Unusual, Promoted Release of Guests from Amphiphilic Cross-Linked Polymer Networks

Brown, Gerald O.; Bergquist, Catherine; Ferm, Paul M.; Wooley, Karen L.

doi:10.1021/ja0534405

Cited by 35 publications

(42 citation statements)

References 20 publications

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“…[41][42][43] These materials were developed initially as non-toxic, anti-biofouling coatings for application in the marine environment, and they have demonstrated remarkable perormance toward this application. [44] Moreover, their complex morphologies were also found to provide nanochannels that exhibit unusual thermallypromoted release of volatile guest molecules, [45] and nanoscale confinement of water swollen within the materials to result in dramatically increased moduli. [46] Finally, the discussion will conclude with recent work, directed toward the preparation of discrete nanoscale forms of the complex amphiphilic HBFP/PEG hybrid structures.…”

Section: Feature Articlementioning

confidence: 99%

“…/PEG, have been investigated extensively, including their anti-biofouling performance against marine organisms, [44] encapsulation and release of guest molecules, [45] and mechanical properties, [46] to explore their applications in aqueous environments, such as non-toxic marine anti-fouling coatings, advanced drug delivery systems, and other potential biomedical devices.…”

Section: Surface Compositionmentioning

confidence: 99%

“…The terpene geraniol was used as a model compound to study the release behavior upon temperature change through the employment of TGA. [45] T Dynamic 50 , defined as the temperature at which 50% mass loss of preloaded geraniol occurred, depended upon the relative balance of hydrophobic HBFP (I) to hydrophilic PEG components ( Figure 5). T reached a minimum at ca.…”

Section: Anti-fouling and Fouling-release Performance Of Hbfp (I) /Pementioning

confidence: 99%

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Hyperbranched Fluoropolymers and their Hybridization into Complex Amphiphilic Crosslinked Copolymer Networks

Bartels¹,

Cheng²,

Powell³

et al. 2007

Macro Chemistry & Physics

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100

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This feature article highlights three types of hyperbranched fluoropolymers (HBFPs) with different structural features, which were synthesized by either polycondensation of fluorinated ABx monomers or self‐condensing vinyl (co)polymerization of fluorinated inimers and/or fluorinated comonomers. Amphiphilic crosslinked networks with hybridization of these hydrophobic HBFPs and linear hydrophilic poly(ethylene glycol)s are also discussed. As microphase‐segregated materials with nanoscale surface heterogeneities, these networks possessed unusual anti‐biofouling abilities, atypical sequestration and release behaviors for guest molecules, and special mechanical properties.magnified image

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Section: Feature Articlementioning

confidence: 99%

Section: Surface Compositionmentioning

confidence: 99%

Section: Anti-fouling and Fouling-release Performance Of Hbfp (I) /Pementioning

confidence: 99%

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Hyperbranched Fluoropolymers and their Hybridization into Complex Amphiphilic Crosslinked Copolymer Networks

Bartels¹,

Cheng²,

Powell³

et al. 2007

Macro Chemistry & Physics

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100

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“…Encapsulation of active ingredients, including flavors in polymer shell of urea-formaldehyde [1]- [4] and melamine-formaldehyde has been versatile [5]- [8]. Control of fragrance diffusion by barrier system of various types has been employed in fragrance prolongation, for instance, cyclodextrin host [9]- [10], solid-lipid nanoparticles [11], amphiphilic-crosslinked polymer network [12], double emulsion system [13], synthetic polymers formed by miniemulsion polymerization [14], coacervation with various carbohydrates [15]- [17], polymer blends [18] and multilayer microcapsules [19]. However, increasing in capacity of fragrance in urea-formaldehyde and melamine-formaldehyde is necessary to prolong the release period.…”

Section: Introductionmentioning

confidence: 99%

Influence of Shell Number on Loading Capacity of Microcapsules Containing Fragrance

Aldred¹,

Chokbundit²,

Saengsorn³

2017

IJCEA

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Abstract-Microcapsules of single-shell melamine-formaldehyde (MF) and double-shell urea-formaldehyde/melamine -formaldehyde (UF/MF) microcapsules loading with fragrance of varied concentrations were prepared using in situ polymerization. The microcapsules were analyzed using Scanning electron microscope (SEM) and Fourier transform infrared spectrometer (FT-IR). Loading capacity of fragrance in the microcapsules in term of percent weight of fragrance was determined using soxhlet extraction. From SEM images, shapes and sizes of single shell MF microcapsules were different depending on concentrations of fragrance and SDS added in the preparation procedure. FT-IR spectra of double-shell UF/MF microcapsules loaded fragrance presented absorption band of C=O at 1674 cm -1 as found in that of fragrance. Percent weight of fragrance in single-shell UF and double-shell UF/MF microcapsules substantially increased with increased concentration of fragrance. Additionally, loading capacity of fragrance in double-shell UF/MF microcapsules were higher than those in single-shell MF microcapsules at the same concentration of fragrance. This would lead to higher prolongation of fragrance release from double-shell UF/MF microcapsules than single-shell MF microcapsules and fulfill the end use applications.

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“…[1,2] Unlike typical hydrogels, [3][4][5] these complex crosslinked networks undergo morphological isomerization upon changes between organic and aqueous media, and have been described as being ''smart'' by Erdodi and Kennedy. [1] This distinct phenomenon leads to reorganization of two phase-incompatible components on the surface as well as in the interior domains, and further transformations, to afford many unique materials properties, such as mechanical behavior, [6] morphological variability, [7,8] sub-surface compartmentalizations and membrane performance, [9,10] surface anti-biofouling, [10][11][12] and biocapability. [13,14] Moreover, such properties can be expanded with the variety and attributes of chemical compositions that polymers possess and the complexity and control of architectures that polymers provide, [15] making it feasible to fabricate these amphiphilic crosslinked networks into intelligent devices for many fields, including the marine coatings industry.…”

Section: Introductionmentioning

confidence: 99%

Hierarchical Inorganic–Organic Nanocomposites Possessing Amphiphilic and Morphological Complexities: Influence of Nanofiller Dispersion on Mechanical Performance

Xu¹,

Bartels²,

Bohnsack

et al. 2008

Adv Funct Materials

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Novel nanocomposites possessing ternary compositions and complex morphologies have been prepared from amphiphilic crosslinked hyperbranched fluoropolymer–poly(ethylene glycol) (HBFP–PEG) in the presence of pristine and chemically functionalized nanoscopic fillers, single‐walled carbon nanotubes (SWNTs) and silica nanoparticles (SiO2). Both SWNTs and SiO2 were engineered specifically to become phase‐designated reinforcing functional materials, SWNT‐g‐PEG and SiO2‐g‐HBFP, which (1) improved the dispersion of fillers, nanotubes, or spherical nanoparticles in the amphiphilic matrices, (2) enhanced the non‐covalent interactions between nanofillers and polymers, and more importantly, (3) maintained reactive functionalities to be further covalently integrated into the complex networks. Tensile moduli (Edry) for these as‐prepared SWNT‐containing composites increased by up to 430% relative to the unfilled material, while those incorporated with SiO2 had a 420% increase of Edry. After swelling in water, the water absorption within the micro‐ and nanochannels of PEG‐rich domains rigidified or softened the entire crosslinked network, as determined by the amount of PEG.

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Unusual, Promoted Release of Guests from Amphiphilic Cross-Linked Polymer Networks

Cited by 35 publications

References 20 publications

Hyperbranched Fluoropolymers and their Hybridization into Complex Amphiphilic Crosslinked Copolymer Networks

Hyperbranched Fluoropolymers and their Hybridization into Complex Amphiphilic Crosslinked Copolymer Networks

Influence of Shell Number on Loading Capacity of Microcapsules Containing Fragrance

Hierarchical Inorganic–Organic Nanocomposites Possessing Amphiphilic and Morphological Complexities: Influence of Nanofiller Dispersion on Mechanical Performance

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