peg300

PEG300 (Polyethylene glycol 300) is a polymer formed from repeating units of ethylene glycol that is water soluble, low immunogenicity, and biocompatible. PEG300 is a neutral polymer with a molecular weight of 300.

DPPE-PEG3000 is a PEG lipid functional end group used for synthesizing liposomes (LPs) and designing conjugated polymer nanoparticles. Liposome nanoparticles (LNPs) modified with biotin and having a carboxylate end can further couple with other biomolecules. The functionalized nanoparticles are applicable for targeted labeling of specific cell proteins. Using streptavidin as a linker, biotinylated PEG lipid-conjugated polymer nanoparticles can interact with biotinylated antibodies on cell surface receptors, facilitating fluorescence-based imaging and sensing applications.

18:0 mPEG3000 PE (ammonium) is a PEG lipid with functional end groups for synthesizing liposomes (LPs) and designing conjugated polymer nanoparticles. These liposomal nanoparticles (LNPs), featuring biotin modifications and carboxyl ends, facilitate further coupling with other biomolecules. The functionalized nanoparticles are useful for targeted labeling of specific cell proteins. Using streptavidin as a linker, biotinylated PEG lipid-conjugated polymer nanoparticles can bind to biotinylated antibodies on cell surface receptors, offering practicality for fluorescence-based imaging and sensing.

18:1 PEG3000 PE is a PEG lipid functional terminal group utilized in the synthesis of liposomes (LPs) for the design of conjugated polymer nanoparticles. Liposome nanoparticles (LNPs), modified with biotin and carboxy terminals, can couple with other biomolecules. Such functionalized nanoparticles are employed for targeted labeling of specific cell proteins. Using streptavidin as a linker, the biotinylated PEG lipid-conjugated polymer nanoparticles can bind with biotinylated antibodies on cell surface receptors, providing utility in fluorescence-based imaging and sensing.

PLGA10000-PEG3000-VS (PLGA10000-PEG3000-Vinylsulfone) is an amphiphilic polymer. These polymers are studied for drug delivery due to their ability to self-assemble into distinct aggregates.

PLGA1000-PEG3000-VS (PLGA1000-PEG3000-Vinylsulfone) is an amphiphilic polymer. Its ability to self-assemble into discrete aggregates makes it valuable for research in drug delivery.

PLGA2000-PEG3000-VS (PLGA2000-PEG3000-Vinylsulfone) is an amphiphilic polymer. Due to its ability to self-assemble into discrete aggregates, this type of polymer is applicable in drug delivery research.

PLGA3000-PEG3000-VS (PLGA3000-PEG3000-Vinylsulfone) is an amphiphilic polymer. Due to its ability to self-assemble into distinct aggregates, this type of polymer is useful in drug delivery research.

PLGA4000-PEG3000-VS (PLGA4000-PEG3000-Vinylsulfone) is an amphiphilic polymer. Due to its ability to self-assemble into discrete aggregates, such an amphiphilic polymer can be utilized in drug delivery research.

PLGA5000-PEG3000-VS (PLGA5000-PEG3000-Vinylsulfone) is an amphiphilic polymer. Such polymers are employed in drug delivery research due to their capability to self-assemble into distinct aggregates.

PLLA5000-PEG3000-VS (PLLA5000-PEG3000-Vinylsulfone) is an amphiphilic polymer. Due to its capability to self-assemble into distinct aggregates, such amphiphilic polymers are utilized in drug delivery research.

PLLA10000-PEG3000-VS (PLLA10000-PEG3000-Vinylsulfone) is an amphiphilic polymer that can self-assemble into discrete aggregates, making it suitable for drug delivery research.

PLLA1000-PEG3000-VS (PLLA1000-PEG3000-Vinylsulfone) is an amphiphilic polymer. Due to its ability to self-assemble into discrete aggregates, it is utilized in drug delivery research.

PLLA4000-PEG3000-VS (PLLA4000-PEG3000-Vinylsulfone) is an amphiphilic polymer. Due to its ability to self-assemble into discrete aggregates, this type of polymer can be utilized in drug delivery research.

PLLA3000-PEG3000-VS (PLLA3000-PEG3000-Vinylsulfone) is an amphiphilic polymer. Such polymers are utilized in drug delivery research due to their ability to self-assemble into discrete aggregates.

PLLA2000-PEG3000-VS (PLLA2000-PEG3000-Vinylsulfone) is an amphiphilic polymer. Due to its ability to self-assemble into discrete aggregates, amphiphilic polymers are employed in drug delivery research.

PLLA6000-PEG3000-PLLA6000 is an amphiphilic triblock copolymer derived from polylactic acid, enhancing the specificity and cell affinity of PLA-based biomaterials. [PLLA6000-PEG3000-PLLA6000] is applicable in drug delivery research.

PLLA8000-PEG3000-PLLA8000 is an amphiphilic triblock polymer derived from polylactic acid (PLA), designed to enhance the specificity and cellular affinity of PLA-based biomaterials. This compound is applicable in drug delivery research.

PLLA5000-PEG3000-Thiol is a polylactic acid derivative that forms micelles in water and undergoes biodegradation through hydrolytic ester bond cleavage. It is applicable in research focused on drug delivery.

PLLA4000-PEG3000-Thiol is a polylactic acid derivative capable of forming micelles in aqueous environments, where it undergoes biodegradation through hydrolysis of its ester bonds. This compound is utilized in the study of drug delivery systems.

PLLA3000-PEG3000-Thiol is a polylactic acid derivative capable of forming micelles in water. It undergoes biodegradation through hydrolytic cleavage of ester bonds and is applicable in drug delivery research.

PLLA2000-PEG3000-Thiol is a polylactic acid derivative capable of forming micelles in aqueous solutions. It undergoes biodegradation through hydrolytic attack on ester bonds and is utilized in drug delivery research.

PLLA1000-PEG3000-Thiol, a polylactic acid derivative, can form micelles in water and undergoes biodegradation through hydrolytic cleavage of ester bonds. It is applicable in drug delivery research.

PLLA10000-PEG3000-Thiol is a polylactic acid derivative capable of forming micelles in aqueous environments. It undergoes biodegradation through hydrolytic attack on ester bonds. This compound is applicable in drug delivery research.