Stanford inventors have devised a method of multiplexing droplet reactions to analyze and identify many reactions in parallel on a single microfluidic chip using off-the-shelf flow control and valving.
Stanford University researchers have developed a system that achieves atmospheric water harvesting with high specific productivity, defined as the rate of water collected per mass of absorbent material.
Researchers in Prof. Juan Santiago's laboratory have developed a technique to rapidly preconcentrate and capture biological targets with high specificity and efficiency. The process can be used to reduce reaction times for microarray analyses and affinity chromatography.
Stanford Prof. Juan Santiago and a team of engineers have developed a method of speeding up chemical reactions between a probe on a surface and a molecule in solution.
Stanford researchers have discovered a way of regulating pressure-driven flow in fluidic passages by utilizing phase change materials to seal fluidic passages.
Electroosmotic (EO) pumps (also known as electrokinetic pumps) generate fluid flow and pressure in a compact system with no moving parts. They can be combined with microchannel heat exchangers to provide cooling for microelectronics. Researchers in Dr.
Engineers in the Stanford Microfluidics Laboratory have developed a sensitive, high-resolution, label-free detection method for identifying and quantifying analytes on chip-based electrophoretic assays.
This invention enables the high-sensitivity, high-resolution stacking, separation, and fluorescence-based detection of non-fluorescent analytes in any electrophoresis platform.
Researchers in Prof. Juan Santiago's laboratory have developed a novel isotachophoresis (ITP) method to easily and seamlessly integrate various electrophoresis-based detection techniques with ITP preconcentration.