2011
DOI: 10.1021/ar1001389
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Heterogeneous Ligand–Nanoparticle Distributions: A Major Obstacle to Scientific Understanding and Commercial Translation

Abstract: CONSPECTUS Nanoparticles conjugated with functional ligands are expected to have a major impact in medicine, photonics, sensing, and nanoarchitecture design. One major obstacle to realizing the promise of these materials, however, is the difficulty in controlling the ligand/nanoparticle ratio. This obstacle can be segmented into three key areas: First, many system designs have failed to account for the true heterogeneity of ligand/nanoparticle ratios that compose each material. Second, the field's accepted … Show more

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Cited by 72 publications
(134 citation statements)
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“…When using nanoparticle systems a mean population zeta potential will not allow the true measure of the ligand distribution across all of the particles to be interpreted, and in a typical reaction the ligand density would follow a poisson distribution [33][34][35] . The spread of the population can have an effect on the reaction kinetics, stability and sensitivity of nanoparticle based assays [36][37][38] .…”
Section: Introductionmentioning
confidence: 99%
“…When using nanoparticle systems a mean population zeta potential will not allow the true measure of the ligand distribution across all of the particles to be interpreted, and in a typical reaction the ligand density would follow a poisson distribution [33][34][35] . The spread of the population can have an effect on the reaction kinetics, stability and sensitivity of nanoparticle based assays [36][37][38] .…”
Section: Introductionmentioning
confidence: 99%
“…3A). In the low limit, a Poisson distribution can typically be used to describe the number of ligands per nanoparticle, because each ligand attachment occupies insufficient SA to impact subsequent attachments (i.e., attachment events are independent) (49). Given this distribution, an average number of ligands can be a deceptive metric that may not fully describe sample heterogeneity and should be used with caution (46,49).…”
Section: Ligands Arranged On Nanoparticle Surfacesmentioning
confidence: 99%
“…In the low limit, a Poisson distribution can typically be used to describe the number of ligands per nanoparticle, because each ligand attachment occupies insufficient SA to impact subsequent attachments (i.e., attachment events are independent) (49). Given this distribution, an average number of ligands can be a deceptive metric that may not fully describe sample heterogeneity and should be used with caution (46,49). In the high limit, the number of ligands can be approximated as dense packing and is dictated by a complex interplay of nanoparticle shape and SA, interligand interactions, and ligand-solvent interactions (10,44).…”
Section: Ligands Arranged On Nanoparticle Surfacesmentioning
confidence: 99%
“…Therefore it has been difficult to satisfy the drug product quality and regulatory requirements including the metabolic fate of the conjugates relative to traditional formulations. Current literature is replete with research efforts on quantitative techniques to evaluate homogeneity of the drug and ligand distribution in the preparation of PAMAM dendrimers (42,43) and the effect of physical instability (aggregation) of HPMA-folate conjugate on folate receptor-mediated uptake (44). Sophisticated analytical techniques such as small angle neutron scattering (SANS), 2D 1 H NOESY and TOCSY NMR and pulsed gradient NMR have been used to characterize polymer-drug nanoconjugates (45,46).…”
Section: Polymer-drug Conjugatesmentioning
confidence: 99%