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Geometric effects in gas vesicle buckling under ultrasound

Hossein Salahshoor, Yuxing Yao, Przemysław Dutka, Nivin N. Nyström, Zhiyang Jin, Ellen Min, Dina Malounda, Grant J. Jensen, M. Ortíz, Mikhail G. Shapiro

2022Biophysical Journal25 citationsDOIOpen Access PDF

Abstract

Acoustic reporter genes based on gas vesicles (GVs) have enabled the use of ultrasound to noninvasively visualize cellular function in vivo. The specific detection of GV signals relative to background acoustic scattering in tissues is facilitated by nonlinear ultrasound imaging techniques taking advantage of the sonomechanical buckling of GVs. However, the effect of geometry on the buckling behavior of GVs under exposure to ultrasound has not been studied. To understand such geometric effects, we developed computational models of GVs of various lengths and diameters and used finite element simulations to predict their threshold buckling pressures and postbuckling deformations. We demonstrated that the GV diameter has an inverse cubic relation to the threshold buckling pressure, whereas length has no substantial effect. To complement these simulations, we experimentally probed the effect of geometry on the mechanical properties of GVs and the corresponding nonlinear ultrasound signals. The results of these experiments corroborate our computational predictions. This study provides fundamental insights into how geometry affects the sonomechanical properties of GVs, which, in turn, can inform further engineering of these nanostructures for high-contrast, nonlinear ultrasound imaging.

Topics & Concepts

BucklingUltrasoundNonlinear systemGeometryInverseMaterials scienceFinite element methodMechanicsAcousticsStructural engineeringMathematicsPhysicsComposite materialEngineeringQuantum mechanicsPhotoacoustic and Ultrasonic ImagingUltrasound and Hyperthermia ApplicationsMicrofluidic and Bio-sensing Technologies
Geometric effects in gas vesicle buckling under ultrasound | Litcius