26 days
Most survive, highest incidence in Ireland and Great Britain
Herniation of meningeal tissue and nervous tissue through defect in skull or spine
29. Myelomeningocele Neurological function disturbances depends on level of the lesion
Important to examine motor, sensory and sphincter function
Lesions below S1 - walk unaided
Lesions above L2 - wheelchair dependent, and develop significant scoliosis
L3 ambulatory with aids
L4/L5 - ambulatory
30. Myelomeningocele
31. Myelomeningocele - Hydrocephalus Hydrocephalus can be present in 80% by 2-3 weeks - examine fontanel and cranial sutures
Pulls cord downward and blocks CSF flow, compression of ventricular and ductal system
Monitor head circumference:
HC > 90%ile then 95% chance
HC < 90%ile then 65% chance
The lower the lesion, the more chance of hydrocephalus more traction on cord
Dx: serial CT or US
32. Myelomeningocele �- Arnold-Chiari Malformation When myelomeningocele is below thoracic level
Inferior displacement of medulla and fourth ventricle, elongation and thinning of upper medulla, lower pons with persistence of embryonic flexure, inferior displacement of lower cerebellum through foramen, bony defects
Associated with syrinx in cervical spinal cord
33. Myelomeningocele - Encephalocele Treatment Careful consideration of delivery of infant by cesarean section
Human fetal surgery - lower rate of needing VP shunt later
Early closure of back lesion if feasible
Prevention of infection
VP Shunt for Hydrocephalus - earlier surgery improves cognitive function of infant
Decompressive upper cervical laminectomy for Arnold-Chiari malformation
34. Etiology Multifactorial inheritance
Single mutant genes - e.g., Meckel Syndrome (Chrom 17, MKS1, large dysplastic kidneys, occipital encephalocele, polydactyly)
Chromosomal abnormalities - e.g., trisomies
Rare syndromes with unknown transmission
Specific teratogens (valproate, thalidomide)
Phenotypes of unknown cause - cloacal extrophy, myelocystocele
Increased occurrence in sibs with one affected sib
35. Prevention - Prenatal Diagnosis Increased levels of alpha - fetoprotein in maternal serum
Optimum test time at 16 - 18 weeks of gestation
Also can use ultrasound for prenatal diagnosis
Prevention by vitamin and folate supplementation - lack of folate causes increase in homocysteine which has been shown to cause neural tube defects in avian embryos
36. Occult Dysraphic States Disorders of Secondary Neurulation in development of lower sacral and coccygeal segments
Incorporation of mesodermal and/or epithelial elements or incomplete fusion of elements
They will have a covering of intact skin and are lower on the back (skin cover is already formed)
Timing is 4th to 6th week of gestation
37. Spina Bifida - Comparison
38. Spina Bifida
39. Spina Bifida
40. Intrauterine Infections
41. TORCH(S) Infections Organism Route Time Symptoms
Symp Asymp
Toxoplasmosis Transplacental T1, T2 + ++++
Syphilis Transplacental T2, T3 + ++++
HIV Transplacental T2-T3, birth + ++++
Parturitional
Rubella Transplacental T1 ++ +++
CMV Transplacental T1, T2 + ++++
Herpes simplex Ascending Birth ++++ +
Parturitional
42. Common outcomes of TORCH infections Microcephaly
MR (IQ<50) Abnormal Brain Development
Cerebral Palsy
Seizures
Sensorineural hearing loss
Ocular pathology (cataracts, chorioretinitis)
Always ask about febrile illness during pregnancy, flu-like illness, even any minor illness
43. TORCH infections �- unique features - CMV: Periventricular calcifications
Cerebellar hypoplasia 33%
Migrational disorders
Polymicrogyria 33%
Lissencephaly 7%
Schizencephaly
Toxoplasma: Granulomatosis
Diffuse cerebral calcifications
Hydrocephalus
44. Congenital CMV infection �- periventricular calcifications + cerebellar hypoplasia
45. Toxoplasmosis Can present with lymphadenopathy and mild flu-like symptoms in mother
Hard to determine if this CT is CMV or Toxo both types of calcifications are present
46. TORCH infections �- unique features - Rubella: Vasculopathy with focal ischemic necrosis
Delayed myelination
Chorioretinitis (Toxo also can have)
Meningoencephalitis
Hearing loss
Herpes: Multifocal parenchymal necrosis
hemorrhagic
Multicystic encephalomalacia
47. Chorioretinitis
48. Herpes simplex:� multicystic encephalomalacia 2/1000 mothers HSV+
Most babies are born asymptomatic
Irritable, poor feeding, bulging fontanels, temp instability, fever
Only some will have vesicular rash
49. What happens when things go wrong?
50. Neonatal Neurology Intraventricular hemorrhage
Hypoxic-Ischemic encephalopathy
Periventricular Leukomalacia
51. INTRAVENTRICULAR HEMORRHAGE Bleeding of Germinal Matrix around frontal horns of ventricles
Can bleed within the germinal matrix (subependymal hemorrhage Grade I)
Can bleed into the ventricles as well (intraventricular hemorrhage Grades II & III)
Can also bleed into parenchyma and ventricles (Grade IV)
Primarily occurs in premature babies
52. Germinal Matrix and Zones�Fetal MRI at 23 weeks GA Arrowhead germinal matrix
Single arrow ventricular or proliferative zone
Dbl arrow subventricular or intermediate zone
Dbl arrowhead subplate
Triple arrow developing cortex or marginal zone
53. Germinal matrix size Size Gestational age
2.5mm 23-24 weeks
1.4mm 32 weeks
0.0mm 36 weeks
We now know that there is persistent stem cell development in both the brain and the spinal cord
54. Ventricular System Blood can move through the ventricular system
As blood clots it will block the free flow of CSF usually within the ventricle where bleeding took place
Gravity will make blood accumulate in back of head also (babies are lying down)
55. Neuropathological consequences Germinal matrix destruction loss of stem cells for neuronal/glial development
Depending on timing of IVH usually glial cells are more affected (remember neurons are made first and early)
Periventricular white matter changes
hemorrhagic infarction (PVHI)
leukomalacia (PVL)
Posthemorrhagic hydrocephalus
56. Intraventricular Hemorrhage Left Grade II no change in size of ventricle, confined to ventricle
Right Grade IV ventricle nearly obliterated, bleed into brain parenchyma
57. Hydrocephalus after IVH Occurs 1-3 weeks after IVH
Rapidity of evolution directly correlates with severity of hemorrhage
Clinically - rapid head growth
- signs of increased ICP
CT head anterior horns dilate before and more severely than posterior horns
May require ventriculo-peritoneal shunting
58. Hydrocephalus Originally a right sided IVH resulting in right sided hydrocephalus
Left sided symptoms in child
Spastic hemiparesis
Focal seizures
59. Break Time!!
60. HYPOXIC-ISCHEMIC�ENCEPHALOPATHY Loss of oxygen (hypoxia) to the brain for prolonged amount of time
Long enough to cause a stroke (ischemia)
Diffuse process as opposed to a stroke in an elderly person which is a focal process
61. Causes of Drop in Oxygenation Maternal shock
hypoxia
placental thrombophlebitis (blocks flow)
abdominal trauma
hypo/hypertension
Fetal infection (arteritis, hypotension)
hydrops fetalis compression of heart
fetal embolism (placenta, other sources)
fetofetal transfusion
Placental premature placental separation
excessive placental infarction
62. Clinical features Stupor or Lethargy
Hypotonia (Floppy) > hypertonia
Weakness
Abnormal sucking, swallowing and gag, poor feeding
Seizures
63. Hypoxic Ischemic Event Loss of oxygen causes neuronal tissue damage
Cystic lesions where neurons are lost diffuse all over
High signal in thalami indicative of loss of oxygen
64. Periventricular Leukomalacia Damage to the white matter around ventricles
Location and extent of damage will define the disability of the patient
65. Cerebral Palsy
66. What happens when things go wrong?
67. Genetic Disorders
68. Metabolic disorders Mainly Autosomal Recessive
Defects in Amino Acid, lipid or protein metabolism
- mostly do not affect brain size
Storage diseases
- may cause macrocephaly
69. Urea Cycle Disorders Deficiency in pathways responsible for urea synthesis
Multiple possible defects (5 enzymes in pathway)
Most have increased ammonia levels which cause symptoms
All are autosomal recessive except Ornithine Transcarbamylase (OTC) which is X-linked
70. CPS1 Carbamyl Phosphate Synthetase
Arginase deficiency does not cause symptoms in the newborn
1/30,000 birthsCPS1 Carbamyl Phosphate Synthetase
Arginase deficiency does not cause symptoms in the newborn
1/30,000 births
71. Ornithine Transcarbamylase (OTC) Deficiency Urea Cycle deficiencies have an incidence of 1/30,000
Age of onset of OTC Deficiency:
newborn (males); childhood (females)
X-linked recessive
- M > F
72. OTC Deficiency �Homozygote Males Usually normal at birth with onset of symptoms 24-72 hours after feeding (protein load)
1. Neurological Manifestations
lethargy -> coma
infantile hypotonia
neonatal seizures
2. Gastrointestinal Manifestations
persistent vomiting (+/- dehydration)
poor feeding
hepatomegaly
3. Others
hyperventilation (due to a respiratory alkalosis)
hypothermia
73. OTC Deficiency � Heterozygote Females In 10% of heterozygote females, onset of symptoms in childhood characterized by recurrent episodes of:
1. Neurological Manifestations
lethargy -> coma
acute ataxia
hyperactivity
migraine-like headaches
2. Gastrointestinal Manifestations
persistent vomiting (+/- dehydration)
hepatomegaly
triggered by sudden protein loads or intercurrent infection
74. OTC - Diagnosis 1. Serum
hyperammonemia >500 mM homozygotes
>100 mM heterozygotes
normal anion gap; respiratory alkalosis
amino acids
low citrulline and arginine
elevated glutamine and alanine
2. Urine
high orotic acid
3. Diagnosis
deficiency of OTC activity in liver, duodenal, and rectal tissue samples (but not leukocytes or cultured skin fibroblasts)
75. OTC - Management Diet - Protein Restriction
High Calorie/Protein Restricted Diet
to minimize tissue catabolism and thus the breakdown of endogenous protein, limit nitrogen, supplement arginine
Convert Nitrogen to an Excretable Compound
1. Sodium Benzoate
- conjugates with glycine and excreted as hippuric acid
2. Sodium Phenylacetate
- conjugates with glutamine and excreted as phenylacetyl-glutamine
3. Dialysis
76. OTC - Prognosis 100% mortality if untreated
a direct correlation between the duration of hyperammonemic coma and morbidity (mental retardation, developmental delays, cortical atrophy)
good prognosis if disorder is treated prospectively from birth
77. NEUROCUTANEOUS DISEASES Remember that the nervous system was derived from ectoderm
The skin is also derived from ectoderm
Skin lesions can be indicative of a problem within the nervous system as well
Neurofibromatosis 1&2, Tuberous Sclerosis
78. NEUROFIBROMATOSIS 1 (NF1) Incidence: ~1:3,300 pretty common
Inheritance: Autosomal Dominant
New Mutations: 50%
Penetrance: 100% (variable expressivity)
Gene Defect: Neurofibromin (NF1) on 17q11.2
Pathophysiology: NF1 protein related to ras GTPase downregulates cellular growth & proliferation. LOF leads to loss of this tumor suppressor activity
79. WHO WAS �VON RECKLINGHAUSEN? German physician 1800s
1862- Introduced the term hemochromatosis
1882- Recognized the origin of neurofibromas from peripheral nerves
NF1 is also called Von Recklinghausen disease
80. NEUROFIBROMATOSIS 1 (NF1) NIH criteria for NF1
Caf-au-lait spots, 6 or more
> 5mm in prepubertal child
> 1.5 cm in postpubertal child
Two or more neurofibromas or 1 plexiform neuroma
Axillary or inguinal freckling
Optic Glioma
Lisch Nodules (Iris Hamartomas)
Dysplasia or thinning of long bone cortex
1st degree relative with NF1
81. NEUROFIBROMATOSIS 1 (NF1) Learning Disabilities
ADD (not ADHD)
Performance IQ < Verbal IQ (Mean IQ: 90-95)
Lifetime cancer risk: ~5%
Optic glioma
Pheochromocytoma
Malignant peripheral nerve sheath tumors
Juvenile chronic myelomonocytic leukemia
Rhabdomyosarcoma
Astrocytomas, schwannomas, neuroblastomas
82. NEUROFIBROMATOSIS 1 (NF1)
83. NEUROFIBROMATOSIS 1 (NF1) Prognosis:
Life Expectancy: Reduced by ~15 years
Major Mortality:
Malignant peripheral nerve sheath tumors (1-4% of pts)
Major Morbidity:
Plexiform Neurofibromas (Disfigurement, loss of function)
Optic Pathway Gliomas (Disfigurement, loss of vision, affect chiasm)
84. NEUROFIBROMATOSIS 2 (NF2) Incidence: 1:40,000 much less common
Inheritance: Autosomal Dominant
New Mutations: 50%
Gene Defect: NF2 gene on 22q
Pathophysiology: Protein product, Merlin/Schwannomin, is a tumor suppressor
Onset: 18-24 yo (range 2-70 yo)
Negative MRI at 30 yo essentially excludes NF2
Multiple CNS tumors- rarely malignant
85. NEUROFIBROMATOSIS (NF2) - Diagnostic Criteria� NIH Diagnostic Criteria
B/L vestibular schwannomas (acoustic neuromas) 95%
1st degree relative with NF2 plus unilateral acoustic neuroma before age 30 yrs
Any 2 of: neurofibroma, meningioma, glioma, schwannoma, juvenile posterior subcapsular opacity
No distinct skin lesions, but can have caf-au-lait spots but not diagnostic featureNo distinct skin lesions, but can have caf-au-lait spots but not diagnostic feature
86. NEUROFIBROMATOSIS 2 (NF2) Left bilateral acoustic neuromas
Right - meningioma
87. NEUROFIBROMATOSIS (NF2) Genetic Testing
DNA based testing - Sequencing
65% sensitivity
Linkage (2 or more affected individuals)
Treatment (ENT, NeuroSurg, Neurology)
Supportive/Symptomatic
No disease altering therapy
Acoustic Neuromas:
small (<1.5cm): Surgical excision
large (>1.5 cm): Debulking
88. TUBEROUS SCLEROSIS Incidence: 1:6,000
Inheritance: Autosomal Dominant
New Mutations: 66%
Gene Defect:
TSC 1 (hamartan) on 9q34
TSC2 (tuberin) on 16p13.3
TSC3, TSC4
Pathophysiology: All tumor suppressor genes. LOF leads to loss of tumor suppressor activity
Penetrance: 100% (variable expressivity)
89. TUBEROUS SCLEROSIS Classic triad:
Adenoma Sebaceum (Angiofibroma; 50-80%)
Epilepsy (~75%)
Mental Retardation/Dev. Disability (~50%)
Diagnostic Criteria (1999 NIH Consensus)
Definite TSC: Two major features or one major feature plus two minor features
Probable TSC: One major feature plus one minor feature
Possible TSC: One major feature or two or more minor features
90. Tuberous Sclerosis�Skin Manifestations Ash-Leaf Macules hypopigmented lesions in 87% of pts, congenital
Confetti Macules 1-3mm, hypopigmented, on pretibial area
Shagreen Patches (subepidermal fibrous patches) 1-10cm, flat, flesh-colored plaque, mainly in LS region, with orange-peel appearance
Facial Angiofibromas (adenoma sebaceum) diagnostic of TS, appear between age 4 10 yrs
Koenen tumors on nail plates (ungual fibroma), appear at puberty
91. Tuberous Sclerosis�Diagnostic Criteria Major
Adenoma sebaceum, ungual fibroma, hypomelanotic patches, Shagreen patch, Cortical Tuber, Subependymal Nodule, Subependymal Giant-Cell Astrocytoma, Retinal Hamartomas, Cardiac Rhabdomyoma, Renal Angiomyolipoma, Facial plaques
Minor
Dental pitting, rectal polyps, bone cysts, white matter migration tracts, gingival fibromas, confetti skin lesions, renal cysts
92. TUBEROUS SCLEROSIS Clinical signs of Tuberous Sclerosis
93. TUBEROUS SCLEROSIS Cardiac Rhabdomyoma
50-80% of patients with cardiac rhabdomyoma have TS can be present at birth
Frequently multiple
May cause LV obstruction, arrhythmia, CHF
Regress with age
Epilepsy
Frequently have Infantile Spasms in childhood
20% of patients with Infantile Spasms have TS
Treatment of choice is ACTH or Vigabatrin
Variety of types in adults
94. Tuberous Sclerosis� Cortical Tubers nodules of glial proliferation occurring in cortex, ganglia or ventricle walls
Other CNS tumors
subependymal hamartomas, paraventricular calcifications (Candle Gutterings)
giant cell astrocytomas
95. Tuberous Sclerosis Left Cortical Tubers MRI
Right Paraventricular Calcifications - CT
96. TUBEROUS SCLEROSIS Prognosis
Major mortality is due to uncontrolled Epilepsy & MR
Renal Disease
Tumors
Otherwise may have normal lifespan
97. Leukodystrophies
Diffuse Cerebral Degenerative Diseases affecting the white matter
Grouped by the characteristics of the myelin breakdown that occurs
Demyelinating loss of myelin
Dysmyelinating cannot form appropriate myelin
Myelinolytic irregular breakdown of myelin (spongy myelinopathy)
98. Dysmyelinating Diseases Classical Adrenoleukodystrophy
Globoid cell leukodystrophy (Krabbe)
Metachromatic leukodystrophy
Hypomyelinative Pelizaeus-Merzbacher disease
Alexander disease
Spongiform - Canavan disease
Miscellaneous Vanishing white matter disease
Cockaynes syndrome
99. Common Features�of Leukodystrophies Reduced brain weight
Optic nerve atrophy
Ventriculomegaly due to loss of brain tissue
Atrophy of corpus callosum basically the CC is all white matter
Sparing of Subcortical U fibers except Canavan and PMD
B/L symmetrical, diffuse to confluent loss of cerebral and cerebellar wm - except PMD PMD Pilezeus-MerzbacherPMD Pilezeus-Merzbacher
100. Common Microscopic Features Reduced myelin staining
Loss of oligodendrocytes which produce myelin sheathing in CNS
Macrophages with myelin debris
Reactive astrocytosis (early) try to fix
Fibrillary astrogliosis (late) fibrous scar
Significant axonal loss eventually
101. Adrenoleukodystrophy Disorder of the peroxisomes
Transmitted as a X-linked trait
Accumulation of very long chain fatty acids (VLCFA)
Due to impaired function of peroxisomal membrane transporter protein
Results in the accumulation of saturated, VLCFA in the rough Endoplasmic Reticulum of tissues throughout the body
Leads to progressive dysfunction of CNS white matter and the adrenal cortex.
102. ALD - Epidemiology Incidence: 1/10,000
Childhood and Adult onset forms
Familial - X-linked recessive
Chrom Xq28 (terminal segment)
gene: peroxisomal membrane protein that is part of ATP Binding Cassette transporter superfamily (Gene is ABCD1 coding protein ALDP)
Affects synthesis of VLCFA-CoA and transport across membrane into peroxisome
>500 mutations reported
103. ALD CNS Pathology CNS White Matter
acute and symmetric demyelinating lesions
perivascular infiltration of lymphocytes
at least 1/3 of patients with ALD are free of neurological manifestations and thus CNS involvement may depend upon some factor other than VLCFA accumulation
No correlation between genotype and phenotype
considered one of the degenerative diseases of white matter of the cerebral cortex
104. ALD - Neurologic Manifestations 1. Presenting Symptoms - Childhood
Normal until about 4 8 years old, progressive neurological dysfunction gait disturbances
Impaired auditory discrimination - difficulties hearing speech in a noisy room or over the telephone
parietal lobe dysfunction - construction & dressing apraxia, stereognosis, graphesthesia, impaired spatial orientation
visual disturbances - field cuts, strabismus, visual acuity
focal or generalized seizures (33%)
105. ALD - Neurologic Manifestations 2. Later Symptoms
tends to progress rapidly with increased spasticity and paralysis, visual and hearing loss, and bulbar musculature dysfunction (loss of ability to speak +/- swallow), cognitive loss -> vegetative state
mean interval between onset of neurologic symptoms and the vegetative state is 1.9 +/- 2 years
may continue in vegetative state for >10 years
106. ALD - Endocrine Manifestations Primary adrenal insufficiency
FTT, nausea & vomiting, postural hypotension, weakness, weight loss, salt craving
mild hyper-pigmentation (over joints, scar tissue, lips, nipples, buccal mucosa)
usually presents after the neurologic manifestations
107. ALD Diagnosis 1. VLCFA
very high levels of VLCFA in the plasma (C26, C24 saturated fats)
positive in 100% of affected males
positive in 85% of carrier females
Mutation Analysis
2. Adrenal Insufficiency
hyponatremia, hyperkalemia, mild metabolic acidosis
low serum cortisol level with elevated ACTH levels
impaired cortisol response to ACTH stimulation in 85%
3. MRI imaging
Cerebral White Matter Lesions (80%)
even in the early stages, striking changes may be found
108. ALD MRI Imaging Left - FLAIR image showing myelin loss, appears flame-like
Right T2 after contrast shows leading edge of demyelination
109. Adrenoleukodystrophy White matter tracts Diffusion Tensor MRI
Left Normal
Right - Adrenoleukodystrophy
110. ALD - Management Adrenal hormone replacement
mandatory, life-saving, no effect on CNS symptoms
Bone marrow transplant
mild progressive cerebral involvement
Diet - to decrease both the exogenous source of VLCFA and the endogenous production of VLCFA (Lorenzo's Oil)
Gene therapy trial
111. References Clinical Pediatric Neurology Fenichel
Fundamental Neuroscience for Basic and Clinical Applications Haines
Neurology of the Newborn - Volpe
Principles of Neural Science Kandel
Child Neurology - Menkes
My patients
Good Luck on the exam We have only scratched the surface!
