Detail publikačního výsledku
DLS Microrheology of biopolymer solution, Probe size effect
HNYLUCHOVÁ, Z.; MONDEK, J.; PEKAŘ, M.
Originální název
DLS Microrheology of biopolymer solution, Probe size effect
Anglický název
DLS Microrheology of biopolymer solution, Probe size effect
Druh
Stať ve sborníku v databázi WoS či Scopus
Originální abstrakt
Structure of biopolymers plays important role for its industrial applications and affect their potential usability. The more information about the micro and macrostructure of the sample the better is evaluation of potential behavior of the sample and suitability for use. For microstructure determination we used passive microrheology method by utilizing diffusing light spectroscopy device and microrheology probes to characterize properties of the sample. Three different probes with unlike particle surfaces were chosen to determine the most appropriate one for biopolymer solutions measurements. To estimate possible probe – biopolymer interactions, which are undesirable for microrheological measurements, zeta potential of particles in the solutions was studied. Results from DLS microrheology were compared with FCS nenorheology measurements. Our data show importance of appropriate particle choice, with an emphasis on the particle surface chemistry. The most suitable particles for biopolymer solutions are polystyrene particles, or PS-COOH particles that avoid particle – biopolymer interaction. DLS and FCS microrheology data exhibit good agreement in wide time range.
Anglický abstrakt
Structure of biopolymers plays important role for its industrial applications and affect their potential usability. The more information about the micro and macrostructure of the sample the better is evaluation of potential behavior of the sample and suitability for use. For microstructure determination we used passive microrheology method by utilizing diffusing light spectroscopy device and microrheology probes to characterize properties of the sample. Three different probes with unlike particle surfaces were chosen to determine the most appropriate one for biopolymer solutions measurements. To estimate possible probe – biopolymer interactions, which are undesirable for microrheological measurements, zeta potential of particles in the solutions was studied. Results from DLS microrheology were compared with FCS nenorheology measurements. Our data show importance of appropriate particle choice, with an emphasis on the particle surface chemistry. The most suitable particles for biopolymer solutions are polystyrene particles, or PS-COOH particles that avoid particle – biopolymer interaction. DLS and FCS microrheology data exhibit good agreement in wide time range.
Klíčová slova
Diffusing light spectroscopy, microrheology, microstructure, zeta potential, fluorescence correlation spectroscopy
Klíčová slova v angličtině
Diffusing light spectroscopy, microrheology, microstructure, zeta potential, fluorescence correlation spectroscopy
Autoři
HNYLUCHOVÁ, Z.; MONDEK, J.; PEKAŘ, M.
Vydáno
05.11.2014
ISBN
978-80-87294-55-0
Kniha
Nanocon 2014 Conference Proceedings
Edice
1
Strany od
1
Strany do
5
Strany počet
5
Plný text v Digitální knihovně
BibTex
@inproceedings{BUT111430,
author="Zuzana {Hnyluchová} and Jakub {Mondek} and Miloslav {Pekař}",
title="DLS Microrheology of biopolymer solution, Probe size effect",
booktitle="Nanocon 2014 Conference Proceedings",
year="2014",
series="1",
pages="1--5",
isbn="978-80-87294-55-0"
}