To investigate the effects of uncertainty in the input variables on FFR and WSS, coronary models were generated based on a synthetically designed single conduit with various geometric parameters of stenosis, as shown in Figure 1. Five uncertain geometric features were considered: proximal, mid, and distal lengths of stenosis; reference lumen diameter of the coronary artery; and diameter-based stenosis severity. The eccentricity of the stenosis was fixed at 35% in all the models. In addition, the mean aortic pressure and normalized microcirculation resistance were included as uncertain physiological variables because the flow rate and cardiac pressure generally play important roles in coronary flow dynamics. The details of the mean value and uncertainty levels for each input variable considered in this study are presented in Table 1. The degree of uncertainty for the input variables was assumed based on the previous study, in which in vivo data typically observed in patients were considered (23). Mean values of vessel geometric parameters were determined by analyzing approximately 400 patients’ left anterior descending (LAD) coronary profiles from the literature (26–29). The mean aortic pressure (P_a) of 90 mm Hg was applied. The microcirculation resistance (R) was set to match the mean flowrate of 1 ml/s under baseline conditions and was reduced by four times (R/4) for the hyperemic condition (30).

An idealized stenotic coronary model with a 3.6 mm-diameter was constructed based on the following equations for the geometric contours.

Here, d(z) and e(z) represent the vessel diameter at the stenotic segment and the central axis of stenosis along its length, respectively. e₀ represents the maximum off-center distance of the stenotic segment; D is the reference lumen diameter of the coronary artery; s₀ is the degree of stenosis.

The eccentricity of stenosis ε₀ is defined as the percentage measure of asymmetry or off-center narrowing within the arterial lumen. Previous studies have demonstrated a higher prevalence of eccentric stenosis compared to concentric stenosis. Mintz et al. (31) reported an occurrence of 795 out of 1,446 (55%) eccentric lesions based on angiography data. Similarly, Yamagishi et al. (32) investigated the morphological characteristics of 114 coronary plaques using intravascular ultrasound and observed that 92 (80%) cases of stenosis exhibited an eccentric pattern. However, Seo et al. (33) reported that lesion eccentricity has no statistically significant effect on FFR. Based on these characteristics, the coronary model in this study considered a fixed eccentricity of 35%, which significantly reduces the CFD computation time.

Eventually, the uncertainties in the variables are propagated to the CFD model via the Latin hypercube sampling method (33) with a uniform distribution.

3D–0D coupled CFD simulations for stenotic coronary flow were performed (34, 35). The flow was assumed to be transient, and the blood was an incompressible Newtonian fluid with a density of 1,050 kg/m³ and kinematic viscosity of 3.5 × 10⁻⁶ m²/s. The unsteady Navier–Stokes equations describing the conservation of mass and momentum of the blood flow are as follows.(4)ρu˙i+ρujui,j=−p,i+(τi,j),j′

For the numerical calculations, these governing equations were split into four steps for time advancement based on a fully implicit fractional step method (36) as follows.(6)Step1:ρu^i−uinΔt+ρ12(u^ju^i,j+ujnui,jn)=−p,in+12(τ^ij+τijn),j

where Δt is the time increment; the superscript n indicates the time level; and u^i and ui∗ are intermediate velocities. The second-order implicit Crank–Nicolson scheme was employed for the diffusion and convection terms.

To accommodate the specific time-varying pressure-flow characteristics of coronary flow, the 0D lumped parameter network (LPN) modeling technique for coronary microcirculation was integrated into 3D CFD at the outlet, as shown in Figure 2. The LPN model represents the coronary circulatory system by combining resistance and capacitance elements based on the similarity between the hydraulic and electric systems. The total resistance and capacitance of the distal coronary bed at rest (baseline) and under the hyperemic condition, which is the maximum flow condition achieved by minimizing microvascular resistance, were determined based on previous studies conducted by Sankaran (24) and Sharma et al. (37). The MPI parallel algorithm was applied to reduce the computation time to a simulation time within 1 h (about 20 min with 64 parallel cores) (35).

A P2P1 finite element scheme (35) was employed with quadratic tetrahedral elements generated using a commercial mesh generator (ICEM-CFD, ANSYS) to achieve higher accuracy. A mesh convergence study was performed by comparing the stenotic pressure drop Δpstenosis in the case of different mesh densities, shown in Figure 3. The difference of Δpstenosis between the medium mesh (the number of nodes ∼1 million) and the densest mesh (the number of nodes ∼1.8 million) is within 0.5%; Meanwhile, the computation time significantly increases from 1,400 s to 3,000 s with the same computational resources (56 parallel cores, Intel Xeon E5-2630 v4). In this way, the mesh with the number of nodes of 1 million was chosen for this study.

For the inlet boundary conditions, a typical aortic pressure waveform (39), scaled using a mean aortic pressure of 90 mmHg, was applied. The duration of each cardiac cycle is 1.0 s and is divided into 120 timesteps. The convergence criteria are 1×10−6,5×10−6 for velocity and mass, respectively. Figure 4 illustrates the blood flow rate under resting (baseline) and hyperemic conditions and the pressure waveforms for a cardiac cycle.

In the nonintrusive polynomial chaos (NIPC) method, a surrogate model f_PC based on polynomials for output Y is generated, as follows.(10)Y≈fPC(X)=∑i=1NP⁡αiΨi(X),

where Ψ_i is the expansion or polynomial (typically orthogonal polynomial) function in relation to the probability distribution of inputs X;αi is a coefficient to be computed; and N_p is the total number of discretization terms.

In practice, N_p is expressed by the following equation in terms of the number of uncertain input parameters n and the order of the polynomial p:(11)Np=(n+p)!n!p!

The inputs X((Xi),i=1,2,..,n) are treated as uncertain variables and hypothesized independent; therefore, the random space of uncertain inputs X is drawn by the joint probability distribution ρ_x, which is consisted of other random variables X_i:(12)ρX(x)=∏i=1n⁡ρXi(xi)

The point collocation NIPC method determines the components a_i by choosing N_s vectors {Xj=(X1,X2,…,Xn)j,j=1,2..,Ns} from the random space and subsequently evaluating the outputs of interest {Yj,j=1,2..,Ns} by deterministic CFD code. Corresponding to each chosen vector there will be an output, a linear system of equations can be established:(13)(Ψ1(X1)Ψ2(X1)…ΨNP(X1)Ψ1(X2)Ψ2(X2)…ΨNP(X2)⋮⋮⋱⋮Ψ1(XNs)Ψ2(XNs)…ΨNP(XNs))(α1α2⋮αNP)=(Y1Y2⋮YNs)

The number of chosen samples N_s should be equal or greater than number of discretization terms N_p; in the case of Ns>Np, the deterministic problem becomes to over-determined system of equations (Eq. 13), then the least squares method can be used to solve (Eq. 14). Hosder et al. (22) suggested that twice as many samples as the minimum (practical) are required to better approximate the statistics at each polynomial degree (Ns=2Np). Here, nps is denoted as the proportion of sample:(15)nps=NsNp

To apply the NIPC method for FFR and WSS, the uncertain input parameters are predefined with a probability distribution, then these parameters are sampled and applied to a deterministic solver to obtain outputs of interest (FFR and WSS); finally, the calculation of UQ and SA was performed. In this study, uncertain input parameters were identified as geometric (Li,Lm,Lo,D,s0) and physiological (Pa,R) features. The uncertain parameters were hypothesized independently distributed and sampled with joint distribution by Latin hypercube to select the collocation points; well-validated in-house CFD code was used to calculate FFR and WSS (35).

The outputs of interest (here, FFR and WSS) are considered as random variables. Practically, the probability density functions of FFR and WSS (ρFFR,andρWSS) are dependent on the uncertain inputs (Li,Lm,Lo,D,s0,Pa,R), which are governed by the CFD model. The characteristics of ρFFR and ρWSS were assessed using uncertainty quantification (UQ) technique, and the contribution of an uncertain input Xi to the outputs of interest was evaluated using the sensitivity analysis (SA).

The convergence rate generally depends on both the number of samples N_s and the order of the polynomial p. Four different maximal polynomial orders were considered (p=1,2,3and4), with the proportion of sample nps=1and2 were used to assess the convergence of UQ measures.

The Python package Chaospy (38) was used to generate stochastic samples and calculate the surrogate model for the simulation output of interest.

Characteristics of unknown distribution of Y using UQ are described as statistical moments (e.g., mean and variance). In the NIPC method, a surrogate model f_PC consisting of orthogonal polynomials used to replace Y; therefore, the mean of unknown distribution of Y can be directly obtained using the coefficients and the orthogonality property. For example, the mean and variance of Y are given by:(16)μ[Y]=E[Y]=∫Ω⁡yρ(y)dy=∫Ω⁡∑i=1NP⁡αiΨi(x)ρX(x)dx=α1

The contribution of the uncertain input parameters to the variation in the output was investigated by sensitivity analysis. The final goal is determining how the uncertainties in the input variables contribute to the variance of the output, either individually or through interactions with other parameters. This is useful for modeling personalization to determine the parameters that need to be optimized to their true values (input prioritization) and those that can be fixed within their uncertainty domains (input fixing). The main and total sensitivity indices (Si and SiT, respectively) (23) were computed to represent input prioritization and input fixing, respectively.

The main sensitivity index, also called the first-order Sobol sensitivity index, is the variance of the conditional expectation of output Y, given the value of input Xi, normalized by the total variance:(18)Si=Var[E[Y|Xi]]Var[Y].

Here, the index i varies from 1 to the number of uncertain input variables n,1≤i≤n.

The main sensitivity index Si represents the expected reduction in the total variance Var[Y] when the input variable Xi is corrected to its true value.

The total sensitivity index SiT includes the sensitivity of both the first-order effects and the interactions (covariance) between a given parameter Xi and all other parameters:(19)SiT=1−Var[E[Y|X−i]]Var[Y],

where X−i is the set of all uncertain input variables except Xi.

The convergence of the UQ measures was assessed by evaluating the mean value obtained with different polynomial orders p and the proportion of sample nps.

Slager et al. (39) reported a tendency to form high-risk plaques localized in stenotic proximal segments with a high WSS. Herein, UQ and SA were conducted to investigate the impact of uncertain input variables on the uncertainty of the average proximal WSS (AWSSprox). A surrogate model was derived from 3D CFD data using PCE.

Figure 6 shows a comparison of the total sensitivity index SiT of AWSSprox for various combinations of polynomial order p and sample size nps. The behavior of SiT exhibited a similar trend for (p,nps) combinations higher than (p=3,nps=2), which suggests suitable convergence.

The degree of stenosis S_o and the mean aortic pressure Pa were always in the highest-sensitivity group, with a main sensitivity greater than 50%, whereas the other variables ranged from 10% to 20%. In addition, the probability density distributions for each combination of (p,nps) were compared, as shown in Figure 7. The probability density distribution by (p=3,nps=2) combination exhibits nearly the same asymmetric shape as the one by (p=4,nps=2) combination with only minor difference of the mean and standard deviation, which indicates the results with the number of polynomials p=3 and p=4 approach the convergence, particularly, when oversampled as nps=2. However, it is clearly exhibited that the proportion of sample, nps=1 is not sufficient for the approximation of the statistics, even though high polynomial order p=4 is applied.

The mean of AWSSprox obtained with different combinations of (p,nps) are given in Figure 8, showing that the obtained mean value tends to converge (relative error < 7.8%) as the polynomial order increases.

Table 2 lists the required number of samples (3D CFD realizations) and the corresponding computing times associated with each combination (p,nps). Based on this observation, the combination (p=3,nps=2) is optimal in terms of the computational cost and prediction accuracy.

As shown in Figure 9, the stenosis severity s0 exhibited the highest main sensitivity index, followed by the mean aortic pressure Pa, whereas the remaining variables exhibited only a minor effect (≤5%). More precisely, these sensitivity indices indicate that if s_o and Pa are changed to their true values, the uncertainty in AWSSprox prediction is reduced by 25% and 9.5%, respectively. The total sensitivity index exhibited a trend similar to that of the main sensitivity index, that is, the greatest influence was from stenosis severity s0 and mean aortic pressure Pa. However, the difference between the main and total sensitivity indices was considerably large. This indicates that the interaction of the input variables in the computational model for WSS prediction is significant; thus, multivariate uncertainty analysis is crucial.

For FFR computations, the same conditions for uncertain input variables were applied, except for microvascular resistance, which was decreased by a factor of 4 relative to the baseline condition, to ensure a hyperemic condition. The FFR was evaluated 20 mm downstream of the stenosis in the pressure fields from the CFD simulations.

Figure 10 shows the statistical characteristics of the probability density of the FFR due to the uncertainty of the input parameters, including the expected values, standard deviation, and 95% prediction interval. Evidently, the distribution is asymmetric and left-skewed toward lower FFR values, unlike AWSSprox which is right-skewed toward higher FFR values.

Figure 11 shows that only the coronary reference diameter D, stenosis severity s0, and microvascular resistance R significantly affected the uncertainty in the FFR prediction. However, the influence of the mean aortic pressure was <0.05. The difference between the main and total sensitivity indices was nearly zero, thus indicating a negligible interaction of the input variables that are independent in the computational model for FFR prediction.