Synthesis of Core Functionalized Polymer Micelles and Shell Cross-Linked Nanoparticles

Ievins, Alexander D.; Wang, Xiaofan; Moughton, Adam O.; Skey, Jared; O’Reilly, Rachel K.

doi:10.1021/ma702702j

Cited by 69 publications

(54 citation statements)

References 85 publications

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“…This resonance corresponds closely in the chemical shift and Rh coupling to that of the related molecular compound [Rh(acac)(CO){P(C 6 H 4 -4-OMe) 3 }] (δ 43.5, J PRh = 175.6 Hz) [45]. It is also essentially identical to that previously reported for [Rh(acac)(CO)(BMOPPP@CCM)] [8] (recalled in the SI, Figure S3).…”

Section: Metal Coordination Inside the Nanoreactorssupporting

confidence: 85%

Coordination Chemistry inside Polymeric Nanoreactors: Metal Migration and Cross-Exchange in Amphiphilic Core-Shell Polymer Latexes

et al. 2016

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Abstract:A well-defined amphiphilic core-shell polymer functionalized with bis(p-methoxyphenylphosphino)phenylphosphine (BMOPPP) in the nanogel (NG) core has been obtained by a convergent RAFT polymerization in emulsion. This BMOPPP@NG and the previously-reported TPP@NG (TPP = triphenylphosphine) and core cross-linked micelles (L@CCM; L = TPP, BMOPPP) having a slightly different architecture were loaded with [Rh(acac)The interparticle metal migration from [Rh(acac)(CO)(TPP@NG)] to TPP@NG is fast at natural pH and much slower at high pH, the rate not depending significantly on the polymer architecture (CCM vs. NG). The cross-exchange using [Rh(acac)(CO)(BMOPPP@Pol)] and [RhCl(COD)(TPP@Pol)] (Pol = CCM or NG) as reagents at natural pH is also rapid (ca. 1 h), although slower than the equivalent homogeneous reaction on the molecular species (<5 min). On the other hand, the subsequent rearrangement of [Rh(acac)(CO)(TPP@Pol)] and [RhCl(COD)(TPP@Pol)] within the TPP@Pol core and of [Rh(acac)(CO)(BMOPPP@Pol)] and [RhCl(COD)(BMOPPP@Pol)] within the BMOPPP@Pol core, leading respectively to [RhCl(CO)(TPP@Pol) 2 ] and [RhCl(CO)(BMOPPP@Pol) 2 ], is much more rapid (<30 min) than on the corresponding homogeneous process with the molecular species (>24 h).

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Section: Metal Coordination Inside the Nanoreactorssupporting

confidence: 85%

Coordination Chemistry inside Polymeric Nanoreactors: Metal Migration and Cross-Exchange in Amphiphilic Core-Shell Polymer Latexes

et al. 2016

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“…In this case, the core of the particles contained a terpyridine side group that could be utilized as a ligand to bind Cu(I) species. [37] The catalytic efficiency of these nanoparticles on mediating "click'' reactions was confirmed using a fluorogenic reaction between an azido coumarin and an alkynyl small molecule. Further, more recent work by Weck and co-workers used poly(2-oxazoline)-based amphiphilic triBCPs with a salen-functionalized hydrophobic block prepared by living cationic polymerization.…”

Section: Cross-linked Polymeric Micellesmentioning

confidence: 94%

“…Hence, a new strategy has been Prospective Article developed which involves the synthesis of functionalized monomers, which can be incorporated selectively into a specific domain of a BCP via robust CRP techniques. [30,[37][38][39][40] This approach allows for the synthesis of functional polymers without the need of protecting groups or post-functionalization steps. [41] The choice of functional monomer provides the possibility of introducing a variety of functional groups into the micelle (core, shell, or surface), which can tune the properties of the nanostructure for different applications.…”

Section: Well-defined Polymeric Nanostructuresmentioning

confidence: 99%

Catalytic polymeric nanoreactors: more than a solid supported catalyst

2012

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Polymeric nanostructures can be synthesized where the catalytic motif is covalently attached within the core domain and protected from the environment by a polymeric shell. Such nanoreactors can be easily recycled, and have shown unique properties when catalyzing reactions under pseudohomogeneous conditions. Many examples of how these catalytic nanostructures can act as nanosized reaction vessels have been reported in the literature. This prospective will focus on the exclusive features observed for these catalytic systems and highlight their potential as enzyme mimics, as well as the importance of further studies to unveil their full potential.

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“…The CuAAC reaction was performed between non-fluorescent phenylethynyl and 13 in the presence of the nanoparticle to afford a highly fluorescent solution, which showed the copper complex had been formed and could be used as an active catalyst for the click reaction. 44 In a similar study, the fluorogenic CuAAC reaction with azido-coumarin 13 was used as a general method to functionalize polymer particles, formed by a starve-fed sequential emulsion polymerization process, under gentle conditions. 45 Recently, Cornelissen and coworkers also described the use of the fluorogenic CuAAC to monitor protein-polymer conjugation.…”

Section: Fluorogenic Conjugation Of Nanoparticles and Polymersmentioning

confidence: 99%