Neuropathology

Question 1

Gross changes in Alzheimers?

Answer 1

Diffuse atrophy
Flattened cortical sulci
Enlarged cerebral ventricles

Question 2

Histological changes in Alzheimers?

Answer 2

Neuronal loss in cortex and hippocampus
Synaptic loss
Granulovascular degeneration
Senile plaques
Neurofibrillary tangles
Hirano bodies

Question 3

What is granulovascular degernation?

Answer 3

Small vacuoles with central granules in cytoplasm of neurons - particularly in temporal lobes

Question 4

Structure of senile plaques

Answer 4

Insoluble amyloid peptide deposits

Peptide called Beta A4 peptide

Question 5

Structure of amyloids

Answer 5

Fibrils of multimeric chains of peptides deposited extracellulaly, with beta pleated sheet confirmation

Question 6

What cleaves beta A4?

Answer 6

Cleaved from amyloid-beta precursor protein by beta and gamma-secretases

Question 7

What prevents cleavage of amyloid beta precursor protein?

Answer 7

Alpha secretase

Question 8

Subtypes of plaques?

Answer 8

Neuritic plaque

Diffuse

Question 9

Structure of neuritic plaque

Answer 9

Beta A in form of amyloid fibrils, among which are irregularly swollen dystrophic neuritis (defenerated neuronal processes)

Question 10

How are neuritic plaques visualised?

Answer 10

Neurites visualised with silver stains.

May be seen as an eosinophilic mass on haematoxylin and eosin stains.

Question 11

Core of neuritic plaques?

Answer 11

May contain dense central core of amyloid

Question 12

Periphery of neuritic plaques?

Answer 12

Microglia and astrocyte processes

Question 13

Diseases in which neuritic plaques are seen?

Answer 13

Normal ageing

Downs

Question 14

What is the ‘apple green’ birefringence of stained stissue with neuritic plaques?

Answer 14

Amyloid sensitive stain Congo red under polaroid light leads to ‘apple green’ stain of neuritic plaques due to presence of beta-pleated sheets.

Question 15

Structure of diffuse plaques?

Answer 15

Consist of non-fibrillar extracellular A beta.

Question 16

Which plaques are not related to cognitive decline?

Answer 16

Diffuse

Question 17

Peptides in diffuse plaques?

Answer 17

Same peptides as those responsible for amyloid formation in neuritic plaques but not polymerized to form fibrils and lack of beta-sheet configuration.

Question 18

What are neurofibrillary tangles composed of?

Answer 18

Cytoskeletal elements - primarily abnormally phosphorylated tau protein.

Question 19

What type of tauopathy is Alzheimers?

Answer 19

One of several degenerative tauopathies

Question 20

What is tau?

Answer 20

Peptide required for microtubule assembly.

Question 21

Function of microtubules?

Answer 21

Transport of materials down axons.

Question 22

What stimulates formation of abnormal tau?

Answer 22

Beta A4 peptide interacts with cholinergic receptors, stimulating abnormal hyperphosphorylation of tau.

Question 23

Where is hyperphosphorylated tau present?

Answer 23

Abnormal tau

Degenerated neurites

Question 24

How can hyperphosphorylated tau be visualised?

Answer 24

Staining with antibody to abnormal tau

Question 25

Which conditions do neurofibrillary tangles occur in?

Answer 25

Alzheimers
Downs
Dementia pugilistica (punch-drunk syndrome)
Parinkson-dementia complex of Guam
Hallervorden-Spatz disease
Normal elderly

Question 26

Location of tangles?

Answer 26

Mainly intraneuronal

Upon neuronal degeneration may appear extracellularly, thus losing their basophilia

Question 27

How can tangles be visualised?

Answer 27

Faintly basophilic

Tau immunostaining and silver impregnation can be used to improve chances of light microscopic detection.

Question 28

Location of tangles on early Alzheimers?

Answer 28

Tangles and neuropil threads are restricted to parts of the entorhinal cortex and CA1 field of hippocampus.

Question 29

Location of tangles as Alzheimers develops?

Answer 29

Tangles and neutrophil threads accumulate in increasing density in other parts of the hippocampus and medical temporal neocortex, then in other cortical regions and in subcortical grey matter structures such as hypothalamus and thalamus.

Question 30

What staging scheme is used to describe extent of tangle related abnormalities in Alzheimers?

Answer 30

Braak and Braak (1995)

Question 31

Which stages of Braak and Braak’s staging scheme operationally define Alzheimers?

Answer 31

Stages V-VI

Question 32

Structure of C Hirano bodies?

Answer 32

Rod-shaped eosinophilic bodies n cytoplasm of neurons

Intracellular aggregates of actin and actin-associated proteins

Question 33

Location of Hirano bodies when neuron dies?

Answer 33

Extracellular space

Question 34

Location of HIrano bodies normally?

Answer 34

Hippocampal pyramidal cells

Question 35

Pathology of cerebral amyloid angiopathy?

Answer 35

Accumulation of A beta in walls of blood vessels, particularly arteries and arterioles in cerebral cortex overlying leptomeninges

Question 36

What % of the elderly have Cerebral amyloid angiopathy?

Answer 36

30%

Question 37

What % of patients with Alzheimers have Cerebral Amyloid Angiopathy?

Answer 37

90%

Question 38

What important disease can Cerebral Amyloid Angiopathy?

Answer 38

Haemorrhagic strokes confined to superficial blood vessels.

Question 39

How does Cerebral Amyloid Angiopathy lead to haemorrhagic stroke?

Answer 39

Rupture of amyloid laden blood vessels causes superficial lobar haemorrhages that may extend into subarachnoid space

Question 40

Relation between tangles and cognitive decline

Answer 40

Increase in number and distribution

Question 41

Link between tangles, neuritic plaque and cognitive decline?

Answer 41

If both are present, presence of even a few tangles in a single field in neocortex can suggest significant cognitive decline.

Question 42

Best neuropathological correlate of decline?

Answer 42

Number of synapces

Question 43

Marker for synapses?

Answer 43

Antibody to synaptophysin, a protein fund in presynaptic endings

Question 44

Where is synaptophysin found?

Answer 44

Presynaptic endings

Question 45

Cellular pattern of neuronal loss in hippocampal pathology?

Answer 45

Subiculum of hippocampal formation and layers II and IV of entorhinal cortex.

Question 46

Affected cells involved in hippocampal pathology?

Answer 46

Connect hippocampal formation with association cortices, basal forebrain, thalamus and hypothalamus, structures crucial to memory.

Question 47

Significance of neuronal loss in hippocampal pathology?

Answer 47

Isolates hippocampal formation from its input and output, contributing to memory disorder in Alzheimers

Question 48

What is Binswanger’s Disease?

Answer 48

Subcortical vascular dementia/subcortical arteriosclerotic encephalopathy
Many small infarctions of what matter that spares cortical regions.
Co-exists with Alzheimers-type changes

Question 49

Which type of dementia co-exists with Alzheimers?

Answer 49

Subcortical

Question 50

Histology of Lewy bodies?

Answer 50

Weakly eosinphilic
Spherical
Cytoplasmic inclusions

Question 51

Where are Lewy bodies in Parkinsons?

Answer 51

Confined to substantia nigra

Question 52

Where are Lewy bodies in Lewy body Dementia?

Answer 52

Substantia nigra
Areas of cerebrum including temporal and frontal lobe and cingulate gyrus
Dorsal motor nucleus of vagus

Question 53

Difference between lewy bodies in substantia nigra and cortex?

Answer 53

In cortex they are less conspicuous, eosinophilic and lack clear halo
Take up homeneous eosinophilic staining in cytoplasm along with peripheral displacement of nucleus

Question 54

Correlation between number of Lewy bodies and cognitive decline?

Answer 54

None

Question 55

What can we use to identify Lewy body?

Answer 55

Antibody to protease ubiquitin

Staining with alpha-synuclein antibodies

Question 56

What do lewy bodies contain?

Answer 56

Accumulations of alpha-synuclein

Question 57

What type of disease is Lewy body dementia?

Answer 57

Degenerative synucleopathies

Question 58

What does alpha-synuclein do?

Answer 58

Accelerates reuptake of dopamine in neurons; this dopamine overload may be toxic

Question 59

What are Lewy neuritis?

Answer 59

Nerve cell processes that contain aggregates of alpha-synuclein

Question 60

Where are Lewy neuritis most numerous?

Answer 60

CA2/3 region of hippocampus

Substania nigra

Question 61

Which diseases do Lewy neurites occur?

Answer 61

Lewy body Dementia

Idiopathic Parkinsons

Question 62

Where does microvacuolation occur in Lewy Body Dementia?

Answer 62

Microvacuoalation of cerebral cortex, mainly in medial temporal region.

Question 63

What are Tauopathies?

Answer 63

Diseases with tau deposits

Question 64

What are synucleopathies?

Answer 64

Disease with alpha synuclein deposits

Question 65

Name some tauopathies?

Answer 65

Alzheimers
Picks
Progressive supranuclear palsy
Corticobasal degenerations
Frontotemporal dementia with Parkinsonism (FTDP-17)

Question 66

Name some synucleopathies?

Answer 66

Parkinsons
Lewy Body Dementia
Multisystem atrophy

Question 67

Which types of pathology is frontotemporal dementia associated with?

Answer 67

Frontal lobe degeneration type
Picks type
Motor neurone disease type

Question 68

Most common type of frontotemporal dementia?

Answer 68

Frontal lobe degeneration

Question 69

Underlying pathology of Frontal lobe degeneration?

Answer 69

Spongiform degeneration or microvacuolation of superficial neuropil seen chiefly in layers III and V of cortex
Loss of large cortical nerve cells with minimal gliosis

Question 70

Which cells are mainly lost in Frontal lobe degeneration?

Answer 70

Large cortical nerve cells

Question 71

Characteristics of Picks disease?

Answer 71

Prepronderance of atrophy in frontotemporal regions

Question 72

What are Pick cells?

Answer 72

Abnormal swollen oval-shaped neuronal cells with loss of Nissl’s substance and peripherally displaced nucleus

Question 73

What are Picks bodies seen in post-mortem?

Answer 73

Argentophilic, tau and ubiquitin reactive filamentous inclusions

Question 74

Are Hirano bodies seen in Picks disease?

Answer 74

Yes but less than in Alzheimers

Question 75

Characteristics of motor neurone disease type frontotemporal disease?

Answer 75

Cerebral atrophy is less marked
Limbic areas are largely preserved
Ubiquitinated inclusions in frontal cortex and hippocampus

Question 76

Cell loss in motor neurone disease type frontotemporal disease?

Answer 76

Large cortical nerve cells
Microvacuolation
Mild gliosis

Question 77

MND pathology in motor neurone disease type frontotemporal disease?

Answer 77

MND pathology in anterior horn cells

Question 78

Pathology in Huntington’s dementia?

Answer 78

Severe loss of small neurons in caudate and putamen with subsequent astrocytosis
Head of caudate shrinks and there is ‘ex vacuo’ dilatation of anterior horns of lateral ventricles

Question 79

Characteristics of Huntington’s dementia?

Answer 79

Protein deposits form nuclear inclusions in neurons

Question 80

Forms of CJD?

Answer 80

Sporadic
Familial
Variant

Question 81

Most common form of CJD?

Answer 81

Sporadic

Question 82

What is variant CJD related to?

Answer 82

Bovine spongiform encephalopathy

Question 83

Characteristic pathological features of CJD?

Answer 83

None due to short course of disease

Question 84

Pathological features of CJD >6 months?

Answer 84

Degree of generalized cerebral atrophy

Question 85

Microscopic changes in CJD?

Answer 85

Spongiform encephalopathy secondary to neutrophil variation
Round to oval vacuoles in neuropil of cortical gray matter - vacuoles are single or multiloculated.
Vacuoles may coalesce to microcysts.

Question 86

Cell loss in CJD?

Answer 86

Neuronal loss

Gliosis

Question 87

What is Prion protein?

Answer 87

Normal neuronal cell surface protein

Question 88

Which gene encodes prion protein?

Answer 88

On chromosome 20

Question 89

What happens to prion protein in CJD?

Answer 89

Chromosome 20 is converted via conformational change to abnormal form - PrPSc.

Question 90

What does PrPSc do?

Answer 90

Protease-resistant
Accumulates in CNS
Triggers conversion of normal PrPc to PrPSc.

Question 91

What causes degenerative changes in cerebral cortex in CJD?

Answer 91

PrPSc.

Question 92

How can PrPSc be identified?

Answer 92

Immunoperoxidase staining

Question 93

How can PrPSc be transmitted between people?

Answer 93

If person has spongiform encephalopathy, via:
pituitary extracts
cornal transplants
dural grafts
contaminated electrodes from neurosurgical procedures

Question 94

Pathology in vCJD?

Answer 94

Marked accumulation of prion protein

Plaques are florid

Question 95

What protein is found in CSF in CJD?

Answer 95

14-3-3

Question 96

What is protein 14-3-3 associated with?

Answer 96

CJD
Viral encephalitis
Stroke

Question 97

Which type of CJD is protein 14-3-3 least frequent in?

Answer 97

Variant CJD

Question 98

In which type of CJD are the EEG changes lacking?

Answer 98

Familial

Question 99

In which type of CJD are 14-3-3 proteins absent?

Answer 99

Familial - <50%

Question 100

What may have an influence on susceptibility of disease?

Answer 100

Presence of polymorphisms at codon 129 of PrP

Question 101

Which aa may be present at codon 129 of PrP?

Answer 101

Methionine

Valine

Question 102

Which phenotype of codon 129 at PrP is present in CJD?

Answer 102

M/M phenotype

Question 103

What % of people with sporadic CJD have M/M phenotype?

Answer 103

73%

Question 104

What % of people with variant CJD have M/M phenotype?

Answer 104

100%

Question 105

Most supportive diagnostic test for CJD?

Answer 105

MRI

Question 106

Abnormality seen in MRI in CJD?

Answer 106

Posterior thalamic region (pulvinar sign)

Question 107

Which type of MRI most shows pulvinar sign?

Answer 107

FLAIR sequences of MRI

Question 108

Age of onset of classic CJD?

Answer 108

7th or 8th decade of life

Question 109

Age of onset of vCJD?

Answer 109

3rd/4th decade of life

Question 110

Course of classic CJD?

Answer 110

5 months

Question 111

Course of vCJD?

Answer 111

1 year

Question 112

Symptoms of classic CJD?

Answer 112

Early neurological signs

Dementia

Question 113

Symptoms of vCJD?

Answer 113

Early psychiatric/behavioural signs with delayed neurological features

Question 114

EEG signs in classic CJD?

Answer 114

Triphasic, sharp waves

Question 115

EEG signs in vCJD?

Answer 115

Triphasic waves rare

Changes often non-specific

Question 116

In which type of CJD are trophasic waves seen?

Answer 116

Classic CJD

Question 117

In which type of CJD is pulvinar sign not seen?

Answer 117

CLassic

Question 118

In which type of CJD are large number of plaques noted in biopsy?

Answer 118

Variant

Question 119

Tonsils in classic CJD?

Answer 119

Prion protein cannot be isolated from lymphoid tissue

Question 120

Tonsils in vCJD?

Answer 120

Tonsillar tissue carries prion agent

Question 121

Major HIV receptors?

Answer 121

CD4

CD8

Question 122

Chemokine receptors associated with HIV?

Answer 122

CXCR4 and CCR5 considered HIV-1 co-receptors

Question 123

Main method of replication in HIV?

Answer 123

CD4+ helper T lymphocytes main route of multiplication and entry apart from monocytes

Question 124

Source of CNS infection in HIV?

Answer 124

Infected CD4+ T cells and monocytes

Question 125

Characteristic of stains of HIV in brain?

Answer 125

Infecting macrophages rather than lymphocytes

Question 126

What is Macrophage-tropism?

Answer 126

Related to mutation in region of gp120 which is the external glycoprotein of HIV

Question 127

Which mutation is related to the external glycoprotein of HIV?

Answer 127

Macrophage-tropism of a specific region of gp120

Question 128

How does HIV-1 cross blood brain barrier?

Answer 128

Trojan Horse hypothesis:

Enters CNS as passenger in cells to the brain via CD4 T cells or monocytes.

Question 129

What confirms the Trojan Horse hypothesis in HIV?

Answer 129

Virus accumulation in perivascular region

Question 130

What is the alternative hypothesis of how HIV enters CNS?

Answer 130

Entry of free HIV-1 by migration between or transcytosis of endothelial cells.

Question 131

Most commonly infected neurocells of HIV-1?

Answer 131

Perivascular macrophage and microglia

Question 132

Which CNS cells contain receptors/co-receptors for HIV-1 entry?

Answer 132

Astrocytes
Oligodendrocytes
Neurons
Perivascular macrophages and microglia

Question 133

Components of mechanism of HIV

Answer 133

Direct effect of HIV-1 infection

Indirect consequences of infection comprising secretion of cytokines and neurotoxins

Question 134

How do infected macrophages and microglia lead to neurodegeneration in HIV?

Answer 134

1. Shedding viral proteins
2. Releasing significant amount of cytokines and neurotoxins into CNS
3. Tat and TNF-alpha contribute to disruption of blood brain barrier which becomes more permeable to infected monocytes and cytokines in periphery

Question 135

What do pro-inflammatory cytokines secreted by infected macrophages and microglia in HIV do?

Answer 135

Activate microglia and astrocytes which in turn secrete neurotoxins

Question 136

What secretes neurotoxins in HIV?

Answer 136

Microglia and astrocytes activated by pro-inflammatory cytokines stimulated by infected macrophages and microglia

Question 137

What type of neuronal injury occurs in HIV?

Answer 137

Apoptosis

Question 138

How does apoptosis occur in HIV to neuronal cells?

Answer 138

By toxic products released by HIV-infected macrophages and microglia or by activated astrocytes

Question 139

Which factors cause demyelination of oligodendrocytes?

Answer 139

Tumour necrosis factor

Question 140

Which factors are neurotoxic and cause apoptosis of neuronal cells?

Answer 140

Platelet activating factor
Quinolinic acid
Nitric oxide
Some metabolites of arachidonic acid

Question 141

Findings in biopsy of HIV in CNS

Answer 141

Infiltration of macrophages in CNS
Formation of microglial nodules
Astrocyte activation and damage
Myelin damage

Question 142

Cells in white and grey matter in biopsy of HIV?

Answer 142

Multinucleated giant cells from virus-induced fusion of microglia and/or macrophages

Question 143

Where is neuronal loss found in biopsies in HIV?

Answer 143

Hippocampus
Basal ganglia
Caudate nucleus

Question 144

Findings in biopsy of severe cases of HIV?

Answer 144

Lipid macrophages

Question 145

Most common psychiatric presentation in AIDs?

Answer 145

HIV-related dementia

Depression

Question 146

What % of HIV-infected patients present with psychosis?

Answer 146

10%

Question 147

What is viral load used for in clinical practice?

Answer 147

To predict stage of disease
Monitor disease progression
Formulate treatment strategies

Question 148

Definition of viral load?

Answer 148

Actual number of viral particles in cubic millimetre of blood

Question 149

Can CSF viral load be used in HIV?

Answer 149

No - not accurate indicator of CNS disease

Question 150

Weight, length and volume changes in schizophrenia re brain?

Answer 150

Decreased weight
Decreased length and volume of cerebral hemispheres
Enlargement of lateral ventricles - particularly temporal horns

Question 151

Which tissue volume is reduced in schizophrenia?

Answer 151

Thalamus

Temporolimbic structures including hippocampus, amygdala and parahyppocampal gyrus

Question 152

White matter reductions in schizophrenia?

Answer 152

Parahippocampal gyrus or hippocampus

Question 153

What happens to septum pellucidi in schizophrenia?

Answer 153

Increased incidence of cavum septi pellucidi

Question 154

What happens to basal ganglia in schizophrenia?

Answer 154

Reduced volume, particularly in preneuroleptic area in catatonic patients.
Enlargement due to classic neuroleptics - reversed by atypicals

Question 155

In which type of epilepsy is schizophrenia-like psychosis more common in?

Answer 155

Temporal lobe epilepsy when focus is on left hemisphere

Question 156

Where is the planum temporale?

Answer 156

Posterior superior surface of superior temporal gyrus

Question 157

What is planum temporale?

Answer 157

Lateralized brain structure involved with language

Question 158

What happens to planum temporale in schizophrenia?

Answer 158

Consistent reversal of normal left-larger-than-right asymmetry of planum temporale surface area

Question 159

What is Heschl’s gyrus?

Answer 159

Primary auditory cortex

Question 160

Is astrogliosis evident in schizophrenia?

Answer 160

No

Question 161

Any cell number or size change in schizophrenia?

Answer 161

Reduced numbers and size in affecting neurons in hippocampus and DLPFC

Question 162

Neuronal density in schizophrenia?

Answer 162

Increased, may relate o observed decrease in neuronal size, with decreased dendritic arborisation and decreased neuropil compartment.

Question 163

Changes in brain archeticture in schizophrenia?

Answer 163

Subtle cytoarchitectural anomalies in hippocampal function, frontal cortex - significant cellular disarray in CA3-CA4 interace

Question 164

What do synaptic studies in schizophrenia show?

Answer 164

Decrements in presynaptic markers in hippocampus and DLPFC.

Reflect reduction in synaptic contacts formed

Question 165

What does decrements in presynaptic markers in hippocampus and DLPFC in schizophrenia support?

Answer 165

Hypothesis of excessive synaptic pruning in schizophrenia.

Question 166

Which synapses are vulnerable in schizophrenia?

Answer 166

Glutamatergic synapses in hippocampus and DLPFC, with predominantly GABAergic involvement in cingulate gyrus.

Question 167

Affect of antipsychotics in histology of schizophrenia?

Answer 167

Alter synaptic and neuronal morphology, particularly caudate-putamen and may increase glial density in prefrontal cortex

Question 168

Pathological changes of Wernickes?

Answer 168

Degenerative changes including gliosis, small haemorrhages in third ventricle and aqueduct and cerebellar atrophy

Question 169

Where is small haemorrhage seen in Wernickes?

Answer 169

Third ventricle
Mamillary bodies
Hypothalamus
Mediodorsal thalamic nucleus
Colliculi
Midbrain tegmentum

Question 170

Brain damage in uncomplicated alcoholism?

Answer 170

Brain shrinkage likely due to white matter loss - reversible

Question 171

Where is alcohol-related neuronal loss found?

Answer 171

Superior frontal association cortex
Hypothalamus - supraoptic and paraventricular nuclei
Cerebellum

Question 172

Cell count changes in autism?

Answer 172

Lower Purkinje cell count

Question 173

Neocortex changes in Autism?

Answer 173

Inconsistent changes - increased cortical volume possibly related to reduced pruning

Question 174

Pathological changes in Autism?

Answer 174

Hypoplasia of cerebellar vemis and cerebellar hemispheres