Simulation of magnetic active polymers for versatile microfluidic devices

Simulation of magnetic active polymers for versatile microfluidic devices

We propose to use a compound of magnetic nanoparticles (20–100 nm) embedded in a flexible polymer (Polydimethylsiloxane PDMS) to filter circulating tumor cells (CTCs). The analysis of CTCs is an emerging tool for cancer biology research and clinical cancer management including the detection, diagnosis...

Full description

Bibliographic Details
Main Authors: Binder Claudia, Kataeva Nadezhda, Bance Simon, Exl Lukas, Reichel Franz, Fischbacher Johann, Özelt Harald, Gusenbauer Markus, Brückl Hubert, Schrefl Thomas
Format: Article
Language:English
Published: EDP Sciences 2013-01-01
Series:EPJ Web of Conferences
Online Access:http://dx.doi.org/10.1051/epjconf/20134002001
id doaj-e91f2e1de01148e898db637df3a50887
record_format Article
spelling doaj-e91f2e1de01148e898db637df3a508872021-08-02T04:07:57ZengEDP SciencesEPJ Web of Conferences2100-014X2013-01-01400200110.1051/epjconf/20134002001Simulation of magnetic active polymers for versatile microfluidic devicesBinder ClaudiaKataeva NadezhdaBance SimonExl LukasReichel FranzFischbacher JohannÖzelt HaraldGusenbauer MarkusBrückl HubertSchrefl ThomasWe propose to use a compound of magnetic nanoparticles (20–100 nm) embedded in a flexible polymer (Polydimethylsiloxane PDMS) to filter circulating tumor cells (CTCs). The analysis of CTCs is an emerging tool for cancer biology research and clinical cancer management including the detection, diagnosis and monitoring of cancer. The combination of experiments and simulations lead to a versatile microfluidic lab-on-chip device. Simulations are essential to understand the influence of the embedded nanoparticles in the elastic PDMS when applying a magnetic gradient field. It combines finite element calculations of the polymer, magnetic simulations of the embedded nanoparticles and the fluid dynamic calculations of blood plasma and blood cells. With the use of magnetic active polymers a wide range of tunable microfluidic structures can be created. The method can help to increase the yield of needed isolated CTCs.http://dx.doi.org/10.1051/epjconf/20134002001
collection DOAJ
language English
format Article
sources DOAJ
author Binder Claudia
Kataeva Nadezhda
Bance Simon
Exl Lukas
Reichel Franz
Fischbacher Johann
Özelt Harald
Gusenbauer Markus
Brückl Hubert
Schrefl Thomas
spellingShingle Binder Claudia
Kataeva Nadezhda
Bance Simon
Exl Lukas
Reichel Franz
Fischbacher Johann
Özelt Harald
Gusenbauer Markus
Brückl Hubert
Schrefl Thomas
Simulation of magnetic active polymers for versatile microfluidic devices
EPJ Web of Conferences
author_facet Binder Claudia
Kataeva Nadezhda
Bance Simon
Exl Lukas
Reichel Franz
Fischbacher Johann
Özelt Harald
Gusenbauer Markus
Brückl Hubert
Schrefl Thomas
author_sort Binder Claudia
title Simulation of magnetic active polymers for versatile microfluidic devices
title_short Simulation of magnetic active polymers for versatile microfluidic devices
title_full Simulation of magnetic active polymers for versatile microfluidic devices
title_fullStr Simulation of magnetic active polymers for versatile microfluidic devices
title_full_unstemmed Simulation of magnetic active polymers for versatile microfluidic devices
title_sort simulation of magnetic active polymers for versatile microfluidic devices
publisher EDP Sciences
series EPJ Web of Conferences
issn 2100-014X
publishDate 2013-01-01
description We propose to use a compound of magnetic nanoparticles (20–100 nm) embedded in a flexible polymer (Polydimethylsiloxane PDMS) to filter circulating tumor cells (CTCs). The analysis of CTCs is an emerging tool for cancer biology research and clinical cancer management including the detection, diagnosis and monitoring of cancer. The combination of experiments and simulations lead to a versatile microfluidic lab-on-chip device. Simulations are essential to understand the influence of the embedded nanoparticles in the elastic PDMS when applying a magnetic gradient field. It combines finite element calculations of the polymer, magnetic simulations of the embedded nanoparticles and the fluid dynamic calculations of blood plasma and blood cells. With the use of magnetic active polymers a wide range of tunable microfluidic structures can be created. The method can help to increase the yield of needed isolated CTCs.
url http://dx.doi.org/10.1051/epjconf/20134002001
work_keys_str_mv AT binderclaudia simulationofmagneticactivepolymersforversatilemicrofluidicdevices
AT kataevanadezhda simulationofmagneticactivepolymersforversatilemicrofluidicdevices
AT bancesimon simulationofmagneticactivepolymersforversatilemicrofluidicdevices
AT exllukas simulationofmagneticactivepolymersforversatilemicrofluidicdevices
AT reichelfranz simulationofmagneticactivepolymersforversatilemicrofluidicdevices
AT fischbacherjohann simulationofmagneticactivepolymersforversatilemicrofluidicdevices
AT ozeltharald simulationofmagneticactivepolymersforversatilemicrofluidicdevices
AT gusenbauermarkus simulationofmagneticactivepolymersforversatilemicrofluidicdevices
AT brucklhubert simulationofmagneticactivepolymersforversatilemicrofluidicdevices
AT schreflthomas simulationofmagneticactivepolymersforversatilemicrofluidicdevices
_version_ 1721242657535033344

Similar Items