Visualization of the intracavitary blood flow in systemic ventricles of Fontan patients by contrast echocardiography using particle image velocimetry

A total of 23 patients were enrolled in this study: 8 Fontan [age 31.5 ± 12 years (mean ± standard error of the mean, SEΜ); 7 women] and 15 controls [age 46 ± 10 years (mean ± standard error of the mean, SEΜ); 6 women]. All patients were in a stable clinical condition, without overt signs or symptoms of heart failure, classified as functional class NYHA I-II. Oxygen saturations of all patients were above 96% indicating the absence of major right-to-left shunting. The study protocol was approved by the ethics committee of our institution. All patients gave written informed consent prior to the examinations. Demographic and clinical characteristics of our study population are summarized in Tables 1 and 2.

To visualize intracavitary flow, a 0.2 ml of intravenous contrast (Sonovue^®) was injected intravenously as a bolus. Images in the apical 4 chamber views plane were obtained and digitally stored using a Sequoia C512 (Siemens, Mountain View, USA) equipped with a 3.5 MHz transducer. Data were analyzed off-line with dedicated research software (Omega Flow, Siemens, Mountain View, USA) capable of tracking contrast enhanced blood flow and visualizing and quantifying blood flow patterns as described recently [4].

The process of vortex formation It is related to the difference in velocity between the high-speed inflow jet after mitral valve opening and the surrounding still fluid in the left ventricle (LV). The shear layer between the moving and the still part of the blood promotes natural swirling of flow inside the ventricle, leading to the vortex formation

A vortex is a mass of fluid whose elements are moving in nearly circular pathlines about a common axis. Vortices are to be distinguished from vorticity, which is the local rate of rotation of infinitesimal fluid elements about their own axes.

The parameter vorticity, describing the curling of the blood flow was colour coded and displayed over the entire cardiac cycle. For the evaluation of vortex morphology and characteristics, we used the parameters as was proposed by Hong et al.[3] In brief, we measured vortex depth (VD), vortex length (VL) and vortex width (VW) indicating the shape of vortex. VL was measured using major-axis length of vortex relative to systemic ventricle length, VW was measured using minor-axis length of vortex relative to systemic ventricle length, and VD represents vertical position of the center of vortex relative to systemic ventricular long axis. A vortex sphericity index (SI) was calculated by VL and VW, as VL/VW ratio.

Changes in regional vorticity can be used to estimate energy dissipation in the fluid. A vortex loses kinetic energy because of fluid viscosity, when a large, and steady vortex is converted in the bloodstream into smaller, rapidly changing vortices. The pulsatility map showed red colour if there is strong vortex. For the evaluation of energy dissipation (pulsatility) of left ventricle vortex, we assessed 3 pulsatility parameters including relative strength (RS), vortex relative strength (VRS), and vortex pulsation correlation (VPC) of left ventricle vortex.

The RS represents the strength of the pulsatile component of vorticity with respect to the average vorticity in the whole left ventricle. The VRS represents the same ratio accounting for the pulsatile vorticity of vortex only instead of the entire left ventricle. The VPC is the correlation between steady and pulsatile vorticity in the vortex, normalized with the vortex strength and area to make a dimensionless parameter.

RS and VRS can be calculated with a mathematic definition as follows [6]:

where ω₀ represents the steady and ω₁ represents the pulsatile component (first harmonic) of regional vorticity.

The VPC can be calculated with a different mathematic definition as follows [6]:

V P C = A v o r t e x ∫ v o r t e x ω 0 ( x , y ) ω 1 ( x , y ) d x d y ∫ v o r t e x ω 0 ( x , y ) d x d y 2 ,where ω₀ represents again the steady and ω₁ represents the pulsatile component (first harmonic) of regional vorticity and A_vortex represents the vortex area.

Two double-blinded examiners repeatedly performed the measurements on 10 randomly selected patients for interobserver analysis. The second observer repeated the measurements 2 months after the first time. Case sequence was randomly arranged each time.

Continuous variables were presented as mean and standard deviation and were compared using the independent Student t test. Comparison of categorical variables was made by the chi-square test. The assessment of intraobserver and interobserver variability was performed by two independent observers or within an observer for quantitative vortex parameters. The agreement between the two measurements was expressed using the 95% confidence interval and determined as the mean of the differences +/-1.96SD [7].

A p value < 0.05 was considered statistically significant. All statistical analyses were performed using the SSPS statistical package (SSPS version 18.0, Inc., Chicago, Illinois)

Clinical characteristics of the study population are shown in Tables 1 and 2. Mean age was 46 ± 10 years for the control group. Of the 8 patients with Fontan circulation (mean age 31.5 ± 12 years), 2 patients (25%) were male. There was no significant difference in age and gender between the controls and Fontan patients groups. The right ventricular systolic function was estimated visually by an experienced echocardiogram while the left ventricular systolic function was calculated by Volumetric Biplane Simpsons' (FS: 29 ± 4.4 vs. 35 ± 5%, p = 0.07), the systemic ventricular end-diastolic dimension (51.8 ± 8.8 vs. 47.5 ± 0.7, p = 0.2), systemic ventricular systolic dimension (37.1 ± 8.2 vs. 32.5 ± 2.1, p = 0.1), and left atrial dimension (42.7 ± 13.8 vs. 37.5 ± 0.7, p = 0.2) were similar in both groups.

Images of the resulting flow patterns from a 29-year old male Fontan patient, born with DILV, VSD and pulmonary atresia are presented in Figure 1 (Additional file 1). To enable comparison with a normal flow pattern, the flow pattern of a 38-year old male without cardiac abnormalities is depicted in Figure 2 (Additional file 2).

In both diastole and systole, distinct and significant differences were observed in the evolution and temporal development of flow structures. The location, shape and sphericity of the main vortices differ clearly from controls in all cardiac cycle [early diastole(A), late diastole(B), ejection (C)] (Figures 1,2). The vortex from the Fontan group was consistently shorter, wider and rounder than in controls. The LV vortex immediately after the onset of the early diastolic phase, redirects the blood flow from LV base, to LV posterior wall, to LV apex during isovolumic relaxation and toward the LV outflow tract and aorta during isovolumic contraction. Pulsatility of systemic ventricular field and vortex represented by RS, VRS and VPC were significantly different in patients with Fontan circulation; red encodes positive vorticity (i.e. counter clockwise rotation of the blood), blue negative vorticity clockwise rotation. The pulsatility in Fontan group was less red encodes and was not at the centre and the apex of systemic ventricle which means not strong vortex. In controls, the vortex was compact, elliptically shaped, and located apically (Figure 3).

VL (0.51 ± 0.09 vs 0.65 ± 0.12, P = 0.010), SI (1.66 ± 0.48 vs 2.41 ± 0.42, p = 0.005), RS (0.77 ± 0.33 vs 1.90 ± 0.47, p = 0.0001), and VRS (0.18 ± 0.13 vs 0.43 ± 0.14, p = 0.001) were significantly lower in Fontan patients. VW (0.32 ± 0.006 vs 0.27 ± 0.04, p = 0.014) and VPC (0.26 ± 0.25 vs -0.22 ± 0.87, p = 0.05) were significantly higher in the Fontan patient group. (Table 3 Figure 4)

Interobserver variability analysis of quantitative vortex parameter measurements are listed in Table 4.