Abstract: Disclosed herein are two related techniques for digital microfluidic (DMF) processing of liquids that rely on electrostatic actuation of fluid through a strip of solid, porous media. In the first technique, droplets in a DMF device containing particles of different sizes are driven through a solid porous medium, allowing for filtering, concentration, and recovery of the particles into droplets on the basis of size. In the second technique, an aliquot of liquid media is loaded directly onto a solid porous medium, where it is wicked into a DMF device, such that the filtrate can be collected into droplets. Both techniques may be useful for generating plasma from whole blood on a DMF device, an operation that will have far-reaching implications for diagnostic applications of digital microfluidics.

Abstract: The present disclosure provides a method for performing agglutination assays on a “two plate” DMF device format. Droplets containing analytes of interest (particles, cells, etc.) are loaded into the DMF device and mixed with solution-phase or dried agglutinating antibodies or antigens. The agglutinating agents bind to their complementary targets (e.g. antibodies or antigens for example) in the sample droplets, which leads to the formation of insoluble aggregates. Active mixing on a DMF device reduces the reaction time and enhances the agglutination effect. Since the agglutinated sample is sandwiched between two plates on the DMF device, it is straightforward to visualize the result by eye or via a digital camera.

Abstract: Disclosed herein are two related techniques for digital microfluidic (DMF) processing of liquids that rely on electrostatic actuation of fluid through a strip of solid, porous media. In the first technique, droplets in a DMF device containing particles of different sizes are driven through a solid porous medium, allowing for filtering, concentration, and recovery of the particles into droplets on the basis of size. In the second technique, an aliquot of liquid media is loaded directly onto a solid porous medium, where it is wicked into a DMF device, such that the filtrate can be collected into droplets. Both techniques may be useful for generating plasma from whole blood on a DMF device, an operation that will have far-reaching implications for diagnostic applications of digital microfluidics.

Abstract: The present disclosure provides a system and method for identifying and targeting individual cells within a cell population for selective extraction of cellular content and a digital microfluidic device having at least one hydrophilic site for receiving cells, an imaging system including a stage for receiving the digital microfluidic device and an imaging module for identifying at least one targeted cell among the cells at the at least one hydrophilic site. The system includes a pulsed laser source for laser lysing the targeted cell thereby releasing the cell content to produce a lysate.

Abstract: The present disclosure provides a system and method for identifying and targeting individual cells within a cell population for selective extraction of cellular content and a digital microfluidic device having at least one hydrophilic site for receiving cells, an imaging system including a stage for receiving the digital microfluidic device and an imaging module for identifying at least one targeted cell among the cells at the at least one hydrophilic site. The system includes a pulsed laser source for laser lysing the targeted cell thereby releasing the cell content to produce a lysate.