“Aptamer fields” can be understood as the interconnected research and application areas where aptamers—short, single-stranded DNA or RNA molecules—are designed and used as highly selective binding agents (often described as “chemical antibodies”) for targets ranging from proteins and small molecules to whole cells. This article explains what defines the aptamer fields, how aptamers are created, where they’re used, and what technical trends are shaping the space. 1) What Are Aptamers (and Why They Matter in Aptamer Fields)? Aptamers are typically ~20–100 nucleotides long and fold into 3D structures that bind specific targets with high affinity and specificity. Unlike antibodies (biological proteins), aptamers are nucleic acids, which affects how they are discovered, synthesized, modified, and integrated into devices. Key reasons aptamers have become a “field” rather than a niche tool: Programmability: sequence-controlled design and chemical modification Manufacturability: scalable synthesis routes compared with biological production Versatility: diagnostics, biosensing, therapeutics, imaging, and research reagents 2) The Core Engine: SELEX and How Aptamers Are Discovered Most aptamers are generated using SELEX (Systematic Evolution of Ligands by EXponential enrichment), an iterative in-vitro selection process that enriches sequences that bind a chosen target. In common workflows, a large random library is…
