Andrew Gomez scite author profile

Recent advances in the area of quantum dots (QDs) have shown their wide range of applications that extend from sensing [50] and bioimaging to catalytic water splitting owing to their remarkable electronic,e lectrochemical, optical, and catalytic properties. [51, 52] Thes ynthesis of QDs can be Alain R. Puente Santiago received his PhD degree in Physical Chemistry with distinction from the University of Cordova, Spain in 2017. He is currently apostdoctoral fellow in Prof. Luis Echegoyen's group in the Chemistry Department of the University of Texas at El Paso. His research interests focus on the developmento flow-dimensional nanohybrids for electrocatalysis. Olivia Fernandez-Delgado was born in Cuba (Havana) in 1993. She obtained her B.S. in Chemistry from the University of Havana in 2016. She is currently pursuing her Ph.D. in the group of Prof. Luis Echegoyen in the University of Texas at El Paso. Her research interests include the synthesis and characterization of new fullerene and carbon nanoonion derivativesf or photovoltaic, catalytic, and biological applications.

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The Role of Membrane Fluidization in the Gel-Assisted Formation of Giant Polymersomes

Greene

Henderson

Gomez

et al. 2016

PLoS ONE

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Polymersomes are being widely explored as synthetic analogs of lipid vesicles based on their enhanced stability and potential uses in a wide variety of applications in (e.g., drug delivery, cell analogs, etc.). Controlled formation of giant polymersomes for use in membrane studies and cell mimetic systems, however, is currently limited by low-yield production methodologies. Here, we describe for the first time, how the size distribution of giant poly(ethylene glycol)-poly(butadiene) (PEO-PBD) polymersomes formed by gel-assisted rehydration may be controlled based on membrane fluidization. We first show that the average diameter and size distribution of PEO-PBD polymersomes may be readily increased by increasing the temperature of the rehydration solution. Further, we describe a correlative relationship between polymersome size and membrane fluidization through the addition of sucrose during rehydration, enabling the formation of PEO-PBD polymersomes with a range of diameters, including giant-sized vesicles (>100 μm). This correlative relationship suggests that sucrose may function as a small molecule fluidizer during rehydration, enhancing polymer diffusivity during formation and increasing polymersome size. Overall the ability to easily regulate the size of PEO-PBD polymersomes based on membrane fluidity, either through temperature or fluidizers, has broadly applicability in areas including targeted therapeutic delivery and synthetic biology.

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Self-Assembled Layering of Magnetic Nanoparticles in a Ferrofluid on Silicon Surfaces

Theis‐Bröhl

Vreeland

Gomez

et al. 2018

ACS Appl. Mater. Interfaces

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This article describes the three-dimensional self-assembly of monodisperse colloidal magnetite nanoparticles (NPs) from a dilute water-based ferrofluid onto a silicon surface and the dependence of the resultant magnetic structure on the applied field. The NPs assemble into close-packed layers on the surface followed by more loosely packed ones. The magnetic field-dependent magnetization of the individual NP layers depends on both the rotational freedom of the layer and the magnetization of the adjacent layers. For layers in which the NPs are more free to rotate, the easy axis of the NP can readily orient along the field direction. In more dense packing, free rotation of the NPs is hampered, and the NP ensembles likely build up quasi-domain states to minimize energy, which leads to lower magnetization in those layers. Detailed analysis of polarized neutron reflectometry data together with model calculations of the arrangement of the NPs within the layers and input from small-angle scattering measurements provide full characterization of the core/shell NP dimensions, degree of chaining, arrangement of the NPs within the different layers, and magnetization depth profile.

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Heparin–chitosan nanoparticle functionalization of porous poly(ethylene glycol) hydrogels for localized lentivirus delivery of angiogenic factors

et al. 2014

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Hydrogels have been extensively used for regenerative medicine strategies given their tailorable mechanical and chemical properties. Gene delivery represents a promising strategy by which to enhance the bioactivity of the hydrogels, though the efficiency and localization of gene transfer have been challenging. Here, we functionalized porous poly(ethylene glycol) hydrogels with heparin-chitosan nanoparticles to retain the vectors locally and enhance lentivirus delivery while minimizing changes to hydrogel architecture and mechanical properties. The immobilization of nanoparticles, as compared to homogeneous heparin and/or chitosan, is essential to lentivirus immobilization and retention of activity. Using this gene-delivering platform, we over-expressed the angiogenic factors sonic hedgehog (Shh) and vascular endothelial growth factor (Vegf) to promote blood vessel recruitment to the implant site. Shh enhanced endothelial recruitment and blood vessel formation around the hydrogel compared to both Vegf-delivering and control hydrogels. The nanoparticle-modified porous hydrogels for delivering gene therapy vectors can provide a platform for numerous regenerative medicine applications.

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Andrew Gomez

Fullerenes as Key Components for Low‐Dimensional (Photo)electrocatalytic Nanohybrid Materials

The Role of Membrane Fluidization in the Gel-Assisted Formation of Giant Polymersomes

Self-Assembled Layering of Magnetic Nanoparticles in a Ferrofluid on Silicon Surfaces

Heparin–chitosan nanoparticle functionalization of porous poly(ethylene glycol) hydrogels for localized lentivirus delivery of angiogenic factors

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