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Acid-PEG5-bis-PEG3-azide
| Catalog Number | R14-0328 |
| Category | Azides |
| Molecular Formula | C39H73N9O18 |
| Molecular Weight | 956.05 |
* Please be kindly noted products are not for therapeutic use. We do not sell to patients.
Product Introduction
A branched linker with two azides for click chemistry and a carboxylic acid
Chemical Information
Product Specification
Application
| Purity | >90% by HPLC |
| Solubility | DCM, THF, acetonitrile, DMF and DMSO |
| Appearance | Oil |
| Storage | -20 °C |
Acid-PEG5-bis-PEG3-azide is a multifunctional linker molecule often used in bioconjugation and drug delivery systems. Here are some key applications of Acid-PEG5-bis-PEG3-azide:
Drug Conjugation: Acid-PEG5-bis-PEG3-azide facilitates the conjugation of therapeutic agents to target molecules through click chemistry. This linker enhances the solubility and stability of drug molecules, allowing for more efficient delivery to target sites. By using this compound, researchers can improve the pharmacokinetics and biodistribution of therapeutic agents, leading to enhanced treatment efficacy.
Surface Modification: This bifunctional PEG linker is widely used to modify surfaces with bioactive molecules. By attaching functionalized PEG chains onto surfaces, it’s possible to reduce nonspecific protein binding and improve biocompatibility. Such modified surfaces are especially useful in creating biosensors, diagnostic tools, and medical devices with reduced immune responses.
Proteomics Research: Acid-PEG5-bis-PEG3-azide is employed in proteomics to crosslink proteins and study protein-protein interactions. This linker can be used to capture transient interactions that are difficult to detect using other methods. Researchers benefit from detailed insights into cellular processes and molecular mechanisms through improved identification and characterization of protein complexes.
Nanoparticle Functionalization: This compound is crucial for the functionalization of nanoparticles in drug delivery and imaging applications. By attaching targeting ligands to nanoparticles via this linker, it is possible to achieve targeted delivery to specific cell types or tissues. This application enhances the selectivity and therapeutic index of nanoparticle-based treatments, improving both efficacy and safety.
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