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Optical coherence elastography based on inverse compositional Gauss-Newton digital volume correlation with second-order shape function

Hao Wu, Jiaqiu Wang, Jorge Alberto Amaya Catano, Cuiru Sun, Zhiyong Li

2022Optics Express16 citationsDOIOpen Access PDF

Abstract

A digital volume correlation (DVC)-based optical coherence elastography (OCE) method with inverse compositional Gauss-Newton (IC-GN) algorithm and second-order shape function is presented in this study. The systematic measurement errors of displacement and strain from our OCE method were less than 0.2 voxel and 4 × 10 −4 , respectively. Second-order shape function could better match complex deformation and decrease speckle rigidity-induced error. Compared to conventional methods, our OCE method could track a larger strain range up to 0.095 and reduce relative error by 30-50%. This OCE method has the potential to become an effective tool in characterising mechanical properties of biological tissue.

Topics & Concepts

OpticsOptical coherence tomographyCoherence (philosophical gambling strategy)Digital image correlationPhysicsGaussPoint spread functionVolume (thermodynamics)InverseFunction (biology)MathematicsGeometryQuantum mechanicsBiologyEvolutionary biologyOptical Coherence Tomography ApplicationsPhotoacoustic and Ultrasonic ImagingOptical measurement and interference techniques
Optical coherence elastography based on inverse compositional Gauss-Newton digital volume correlation with second-order shape function | Litcius