Issue 12, 2017

Using μ2rheology to quantify rheological properties during repeated reversible phase transitions of soft matter

Abstract

A microfluidic device is designed to measure repeated phase transitions, gelation and degradation, on a single sample by exchanging the surrounding fluid while minimizing shear stress. This device enables quantitative microrheological characterization of material properties over multiple phase transitions, determining whether the material returns to the same equilibrium state. Fluid exchange is accomplished by using a two layer design, the sample is trapped in the first layer and the second layer is a well for the exchanging fluid. Fluid enters the sample chamber symmetrically creating equal pressure around the sample, trapping it in place. Multiple particle tracking (MPT) microrheology, a passive microrheological technique, measures the dynamic rheological properties during each phase transition. Combining rheological characterization and sample manipulation using microfluidics is termed μ2rheology. The utility of this technique is demonstrated by characterizing several phase transitions of a fibrous colloidal gel, hydrogenated castor oil. Gelation and degradation is induced by an osmotic pressure gradient created by contact with a glycerine based gelling agent and water, respectively. Several transitions are measured using a single sample. Nine transitions, five gel–sol and four sol–gel, are the maximum number of transitions characterized in a single sample. This microfluidic device and measurement technique is widely applicable and can be easily adapted to any system where solvent exchange is used to induce a change in material properties.

Graphical abstract: Using μ2rheology to quantify rheological properties during repeated reversible phase transitions of soft matter

Supplementary files

Article information

Article type
Paper
Submitted
02 Mar 2017
Accepted
21 May 2017
First published
22 May 2017

Lab Chip, 2017,17, 2085-2094

Using μ2rheology to quantify rheological properties during repeated reversible phase transitions of soft matter

M. D. Wehrman, M. J. Milstrey, S. Lindberg and K. M. Schultz, Lab Chip, 2017, 17, 2085 DOI: 10.1039/C7LC00222J

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