A feasible dose-volume estimation of radiotherapy treatment with optimal transport using a concept for transportation of Ricci-flat time-varying dose-volume

Yusuke Anetai, Jun'ichi Kotoku
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Abstract

In radiotherapy, the dose-volume histogram (DVH) curve is an important means of evaluating the clinical feasibility of tumor control and side effects in normal organs against actual treatment. Fractionation, distributing the amounts of irradiation, is used to enhance the treatment effectiveness of tumor control and mitigation of normal tissue damage. Therefore, dose and volume receive time-varying effects per fractional treatment event. However, the difficulty of DVH superimposition of different situations prevents evaluation of the total DVH despite different shapes and receiving dose distributions of organs in each fraction. However, an actual evaluation is determined traditionally by the initial treatment plan because of summation difficulty. Mathematically, this difficulty can be regarded as a kind of optimal transport of DVH. For this study, we introduced DVH transportation on the curvilinear orthogonal space with respect to arbitrary time ($T$), time-varying dose ($D$), and time-varying volume ($V$), which was designated as the TDV space embedded in the Riemannian manifold.Transportation in the TDV space should satisfy the following: (a) the metrics between dose and volume must be equivalent for any fractions and (b) the cumulative characteristic of DVH must hold irrespective of the lapse of time. With consideration of the Ricci-flat condition for the $D$-direction and $V$-direction, we obtained the probability density distribution, which is described by Poisson's equation with radial diffusion process toward $T$. This geometrical requirement and transportation equation rigorously provided the feasible total DVH.
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利用理奇平面时变剂量-体积传输概念,以最佳传输方式估算可行的放疗剂量-体积
在放射治疗中,剂量-体积直方图(DVH)曲线是根据实际治疗情况评估肿瘤控制和正常器官副作用的临床可行性的重要手段。分次放射治疗是通过分配照射量来提高控制肿瘤和减轻正常组织损伤的治疗效果。因此,每次分次治疗的剂量和体积都会产生不同时间的效果。然而,由于不同情况下的 DVH 难以叠加,因此尽管每个分次中器官的形状和受照剂量分布不同,也无法评估总的 DVH。然而,由于求和困难,实际评估传统上由初始治疗方案决定。从数学上讲,这种困难可以被视为 DVH 的一种优化传输。在本研究中,我们引入了 DVH 在任意时间($T$)、时变剂量($D$)和时变体积($V$)的曲线正交空间上的传输,并将其命名为嵌入黎曼manifold 的 TDV 空间:(a) 对于任何分数,剂量和体积之间的对称性必须相等;(b) 无论时间如何变化,DVH 的累积特性必须成立。考虑到 $D$ 方向和 $V$ 方向的利玛窦平坦条件,我们得到了概率密度分布,该分布由泊松比方程描述,具有向 $T$ 的径向扩散过程。这一几何要求和传输方程严格提供了可行的总 DVH。
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