Laser-Fabricated 2D Molybdenum Disulfide Electronic Sensor Arrays for Rapid, Low-Cost, Ultrasensitive Detection of Influenza A and SARS-Cov-2.

Multiplex electronic antigen sensors for detection of SARS-Cov-2 spike glycoproteins and hemagglutinin from influenza A are fabricated using scalable processes for straightforward transition to economical mass-production. The sensors utilize the sensitivity and surface chemistry of a 2D MoS ₂ transducer for attachment of antibody fragments in a conformation favorable for antigen binding with no need for additional linker molecules. To make the devices, ultra-thin layers (3 nm) of amorphous MoS ₂ are sputtered over pre-patterned metal electrical contacts on a glass chip at room temperature. The amorphous MoS ₂ is then laser annealed to create an array of semiconducting 2H-MoS ₂ transducer regions between metal contacts. The semiconducting crystalline MoS ₂ region is functionalized with monoclonal antibody fragments complementary to either SARS-CoV-2 S1 spike protein or influenza A hemagglutinin. Quartz crystal microbalance experiments indicate strong binding and maintenance of antigen avidity for antibody fragments bound to MoS ₂ . Electrical resistance measurements of sensors exposed to antigen concentrations ranging from 2-20 000 pg mL ^-1 reveal selective responses. Sensor architecture is adjusted to produce an array of sensors on a single chip suited for detection of analyte concentrations spanning six orders of magnitude from pg mL ^-1 to µg mL ^-1 .
Competing Interests: The authors declare no conflict of interest.
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