Alzheimer’s disease, a progressive neurodegenerative disorder, is marked by beta-amyloid plaque accumulation and cognitive decline. The limited efficacy and significant side effects of anti-amyloid monoclonal antibody therapies have prompted exploration into innovative treatments like focused ultrasound therapy. Focused ultrasound shows promise as a non-invasive technique for disrupting the blood–brain barrier, potentially enhancing drug delivery directly to the brain and improving the penetration of existing therapeutic agents.

Researchers from Brown University and their collaborators have developed a new way to measure the properties of cells—an important development, they say, because accurate measurements of changes in cell elasticity can be used to better understand diseases, diagnose patient symptoms and provide more accurate prognoses.

For example, cancer cells from tumors typically soften as they become more dangerous and likely to spread, while blood diseases like malaria and sickle cell can cause red blood cells to stiffen. Mechanical changes on a cellular level are also seen in neurodegenerative, cardiovascular and chronic inflammatory illnesses.

As detailed in a study in the journal Lab on a Chip, the researchers developed what they call a “mechanophenotyping cytometer”—a microfluidic device designed to measure a cell’s physical size and squishiness, known as its mechanical phenotype.