2006
DOI: 10.1002/anie.200600545
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Multifunctional Lipid/Quantum Dot Hybrid Nanocontainers for Controlled Targeting of Live Cells

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Cited by 212 publications
(160 citation statements)
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References 70 publications
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“…If this step does not occur, the single nanoparticles will remain in a stable micelle state, which generally coincides with previously documented observations. 18,19 Interestingly, this approach can be applied to different nanoparticle sizes: In an additional trial, we observed that nanoparticles with a mean core diameter of 7.2 ( 0.9 nm form similar structures, as well (Figure 5B), which shows that even nanoparticles up to 8.1 nm ( Figure 5B, inset) can be inserted between the liposomal bilayer by following this methodology.…”
Section: Resultsmentioning
confidence: 89%
See 1 more Smart Citation
“…If this step does not occur, the single nanoparticles will remain in a stable micelle state, which generally coincides with previously documented observations. 18,19 Interestingly, this approach can be applied to different nanoparticle sizes: In an additional trial, we observed that nanoparticles with a mean core diameter of 7.2 ( 0.9 nm form similar structures, as well (Figure 5B), which shows that even nanoparticles up to 8.1 nm ( Figure 5B, inset) can be inserted between the liposomal bilayer by following this methodology.…”
Section: Resultsmentioning
confidence: 89%
“…18,20,22 On the other hand, spheres larger than approximately 6.5 nm in diameter, 22 or around the overall bilayer thickness in general, 13,23 rather induce lipid monolayer adsorption onto the surface and result in stable micelle-like structures. These norms have been repetitively validated in experimental studies, 18,19 and larger nanoparticles (i.e., >22 nm) in turn are known to be wrapped up by a lipid bilayer. 12,15 These boundaries can be cumbersome when designing application-oriented nanocontainers, as specific nanoparticle properties (i.e., optical, thermal and/or magnetic) ; which make them desirable in the first place ; are mostly governed by their size.…”
mentioning
confidence: 92%
“…31 In other work, qdots were localized inside or adjacent to cellular membranes by using vesicle delivery methods. 48 Membrane simulations also predict that, with proper surface chemistry, the localization of larger nanocrystals inside a bilipid layer can be free-energetically favorable. 49 However, developing surface chemistries capable of localizing large nanocrystals (R ~ 4 nm) specifically within neural membranes remains a substantial challenge.…”
Section: Discussionmentioning
confidence: 96%
“…Owing to the additional layer bound by hydrophobic interactions, this coating strategy can be applied regardless of the material of the inorganic particle core. Variations include the embedding of hydrophobic quantum dots into the lipid bilayer of vesicles and liposomes (Gopalakrishnan et al 2006) and paramagnetic lipids that yield fluorescent nanoparticles with additional magnetic properties (Mulder et al 2006a,b).…”
Section: (C) Additional Coating Layersmentioning
confidence: 99%