Jeniree A. Flores scite author profile

Well-defined, magnetic shell cross-linked knedel-like nanoparticles (MSCKs) with hydrodynamic diameters ca. 70 nm were constructed through the co-assembly of amphiphilic block copolymers of PAA20-b-PS280 and oleic acid-stabilized magnetic iron oxide nanoparticles using tetrahydrofuran, N,N-dimethylformamide, and water, ultimately transitioning to a fully aqueous system. These hybrid nanomaterials were designed for application as sequestering agents for hydrocarbons present in crude oil, based upon their combination of amphiphilic organic domains, for aqueous solution dispersibility and capture of hydrophobic guest molecules, with inorganic core particles for magnetic responsivity. The employment of these MSCKs in a contaminated aqueous environment resulted in the successful removal of the hydrophobic contaminants at a ratio of 10 mg of oil per 1 mg of MSCK. Once loaded, the crude oil-sorbed nanoparticles were easily isolated via the introduction of an external magnetic field. The recovery and reusability of these MSCKs were also investigated. These results suggest that deployment of hybrid nanocomposites, such as these, could aid in environmental remediation efforts, including at oil spill sites, in particular, following the bulk recovery phase.

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Acetal metathesis polymerization (AMP): A method for synthesizing biorenewable polyacetals

Pemba

Flores

Miller

2013

Green Chem.

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Polyalkylene acetals are synthesized from simple bio-derived diols and diethoxymethane via a novel technique involving interchange of acetal functional groups. This Acetal Metathesis Polymerization (AMP) method provides a route to polyacetals that are designed to degrade under abiotic conditions via simple acidcatalyzed hydrolysis. † Electronic supplementary information (ESI) available: Synthetic details and complete polymer characterization data. See

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Holistic Assessment of Covalently Labeled Core–Shell Polymeric Nanoparticles with Fluorescent Contrast Agents for Theranostic Applications

et al. 2014

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The successful development of degradable polymeric nanostructures as optical probes for use in nanotheranostic applications requires the intelligent design of materials such that their surface response, degradation, drug delivery and imaging properties are all optimized. In the case of imaging, optimization must result in materials that allow differentiation between unbound optical contrast agents and labeled polymeric materials as they undergo degradation. In this study, we have shown that use of traditional electrophoretic gel-plate assays for determination of the purity of dye-conjugated degradable nanoparticles is limited, due to polymer degradation characteristics. To overcome these limitations, we have outlined a holistic approach to evaluating dye-and peptide-polymer nanoparticle conjugation by utilizing steady-state fluorescence, anisotropy, and emission and anisotropy life-time decay profiles, through which nanoparticle-dye binding can be assessed independent of perturbations, such as those presented during the execution of electrolyte gel-based assays. This approach has been demonstrated to provide an overall understanding of the spectral signature-structure-function relationship, ascertaining key information on interactions between the fluorophore, polymer and solvent components that have a direct and measurable impact on the emissive properties of the optical probe. The use of these powerful techniques provides feedback that can be utilized to improve nanotheranostics by evaluating dye emissivity in degradable nanotheranostic systems, which has become increasingly important as modern platforms transition to architectures intentionally reliant on degradation and built-in environmental responses.

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In vivo fate tracking of degradable nanoparticles for lung gene transfer using PET and Ĉerenkov imaging

et al. 2016

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Nanoparticles (NPs) play expanding roles in biomedical applications including imaging and therapy, however, their long-term fate and clearance profiles have yet to be fully characterized in vivo. NP delivery via the airway is particularly challenging, as the clearance may be inefficient and lung immune responses complex. Thus, specific material design is required for cargo delivery and quantitative, noninvasive methods are needed to characterize NP pharmacokinetics. Here, biocompatible poly(acrylamidoethylamine)-b-poly(DL-lactide) block copolymer-based degradable, cationic, shell-cross-linked knedel-like NPs (Dg-cSCKs) were employed to transfect plasmid DNA. Radioactive and optical beacons were attached to monitor biodistribution and imaging. The preferential release of cargo in acidic conditions provided enhanced transfection efficiency compared to non-degradable counterparts. In vivo gene transfer to the lung was correlated with NP pharmacokinetics by radiolabeling Dg-cSCKs and performing quantitative biodistribution with parallel positron emission tomography and Čerenkov imaging. Quantitation of imaging over 14 days corresponded with the pharmacokinetics of NP movement from the lung to gastrointestinal and renal routes, consistent with predicted degradation and excretion. This ability to noninvasively and accurately track NP fate highlights the advantage of incorporating multifunctionality into particle design.

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Recyclable Hybrid Inorganic/Organic Magnetically Active Networks for the Sequestration of Crude Oil from Aqueous Environments

et al. 2015

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Hybrid inorganic/organic composite materials have been synthesized from the coupling of amine-functionalized iron oxide nanoparticles (amine-IONs) and pre-established shell cross-linked knedel-like (SCK) polymer nanoconstructs. The magnetically active hybrid networks (MHNs), composed of several interconnected SCKs bound to magnetically active amine-IONs, were designed for their application in the sequestration of hydrophobic contaminants from polluted environments. Initial assessment of the ability of the MHNs to capture complex pollutants, such as crude oil (oil), determined a loading capacity in the range of 3.5−4.5 mg of oil sequestered/mg of MHNs. The magnetic component of the hybrid nanoconstructs was exploited as a facile method of manipulation of the loaded networks, which allowed for the recovery of ca. 93% of the MHNs deployed in water, as well as ca. 90% recovery of the oil originally sequestered. Reutilization of these materials exhibited comparable efficiency after three cycles of remediation, which involved deployment, magnetic recovery, and organic washes to remove the cargo. The multiple characteristics of these materials could be exploited in the cleaning of water contaminated during the process of drilling, extraction, and transport of crude oil, among other applications.

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Jeniree A. Flores

Robust Magnetic/Polymer Hybrid Nanoparticles Designed for Crude Oil Entrapment and Recovery in Aqueous Environments

Acetal metathesis polymerization (AMP): A method for synthesizing biorenewable polyacetals

Holistic Assessment of Covalently Labeled Core–Shell Polymeric Nanoparticles with Fluorescent Contrast Agents for Theranostic Applications

In vivo fate tracking of degradable nanoparticles for lung gene transfer using PET and Ĉerenkov imaging

Recyclable Hybrid Inorganic/Organic Magnetically Active Networks for the Sequestration of Crude Oil from Aqueous Environments

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