“High-throughput aptamer screening” is a method used to rapidly identify aptamers—short single-stranded DNA or RNA molecules—that can bind specifically to a target molecule, such as a protein, small molecule, or even whole cells. Let’s break this down in detail: 1. What Are Aptamers? Aptamers are oligonucleotides (DNA or RNA) that fold into specific three-dimensional shapes allowing them to bind with high affinity and specificity to their targets. They function similarly to antibodies but are synthetic, smaller, more stable, and can be chemically modified. 2. High-Throughput Screening (HTS) in Aptamer Discovery Traditional aptamer discovery uses SELEX (Systematic Evolution of Ligands by Exponential Enrichment), which involves multiple iterative rounds of binding, separation, and amplification. High-throughput aptamer screening accelerates this process by using automation and large-scale technologies to simultaneously test thousands to millions of sequences against the target. 3. Key Techniques in High-Throughput Aptamer Screening Microarray-Based Screening Thousands of aptamer candidates are immobilized on a chip. The target (protein, small molecule, or cell) is fluorescently labeled and applied. Aptamers that bind the target emit signals detected by imaging. Next-Generation Sequencing (NGS)-Coupled SELEX After each SELEX round, sequences are analyzed via NGS. Sequence enrichment patterns reveal high-affinity aptamer candidates without the need for extensive…
What is Small Molecule SELEX? SELEX is an iterative in vitro selection process that sifts through a vast random library of nucleic acid sequences (typically 10^13 - 10^15 different molecules) to find the few that bind tightly and specifically to a target. The Challenge with Small Molecules: Low epitope density: Small molecules offer limited surface area for binding, making it hard to find high-affinity aptamers. Immobilization required: They must be attached to a solid support (beads, chip, column) for partitioning, which can mask potential binding sites or introduce non-specific interactions. Negative Selection is Crucial: To avoid selecting aptamers that bind to the immobilization matrix instead of the target. Standard Service Workflow (What the Provider Does): Project Design & Target Immobilization: Consultation: The provider works with you to understand the target's chemistry, desired affinity, and application (e.g., biosensor, therapeutic inhibitor, diagnostic). Conjugation: They chemically conjugate your small molecule to an appropriate carrier (e.g., beads, magnetic particles, agarose resin, or a surface like a chip). This is a critical, proprietary step for many providers. The SELEX Cycle (Repeated 8-15 rounds): Incubation: The vast oligonucleotide library is incubated with the immobilized target. Partitioning: Unbound sequences are washed away. Sequences bound to the target (and unfortunately, sometimes to the matrix) are retained. Elution: Bound…
CELL-SELEX (Cell-Based Systematic Evolution of Ligands by EXponential enrichment) is a selection strategy used to discover nucleic-acid aptamers—short single-stranded DNA or RNA molecules that fold into shapes capable of binding cellular targets with high affinity and specificity. What makes CELL-SELEX AND BIOMARKER DISCOVERY such a powerful pairing is that cell-SELEX can enrich binders against native cell-surface features (often membrane proteins, glycoproteins, lipids, or complex epitopes) without needing to know the target in advance. This is especially valuable in biomarker discovery, where the “best” marker may be unknown, heterogeneous, or highly dependent on the cellular context. 1) What CELL-SELEX Is (and Why It Matters for Biomarkers) Traditional SELEX often starts with a purified target (e.g., a recombinant protein). In cell-SELEX, the “target” is a living cell population that represents a phenotype you care about—such as a disease subtype, drug-resistant cells, activated immune cells, or a specific differentiation stage. The selection process enriches aptamers that bind those cells while removing sequences that bind irrelevant or shared features. Why this matters for biomarkers: Native conformation is preserved. Cell-surface proteins keep their natural folding, post-translational modifications, and membrane context—features that can be lost in purified preparations. Unbiased discovery. You can discover binding…
When people search “aptamers vs antibodies”, they usually want a clear answer to one question: which binding reagent is better for my target and my workflow? The honest scientific answer is that aptamers and antibodies solve the same problem (molecular recognition) with very different chemistry, and those differences create predictable trade-offs in performance, manufacturability, and real-world robustness. This article explains those trade-offs in a decision-friendly way—focusing on mechanisms, measurable properties, and typical failure modes—so you can pick the right reagent for diagnostics, biosensing, or therapeutic R&D. What Are Aptamers? Aptamers are short, single-stranded DNA or RNA oligonucleotides that fold into 3D shapes capable of binding a target (proteins, small molecules, cells, even toxic or non-immunogenic targets). They’re usually discovered by SELEX(Systematic Evolution of Ligands by EXponential enrichment), an in vitro selection process that iteratively enriches sequences with the best binding. SELEX in one breath (why it matters) SELEX is essentially “laboratory evolution”: bind → separate → amplify → repeat. Because it’s in vitro, you can design selection pressure to prioritize what you actually need (high salt tolerance, temperature stability, discrimination against look-alike proteins, etc.). What Are Antibodies? Antibodies are proteins produced by immune systems (or…
“CATALOG APTAMERS & REAGENTS” usually refers to ready-to-order, pre-characterized aptamer affinity binders and the supporting assay reagents that make those binders usable in real experiments (e.g., labeling, immobilization, buffers, and controls). Aptamers themselves are short, single-stranded DNA or RNA (or related chemistries) selected from very large libraries to bind a specific target with high affinity and specificity—often described as antibody-like binding, but built from nucleic acids and produced by chemical synthesis. 1) What Are Aptamers (and Why They Matter as Reagents)? Aptamers are single-stranded nucleic acids that fold into 3D structures capable of recognizing targets such as proteins, small molecules, ions, or even cells. They are typically discovered through SELEX (Systematic Evolution of Ligands by EXponential enrichment), an iterative selection process that enriches sequences that bind the desired target. What makes aptamers especially “catalog-friendly” is that once a sequence is known, it can be reliably reproduced by chemical synthesis, and easily chemically modified (for example, adding a fluorophore or biotin) to fit common assay formats. 2) “Catalog Aptamers” vs Custom Aptamer Discovery Catalog Aptamers (ready-to-order) Catalog aptamers are fixed, known sequences that have been previously selected and are sold as standard products. Their main value…