The mechanical properties of cells and their environments strongly influence how biological systems function. They can determine the cells’ shapes, dictate how the cells move, and even affect gene expression. When it comes to investigating those properties, though, traditional biophysical techniques, such as bulk rheological measurements, take a long time and can require large sample volumes. Now Richard Superfine, Leandra Vicci, and their colleagues at the University of North Carolina at Chapel Hill have built a microscope system to speed up the process. Shown here, their shoebox-sized instrument is an array of 12 independent fluorescence microscopes, whose objectives are spaced to work with a standard lab plate with 96 sample wells. Three stepper motors move the lab plate in an automated sequence over the objective array. The package is designed for a technique called passive microrheology, which measures the mechanical properties of a biofluid by tracking the thermal motion...

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