A hybrid model is proposed in this study to predict rectal tumour response during radiotherapy treatment. As the oxygen partial pressure distribution ( p O 2) is a data which is naturally represented at the microscopic scale, we firstly estimate the optimal pO 2 distribution using both a diffusion equation and a discrete multi-scale model (that we proposed in a previous study). The aim is to use the effectiveness in algorithmic complexity of the discrete model and its multi-scale aspect in this work to estimate biological information at cellular scale and then construct them at macroscopic scale. Secondly, the obtained pO 2 distribution results are used as an input of a biomechanical model in order to simulate tumour volume evolution during radiotherapy. FDG PET images of 21 rectal cancer patients undergoing radiotherapy are used to simulate the tumour evolution during the treatment. The simulated results using the proposed hybride model, allow the interpretation of tumour aggressiveness.
The simulation of tumour growth and tumour response to radiation therapy remains a major research topic due to the overall impact of cancer [
The new dynamic model for tumour response to radiotherapy that is proposed in this study comprises two main steps. As a first step, a diffusion equation is used to model the pO2 evolution in the tumour at each time step [
Oxygen transport in tissues via blood vessels obviously depends on vessels structure but also on other biological constraints linked to the tumour behaviour. In the present study, Equation (1) was chosen to locally model the pO2 evolution [
∂ p O 2 ∂ t = 2 P m R ( p c a p − p O 2 ) + ∇ ⋅ ( D ∇ p O 2 ) − c max ⋅ p O 2 p O 2 + P h ⋅ ρ (1)
where, ρ represents the cell density in a voxel, with:
· 2 P m R ( p c a p − p O 2 ) : the source term, P m is the blood vessels permittivity and
R the radius;
· ∇ ⋅ ( D ∇ p O 2 ) : the diffusion term, D is the diffusion coefficient;
· c max ⋅ p O 2 p O 2 + P h : the oxygen consumption per unit cell density, c max is the maximum consumption of pO2, and P h is the pO2 at c max 2 .
In order to provide personalized simulation according to patient specific data coming from images, a parameter controlling the source term was introduced. By denoting μ this parameter, pO2 distributions for a given patient are obtained by solving Equation (2). The values of the fixed parameters are given in
∂ p O 2 ∂ t = μ ( p c a p − p O 2 ) + ∇ ⋅ ( D ∇ p O 2 ) − c max ⋅ p O 2 p O 2 + P h ⋅ ρ (2)
Since pO2 consumption is a process that takes place at the cellular scale, a multi-scale approach is used in order to estimate the optimal distributions from macroscopic PET image data. The diagram shown in
| Parameter | symbol | Value and reference |
|---|---|---|
| Diffusion coefficient | D | 2 × 10−9 m2·s−1 [ |
| Maximum consumption of pO2 | c max | 1 mmHg s−1 [ |
| pO2 at c max / 2 | P h | 2.5 mmHg [ |
| pO2 in the arterie | P c a p | 40 mmHg [ |
| Radio-sensitivity coefficient | α | 0.044 Gy−1 |
| Radio-sensitivity coefficient | β | 0.089 Gy−2 |
| Hypoxic threshold | p O 2 h | fixed at 5 mmHg [ |
found in [
Optimal pO2 distributions are estimated by minimizing a cost function which depends on the number of cells given by simulated and real data. These numbers are calculated from clinical and simulated FDG PET [
1) an acceptability criterion is defined by means of a cost function F (Equation (3)); for every voxel index ( l , n , m ) :
F ( P 1 , P 2 ) ( l , m , n ) = ( 1 − N 8 s ( l , m , n ) N 8 c ( l , m , n ) ) 2 + ( 1 − N 15 s ( l , m , n ) N 15 c ( l , m , n ) ) 2 (3)
where, N 8 s and N 15 c are the total numbers of tumour cells calculated respectively from simulated and clinical images. P 1 and P 2 are pO2 distributions at day 0 and at day 8 respectively;
2) The capillary pressure is initialized at t = t 0 ( t 0 corresponds to day 0) as P c a p = 40 mmHg (pO2 in the arteries [
3) Equation (2) is solved at each time step using finite difference method;
4) pO2 distributions obtained in 3) are used as an input for the discrete model [
5) If the result of the cost function is less than a set threshold, the value of the parameter μ and the pO2 distributions are saved, and the algorithm is stoped. Otherwise, the parameter μ is modified using simulated annealing method [
The final optimal pO2 maps are used as input of a biomechanical model that we describe now.
We denote by A ⊂ R 3 an image containing a patient tumour at time t ∈ [ 0, ϒ ] , where ϒ is the time between the beginning of the first image acquisition (before treatment) and the last acquisition (15 days after the beginning of the irradiation for 17 patients, or after radiotherapy and just before surgery for 4 patients). Then, we denote by Ω ( t ) , the tumour zone in the image A (See
Ω ( t ) = { ( x , y , z ) ∈ A / ρ ( x , y , z , t ) > 0 } (4)
In this study, it is assumed that the tumour tissue is composed either of proliferative cells, quiescent cells, or necrotic cells [
are denoted by ρ p ( x , t ) , ρ q ( x , t ) and ρ N ( x , t ) respectively, ( x = ( x , y , z ) ∈ Ω ( t ) ). They satisfy an advection-reaction-diffusion equation [
∂ ρ l ∂ t + ∇ ⋅ K = S r ( ρ l ) + ∇ ⋅ J − T r ( ρ l ) (5)
where, l = p , q , N and:
· Sr is the modelling tumour cells natural death and birth phenomena;
· ∇ ⋅ J models migratory movements; with J = D ( x ) ∇ ρ l , D is the diffusion coefficient;
· T models the cell death caused by radiotherapy;
· ∇ ⋅ is the divergence operator. K = v ⋅ ρ l is the physical flow given by the system advection (all cells have the same advective velocity v ).
Since rectal tumours are solid tumours, we assume that there is no migratory phenomenon caused by cells movement. Therefore, J in Equation (5) vanishes. The only cell movements considered are the movements caused by the tumour volume variation. The source term Sr is modelled by a logistic function:
S ( ρ l ) = ζ ( p O 2 ) ρ l ( 1 − ρ l Φ ) (6)
with,
ζ ( p O 2 ) = σ ⋅ 1 + tanh ( p O 2 − p O 2 h ) 2 (7)
where, σ > 0 is the intrinsic growth rate, Φ is the maximum capacity of a voxel. p O 2 h is the hypoxic threshold and tanh represents the classical hyperbolic tangent function. The term ζ gives a distinction between proliferating and quiescent cells, and was inspired by [
S F ( p O 2 ) = exp ( − α d ⋅ p O 2 ⋅ ( 1 + ι ⋅ β α ⋅ d ⋅ p O 2 ) ) (8)
where, ι is an adjustment parameter of radiotherapy d accumulation while α and β are classical radio-sensitivities parameters. Thus, tumour cells densities killed by irradiation are modelled as:
T ( ρ l ) = ( 1 − S F ( p O 2 ) ) ⋅ ρ l (9)
In this study, a macroscopic representation of the oxygen partial pressure in the tumour is considered. Indeed, according to the value of the pO2 in the voxel, for methodological reasons, it exists either a density of proliferating and necrotic cells, or only a density of quiescent and necrotic cells. After normalization, we obtain the following Relation (10):
ρ p ( x , t ) + ρ N ( x , t ) = 1 or ρ q ( x , t ) + ρ N ( x , t ) = 1 (10)
As one can notice, Equation (5) is not closed because it has two unknown variables: cell density and velocity v ( K = v ⋅ ρ l ). To close this equation, it is assumed that tumour environment is isotropic and porous, allowing to use Darcy’s law:
v = − ∇ Π (11)
where, Π represents the local pressure. Based on the previous descriptions, tumour cells densities evolution equation is given by ( ρ ∈ { ρ p , ρ q } ):
{ ∇ ⋅ ( v ( x , t ) ρ ( x , t ) ) = S ( ρ ( x , t ) ) − T ( ρ ( x , t ) ) ∂ t ρ N + ∇ ⋅ ( v ρ N ) = 0 v ( x , t ) = − ∇ Π ( x , t ) (12)
The determination of pressure Π will lead to the knowledge of v allowing to close the system (12). By summing the first two equations of this system and by using (10), we obtain:
∇ ⋅ v = S ( ρ ) − T ( ρ ) (13)
Then by replacing v by its expression given by (11) in (13), we obtain:
− Δ Π = S ( ρ ) − T ( ρ ) (14)
The system (15) summarizes all the equations needed for the simulation:
{ ∂ t ρ ( x , t ) + ∇ ⋅ ( v ( x , t ) ρ ( x , t ) ) = S ( ρ ( x , t ) ) − T ( ρ ( x , t ) ) ∂ t ρ N + ∇ ⋅ ( v ρ N ) = 0 v ( x , t ) = − ∇ Π ( x , t ) − Δ Π = S ( ρ ) − T ( ρ ) Π ( x , t ) = 0 ρ ( x ,0 ) = ρ 0 ( x ) (15)
For simulation purposes we used a finite volumes based method and a 3D cartesian grid [ 0, I x ] × [ 0, I y ] × [ 0, I z ] , where I x , I y and I z are voxels numbers in the x, y and z directions, respectively (see
∂ ρ ∂ t ( x , t ) + ∇ ( ρ ( x , t ) v ( x , t ) ) = 0 (16)
d ρ d t ( x , t ) = S ( ρ ( x , t ) ) − T ( ρ ( x , t ) ) (17)
In practice, the two equations above are simulated by running the following algorithm:
1) Equation (14) is used to determine the pressure field Π ;
2) Equation (11) is used to compute the velocity field v , knowing the pressure field Π ;
3) Proliferating ( ρ p ) and quiescent ( ρ q ) cells densities are computed by simulating Equations (16) and (17);
4) If necessary, necrotic cells densities were computed as follows: ρ N = 1 − ρ p − ρ q .
The discretization and numerical schemes used are presented in the Subsection 6.1.
The proposed model (Equation (15)) contains three parameters: σ , Φ and ι , which are analyzed using Sobol sensitivity indices [
The tumour volume at time t is calculated by:
V ( t ) = ∫ Ω ( t ) 1 { x / ρ ( t , x ) > 0 } d x (18)
where, 1 { x / ρ ( t , x ) > 0 } is the indicator function defined on { x / ρ ( t , x ) > 0 } .
The correlation formula for clinical and simulated volumes comparison is:
C o r r ( % ) = ( 1 − | V s − V c | V c ) ⋅ 100 (19)
where, C o r r is the correlation result, V s and V c are the simulated and clinical volumes, respectively.
A clinical database containing 17 patients is used to evaluate the proposed model. First, optimal pO2 distributions are estimated using the diffusion equation and the stochastic multi-scale model, as explained above. Second, the obtained pO2 results are used as an input to the biomechanical model in order to simulate tumour volume evolution during radiotherapy. FDG PET images are used for both the pO2 estimation and the tumour volume evolution for each patient.
The specific data for patient 5 and 12 are given as examples of obtained results. For these two patients, values for the parameter μ are 0.13 and 0.8 respectively. The distribution of oxygen partial pressure over time is given in
| Patient # | day 8 | p O 2 ¯ 8 | day 15 | p O 2 ¯ 15 |
|---|---|---|---|---|
| 1 | 1.863 ≤ p O 2 ≤ 6.448 | 4.525 | 2.186 ≤ p O 2 ≤ 10.480 | 6.787 |
| 2 | 1.267 ≤ p O 2 ≤ 6.157 | 3.59 | 0.386 ≤ p O 2 ≤ 11.548 | 6.886 |
| 3 | 2.198 ≤ p O 2 ≤ 5.284 | 3.688 | 3.027 ≤ p O 2 ≤ 11.422 | 8.281 |
| 4 | 1.616 ≤ p O 2 ≤ 5.73 | 3.646 | 3.023 ≤ p O 2 ≤ 10.333 | 6.991 |
| 5 | 0.937 ≤ p O 2 ≤ 3.098 | 1.768 | 1.018 ≤ p O 2 ≤ 5.129 | 2.696 |
| 6 | 1.112 ≤ p O 2 ≤ 4.033 | 2.656 | 0.899 ≤ p O 2 ≤ 9.250 | 5.717 |
| 7 | 1.179 ≤ p O 2 ≤ 4.722 | 3.043 | 1.697 ≤ p O 2 ≤ 9.821 | 6.345 |
| 8 | 1.120 ≤ p O 2 ≤ 4.243 | 2.308 | 1.864 ≤ p O 2 ≤ 9.234 | 5.236 |
| 9 | 1.207 ≤ p O 2 ≤ 4.550 | 2.969 | 2.174 ≤ p O 2 ≤ 9.144 | 6.129 |
| 10 | 0.514 ≤ p O 2 ≤ 2.226 | 1.185 | 0.195 ≤ p O 2 ≤ 3.930 | 0.670 |
| 11 | 0.801 ≤ p O 2 ≤ 4.378 | 1.812 | 0.781 ≤ p O 2 ≤ 6.749 | 3.275 |
| 12 | 1.531 ≤ p O 2 ≤ 5.029 | 3.257 | 0.970 ≤ p O 2 ≤ 7.893 | 6.717 |
| 13 | 0.800 ≤ p O 2 ≤ 5.181 | 2.449 | 1.122 ≤ p O 2 ≤ 9.014 | 5.053 |
| 14 | 0.479 ≤ p O 2 ≤ 4.237 | 1.602 | 0.635 ≤ p O 2 ≤ 7.300 | 3.187 |
| 15 | 0.719 ≤ p O 2 ≤ 6.912 | 3.003 | 0.867 ≤ p O 2 ≤ 9.827 | 5.338 |
| 16 | 0.844 ≤ p O 2 ≤ 6.218 | 3.100 | 1.197 ≤ p O 2 ≤ 9.018 | 5.129 |
| 17 | 0.731 ≤ p O 2 ≤ 5.956 | 2.439 | 0.376 ≤ p O 2 ≤ 9.305 | 4.887 |
According to the value of pO2 in a voxel, the system of Equation (15) is simulated by considering only the proliferating and necrotic cells or only the necrotic and quiescent cells in the voxel. Sensitivities of biomechanical model parameters according to Sobol analysis are presented in
optimal adjustment parameters obtained for patients 5 and 12 are given in
| Parameter # | Indice |
|---|---|
| σ | 0.482031 |
| Φ | 0.020014 |
| ι | 0.430759 |
| Patient # | σ | Φ | ι |
|---|---|---|---|
| 5 | 0.028 | 2 | 0.001 |
| 12 | 0.00026 | 2 | 0.0016 |
| Patient # | Correlations at day 8 (%) | Correlations at day 15 (%) |
|---|---|---|
| 1 | 92.954 | 51.495 |
| 2 | 94.444 | 91.270 |
| 3 | 99.324 | 64.925 |
| 4 | 94.759 | 61.851 |
| 5 | 97.721 | 95.584 |
| 6 | 92.366 | 92.135 |
| 7 | 93.092 | 98.739 |
| 8 | 98.624 | 92.661 |
| 9 | 98.361 | 70.238 |
| 10 | 91.008 | 92.830 |
| 11 | 95.432 | 96.388 |
| 12 | 90.074 | 71.585 |
| 13 | 98.895 | 96.244 |
| 14 | 90.452 | 70.435 |
| 15 | 99.214 | 94 |
| 16 | 91.150 | 72 |
| 17 | 91.667 | 90.415 |
In order to compare the aggressiveness of tumours, the example of patient 12 is also given (see
One of the objectives of this study is to build a model able to propose the potential extent of the tumour a few days before surgery in order to help resection planning. To this end, the model is also applied to four other patients who have one additional PET image a few days prior to surgery. Results can be seen on
| Patient # | day 8 (%) | day 15 (%) | day 90 (%) |
|---|---|---|---|
| 18 | 97.861 | 86.186 | 90.698 |
| 19 | 98.540 | 90.0552 | 35.112 |
| 20 | 82.031 | 96.774 | 97.678 |
| 21 | 88.799 | 91.242 | 98.233 |
The impact of pO2 remains one of the most studied biological phenomena in simulations of tumour growth and tumour response to radiotherapy [
Concerning this second part, the source term is a logistic function whose growth rate depends on the oxygen partial pressure. This made the entire reaction term dependent on pO2, leading to an increased complexity. The challenge is to find the oxygen distribution that would provide the best prediction in terms of tumour volume evolution. This hybrid methodology is applied to a set of real data and the obtained results appeared satisfactory since a reasonably good agreement is observed between real and computed data (see
The above encouraging results suggest that this study will benefit from a validation on a larger database, including a comprehensive clinical follow-up of the patients. However, despite the variation of tumour cell densities between voxels, as driven by the computed flux, this model does not directly take into account tumour deformations. This is illustrated by the fact that according to Dice
| Patient # | 18 | 19 | 20 | 21 |
|---|---|---|---|---|
| Dice | 0.2456 | 0.1583 | 0.4062 | 0.5524 |
metric [
The mechanical constraints that are at the origin of the shape alteration are indeed difficult to control. This point clearly represents a potential improvement of our method, and in this context, it will be valuable to use anatomical information provided by CT or MRI images for example.
In this study, we proposed a methodology for simulating tumour growth and tumour response to radiation therapy. The adopted approach is based on the synergy between a discrete multi-scale stochastic model and a continuous model based on advection-reaction equations. This image-based process can be personalised according to available clinical data. The evaluation of the method on actual FDG images of patients suffering from rectal cancer is encouraging and opens several opportunities for improvement. The use of multi-modal images providing additional functional information instead of the single modality as presented here will certainly reinforce the robustness and the reliability of the simulations. Also, the introduction of morphological images like X-ray computed tomography is expected to help manage the mechanical constraints that can modify the shape of the tumour and influence its deformation.
The authors would like to thank the Bretagne Region and the LaTIM for their financial support.
The authors declare no conflicts of interest regarding the publication of this paper.
Apeke, S., Gaubert, L., Boussion, N., Visvikis, D., Saut, O., Colin, T., Lambin, P., Rodin, V. and Redou, P. (2022) An Hybrid Model for Rectal Tumour Response Prediction during Radiotherapy. Open Journal of Biophysics, 12, 245-264. https://doi.org/10.4236/ojbiphy.2022.124012
Denote by ρ i , j , k n = ρ ( ( x i , y j , z k ) , t n ) , the local cells densities at time t n and at the position ( x i , y j , z k ) , by v i , j , k n = v ( ( x i , y j , z k ) , t n ) and Π i , j , k n = Π ( ( x i , y j , z k ) , t n ) the corresponding advection velocity and local pressure respectively. The numerical approaches used for the simulation are as follows:
· A finite difference method based on an implicit Euler scheme is used for simulating Equation (14);
· A finite volume method with the 5th order WENO scheme (Weighted Essentially Non-Oscillatory [
∂ t ρ + ∂ x ( v x ρ ) + ∂ y ( v y ρ ) + ∂ z ( v z ρ ) = 0 (20)
and by integrating it, we obtain:
ρ ¯ i j k n + 1 / 2 = ρ ¯ i j k n − Δ t Δ x ( F i + 1 / 2 − F i − 1 / 2 ) − Δ t Δ y ( G j + 1 / 2 − G j − 1 / 2 ) − Δ t Δ z ( H k + 1 / 2 − H k − 1 / 2 ) (21)
where, ρ ¯ i j k n is the mean local tumour cells densities, F i , G j and H k , are their numerical flow, respectively in the x, y and z directions. For all i, j and k, we wrote Δ x i = Δ x , Δ y j = Δ y , and Δ z k = Δ z , with Δ x , Δ y , and Δ z representing voxel dimensions in the x, y and z directions. Δ t is the time step;
· A finite differences method based on an explicit Euler scheme is used for simulating Equation (17), with a discretization given by:
ρ ¯ i j k n + 1 = ρ ¯ i j k n + 1 / 2 + Δ t ⋅ ( S i , j , k n + 1 / 2 − T i , j , k n + 1 / 2 ) (22)
where, S i , j , k n + 1 / 2 = S ( ρ ¯ ( x i , y j , z k , t + 1 / 2 ) ) , and T i , j , k n + 1 / 2 = T ( ρ ¯ ( x i , y j , z k , t + 1 / 2 ) ) .