Rapid Fabrication of Superhydrophobic Virtual Walls for Microfluidic Gas Extraction and Sensing

Based on the virtual walls concept, where fluids are guided by wettability, we demonstrate the application of a gas phase extraction microfluidic chip. Unlike in previous work, the chip is prepared using a simple, rapid, and low-cost fabrication method. Channels were cut into double-sided adhesive tape (280 mu m thick) and bonded to hydrophilic glass slides. The tape was selectively made superhydrophobic by 'dusting' with hydrophobic silica gel to enhance the wettability contrast at the virtual walls. Finally, the two glass slides were bonded using tape, which acts as a spacer for gas transport from/to the guided liquids. In our example, the virtual walls create a stable liquid-vapor-liquid flow configuration for the extraction of a volatile analyte (ammonia), from one liquid stream to the other through the intermediate vapor phase. The collector stream contained a pH indicator to visualize the mass transport. Quantitative analysis of ammonium hydroxide in the sample stream (<1 mM) was possible using a characteristic onset time, where the first pH change in the collector stream was detected. The effect of gap length, flow rates, and pH of the collector stream on the onset time is demonstrated. Finally, we demonstrate the analysis of ammonium hydroxide in artificial human saliva to show that the virtual walls chip is suitable for extracting volatile analytes from biofluids.

Automated summary

This study demonstrates the application of a gas phase extraction microfluidic chip based on the concept of virtual walls where fluids are guided by wettability. The chip is prepared using a simple, rapid, and low-cost fabrication method, allowing for the stable liquid-vapor-liquid flow configuration for the extraction of volatile analytes. The analysis of ammonium hydroxide in artificial human saliva shows that the virtual walls chip is suitable for extracting volatile analytes from biofluids.