A recent study conducted by researchers at the University of Washington has shed light on the behavior of immune cells known as microglia in the brains of individuals with Alzheimer’s disease compared to those in healthy brains. This research, which was published in August, offers insights into potential new targets for treatment of Alzheimer’s disease.

Microglia are a type of immune cell found in the brain that play a crucial role in maintaining brain health by clearing waste and supporting normal brain function. These cells have the unique ability to adapt their shape and mobility to respond to infections and remove dead cells. Additionally, they play a role in shaping the brain’s circuitry during development.

In the context of Alzheimer’s disease, the role of microglia has been less clear. Some studies have suggested that certain microglia may respond excessively, leading to inflammation and contributing to the death of brain cells. Despite this understanding, clinical trials of anti-inflammatory medications for Alzheimer’s have not yielded significant results.

To delve deeper into the role of microglia in Alzheimer’s disease, neuroscientists Katherine Prater and Kevin Green, along with colleagues from various US institutions, conducted research using brain autopsy samples from individuals with Alzheimer’s and healthy controls. The study focused on analyzing the gene activity of microglia to understand their behavior.

Using a novel method called single-nucleus RNA sequencing, the researchers were able to identify ten distinct clusters of microglia within the brain tissue. Interestingly, three of these clusters had not been previously observed, and one of them was more prevalent in individuals with Alzheimer’s disease. These particular microglia had active genes associated with inflammation and cell death, indicating a potential link to the disease’s progression.

Overall, the study found that microglia clusters in the brains of those with Alzheimer’s were more likely to be in a pre-inflammatory state. This meant that they were more inclined to produce inflammatory molecules that could harm brain cells and potentially contribute to the advancement of the disease. Furthermore, these microglia types in Alzheimer’s brains appeared to be less effective at their usual tasks of clearing dead cells and waste and supporting healthy brain aging.

One significant finding from the research was the suggestion that microglia types can change over time. This dynamic nature of microglia behavior implies that it may not be possible to definitively determine a person’s microglia type solely by examining their brain. Understanding how microglia change over time may provide valuable insights into their role in Alzheimer’s disease.

Katherine Prater, one of the lead researchers, emphasized that this research is still in its early stages. However, it represents a significant step forward in our understanding of the role of microglia in Alzheimer’s disease and points to specific microglia clusters as potential targets for future treatments.

The research team is optimistic that their findings will pave the way for the development of new therapies aimed at improving the lives of individuals affected by Alzheimer’s disease. By identifying the genetic profiles of these microglia, researchers hope to uncover their specific functions and behaviors, which could ultimately lead to treatments that prevent or slow the progression of the disease.

In summary, the study conducted by the University of Washington researchers highlights the differences in microglia behavior between Alzheimer’s and healthy brains, suggesting that specific microglia clusters may serve as potential treatment targets for Alzheimer’s disease. While the research is in its early stages, it offers hope for the development of new therapies to enhance the quality of life for those affected by this devastating neurodegenerative disease.