PERFORM Publications

Keyword search (4,163 papers available)

Title		Authors	PubMed ID
1	Proximal sound printing: direct 3D printing of microstructures on polymers	Foroughi S; Habibi M; Packirisamy M;	41500993 ENCS
2	Improved electrical performance of PDMS and PEDOT: PSS composites with MWCNT and AgNP particles	Shafagh SH; Deen I; Packirisamy M;	41424586 ENCS
3	Robust and Compact Electrostatic Comb Drive Arrays for High-Performance Monolithic Silicon Photonics	Fasihanifard M; Packirisamy M;	41156349 ENCS
4	Angled electrode comb drives for enhanced actuator in silicon photonic applications	Fasihanifard M; Packirisamy M;	41130948 ENCS
5	Microfluidic Liquid Biopsy Minimally Invasive Cancer Diagnosis by Nano-Plasmonic Label-Free Detection of Extracellular Vesicles: Review	Neriya Hegade KP; Bhat RB; Packirisamy M;	40650129 ENCS
6	Alzheimer model chip with microglia BV2 cells	Yazdanpanah Moghadam E; Sonenberg N; Packirisamy M;	40623989 ENCS
7	Printing of Cantilevers and Millifluidic Devices Using Ultrasound Waves	Foroughi S; Karamzadeh V; Habibi M; Packirisamy M;	40538575 ENCS
8	PEDOT:PSS-MWCNT Nanocomposite Wire for Routing in Energy Harvesting Devices	Shafagh SH; Deen I; Mamsapuram Panneerselvam D; Packirisamy M;	40283259 ENCS
9	Microfluidic Wound-Healing Assay for Comparative Study on Fluid Dynamic, Chemical and Mechanical Wounding on Microglia BV2 Migration	Yazdanpanah Moghadam E; Sonenberg N; Packirisamy M;	39203655 ENCS
10	Holographic direct sound printing	Derayatifar M; Habibi M; Bhat R; Packirisamy M;	39107289 ENCS
11	Microfluidic Wound-Healing Assay for ECM and Microenvironment Properties on Microglia BV2 Cells Migration	Yazdanpanah Moghadam E; Sonenberg N; Packirisamy M;	36832056 ENCS
12	Microfluidics in smart packaging of foods	Pou KRJ; Raghavan V; Packirisamy M;	36192908 ENCS
13	Gold Nano-Bio-Interaction to Modulate Mechanobiological Responses for Cancer Therapy Applications	Sohrabi Kashani A; Larocque K; Piekny A; Packirisamy M;	35839330 BIOLOGY
14	Microfluidic Platforms for the Isolation and Detection of Exosomes: A Brief Review	Raju D; Bathini S; Badilescu S; Ghosh A; Packirisamy M;	35630197 ENCS
15	Direct sound printing	Habibi M; Foroughi S; Karamzadeh V; Packirisamy M;	35387993 ENCS
16	Arraying of microphotosynthetic power cells for enhanced power output	Kuruvinashetti K; Packirisamy M;	35359612 ENCS
17	Simple, Economical Methods for the Culture of Green Algae for Energy Harvesting from Photosynthesis in a Microfluidic Environment	Kuruvinashetti K; Rahimi S; Pakkiriswami S; Packirisamy M;	34898042 ENCS
18	Magnetic particle based liquid biopsy chip for isolation of extracellular vesicles and characterization by gene amplification	Bathini S; Pakkiriswami S; Ouellette RJ; Ghosh A; Packirisamy M;	34517262 ENCS
19	Cancer-Nano-Interaction: From Cellular Uptake to Mechanobiological Responses	Sohrabi Kashani A; Packirisamy M;	34502495 ENCS
20	Optical Fiber Array Sensor for Force Estimation and Localization in TAVI Procedure: Design, Modeling, Analysis and Validation	Bandari N; Dargahi J; Packirisamy M;	34450813 ENCS
21	Using intracellular plasmonics to characterize nanomorphology in human cells.	Sohrabi Kashani A, Piekny A, Packirisamy M	33365137 BIOLOGY
22	Cancer cells optimize elasticity for efficient migration.	Kashani AS; Packirisamy M;	33204453 ENCS
23	Gold Nano-Island Platforms for Localized Surface Plasmon Resonance Sensing: A Short Review.	Badilescu S, Raju D, Bathini S, Packirisamy M	33066088 ENCS
24	Toward Task Autonomy in Robotic Cardiac Ablation: Learning-Based Kinematic Control of Soft Tendon-Driven Catheters.	Jolaei M, Hooshiar A, Dargahi J, Packirisamy M	32678722 ENCS
25	Lab-On-A-Chip for the Development of Pro-/Anti-Angiogenic Nanomedicines to Treat Brain Diseases.	Subramaniyan Parimalam S, Badilescu S, Sonenberg N, Bhat R, Packirisamy M	31817343 ENCS
26	Nano-Bio Interactions of Extracellular Vesicles with Gold Nanoislands for Early Cancer Diagnosis.	Bathini S, Raju D, Badilescu S, Kumar A, Ouellette RJ, Ghosh A, Packirisamy M	31549028 ENCS
27	Flow force augmented 3D suspended polymeric microfluidic (SPMF3 ) platform.	Marzban M, Dargahi J, Packirisamy M	30025169 ENCS
28	Tuning of Morphology and Stability of Gold Nanostars Through pH Adjustment.	Kumar R, Badilescu S, Packirisamy M	30913757 ENCS
29	Efficient Low Shear Flow-based Trapping of Biological Entities.	Sohrabi Kashani A, Packirisamy M	30940862 ENCS
30	Acoustofluidic Micromixing Enabled Hybrid Integrated Colorimetric Sensing, for Rapid Point-of-Care Measurement of Salivary Potassium.	Surendran V, Chiulli T, Manoharan S, Knisley S, Packirisamy M, Chandrasekaran A	31141923 ENCS
31	The effect of hydrogen nanobubbles on the morphology of gold-gelatin bionanocomposite films and their optical properties.	Alsawafta M, Badilescu S, Truong VV, Packirisamy M	22248640 PHYSICS

Title:	Using intracellular plasmonics to characterize nanomorphology in human cells.
Authors:	Sohrabi Kashani A, Piekny A, Packirisamy M
Link:	https://www.ncbi.nlm.nih.gov/pubmed/33365137
DOI:	10.1038/s41378-020-00219-w
Publication:	Microsystems & nanoengineering
Keywords:	Engineering; Nanoparticles;
PMID:	33365137	Category:	Microsyst Nanoeng	Date Added:	2020-12-29
Dept Affiliation:	BIOLOGY 1 Optical Bio-Microsystem Lab, Micro-Nano-Bio-Integration Center, Department of Mechanical, Industrial and Aerospace Engineering, Concordia University, 1455 De Maisonneuve Blvd. W., Montreal, QC H3G 1M8 Canada. 2 Department of Biology, Concordia University, 7141 Sherbrooke Street W., Montreal, QC H4B 1R6 Canada.

Description:

Using intracellular plasmonics to characterize nanomorphology in human cells.

Microsyst Nanoeng. 2020; 6:110

Authors: Sohrabi Kashani A, Piekny A, Packirisamy M

Abstract

Determining the characteristics and localization of nanoparticles inside cells is crucial for nanomedicine design for cancer therapy. Hyperspectral imaging is a fast, straightforward, reliable, and accurate method to study the interactions of nanoparticles and intracellular components. With a hyperspectral image, we could collect spectral information consisting of thousands of pixels in a short time. Using hyperspectral images, in this work, we developed a label-free technique to detect nanoparticles in different regions of the cell. This technique is based on plasmonic shifts taking place during the interaction of nanoparticles with the surrounding medium. The unique optical properties of gold nanoparticles, localized surface plasmon resonance bands, are influenced by their microenvironment. The LSPR properties of nanoparticles, hence, could provide information on regions in which nanoparticles are distributed. To examine the potential of this technique for intracellular detection, we used three different types of gold nanoparticles: nanospheres, nanostars and Swarna Bhasma (SB), an Indian Ayurvedic/Sidha medicine, in A549 (human non-small cell lung cancer) and HepG2 (human hepatocellular carcinoma) cells. All three types of particles exhibited broader and longer bands once they were inside cells; however, their plasmonic shifts could change depending on the size and morphology of particles. This technique, along with dark-field images, revealed the uniform distribution of nanospheres in cells and could provide more accurate information on their intracellular microenvironment compared to the other particles. The region-dependent optical responses of nanoparticles in cells highlight the potential application of this technique for subcellular diagnosis when particles with proper size and morphology are chosen to reflect the microenvironment effects properly.

PMID: 33365137 [PubMed]

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