G. M. Nabar scite author profile

Purpose Poly(lactic- co -glycolic acid) (PLGA) is widely used for drug delivery because of its biocompatibility, ability to solubilize a wide variety of drugs, and tunable degradation. However, achieving sub-100 nm nanoparticles (NPs), as might be desired for delivery via the enhanced permeability and retention effect, is extremely difficult via typical top-down emulsion approaches. Methods Here, we present a bottom-up synthesis method yielding PLGA/block copolymer hybrids (ie, “PolyDots”), consisting of hydrophobic PLGA chains entrapped within self-assembling poly(styrene- b -ethylene oxide) (PS- b -PEO) micelles. Results PolyDots exhibit average diameters <50 nm and lower polydispersity than conventional PLGA NPs. Drug encapsulation efficiencies of PolyDots match conventional PLGA NPs (ie, ~30%) and are greater than those obtained from PS- b -PEO micelles (ie, ~7%). Increasing the PLGA:PS- b -PEO weight ratio alters the drug release mechanism from chain relaxation to erosion controlled. PolyDots are taken up by model glioma cells via endocytotic mechanisms within 24 hours, providing a potential means for delivery to cytoplasm. PolyDots can be lyophilized with minimal change in morphology and encapsulant functionality, and can be produced at scale using electrospray. Conclusion Encapsulation of PLGA within micelles provides a bottom-up route for the synthesis of sub-100 nm PLGA-based nanocarriers with enhanced stability and drug-loading capacity, and tunable drug release, suitable for potential clinical applications.

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Steering microtubule shuttle transport with dynamically controlled magnetic fields

Mahajan

Ruan

Dorcéna

et al. 2016

Nanoscale

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Nanoscale control of matter is critical to the design of integrated nanosystems. Here, we describe a method to dynamically control directionality of microtubule (MT) motion using programmable magnetic fields. MTs are combined with magnetic quantum dots (i.e., MagDots) that are manipulated by external magnetic fields provided by magnetic nanowires. MT shuttles thus undergo both ATP-driven and externally-directed motion with a fluorescence component that permits simultaneous visualization of shuttle motion. This technology is used to alter the trajectory of MTs in motion and to pin MT motion. Such an approach could be used to evaluate the MT-kinesin transport system and could serve as the basis for improved lab-on-a-chip technologies based on MT transport.

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Nanoparticle packing within block copolymer micelles prepared by the interfacial instability method

2018

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The interfacial instability method has emerged as a viable approach for encapsulating high concentrations of nanoparticles (NPs) within morphologically diverse micelles. In this method, transient interfacial instabilities at the surface of an emulsion droplet guide self-assembly of block co-polymers and NP encapsulants. Although used by many groups, there are no systematic investigations exploring the relationship between NP properties and micelle morphology. Here, the effect of quantum dot (QD) and superparamagnetic iron oxide NP (SPION) concentration on the shape, size, and surface deformation of initially spherical poly(styrene-b-ethylene oxide) (PS-b-PEO) micelles was examined. Multi-NP encapsulation and uniform dispersion within micelles was obtained even at low NP concentrations. Increasing NP concentration initially resulted in larger numbers of elongated micelles and cylinders with tightly-controlled diameters smaller than those of spherical micelles. Beyond a critical NP concentration, micelle formation was suppressed; the dominant morphology became densely-loaded NP structures that were coated with polymer and exhibited increased polydispersity. Transmission electron microscopy (TEM) and small angle X-ray scattering (SAXS) revealed that NPs in densely-loaded structures can be well-ordered, with packing volume fractions of up to 24%. These effects were enhanced in magnetic composites, possibly by dipole interactions. Mechanisms governing phase transitions triggered by NP loading in the interfacial instability process were proposed. The current study helps establish and elucidate the active role played by NPs in directing block copolymer assembly in the interfacial instability process, and provides important guiding principles for the use of this approach in generating NP-loaded block copolymer composites.

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Photo-switchable quantum dots based on reversible FRET

Fan

Nabar

Miller

et al. 2014

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Self-assembly and sedimentation of 5 nm SPIONs using horizontal, high magnetic fields and gradients

Gómez-Pastora

Sundar

et al. 2020

Separation and Purification Technology

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Quantitative Determination of Perchlorate Ion in Solution

Nabar¹,

Ramachandran²

1959

Anal. Chem.

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Mechanotransduction Effects on Endothelial Cell Proliferation via CD31 and VEGFR2: Implications for Immunomagnetic Separation

Mahajan

Nabar

Xue

et al. 2017

Biotechnology Journal

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Immunomagnetic separation is used to isolate circulating endothelial cells (ECs) and endothelial progenitor cells (EPCs) for diagnostics and tissue engineering. However, potentially detrimental changes in cell properties have been observed post-separation. Here, we studied the effect of mechanical force, which is naturally applied during immunomagnetic separation, on proliferation of human umbilical vein endothelial cells (HUVEC), kinase insert domain-positive receptor (KDR) cells, and peripheral blood mononuclear cells (PBMCs). Cells were exposed to CD31 or Vascular Endothelial Growth Factor Receptor-2 (VEGFR2) targeted MACSi beads at varying bead to cell ratios and compared to free antibody and unconjugated beads. A vertical magnetic gradient was applied to static 2D cultures, and a magnetic cell sorter was used to analyze cells in dynamic flow. No significant difference in EC proliferation was observed for controls or VEGFR2-targeting beads, whereas CD31-conjugated beads increased proliferation in a dose dependent manner in static 2-D cultures. This effect occurred in the absence of magnetic field, but was more pronounced with magnetic force. After flow sorting, similar increases in proliferation were seen for CD31 targeting beads. Thus, the effects of targeting antibody and magnetic force applied should be considered when designing immunomagnetic separation protocols for ECs.

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Morphology of block copolymer micelles formed via electrospray enabled interfacial instability

Souva

Nabar

Winter

et al. 2018

Journal of Colloid and Interface Science

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G. M. Nabar

Micelle-templated, poly(lactic-<em>co</em>-glycolic acid) nanoparticles for hydrophobic drug delivery

Steering microtubule shuttle transport with dynamically controlled magnetic fields

Nanoparticle packing within block copolymer micelles prepared by the interfacial instability method

Photo-switchable quantum dots based on reversible FRET

Self-assembly and sedimentation of 5 nm SPIONs using horizontal, high magnetic fields and gradients

Quantitative Determination of Perchlorate Ion in Solution

Mechanotransduction Effects on Endothelial Cell Proliferation via CD31 and VEGFR2: Implications for Immunomagnetic Separation

Morphology of block copolymer micelles formed via electrospray enabled interfacial instability

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