AssessmentsDementia: Pathology review
USMLE® Step 1 style questions USMLE
A 71-year-old woman is brought to the clinic by her partner due to worsening insomnia and cognitive impairment for the past 3 months. According to the husband, the patient had previously been able to drive to the grocery store and play racquetball. However, she is no longer able to complete these activities on her own. The patient has no history of psychiatric conditions, but her mother died from Alzheimer disease in her 80s. In the office, the patient’s temperature is 37.0°C (98.6°F), pulse is 88/min, respirations are 13/min, and blood pressure is 122/84 mmHg. Physical exam reveals ataxic gait and an inability to follow multi-step instructions. When a nearby door is shut loudly, the patient is startled, causing her arms to clench involuntarily. Further evaluation of this patient is most likely to reveal which of the following findings?
Content Reviewers:Yifan Xiao, MD
At the neurology department, a 60 year old male, named Oliver, is brought in by his son because lately Oliver has become more aggressive, impolite and he seems to have lost his interest in his family.
Recently, he has also started repeating conversations.
Next, there’s a 72 year old female, named Iris, who is also brought by her son.
Iris is always staying at home because she is embarrassed that she’s unable to hold her urine.
She also has a hard time finding her things at home because she forgets where she has placed them.
Her son has noticed that she is walking strangely, as if her feet stick to the ground.
Finally, there’s a 35-year old male, named Alasdair, who is brought by his partner because in the past few weeks he has started repeating conversations and misplacing their belongings.
Alasdair also has episodes of jerking movements of his left arm and he has fallen twice in the last few days.
His medical history reveals corneal transplantation 6 months ago.
Okay, so all of these people have dementia.
Dementia occurs when there’s a decline in at least one cognitive function and it impairs daily functioning.
Remember that they need to have intact consciousness.
Dementia can result from reversible and irreversible causes.
Irreversible causes include Alzheimer disease, which is by far the most common cause of dementia, vascular dementia, which is the second most common cause, frontotemporal dementia, Lewy body dementia, Parkinson disease, Huntington disease, and Creutzfeldt-Jakob disease, or CJD.
Okay, so let’s take a closer look at the irreversible causes of dementia, starting with Alzheimer disease, which is a very high yield topic for the exams!
In the cell membrane of a neuron, there’s a molecule called amyloid precursor protein, or APP.
Normally, old APP gets chopped up by two enzymes called alpha secretase and gamma secretase to a soluble peptide.
But if another enzyme, called beta secretase, teams up with gamma secretase instead, then the chopped up fragment isn’t soluble, and creates a monomer called amyloid beta.
For the test remember that these amyloid beta monomers bond together outside the neurons, and form beta-amyloid plaques.
These plaques get between the neurons and impair brain function.
Also, it’s important to know that amyloid plaque can deposit around blood vessels in the brain, causing amyloid angiopathy, which weakens the walls of the vessels and increases the risk of hemorrhage.
Alright, now neurons are held together by their cytoskeleton, which is partly made up of microtubules, which also form tracks along the cell to ship nutrients and molecules.
A protein called tau makes sure that these tracks don’t break apart.
It’s thought that the beta amyloid plaques outside the neuron, initiate pathways inside the neuron that lead to activation of kinase, an enzyme that transfers phosphate groups to the tau protein.
The tau protein stops supporting the microtubules, gets tangled with other tau proteins, forming neurofibrillary tangles inside the neuron.
This makes Alzheimer disease a tauopathy.
Okay, so remember, the tangles are found inside the cell, as opposed to the beta-amyloid plaques that are found outside the cells.
Neurons with tangles and non-functioning microtubules can’t function, and end up undergoing apoptosis.
The number of neurofibrillary tangles increases as the disease progresses.
In addition, low acetylcholine levels in the nucleus basalis and the hippocampus also contribute to the cognitive symptoms seen in Alzheimer disease.
This is due to impaired activity of an enzyme responsible for acetylcholine synthesis, called choline acetyltransferase in these areas of the brain.
Okay, now Alzheimer disease can be either sporadic or familial.
Sporadic is used to describe the late-onset type which is probably a combination of genetic and environmental risk factors, and accounts for the majority of cases.
A gene that’s been identified as possibly contributing is the e4 allele of apolipoprotein E gene, or APOE-e4. Apolipoprotein E helps break down beta-amyloid, but the e4 allele seems to be less effective than the other alleles, meaning patients are more likely to develop beta-amyloid plaques.
This can be caused by several gene mutations, and accounts for about 5 to 10% of cases.
For example, mutations in the PSEN-1 or PSEN-2 genes on chromosome 14 or chromosome 1, respectively, have been linked to early-onset Alzheimer’s.
These genes encode for presenilin-1 and presenilin-2, both protein subunits of gamma-secretase.
Mutations in these genes change the location where gamma secretase chops APP, producing different length beta amyloid molecules, which seem to be better at clumping up and forming plaques.
The gene responsible for producing APP is located on chromosome 21, which means that individuals with Down syndrome have an extra APP gene potentially increasing the amount of amyloid plaque buildup.
Next up is vascular dementia, where there’s a progressive loss of brain function caused by long term poor blood flow to the brain.
This leads to a gradual decrease in blood flow to the brain, which is called chronic ischemia.
Sometimes, small parts of the plaques can break away, and can then eventually block a smaller artery, completely stopping the blood supply to the parts of the brain.
Other times, the tiny perforating arteries are affected by atherosclerosis and can get completely blocked off by plaque growing within them.
Regardless of the cause, once blood supply to the brain falls below the demands of the tissue, it’s considered an ischemic stroke.
The tissue damage from an ischemic stroke is usually permanent, and the dead tissue liquefies in a process called liquefactive necrosis.
Brain tissue necrosis leads to a loss of mental functions governed by that area.
Now, if another stroke happens later on, more brain tissue might die off, over time this damage gets worse and worse, and the final result is dementia.
Next is frontotemporal dementia.
For the test, remember that frontotemporal dementia refers to atrophy of the frontal lobes that eventually progresses to the temporal lobes, with relative sparing of the parietal and occipital lobes.
Tau comes in different isoforms, like the 3R and the 4R isoforms.
They also start clumping together, forming tangles.
A key difference is that the tangles in Pick disease, are called Pick bodies, and they’re only made up of the 3R isoforms, whereas the neurofibrillary tangles in Alzheimer disease are made up of both 3R and 4R tau isoforms.
Now, neurons with loads of tangles and non-functioning microtubules don't function well, and the neurons undergo apoptosis.
Okay, now next is Lewy body dementia.
The underlying cause of Lewy body dementia isn’t well understood.
The misfolded alpha-synuclein aggregates to form Lewy bodies that deposit inside neurons, particularly in the cortex and the substantia nigra.
Under a microscope, Lewy bodies look like dark, eosinophilic inclusions inside the affected neurons.
As the disease progresses, more and more neurons accumulate Lewy bodies and die.
The significance of Lewy bodies, however, is unknown, but remember that they’re also seen in other diseases like Parkinson disease.
Alright, now Parkinson disease can also cause dementia.
This is a slowly progressive genetic disorder that primarily affects individuals over 50 years old.
It’s characterized by the loss of dopamine-producing, or dopaminergic, neurons in the substantia nigra, which is a part of the basal ganglia.
Normally, within the basal ganglia there’s a balance between dopamine, which promotes movement, and acetylcholine, which inhibits movement.
In Parkinson disease, the loss of dopaminergic neurons, results in less movement, difficulties in speech and swallowing, as well as cognitive symptoms, like dementia in the later stages of the disease.
Next, there’s Huntington disease, which is very high yield!
So, Huntington disease is an autosomal dominant neurodegenerative disorder that typically affects individuals around 40 years of age.
It is caused by a mutation in the Huntington disease, or HD, gene on chromosome 4.
This gene contains a CAG trinucleotide repeat, which encode for the amino acid glutamine,
The gene encodes for a protein called huntingtin.
The mutated protein aggregates within the neuronal cells of the caudate and putamen of the basal ganglia, causing neuronal cell death.
So, the caudate and the putamen of the basal ganglia are the areas of the brain affected in Huntington disease.
The brain regions affected by Huntington disease have decreased GABA and acetylcholine and increased dopamine levels.
There’s also excessive activation of a subtype of glutamate receptors, called NMDA receptors, that leads to glutamate excitotoxicity, a process by which neurons are damaged.
Over time, if enough neurons die in the caudate and putamen, which together form the dorsal striatum, this can cause actual loss of brain tissue volume in these areas, which can expand to the lateral ventricles.
These areas of the brain play an important role in movement, particularly, inhibiting it, and that’s why Huntington disease causes movement problems like chorea and athetosis.
But they also have cognitive symptoms, like dementia.
Alright, now another high yield concept about Huntington disease is a phenomenon called anticipation, which is where there’s an increased number of trinucleotide repeats in subsequent generations.
This leads to an earlier onset and more severe presentation of the disease.
This process of adding more repeats is called repeat expansion.
It happens way more in the production of sperm than eggs, and so anticipation generally occurs when the biological father is the affected parent.
Finally, a rare cause of dementia is Creutzfeldt-Jakob disease, or CJD.
CJD is the most common cause of spongiform encephalopathy and it’s a high yield topic for the exams!
Misfolded means that they change from having mostly α-helices to having a lot of ß pleated-sheets and so, they become resistant to being broken down by proteases.
As a result, prions accumulate within the neuron and trigger apoptosis with the help of an intracellular 14-3-3 protein.
When large numbers of neurons die, the brain gets replaced by cysts making it look like a sponge.
That’s why these diseases are called spongiform encephalopathies.
Now, there are actually four types of CJD; familial or fCJD, variant or vCJD, iatrogenic or iCJD, and sporadic or sCJD.
Familial Creutzfeldt-Jakob disease occurs when there’s a mutation in the PRNP gene which encodes for the prion protein.
Variant Creutzfeldt-Jakob disease is caused by eating the meat of cows with prions in the muscle tissue.
In cows, these prions cause bovine spongiform encephalopathy, which is more commonly called “Mad cow disease.”
When sheep are fed cow meat, the prion causes the disease Scrapie.
If a person eats the meat of affected cows or sheep, the prions get absorbed through the intestines into the bloodstream.
Iatrogenic Creutzfeldt Jakob disease is caused by medical procedures, like a corneal transplant, where the transplanted organ or the instruments gets contaminated by prions.
Finally, there’s sporadic Creutzfeldt-Jakob disease which pops up in populations randomly without a clear cause.
Now let’s quickly go over the reversible causes of dementia.
A key finding in pseudodementia is that individuals are often anxious about their memory impairment as opposed to other causes of dementia, like Alzheimer disease.
It’s caused by abnormal venous drainage of the cerebrospinal fluid, resulting in hydrocephalus.
Since the frontal lobe is the most affected, Individuals with NPH usually present with urinary incontinence and gait disturbance at first, and then dementia.
Alright, now let’s switch gears and talk about clinical presentation.
Although all these disorders can cause dementia, many of them also cause other symptoms that will be key clues for the correct diagnosis.
But before that, let’s take a look at how dementia typically presents.
Most of the time, a close family member or friend notices the individual’s change in cognition.
This includes impaired memory, which leads to repeating conversations or misplacing belongings.
Language impairment can make it hard to think of common words.
Additionally, concentration and executive function are impaired, so individuals have a hard time with complex tasks, like managing their finances.
Visuospatial impairment can prevent them from recognizing faces and navigating in familiar locations.
Sometimes, family members also notice changes in the individual’s personality.
Okay, now there are specific symptoms that can help you identify the different causes of dementia.
For the exams remember that Alzheimer disease has an insidious onset and gradual progression.
Individuals usually go through 3 phases.
First is the asymptomatic phase.
Second is a predementia phase called mild cognitive impairment, during which there’s gradual onset of memory impairment without much impairment in other cognitive domains, and no impairment in daily functioning.
This differs from normal aging, because the memory impairment is greater than expected for the individual’s age.
The third phase is the dementia phase, and that’s where individuals develop more significant memory loss, followed by slow, gradual loss of the other cognitive functions, such as language, visuospatial, and executive functions.
Now, there are two main types of memory: episodic memory, which is memory of events, and semantic memory, which memory of words and vocabulary.
Early on, episodic memory is impaired and semantic memory remains intact.
Later on, both episodic and semantic memory get impaired.
Episodic memory can be subclassified into immediate, recent, or long term.