Diagnosing dementia
A key in issue
the fight against Alzheimer’s disease is accurate identification of the
disease. In many diseases, like chickenpox or COVID, there are
unambiguous clinical signs or reasonably accurate diagnostic tests. But
the main sign of Alzheimer’s, memory loss, can also be part of normal
aging. Other conditions and dementias can also interfere with memory
function, making clear identification tricky. While there is still much
work to be done, recent advances in Alzheimer’s disease testing reflect
improved test performance and a reduction in the invasiveness of the
tests.
Standard practice for Alzheimer’s disease diagnosis involves:
1)
Asking the patient and the caregiver for a medical history, including
duration of symptoms, past medical problems, current medication use,
diet and lifestyle, ability to carry out activities of daily living and
changes in personality or behavior.
2) Administering a psychiatric evaluation for depression or other mental health conditions.
3) Ordering blood, urine and other standard lab tests to identify other possible causes of the problem.
4)
Performing a brain scan to support an Alzheimer’s diagnosis and rule
out other possible causes
(https://www.nia.nih.gov/health/how-alzheimers-diseasediagnosed).
The focus is on ruling out other contributors to memory loss rather than positively identifying Alzheimer’s disease.
Several
new tests look promising for the sensitive and specific identification
of Alzheimer’s. The terms “sensitive” and “specific” in research reflect
how well a test works. “Sensitivity” is used to describe how well a
test identifies people who have a disease. At the same time, specificity
refers to how well a test identifies people who do not have a disease.
It is also important, both clinically and in research, to ensure that
sick people don’t get a negative test result (false negative), and that
well people don’t get a positive result (false positive).
The
most data on disease identification comes from tests of the proteins
that make up plaques (Beta Amyloid) and tangles (Tau), which are
hallmark signs of the disease. These proteins are identified using
positron emission tomography (PET), a brain imaging technology in which
substances containing radioactive isotopes are introduced into the body,
allowing localization of physiological processes.
A
study of Beta Amyloid PET showed a low false negative but a high false
positive rate. Longitudinal data correctly classified 89% of
participants who progressed to AD but only 58% of participants who did
not progress to AD (Amivid; Martinez et al., 2017). However, more recent
studies using blood samples showed promising results using a less
invasive technique. Plasma B-amyloid showed specificity/sensitivity of
91% and 71%, respectively, with an overall diagnostic accuracy of 86%.
The biomarker-positive group was 7.9 times more likely to develop
clinical AD (Nabers et al., 2018).
Tau
testing, specifically the optimization of the radioactive isotope, is
in an early stage of development. A recent Tau study identified mild
cognitive impairment with a sensitivity of 38% and specificity of 95%
(Leuzy et al., 2020). A positive Tau test was strongly indicative of
Alzheimer’s disease, but a negative test did not exclude the diagnosis.
Another
classic sign of Alzheimer’s disease is brain atrophy, or shrinkage, due
to cell death. Atrophy is measured using magnetic resonance imaging
(MRI). This medical imaging technique uses a magnetic field and
computergenerated radio waves to create detailed images of the body’s
tissues. A new study used artificial intelligence modeling methods to
identify early Alzheimer’s in simple brain scans. The model identified a
handful of brain size and shape parameters from hundreds of
possibilities that were optimal for discrimination. They reported 98%
accuracy even when the sample included other diseases such as
Parkinson’s and frontotemporal dementia (Inglese et al., 2022).
In
addition to tests for classic signs of AD, there are tests of new
emerging targets in various stages of development. Cellular energy
production, specifically the function of mitochondria, the powerhouse of
the cell, has been targeted using PET and blood samples.
Neuroinflammation, or activation of the brain’s innate immune system
following injury or disease, such as accumulation of Beta Amyloid, is also a new target. Both are in the initial stages of development.
At
LSU Health Shreveport, our team is working on a test based on the
cardiovascular contribution to Alzheimer’s disease. There is growing
evidence that high cholesterol, high blood pressure and diabetes
increase the risk of the disease, particularly in the preliminary
stages. We are studying a blood test for a molecule called hydrogen
sulfide, which is important for signaling in the cardiovascular and
nervous systems. We have shown that hydrogen sulfide levels are
increased when cognitive function decreases. Hydrogen sulfide was
associated with cognitive performance and an M R I - based measure of
vascular disease in the brain (Disbrow et al., 2021).
Our blood test showed a sensitivity of 80% and a specificity of 98%.
Even
with these advances, none of these tests are 100% sensitive and
specific. We are advancing rapidly, but our ability to measure our
targets is not perfect. We may be including more than a single disease
in our current definition of “Alzheimer’s disease,” so our quest for
better identification will likely improve the precision of our
description of the disease and the tests we are using.
To learn more about the Center for Brain Health, visit www.lsuhs.edu/cbh.
Elizabeth Disbrow, Ph.D., professor, Department of Neurology, and director, Center for Brain Health at LSU Health Shreveport.
