Scattering Studies of Hydrophobic Monomers in Liposomal Bilayers: An Expanding Shell Model of Monomer Distribution

Richter, A. G.; Dergunov, Sergey A.; Ganus, Bill; Thomas, Zachary P.; Pingali, Sai Venkatesh; Urban, Volker S.; Liu, Yun; Porcar, Lionel; Pinkhassik, Eugene

doi:10.1021/la1050942

Cited by 28 publications

(37 citation statements)

References 26 publications

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“…This interpretation of the NMR signals is in line with previously reported analysis of the NMR spectra of bilayer‐bound molecules . It is also supported by our previous study of the distribution of monomers in the bilayer based on small‐angle neutron and X‐ray scattering . Specific ratios of the differential locations of monomers appear to depend on the mobility and hydrophobicity of the monomers and their ability to form intra‐ and intermolecular complexes within the bilayer.…”

Section: Figuresupporting

confidence: 90%

Bilayer‐Templated Two‐Dimensional RAFT Polymerization for Directed Assembly of Polymer Nanostructures

Dergunov

Pinkhassik

2020

Angew Chem Int Ed

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Co-localization of monomers, crosslinkers, and chain-transfer agents (CTA) within self-assembled bilayers in an aqueous suspension enabled the successful directed assembly of nanocapsules using a reversible addition-fragmentation chain transfer (RAFT) process without compromising the polymerization kinetics. This study uncovered substantial influence of the organized medium on the course of the reaction, including differential reactivity based on placement and mobility of monomers, crosslinkers, and CTAs within the bilayer.

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Section: Figuresupporting

confidence: 90%

Bilayer‐Templated Two‐Dimensional RAFT Polymerization for Directed Assembly of Polymer Nanostructures

Dergunov

Pinkhassik

2020

Angew Chem Int Ed

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“…20 The same type of analysis was performed for the surfactant vesicles by analyzing data in the bilayer-thickness Guinier region. At these Q values (∼0.04− 0.08 Å −1 ), the bilayer appears as a flat sheet with thickness d. For QR g < 1, where R g is related to the thickness as d = R g (12) 1/2 , the intensity of scattering from a sheet goes as I ∝ exp(−Q 2 R g 2 )/Q 2 .…”

Section: Resultsmentioning

confidence: 99%

Facile Directed Assembly of Hollow Polymer Nanocapsules within Spontaneously Formed Catanionic Surfactant Vesicles

et al. 2014

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Surfactant vesicles containing monomers in the interior of the bilayer were used to template hollow polymer nanocapsules. This study investigated the formation of surfactant/monomer assemblies by two loading methods, concurrent loading and diffusion loading. The assembly process and the resulting aggregates were investigated with dynamic light scattering, small angle neutron scattering, and small-angle X-ray scattering. Acrylic monomers formed vesicles with a mixture of cationic and anionic surfactants in a broad range of surfactant ratios. Regions with predominant formation of vesicles were broader for compositions containing acrylic monomers compared with blank surfactants. This observation supports the stabilization of the vesicular structure by acrylic monomers. Diffusion loading produced monomer-loaded vesicles unless vesicles were composed from surfactants at the ratios close to the boundary of a vesicular phase region on a phase diagram. Both concurrent-loaded and diffusion-loaded surfactant/monomer vesicles produced hollow polymer nanocapsules upon the polymerization of monomers in the bilayer followed by removal of surfactant scaffolds.

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“…SANS is also an excellent tool for studying biomembranes, such as pure lipids (Kučerka et al, 2011;Pan et al, 2012) and their interactions with membrane-active peptides in both solid state (Lee et al, 2011) and vesicle solutions (Qian & Heller, 2011). Selective deuterium labeling made it possible to determine where small hydrocarbons reside in lipid bilayers (Richter et al, 2011). The Bio-SANS was also used to study differences between the thylakoid membranes inside of living wild-type and mutant cyanobacteria and to understand how their thylakoid membranes respond to changes in illumination (Liberton et al, 2013).…”

Section: Biological Membranesmentioning

confidence: 99%

The Bio-SANS instrument at the High Flux Isotope Reactor of Oak Ridge National Laboratory

et al. 2014

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Small-angle neutron scattering (SANS) is a powerful tool for characterizing complex disordered materials, including biological materials. The Bio-SANS instrument of the High Flux Isotope Reactor of Oak Ridge National Laboratory (ORNL) is a high-flux low-background SANS instrument that is, uniquely among SANS instruments, dedicated to serving the needs of the structural biology and biomaterials communities as an open-access user facility. Here, the technical specifications and performance of the Bio-SANS are presented. Sample environments developed to address the needs of the user program of the instrument are also presented. Further, the isotopic labeling and sample preparation capabilities available in the Bio-Deuteration Laboratory for users of the Bio-SANS and other neutron scattering instruments at ORNL are described. Finally, a brief survey of research performed using the Bio-SANS is presented, which demonstrates the breadth of the research that the instrument's user community engages in.

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Scattering Studies of Hydrophobic Monomers in Liposomal Bilayers: An Expanding Shell Model of Monomer Distribution

Cited by 28 publications

References 26 publications

Bilayer‐Templated Two‐Dimensional RAFT Polymerization for Directed Assembly of Polymer Nanostructures

Bilayer‐Templated Two‐Dimensional RAFT Polymerization for Directed Assembly of Polymer Nanostructures

Facile Directed Assembly of Hollow Polymer Nanocapsules within Spontaneously Formed Catanionic Surfactant Vesicles

The Bio-SANS instrument at the High Flux Isotope Reactor of Oak Ridge National Laboratory

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