One- and two-particle microrheology of soft materials based on optical-flow image analysis

Matteo Brizioli; Manuel A. Escobedo-Sánchez; Patrick M. McCall; Yael Roichman; Veronique Trappe; Margaret L. Gardel; Stefan U. Egelhaaf; Fabio Giavazzi; Roberto Cerbino

doi:10.1039/d4sm01390e

One- and two-particle microrheology of soft materials based on optical-flow image analysis

Matteo Brizioli, Manuel A. Escobedo-Sánchez, Patrick M. McCall, Yael Roichman, Veronique Trappe, Margaret L. Gardel, Stefan U. Egelhaaf, Fabio Giavazzi^*, Roberto Cerbino^*

^*Corresponding author for this work

School of Chemistry

Research output: Contribution to journal › Article › peer-review

Abstract

Particle-tracking microrheology probes the rheology of soft materials by accurately tracking an ensemble of embedded colloidal tracer particles. One-particle analysis, which focuses on the trajectory of individual tracers is ideal for homogeneous materials that do not interact with the particles. By contrast, the characterization of heterogeneous, micro-structured materials or those where particles interact directly with the medium requires a two-particle analysis that characterizes correlations between the trajectories of distinct particle pairs. Here, we propose an optical-flow image analysis as an alternative to the tracking-based algorithms to extract one and two-particle microrheology information from video microscopy images acquired using diverse imaging contrast modalities. This technique, termed optical-flow microrheology (OFM), represents a high-throughput, operator-free approach for the characterization of a broad range of soft materials, making microrheology accessible to a wider scientific community.

Original language	English
Pages (from-to)	1373-1381
Number of pages	9
Journal	Soft Matter
Volume	21
Issue number	7
DOIs	https://doi.org/10.1039/d4sm01390e
State	Published - 14 Jan 2025

Funding

Funders	Funder number
Universität Wien
Associazione Italiana per la Ricerca sul Cancro	MFAG-22083
Agenzia Spaziale Italiana	2023-19-U.0, 2023-20-U.0
Schweizerischer Nationalfonds zur Förderung der Wissenschaftlichen Forschung	197340

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10.1039/d4sm01390e

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abstract = "Particle-tracking microrheology probes the rheology of soft materials by accurately tracking an ensemble of embedded colloidal tracer particles. One-particle analysis, which focuses on the trajectory of individual tracers is ideal for homogeneous materials that do not interact with the particles. By contrast, the characterization of heterogeneous, micro-structured materials or those where particles interact directly with the medium requires a two-particle analysis that characterizes correlations between the trajectories of distinct particle pairs. Here, we propose an optical-flow image analysis as an alternative to the tracking-based algorithms to extract one and two-particle microrheology information from video microscopy images acquired using diverse imaging contrast modalities. This technique, termed optical-flow microrheology (OFM), represents a high-throughput, operator-free approach for the characterization of a broad range of soft materials, making microrheology accessible to a wider scientific community.",

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AU - Brizioli, Matteo

AU - Escobedo-Sánchez, Manuel A.

AU - McCall, Patrick M.

AU - Roichman, Yael

AU - Trappe, Veronique

AU - Gardel, Margaret L.

AU - Egelhaaf, Stefan U.

AU - Giavazzi, Fabio

AU - Cerbino, Roberto

PY - 2025/1/14

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AB - Particle-tracking microrheology probes the rheology of soft materials by accurately tracking an ensemble of embedded colloidal tracer particles. One-particle analysis, which focuses on the trajectory of individual tracers is ideal for homogeneous materials that do not interact with the particles. By contrast, the characterization of heterogeneous, micro-structured materials or those where particles interact directly with the medium requires a two-particle analysis that characterizes correlations between the trajectories of distinct particle pairs. Here, we propose an optical-flow image analysis as an alternative to the tracking-based algorithms to extract one and two-particle microrheology information from video microscopy images acquired using diverse imaging contrast modalities. This technique, termed optical-flow microrheology (OFM), represents a high-throughput, operator-free approach for the characterization of a broad range of soft materials, making microrheology accessible to a wider scientific community.

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One- and two-particle microrheology of soft materials based on optical-flow image analysis

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