2020
DOI: 10.1021/acs.molpharmaceut.9b01111
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How Corona Formation Impacts Nanomaterials as Drug Carriers

Abstract: As drugs/drug carriers, upon encountering physiological fluids, nanoparticles adsorb biological molecules almost immediately to form a biocorona, which is often simply called a corona. Once the corona is formed, it dictates the subsequent fate of the drug nanoparticle as a therapeutic agent. Protein adsorption on micron-size or even bigger particles was originally described by the Vroman effect. It has served as a useful framework to understand the corona formation. Proteins that are irreversibly adsorbed on n… Show more

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Cited by 53 publications
(41 citation statements)
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“…REPES analysis of the PMPC-PVBTMA system shows the growth of~200 nm aggregates over 1 to 10 h. This slight stability issue may be mitigated by increasing the degree of polymerization of PMPC, as the total length of the zwitterionic corona in micelles were previously shown to affect nanoparticle stabilization and delivery efficacy [33]. Nevertheless, because protein adsorption onto nanoparticle carriers in biological settings is a known design consideration for micelle assemblies [65,66], the prepared PCMs and zPCM show good overall resistance to destabilization by serum.…”
Section: Pcms and Zpcms In Biologically Relevant Conditionsmentioning
confidence: 99%
“…REPES analysis of the PMPC-PVBTMA system shows the growth of~200 nm aggregates over 1 to 10 h. This slight stability issue may be mitigated by increasing the degree of polymerization of PMPC, as the total length of the zwitterionic corona in micelles were previously shown to affect nanoparticle stabilization and delivery efficacy [33]. Nevertheless, because protein adsorption onto nanoparticle carriers in biological settings is a known design consideration for micelle assemblies [65,66], the prepared PCMs and zPCM show good overall resistance to destabilization by serum.…”
Section: Pcms and Zpcms In Biologically Relevant Conditionsmentioning
confidence: 99%
“…DCS is capable of separating the components of a mixture based on their densities and sizes, as larger and denser components require lower centrifugal forces to sediment. It is capable of analyzing the sizes of particles in the range of 0.01–40 μm and has been widely applied in measuring the sizes of NP-PC complexes [ 21 , 41 ]. For NPs with homogenous density and a simple shape, the particle size can be obtained directly, via the time taken by the NPs to travel from the center of a DCS disk through a defined viscous sucrose gradient under a strong centrifugal force to a detector placed at the outer rim of the disk [ 26 ].…”
Section: Characterization Approachesmentioning
confidence: 99%
“…The biological identity is largely dictated by the protein corona, a protein coat on the surface of nanomaterials that forms through the adsorption of proteins from the blood or cell culture media. As the protein corona is the first to interface with the cell membrane, the biological identity can greatly impact the cellular uptake of nanomaterials [3].…”
Section: How Do Cells Interface With Nanomaterials?mentioning
confidence: 99%