Abstract: The present application relates to biosensors, for example comprising an high-molecular weight, tandem repeating, structure-switching nucleic acid aptamers (concatemeric aptamers) to rapidly create patterned sensors via, for example, inkjet printing. These concatemeric aptamer reporters remain immobilized at the point of printing through strong adsorption but retain sufficient segmental mobility to undergo structure switching and reporter signalling to provide both qualitative and quantitative detection of one or more analytes. In certain embodiments, inkjet printing allows for the patterning of internally referenced sensors with multiplexed detection, and provides a generic platform for on-demand printing of sensors even in remote locations.

Abstract: The present application relates to a new class of macroporous bio/inorganic hybrids, engineered through a high-throughput materials screening approach that entrap micron-sized concatemeric DNA aptamers. The entrapment of these long-chain DNA aptamers allows their retention within the macropores of the silica material, so that aptamers can interact with high molecular weight targets such as proteins.

Abstract: The present application relates to biosensors, for example comprising an high-molecular weight, tandem repeating, structure-switching nucleic acid aptamers (concatemeric aptamers) to rapidly create patterned sensors via, for example, inkjet printing. These concatemeric aptamer reporters remain immobilized at the point of printing through strong adsorption but retain sufficient segmental mobility to undergo structure switching and reporter signalling to provide both qualitative and quantitative detection of one or more analytes. In certain embodiments, inkjet printing allows for the patterning of internally referenced sensors with multiplexed detection, and provides a generic platform for on-demand printing of sensors even in remote locations.