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3,5-divinylthienyl-BODIPYs
| Catalog Number | F01-0099 |
| Category | BODIPY |
| Molecular Formula | C29H23BF2N2S2 |
| Molecular Weight | 512.455 |
* Please be kindly noted products are not for therapeutic use. We do not sell to patients.
Product Introduction
BODIPY dyes are used to generate fluorescent conjugates of proteins, nucleotides, oligonucleotides and dextrans, as well as to prepare fluorescent enzyme substrates, fatty acids, phospholipids, lipopolysaccharides, receptor ligands and polystyrene microspheres.
Product Specification
Application
| Excitation | 649 |
| Emission | 667 |
| Storage | Store at -20°C |
3,5-divinylthienyl-BODIPYs are fluorescent dyes that find extensive use in scientific research due to their unique photophysical properties. Here are some key applications of 3,5-divinylthienyl-BODIPYs:
Fluorescence Imaging: 3,5-divinylthienyl-BODIPYs are used in fluorescence microscopy to visualize and track molecules within biological samples. Their bright fluorescence and stability make them suitable for imaging cellular structures and dynamic processes in living cells. This application is crucial for understanding cellular interactions, protein localization, and biomolecular functions.
Photodynamic Therapy (PDT): These BODIPY derivatives can act as photosensitizers in photodynamic therapy for cancer treatment. Upon light activation, they generate reactive oxygen species that can selectively kill cancer cells. This targeted approach minimizes damage to surrounding healthy tissues and provides a promising strategy for non-invasive cancer therapy.
Chemical Sensing: 3,5-divinylthienyl-BODIPYs are employed in the development of chemical sensors for detecting various analytes, such as ions and small molecules. Their fluorescence properties can change upon binding with specific target substances, allowing for rapid and sensitive detection.
Energy Transfer Studies: In materials science, 3,5-divinylthienyl-BODIPYs are used to study energy transfer processes in donor-acceptor systems. Their ability to efficiently transfer energy allows researchers to design and investigate novel photoactive materials and light-harvesting systems. These studies contribute to advancements in fields such as organic electronics and solar energy conversion.
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