Acoustic response of compliable microvessels containing ultrasound contrast agents

Oscillating microbubbles within microvessels could induce stresses that lead to bioeffects or vascular damage. Previous work has attributed vascular damage to the vessel expansion or bubble jet. However, ultra-high speed images of recent studies suggest that it could happen due to the vascular invagination. Numerical simulations of confined bubbles could provide insight into understanding the mechanism behind bubble-vessel interactions. In this study, a finite element model of a coupled bubble/fluid/vessel system was developed and validated with experimental data. Also, for a more realistic study viscoelastic properties of microvessels were assessed and incorporated into this comprehensive numerical model. The wall shear stress (WSS) and circumferential stress (CS), metrics of vascular damage, were calculated from these simulations. Resultant amplitudes of oscillation were within 15% of those measured in experiments (four cases). Among the experimental cases, it was numerically found that maximum WSS values were between 1.1-18.3 kPa during bubble expansion and 1.5-74 kPa during bubble collapse. CS was between 0.43-2.2 MPa during expansion and 0.44-6 MPa while invaginated. This finding confirmed that vascular damage could occur during vascular invaginations. Predicted thresholds in which these stresses are higher during vessel invagination were calculated from simulations.

Section: Introductionmentioning

confidence: 99%

Mechanisms of microbubble–vessel interactions and induced stresses: A numerical study

Hosseinkhah

Chen

Matula

et al. 2013

“…This bioeffect is readily observable, of clear biological significance and serves as the threshold of concern for patient risk. While the modeling of specific mechanisms of capillary injury, such as capillary stretching (Qin and Ferrara, 2006;Miao et al 2008), vessel invagination (Hosseinkhah et al 2013), jet impingement (Chen et al 2011), and fluid stress (Hosseinkhah et al 2015), and possibly others, is an ultimate goal, such modeling likely would require extensive detailed theoretical analysis by three-dimensional finite-amplitude methods for any full accounting of the complex microbubble-capillary problem. Here, we pursue the general approach of the MI which was based primarily on theoretical microbubble behavior in an effort to obtain general insights into the problem.…”

Section: Introductionmentioning

confidence: 99%

A two-criterion model for microvascular bioeffects induced in vivo by contrast microbubbles exposed to medical ultrasound

Church¹,

Miller

2015

The mechanical index (MI) is a theoretical exposure parameter for cavitational bioeffects of diagnostic ultrasound. The theory for the MI assumed that bubbles of all relevant sizes exist in tissue, a condition that is approximated for tissues that include a microbubble contrast agent. Therefore, the MI should allow science-based safety guidance for contrast-enhanced diagnostic ultrasound. However, theoretical predictions of bioeffects thresholds based on the MI typically do not concur with the frequency dependence of experimentally measured thresholds for bioeffects. For example, experimental thresholds for glomerular capillary hemorrhage in rats infused with contrast microbubbles increased approximately linearly with frequency (Miller et al. UMB 2008b; 34:1678), while the MI predicted a square-root dependence. Here, cavitation thresholds were computed for linear versions of the acoustic pulses used in that study assuming bubbles containing either air, C 3 F 8 , or a 1:1 mixture of the two and surrounded by either blood or kidney tissue. While no single threshold criterion was successful, combining results for one criterion that maximized circumferential stress in the capillary wall with another that ensured an inertial collapse produced thresholds that were consistent with experimental data. This suggests that a contrast-specific safety metric may be achieved following validation of this 2-criterion model.

“…Finite volume and finite element models of a bubble in a compliant tube have recently been developed to investigate the interaction of an ultrasonically excited bubble and a microvessel (Gao et al, 2007;Qin and Ferrara, 2006;Qin et al, 2006;. These models were used to predict the amplitude and asymmetry of bubble response and the stresses on the tube wall.…”

Section: Introductionmentioning

confidence: 99%

Natural frequencies of two bubbles in a compliant tube: Analytical, simulation, and experimental results

Jang

Zakrzewski

Rossi

et al. 2011

Motivated by various clinical applications of ultrasound contrast agents within blood vessels, the natural frequencies of two bubbles in a compliant tube are studied analytically, numerically, and experimentally. A lumped parameter model for a five degree of freedom system was developed, accounting for the compliance of the tube and coupled response of the two bubbles. The results were compared to those produced by two different simulation methods: (1) an axisymmetric coupled boundary element and finite element code previously used to investigate the response of a single bubble in a compliant tube and (2) finite element models developed in COMSOL Multiphysics. For the simplified case of two bubbles in a rigid tube, the lumped parameter model predicts two frequencies for in-and out-of-phase oscillations, in good agreement with both numerical simulation and experimental results. For two bubbles in a compliant tube, the lumped parameter model predicts four nonzero frequencies, each asymptotically converging to expected values in the rigid and compliant limits of the tube material.