User:Granto uw/sandbox dropletdraft

Droplet sorting
Droplet sorting in microfluidics is an important technique, allowing for discrimination based on factors ranging from droplet size to chemicals labeled with fluorescent tags within the droplet, stemming off of the work done to sort cells in Flow Cytometry. Within the realm of droplet sorting there are two main types, bulk sorting, which uses either active or passive methods, and precise sorting, which relies mainly on active methods. Bulk sorting is applied to samples with a large number of droplets (> 2000 s-1) that can be sorted based off intrinsic properties of the droplets (such as viscosity, density, etc.) without checking each droplet. Precise sorting, on the other hand, aims to separate droplets that meet certain criteria that is checked on each droplet.

Passive sorting is done through control of the microfluidic channel design, allowing for discrimination based on droplet size. Size sorting relies on the bifurcating junctions in the channel to divert the flow, which causes droplets to sort based on how they interact with the cross section of that flow, the shear rate, which relates directly to their size. Other passive methods include inertia and microfiltration, each having to do with the physical properties, such as inertia, and density, of the droplet. Active sorting uses additional devices attached to the microfluidic device to alter the path of a droplet during flow by controlling some aspect, including thermal, magnetic, pneumatic, acoustic, hydrodynamic and electric control. These controls are utilized to sort the droplets in response to some signal detection from the droplets such as fluorescence intensity.

Precise sorting methods utilize these active sorting methods by first making a decision (e.g., fluorescence signal) about the droplets then altering their flow with one of the aforementioned methods. A technique called Fluorescent Activated Droplet Sorting (FADS) has been developed which utilizes electric field-induced active sorting with fluorescent detection to sort up to 2000 droplets per second. The method relies on, but is not limited to, enzymatic activity of compartmentalized target cells to activate a fluorogenic substrate within the droplet. When a fluorescing droplet is detected, two electrodes are switched on applying a field to the droplet, which shifts its course into the selection channel, while non-fluorescing droplets flow through the main channel to waste. Other methods utilize different selection criteria, such as absorbance of droplet, number of encapsulated particles, or image recognition of cell shapes. Sorting can be done to improve encapsulation purity, an important factor for collecting sample for further experiments.