An international working group of experts has agreed on guidelines to help increase scientific and public awareness about a brain condition that mimics Alzheimer’s disease. The condition is not new but has come to light in recent research and clinical trials. Share on Pinterest Researchers have identified a misfolded protein in the brain that may be ‘a possible Alzheimer’s mimic.’ Scientists have recently recognized Limbic-predominant Age-related TDP-43 Encephalopathy (LATE) as a “newly named pathway to dementia.” The working group consists of scientists from a number of centers that receive support from the National Institutes of Health (NIH), together with colleagues from other countries. The experts suggest that the public health impact of LATE on people in their mid-80s and older is probably about the same, if not bigger, than that of Alzheimer’s disease. In a report that now features in the journal Brain, the group proposes the first definition of LATE and recommends guidelines for those who are concerned with diagnosis and furthering research. Richard J. Hodes, M.D., who is director of the National Institute on Aging (NIA), which forms part of the NIH, says that even though researchers working on Alzheimer’s disease are making progress, they still ask themselves: “When is Alzheimer’s disease not Alzheimer’s disease in older adults?”

How LATE differs from Alzheimer’s disease The new report explains that while LATE has clinical features of Alzheimer’s disease, postmortem tests have revealed that it affects brain tissue differently. One of the main differences concerns a protein called transactive response DNA binding protein of 43 kDa (TDP-43). TDP-43’s role in cells is to switch genes on and off for various functions. However, to do this, it must have the correct, folded 3D shape. Recent research has revealed that badly folded TDP-43 frequently occurs in older adults. As badly folded TDP-43 accumulates, it begins to affect the person’s ability to remember and think. Around 25% of those over 85 years old have difficulties with thinking and memory due to badly folded TDP-43. Studies have also implicated badly folded TDP-43 in other, more uncommon brain diseases, such as amyotrophic lateral sclerosis and a type of dementia called frontotemporal lobar degeneration. Another difference between LATE and Alzheimer’s disease is that the presence of badly folded TDP-43 often occurs with hippocampal sclerosis, a condition that causes loss of cells and tissue in the hippocampus. The hippocampus is important for memory and learning, and people with hippocampal sclerosis can have symptoms of memory and thinking impairment that are similar to those of Alzheimer’s disease.

Understanding other causes of dementia Nina Silverberg, Ph.D., who is director of the Alzheimer’s Disease Centers Program at NIA, co-chaired the workshop in which the expert group developed the guidelines. The workshop took place in Atlanta, GA, on October 17–18, 2018. As well as scientists from the United States, the working group includes experts from Australia, Austria, Japan, Sweden, and the United Kingdom. Their expertise ranges from brain imaging and clinical diagnosis to genetics, neuropathology, and neuropsychology. Silverberg explains that those working in the field have learned two things from recent clinical trials and research: “First, not all of the people we thought had Alzheimer’s have it; second, it is very important to understand the other contributors to dementia.” A distinguishing feature of Alzheimer’s disease is the presence of a protein called beta-amyloid, which, like TDP-43, can also cause problems when it does not fold correctly. As more and more evidence from postmortem tests has emerged, it suggests that many people who took part in clinical trials probably did not have beta-amyloid deposits, although their symptoms matched those of Alzheimer’s. Silverberg says that it was the growing body of research “implicating TDP-43 as a possible Alzheimer’s mimic” that prompted the workshop as a need “to provide a starting point for further research that will advance our understanding of another contributor to late-life brain changes.”