January 30, 2024

Research in Context: Diagnosing dementia

Detecting brain diseases early

Until recently, a diagnosis of dementia might help explain cognitive decline, but there were no available treatments. In the last several years, the first drugs to slow the progression of Alzheimer鈥檚 have reached the market. This special Research in Context feature explores approaches to the diagnosis of Alzheimer鈥檚 and other dementias and the development of strategies to try to prevent their progression.

Elderly father with adult son and grandson out for a walk in the park. adriaticfoto / Shutterstock

Diseases that degrade the mind strike at the very heart of our humanity. Unfortunately, such diseases aren鈥檛 rare. Strokes, infections, and chronic conditions like diabetes can all cause lasting damage to the brain. And more than 6 million Americans are living with Alzheimer鈥檚 disease and other dementias鈥攁 number that is expected to rise over the coming decades.

Dementia is a loss of thinking, remembering, and reasoning skills that affects everyday life. The risk for developing dementia increases sharply with age, but dementia is not part of the healthy aging process.

鈥淲hen [older] people start to have memory problems, cognitive problems, it鈥檚 due to a disease. It鈥檚 not a normal consequence of aging,鈥 explains Dr. Michael Weiner, a dementia researcher at the University of California, San Francisco.

While there are several different forms of dementia, Alzheimer鈥檚 disease is the most common. Until recently, a diagnosis of dementia might help explain cognitive decline, but there were no treatments available to change the course of the disease. However, the last several years have brought a major change, as the first drugs that can slow the progression of Alzheimer鈥檚 have reached the market.

NIH-funded researchers are now drawing on decades of advances in detecting the changes that lead to Alzheimer鈥檚 and other dementias to develop strategies to try to prevent or slow their progression.

鈥淭here鈥檚 really consistent evidence that the process of Alzheimer鈥檚 disease in the brain begins at least a decade before symptoms appear鈥攎aybe even two decades,鈥 explains Dr. Reisa Sperling, an Alzheimer鈥檚 disease researcher at Harvard Medical School. The same appears to be true for many other dementias. 鈥淏ut that鈥檚 a glass-half-full situation, because it means we can potentially detect the disease before there is irreversible damage.鈥

Seeing damage in the brain

Brain image of woman showing large red areas. Brain PET measurements of a woman with an inherited condition that causes early-onset Alzheimer鈥檚 disease show high levels of amyloid plaques for her age. Blue represents lowest levels and red represents highest.Arboleda-Velasquez et al., Nature Medicine

Some types of damage to the brain, like from a stroke, are relatively easy to pick out with a CT scan in the emergency department. But the brain changes associated with dementia start at the molecular level and get worse slowly. In the past, this made them difficult to detect.

For example, until fairly recently, Alzheimer鈥檚 disease could only be confirmed after death. Characteristic damage to the brain could be seen during an autopsy. This damage includes abnormal clumps, called plaques, of a protein called amyloid-beta. It also involves bundles of fibers, or tangles, formed by another protein called tau.

Together, these harmful substances are thought to gum up the activity of neurons鈥攖he brain cells that convey chemical and electrical messages to create thoughts. This is associated with a progressive worsening of the cognitive symptoms of Alzheimer's disease.

鈥淭raditionally, the diagnosis of Alzheimer鈥檚 disease in patients聽was based on the clinical symptoms of dementia,鈥 explains Dr. Eliezer Masliah, an aging expert at NIH.

In the early 2000s, biomarkers to diagnose Alzheimer鈥檚 disease in living people first became available for research. Broadly, a biomarker is any measurable characteristic that can reliably help diagnose disease. Biomarkers may include molecules found in blood tests, results from imaging exams, or other characteristics.

For Alzheimer鈥檚 disease, a breakthrough came with positron emission tomography, or PET scans. This imaging technique could pinpoint the buildup of amyloid-beta in the brain. 鈥淭hat鈥檚 currently the gold standard for Alzheimer鈥檚 diagnosis,鈥 Weiner notes.

NIH-funded research has continued to build on this advance. For example, a recent study found that using PET to image tau in the brain was even better at predicting future brain degeneration than measuring amyloid-beta. PET imaging of tau may also aid future clinical trials.

PET scans, however, are extremely expensive and require exposure to radiation. Other tests have become available that don鈥檛 require brain imaging. One type measures amyloid-beta levels in the cerebrospinal fluid, or CSF, instead. Though less expensive than PET scans, these tests require a lumbar puncture鈥攖he insertion of a needle into the spinal canal. This procedure must be done by a specialist, typically takes 30 to 60 minutes, and not everyone can have one.

Building on the promise of these methods, researchers have been working to develop quicker and easier tests for biomarkers of Alzheimer鈥檚 disease. Blood tests would be ideal. 鈥淭he advantages of a blood test are that it鈥檚 easy to obtain, it鈥檚 very fast, and it鈥檚 much cheaper,鈥 Masliah says.

Such tests have the potential to greatly widen access to early diagnosis and treatment for Alzheimer鈥檚 disease. 鈥淢ost people with Alzheimer鈥檚 disease are cared for by general practitioners, not specialty clinics,鈥 Sperling explains. 鈥淚f these blood tests are accurate, people who aren鈥檛 Alzheimer鈥檚 specialists could use them to figure out how best to care for patients.鈥

Better tests for Alzheimer鈥檚

Immunofluorescence image of purple clusters around loose light blue clusters. Lysosomes (purple) within nerve cells that surround amyloid plaques (light blue) in a mouse model of Alzheimer鈥檚 disease. Swetha Gowrishankar and Shawn Ferguson, Yale School of Medicine

The most obvious target for an Alzheimer鈥檚 blood test is amyloid-beta. Dysfunctional forms of this protein can build up in the brain long before damage to neurons occurs. Studies have found that these abnormal proteins can also make their way into the bloodstream.

An NIH-funded research team recently developed a test that could detect clumps of amyloid-beta in the bloodstream. It could distinguish these clumps from other types of amyloid that aren鈥檛 thought to harm the brain. The test proved better at predicting the later development of Alzheimer鈥檚 dementia than other more invasive tests.

Another candidate for a blood-based biomarker of Alzheimer鈥檚 is tau. Tau tangles in the brain are thought to occur later in Alzheimer鈥檚 disease, but blood tests for some forms of tau have shown promise for early detection. One type of tau, called p-tau-217, for example, has recently shown especially strong results.

Two recent NIH-funded studies found that blood tests for p-tau-217 identified, with about 90% accuracy, people with Alzheimer鈥檚-related changes in the brain that were later verified by PET imaging.

Another class of promising biomarkers for Alzheimer鈥檚 are molecules that get released when neurons and other types of brain cells are damaged. Some of these molecules aren鈥檛 unique to Alzheimer鈥檚 and so might also be used for early diagnoses of different types of dementia.

Tests for other dementias

Gloved hand holding a test tube with brain images in background Science RF / Adobe Stock

Other types of dementia may be rarer than Alzheimer鈥檚 but no less devastating. Potential biomarkers for the early detection of other forms of dementia include a protein called 伪-synuclein. This may be able to help diagnose Lewy body dementia, as well as Parkinson鈥檚 disease, which can also affect the brain.聽

Researchers have also been studying potential biomarkers for a group of disorders that have some similarities to Alzheimer鈥檚, collectively known as frontotemporal disorders, or FTD. These rose in the public consciousness in 2023, when the family of actor Bruce Willis revealed his diagnosis.

Unlike Alzheimer鈥檚, FTD tends to occur most often in those under the age of 65 and starts with behavior or language changes. But like Alzheimer鈥檚, FTD can be difficult to diagnose before symptoms develop鈥攁nd sometimes even afterward鈥攅specially in people with no family history of the disease.

Recently, NIH-funded researchers showed that blood tests for a protein called neurofilament light chain, or NfL, hold promise for early detection of FTD and related conditions, such as amyotrophic lateral sclerosis, or ALS. NfL is one of the proteins released when nerve cells in the brain or body are damaged.

鈥淣fL won鈥檛 ever, on its own, be a diagnostic biomarker for any of the neurodegenerative diseases,鈥 explains Dr. Tania Gendron, an FTD researcher at the Mayo Clinic. 鈥淗owever, there are some diseases, like FTD or ALS, that have symptoms that might be mimicked by other diseases that are not neurodegenerative. So what NfL could do is help facilitate a diagnosis by ruling out or ruling in neuronal injury.鈥

Gendron and her collaborators found that, among people who carried a genetic risk factor for FTD, NfL levels in the blood were higher in those who later developed symptoms compared with those who didn鈥檛. Higher levels of NfL in blood samples taken at the start of the study were also associated with faster cognitive decline.

Having a test to catch FTD early would enable testing of treatments that aim to halt the disease before it causes substantial damage. But while NfL can detect neural damage, it can鈥檛 tell what molecular mechanisms set off that process. Many different genetic factors can affect FTD, and these will likely require different treatment strategies.

鈥淲e believe it's ideal to stop the molecular underpinnings of FTD as early as possible in its tracks,鈥 Gendron explains. 鈥淚t鈥檚 like one domino hits another domino, and then it just becomes chaos, like a snowball going down a mountain. So if you could halt the first key molecular events that trigger the disease, then you鈥檇 be better able to, hopefully, prevent worsening of that disease.鈥

Improving diversity, improving accuracy

Senior man with his eyes closed embracing a woman while standing in nursing home. wavebreakmedia / Shutterstock

Several blood tests for Alzheimer鈥檚 disease have already received a type of certification called CLIA, which means the test reliably measures what it claims to measure. To date, none have been approved by the Food and Drug Administration for guiding treatment. But the tests that have reached the CLIA stage are already being adopted by memory clinics and large, ongoing treatment studies, Sperling explains.

For example, Sperling鈥檚 team has been running large NIH-funded clinical trials of drugs to prevent the progression of Alzheimer鈥檚 disease. As imaging biomarkers have become more widespread, they鈥檝e pushed the timeline for intervention earlier and earlier鈥攆rom full-blown Alzheimer鈥檚 disease to its precursor, called mild cognitive impairment, and finally to people without any symptoms of cognitive decline.

For one of their ongoing studies, called AHEAD, 鈥渢he first step for screening is now a blood test,鈥 Sperling says. 鈥淚n terms of therapeutics that target amyloid buildup, treating earlier is better, probably even before symptoms develop. And the blood-based biomarkers are pretty good at finding people at that early stage of amyloid buildup.鈥

One roadblock has been that such blood tests haven鈥檛 been widely tested in diverse populations, Weiner explains. In the past, biomarker tests for dementia have largely enrolled people from white, well-educated, relatively wealthy groups. 鈥淏ut these tests should be validated in populations that really look like America,鈥 Weiner says.

The relationship between amyloid PET levels and dementia outcomes, for example, appears to vary across different populations. 鈥淲e don鈥檛 really understand the relationship of amyloid PET to Alzheimer鈥檚 pathology in the Black population very well,鈥 Weiner notes. That could lead to sub-optimal treatment for many patients.

For almost 20 years, Weiner and his team have been running a large NIH-funded study to improve biomarkers for Alzheimer鈥檚 disease. In the last year, they鈥檝e doubled participation among people from underrepresented groups.

鈥淯nderrepresented means Black, Latino, Asian/Pacific Islander, but also anyone with 12 years of education or less. And people from rural areas are also considered underrepresented,鈥 he adds. His team hopes to eventually have more than half of their participants come from underrepresented groups. Having diversity during a test鈥檚 validation greatly increases its likelihood of being useful across populations.

Sperling鈥檚 group is also working to diversify their study participants. They noticed that many people from communities of color weren鈥檛 meeting the amyloid PET criteria for study participation, regardless of their symptoms. So this year, they started a new study that uses blood tests to explore what happens in the brains of people who have low levels of amyloid on PET scans but are at risk for developing dementia in the future.

The team hopes to find patterns in blood tests that will help inform future prevention strategies. 鈥淚 think we鈥檙e getting closer to precision medicine,鈥 Sperling says. 鈥淚f amyloid is not the main contributor to Alzheimer鈥檚 symptoms in some communities, then we鈥檒l need other drugs.鈥

Reliable, early biomarkers will also allow for the testing of strategies that may sound like science fiction today, such as anti-Alzheimer鈥檚 vaccines, Sperling explains. 鈥淭hat鈥檚 the future鈥攖hat鈥檚 the way you鈥檇 be able to get preventive treatment to millions, or tens or hundreds of millions of people who need it.鈥

鈥淲hat鈥檚 happening with biomarkers in Alzheimer鈥檚 disease is a real breakthrough; it has completely transformed the field,鈥 Masliah says. 鈥淏ut I can鈥檛 stress enough the importance of people participating in these studies. All these breakthroughs have been not only due to the great work that the researchers are doing, but to the people who are volunteering to take part.鈥

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鈥攂y Sharon Reynolds

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References: 聽La Joie R, Visani AV, Baker SL, Brown JA, Bourakova V, Cha J, Chaudhary K, Edwards L, Iaccarino L, Janabi M, Lesman-Segev OH, Miller ZA, Perry DC, O'Neil JP, Pham J, Rojas JC, Rosen HJ, Seeley WW, Tsai RM, Miller BL, Jagust WJ, Rabinovici GD.聽Sci Transl Med. 2020 Jan 1;12(524). pii: eaau5732. doi: 10.1126/scitranslmed.aau5732. PMID:31894103.

聽Shea D, Colasurdo E, Smith A, Paschall C, Jayadev S, Keene CD, Galasko D, Ko A, Li G, Peskind E, Daggett V.聽Proc Natl Acad Sci U S A. 2022 Dec 13;119(50):e2213157119. doi: 10.1073/pnas.2213157119. Epub 2022 Dec 9. PMID:聽36490316.

聽Palmqvist S, Janelidze S, Quiroz YT, Zetterberg H, Lopera F, Stomrud E, Su Y, Chen Y, Serrano GE, Leuzy A, Mattsson-Carlgren N, Strandberg O, Smith R, Villegas A, Sepulveda-Falla D, Chai X, Proctor NK, Beach TG, Blennow K, Dage JL, Reiman EM, Hansson O.聽JAMA. 2020 Jul 28. doi: 10.1001/jama.2020.12134. Online ahead of print. PMID: 32722745.

聽Barth茅lemy NR, Horie K, Sato C, Bateman RJ.聽J Exp Med. 2020 Nov 2;217(11):e20200861. doi: 10.1084/jem.20200861. PMID: 32725127.

. Gendron TF, Heckman MG, White LJ, Veire AM, Pedraza O, Burch AR, Bozoki AC, Dickerson BC, Domoto-Reilly K, Foroud T, Forsberg LK, Galasko DR, Ghoshal N, Graff-Radford NR, Grossman M, Heuer HW, Huey ED, Hsiung GR, Irwin DJ, Kaufer DI, Leger GC, Litvan I, Masdeu JC, Mendez MF, Onyike CU, Pascual B, Ritter A, Roberson ED, Rojas JC, Tartaglia MC, Wszolek ZK, Rosen H, Boeve BF, Boxer AL; ALLFTD consortium, Petrucelli L.聽Cell Reports Medicine. 2022 Apr 19;3(4):100607. doi: 10.1016/j.xcrm.2022.100607. eCollection 2022 Apr 19. PMID: 35492244.

聽Ashton NJ, Janelidze S, Al Khleifat A, Leuzy A, van der Ende EL, Karikari TK, Benedet AL, Pascoal TA, Lle贸 A, Parnetti L, Galimberti D, Bonanni L, Pilotto A, Padovani A, Lycke J, Novakova L, Axelsson M, Velayudhan L, Rabinovici GD, Miller B, Pariante C, Nikkheslat N, Resnick SM, Thambisetty M, Sch枚ll M, Fern谩ndez-Eulate G, Gil-Bea FJ, L贸pez de Munain A, Al-Chalabi A, Rosa-Neto P, Strydom A, Svenningsson P, Stomrud E, Santillo A, Aarsland D, van Swieten JC, Palmqvist S, Zetterberg H, Blennow K, Hye A, Hansson O.聽Nat Commun.聽2021 Jun 7;12(1):3400. doi: 10.1038/s41467-021-23620-z. PMID:聽34099648.