Functional nucleic acids (FNAs), which include both DNA/RNA aptamers and DNA enzymes, have emerged as promising biological recognition elements for biosensors. These species typically require immobilization on or within a solid support, which is usually interfaced to some kind of signal transducer and readout system when use in biosensor. Our group has successfully immobilized several functional nucleic acids in the past, including fluorescence-signalling DNA enzymes, DNA aptamers and RNA aptamers by entrapping them into porous silica or organosilica materials prepared by the sol-gel method using percursors such as sodium silicate (SS), diglyceryl silane (DGS), tetrametylorthosilicate (TMOS) and trimethoxymethysilane (MTMS).
While the earlier work established the ability of entrapped FNAs to retain binding and catalytic activity, only limited information was obtained on how different factors affect the performance of immobilized FNAs, and no information was obtained on the effects of aging and storage conditions on FNA performance. The initial objective of this thesis was to employ advanced fluorescence methods to better understand the nature of immobilized DNA and RNA aptamers, and in particular how entrapment in different sol-gel based materials affected FNA performance for detection of small molecule analytes. It was found that the ability of the entrapped aptamer reporters to remain fully hybridized was the most important factor in terms of signalling capability for both DNA and RNA aptamer reporters. It was also observed that more polar materials derived from SS were optimal for both types of aptamer reporters, since these allowed the entrapped aptamers to remain hydridized to their complementary strands and still retain the dynamic motion needed to undergo structure switching, while providing a minimum degree of leaching.
The second objective of my research was to develop a paper-based biosensing device incorporating immobilized DNA and RNA aptamers that could be used in the fields of point-of-care diagnostics to further expand the utility of structure-switching aptamer reporters to real world application. A dual response (fluorescence / colorimetric) paper-based sensor utilized printed graphene oxide to immobilize both a RNA and a DNA aptamer in a recognition zone. Upon target addition, the aptamer desorbed and eluted to an amplification zone where rolling circle amplification was used to generate a colorimetric output. This sensor could function with clinical samples such as serum and stool, and allowed detection of key bacterial markers (ATP and glutamate dehydrogenase) at clinically relevant levels. / Thesis / Doctor of Philosophy (PhD)
Identifer | oai:union.ndltd.org:mcmaster.ca/oai:macsphere.mcmaster.ca:11375/23447 |
Date | 07 December 2017 |
Creators | Hui, Christy |
Contributors | Brennan, John, Chemical Biology |
Source Sets | McMaster University |
Language | English |
Detected Language | English |
Type | Thesis |
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