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Particle-Based Microrheology As a Tool for Characterizing Protein-Based Materials

Michael Meleties, Rhett L. Martineau, Maneesh K. Gupta, Jin Kim Montclare

2022ACS Biomaterials Science & Engineering20 citationsDOI

Abstract

Microrheology based on video microscopy of embedded tracer particles has the potential to be used for high-throughput protein-based materials characterization. This potential is due to a number of characteristics of the techniques, including the suitability for measurement of low sample volumes, noninvasive and noncontact measurements, and the ability to set up a large number of samples for facile, sequential measurement. In addition to characterization of the bulk rheological properties of proteins in solution, for example, viscosity, microrheology can provide insight into the dynamics and self-assembly of protein-based materials as well as heterogeneities in the microenvironment being probed. Specifically, passive microrheology in the form of multiple particle tracking and differential dynamic microscopy holds promise for applications in high-throughput characterization because of the lack of user interaction required while making measurements. Herein, recent developments in the use of multiple particle tracking and differential dynamic microscopy are reviewed for protein characterization and their potential to be applied in a high-throughput, automatable setting.

Topics & Concepts

MicrorheologyCharacterization (materials science)RheologyParticle (ecology)MicroscopyThroughputNanotechnologyMaterials scienceTracking (education)Biological systemViscosityNanoparticle tracking analysisComputer scienceChemistryPhysicsGeologyBiologymicroRNABiochemistryPedagogyOceanographyOpticsWirelessTelecommunicationsComposite materialGenePsychologyMicrovesiclesBlood properties and coagulationRheology and Fluid Dynamics StudiesErythrocyte Function and Pathophysiology
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