Keyword search (4,164 papers available)

"nanoparticles" Keyword-tagged Publications:

Title Authors PubMed ID
1 Improved electrical performance of PDMS and PEDOT: PSS composites with MWCNT and AgNP particles Shafagh SH; Deen I; Packirisamy M; 41424586
ENCS
2 Light-Activated Micromotors in Air Propelled by Thermal Convection Mena-Giraldo P; Mandl GA; Quezada-Novoa V; Garcia-Henao C; Bondon N; Hazlett MJ; Capobianco JA; 40964823
CNSR
3 A synthetic model of bioinspired liposomes to study cancer-cell derived extracellular vesicles and their uptake by recipient cells López RR; Ben El Khyat CZ; Chen Y; Tsering T; Dickinson K; Bustamante P; Erzingatzian A; Bartolomucci A; Ferrier ST; Douanne N; Mounier C; Stiharu I; Nerguizian V; Burnier JV; 40069225
ENCS
4 Long-lasting antimicrobial effect of multipurpose ZnO nanoparticle-loaded dental resins enhanced by blue light photodynamic therapy Leite ML; Comeau P; Zaghwan A; Shen Y; Manso AP; 39765362
ENCS
5 3D bioheat transfer mapping reveals nanomagnetic particles effectiveness in radiofrequency hyperthermia breast cancer treatment comparing to experimental study Kavousi M; Saadatmand E; Masoumbeigi M; Mahdavi R; Riyahi Alam N; 39557504
PHYSICS
6 Non-invasive paper-based sensors containing rare-earth-doped nanoparticles for the detection of D-glucose López-Peña G; Ortiz-Mansilla E; Arranz A; Bogdan N; Manso-Silván M; Martín Rodríguez E; 38729020
CHEMBIOCHEM
7 Tailoring plasmonic sensing strategies for the rapid and sensitive detection of hypochlorite in swimming water samples Sadiq Z; Al-Kassawneh M; Safiabadi Tali SH; Jahanshahi-Anbuhi S; 38451315
ENCS
8 Janus Micromotors for Photophoretic Motion and Photon Upconversion Applications Using a Single Near-Infrared Wavelength Mena-Giraldo P; Kaur M; Maurizio SL; Mandl GA; Capobianco JA; 38197400
CHEMBIOCHEM
9 SiCNFe Ceramics as Soft Magnetic Material for MEMS Magnetic Devices: A Mössbauer Study Stiharu I; Andronenko S; Zinnatullin A; Vagizov F; 37241549
PHYSICS
10 Gold Nanoparticles-Based Colorimetric Assays for Environmental Monitoring and Food Safety Evaluation Sadiq Z; Safiabadi Tali SH; Hajimiri H; Al-Kassawneh M; Jahanshahi-Anbuhi S; 36629748
ENCS
11 Utilization of a biosurfactant foam/nanoparticle mixture for treatment of oil pollutants in soil Vu KA; Mulligan CN; 35834082
ENCS
12 Remediation of oil-contaminated soil using Fe/Cu nanoparticles and biosurfactants Vu KA; Mulligan CN; 35361056
ENCS
13 Electrospun Upconverting Nanofibrous Hybrids with Smart NIR-Light-Controlled Drug Release for Wound Dressing Huang HY; Skripka A; Zaroubi L; Findlay BL; Vetrone F; Skinner C; Oh JK; Cuccia LA; 35019380
CHEMBIOCHEM
14 Microfluidic Shear Processing Control of Biological Reduction Stimuli-Responsive Polymer Nanoparticles for Drug Delivery. Huang Y, Jazani AM, Howell EP, Reynolds LA, Oh JK, Moffitt MG 33455300
CHEMBIOCHEM
15 Using intracellular plasmonics to characterize nanomorphology in human cells. Sohrabi Kashani A, Piekny A, Packirisamy M 33365137
BIOLOGY
16 Controlled Microfluidic Synthesis of Biological Stimuli-Responsive Polymer Nanoparticles. Huang Y, Moini Jazani A, Howell EP, Oh JK, Moffitt MG 31820915
CHEMBIOCHEM
17 The Key Role of Intrinsic Lifetime Dynamics from Upconverting Nanosystems in Multiemission Particle Velocimetry Tessitore G; Maurizio SL; Sabri T; Skinner CD; Capobianco JA; 32924221
CNSR
18 Exploring the biophysicochemical alteration of green alga Asterococcus superbus interactively affected by nanoparticles, triclosan and illumination. Xin X, Huang G, An C, Lu C, Xiong W 32473326
ENCS
19 Wavelength-Selective Nonlinear Imaging and Photo-Induced Cell Damage by Dielectric Harmonic Nanoparticles. Kilin V, Campargue G, Fureraj I, Sakong S, Sabri T, Riporto F, Vieren A, Mugnier Y, Mas C, Staedler D, Collins JM, Bonacina L, Vogel A, Capobianco JA, Wolf JP 32282184
CNSR
20 Surface Response Based Modeling of Liposome Characteristics in a Periodic Disturbance Mixer. López RR, Ocampo I, Sánchez LM, Alazzam A, Bergeron KF, Camacho-León S, Mounier C, Stiharu I, Nerguizian V 32106424
ENCS

 

Title:Microfluidic Shear Processing Control of Biological Reduction Stimuli-Responsive Polymer Nanoparticles for Drug Delivery.
Authors:Huang YJazani AMHowell EPReynolds LAOh JKMoffitt MG
Link:https://www.ncbi.nlm.nih.gov/pubmed/33455300
DOI:10.1021/acsbiomaterials.0c00896
Publication:ACS biomaterials science & engineering
Keywords:directed self-assemblydrug deliverymicrofluidicsnanoparticlesreduction-responsive block copolymers
PMID:33455300 Category:ACS Biomater Sci Eng Date Added:2021-01-20
Dept Affiliation: CHEMBIOCHEM
1 Department of Chemistry, University of Victoria, PO Box 1700 Stn CSC, Victoria, BC V8W 2Y2, Canada.
2 Department of Chemistry and Biochemistry, Concordia University, 7141 Sherbrooke Street West, Montreal, Quebec H4B 1R6, Canada.
3 Department of Biochemistry and Microbiology, University of Victoria, PO Box 1700 Stn CSC, Victoria, BC V8W 2Y2, Canada.

Description:

Microfluidic Shear Processing Control of Biological Reduction Stimuli-Responsive Polymer Nanoparticles for Drug Delivery.

ACS Biomater Sci Eng. 2020 Sep 14; 6(9):5069-5083

Authors: Huang Y, Jazani AM, Howell EP, Reynolds LA, Oh JK, Moffitt MG

Abstract

We demonstrate microfluidic manufacturing of glutathione (GSH)-responsive polymer nanoparticles (PNPs) with controlled in vitro pharmacological properties for selective drug delivery. This work leverages previous fundamental work on microfluidic control of the physicochemical properties of GSH-responsive PNPs containing cleavable disulfide groups in two different locations (core and interface, DualM PNPs). In this paper, we employ a two-phase gas-liquid microfluidic reactor for the flow-directed manufacturing of paclitaxel-loaded or DiI-loaded DualM PNPs (PAX-PNPs or DiI-PNPs, where DiI is a fluorescent drug surrogate dye). We find that both PAX-PNPs and DiI-PNPs exhibit similar flow-tunable sizes, morphologies, and internal structures to those previously described for empty DualM PNPs. Fluorescent imaging of DiI-PNP formulations shows that microfluidic manufacturing greatly improves the homogeneity of drug dispersion within the PNP population compared to standard bulk microprecipitation. Encapsulation of PAX in DualM PNPs significantly increases its selectivity to cancerous cells, with various PAX-PNP formulations showing higher cytotoxicity against cancerous MCF-7 cells than against non-cancerous HaCaT cells, in contrast to free PAX, which showed similar cytotoxicity in the two cell lines. In addition, the characterization of DualM PNP formulations formed at various microfluidic flow rates reveals that critical figures of merit for drug delivery function-including encapsulation efficiencies, GSH-triggered release rates, rates of cell uptake, cytotoxicities, and selectivity to cancerous cells-exhibit microfluidic flow tunability that mirrors trends in PNP size. These results highlight the potential of two-phase microfluidic manufacturing for controlling both structure and drug delivery function of biological stimuli-responsive nanomedicines toward improved therapeutic outcomes.

PMID: 33455300 [PubMed - in process]




BookR developed by Sriram Narayanan
for the Concordia University School of Health
Copyright © 2011-2026
Cookie settings
Concordia University