CUSTOM APTAMER DISCOVERY & DEVELOPMENT is the process of creating target-specific single-stranded DNA or RNA aptamers—short nucleic acids that fold into 3D shapes capable of binding proteins, small molecules, cells, vesicles, or other targets with antibody-like selectivity. Most custom programs rely on SELEX (Systematic Evolution of Ligands by EXponential enrichment), then refine “hits” into robust, application-ready binders through sequencing-driven analysis and post-selection optimization. 1) What Aptamers Are (and Why They’re Used) Aptamers are typically ~15–90 nucleotides long and can be engineered to bind targets across a wide size range (from small molecules to whole cells). They’re attractive because they are chemically synthesized (batch-to-batch consistency), can be readily labeled (fluorophores, biotin, etc.), and are generally thermally stable and re-foldable—features that often simplify assay development and manufacturing. Common aptamer use cases Diagnostics & biosensors (capture probes, signal transducers, point-of-care formats) Targeted delivery & therapeutics research (cell-directed binding, payload delivery concepts) Affinity purification & analytical workflows (pull-downs, enrichment, separations) 2) The Core Workflow in Custom Aptamer Discovery A custom program is best thought of as a pipeline with four linked decisions: target format → selection strategy → analytics → optimization. Step A — Target Definition and “Bindability” Planning…
Molecular imaging is a family of techniques that visualizes biological processes in living subjects by using probes that bind to specific molecular targets. In nuclear medicine, PET (positron emission tomography) and SPECT (single-photon emission computed tomography) are workhorse modalities because they can detect tiny (trace) amounts of radiolabeled compounds and quantify target-related signals in vivo. Within PET/SPECT, targeted peptides have become a major probe class: short amino-acid sequences engineered to recognize receptors or other biomarkers (often overexpressed in tumors or diseased tissue), then “tagged” with a radionuclide so the binding event becomes imageable. 1) What Makes Peptide Targeting So Useful in PET and SPECT? Peptides sit in a sweet spot between small molecules and antibodies: High affinity and specificity (when well-designed): peptides can be tuned to fit receptor binding pockets or interaction surfaces, producing strong target-to-background contrast. Fast pharmacokinetics: many peptides clear from blood relatively quickly, which can reduce background signal and enable same-day imaging workflows (depending on isotope half-life and probe design). Chemically modular: it’s typically straightforward to add linkers, chelators, or stabilizing modifications without destroying binding—if the chemistry is placed away from the binding “hot spots.” In practice, peptide probes often target cell-surface receptors…
Peptide therapeutics (sometimes called “peptide therapy” in popular health content) refers to the design and development of peptide-based medicines—short chains of amino acids engineered to treat, manage, or modify disease. Unlike vague wellness claims, therapeutic peptides in drug development are defined, characterized, and manufactured as medicinal products with measurable pharmacology, safety testing, and quality controls. Peptides occupy a practical middle ground between small molecules and large biologics: they can be highly selective like proteins while remaining more modular and tunable through chemical design. What Exactly Are Peptides in Medicine? A peptide is a molecule made of amino acids linked by peptide bonds. In therapeutics, peptides are often sized to be large enough to recognize biological targets precisely, but small enough to be synthesized and optimized with medicinal chemistry approaches. Reviews describe peptide drugs as a distinct class with strengths such as specificity and structural versatility, alongside known limitations such as enzymatic breakdown and delivery barriers. Why Peptide Drugs Matter: The Biological “Sweet Spot” Peptide therapeutics are valuable because they can: Bind targets with high specificity (reducing off-target effects compared with many small molecules). Mimic or modulate natural signaling pathways, because many hormones and signaling mediators are peptide-like.…