使用贝叶斯特征选择算法识别基于三维剂量分布形状的剂量反应模型:头颈部癌症试验的一个例子

2010 Ninth International Conference on Machine Learning and Applications Pub Date : 2010-12-12 DOI:10.1109/ICMLA.2010.113

F. Buettner, S. Gulliford, S. Webb, M. Partridge, A. Miah, K. Harrington, C. Nutting

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引用次数: 4

摘要

唾液流量减少和口干是头颈部肿瘤放疗后常见的副作用。口干症可以根据腮腺的剂量来建模。迄今为止，所有空间信息都已被丢弃，剂量-反应模型通常被简化为平均剂量。我们提出了新的形态学剂量反应模型，并使用多变量贝叶斯逻辑回归来模拟口干症。我们使用三维不变统计矩作为形态描述符来量化三维剂量分布的形状。由于这导致潜在预测因子的数量非常多，因此我们应用贝叶斯变量选择算法来基于所有潜在预测因子的任意子集找到最佳模型。为此，我们确定成为所有潜在模型的最佳模型的后验概率，并计算一个变量应该包含在模型中的边际概率。这是使用可逆跳跃马尔可夫链蒙特卡洛算法完成的。使用偏差信息准则和留一交叉验证(LOOCV)对最佳模型的性能进行量化。该方法应用于64例接受调强放疗(IMRT)或常规放疗的头颈癌患者。结果表明，与传统的平均剂量模型相比，当包含形态学信息时，模型拟合和曲线下面积(AUC)都有显着增加。IMRT患者的最佳平均剂量模型LOOCV后的AUC仅为0.63，而最佳形态学模型的AUC为0.90。对于普通患者，平均剂量模型和形态学模型的AUC分别为0.55和0.86。对于合并所有患者的联合模型，平均剂量模型的AUC为0.75，形态学模型的AUC为0.88。我们已经证明，不变统计矩是一个很好的形态计量描述符，通过使用贝叶斯变量选择，我们能够识别具有比传统平均剂量模型高得多的预测能力的模型。

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Using a Bayesian Feature-selection Algorithm to Identify Dose-response Models Based on the Shape of the 3D Dose-distribution: An Example from a Head-and-neck Cancer Trial

A reduction in salivary flow and xerostomia are common side-effects after radiotherapy of head and neck tumours. Xerostomia can be modeled based on the dose to the parotid glands. To date, all spatial information has been discarded and dose-response models are usually reduced to the mean dose. We present novel morphological dose-response models and use multivariate Bayesian logistic regression to model xerostomia. We use 3D invariant statistical moments as morphometric descriptors to quantify the shape of the 3D dose distribution. As this results in a very high number of potential predictors, we apply a Bayesian variable-selection algorithm to find the best model based on any subset of all potential predictors. To do this, we determine the posterior probabilities of being the best model for all potential models and calculate the marginal probabilities that a variable should be included in a model. This was done using a Reversible Jump Markov Chain Monte Carlo algorithm. The performance of the best model was quantified using the deviance information criterion and a leave-one-out cross-validation (LOOCV). This methodology was applied to 64 head and neck cancer patients treated with either intensity-modulated radiotherapy (IMRT) or conventional radiotherapy. Results show a substantial increase in both model-fit and area under the curve (AUC) when including morphological information compared to conventional mean-dose models. The best mean-dose model for IMRT patients only resulted in an AUC of 0.63 after LOOCV while the best morphological model had an AUC of 0.90. For conventional patients the mean-dose model and the morphological model had AUC of 0.55 and 0.86 respectively. For a joint model with all patients pooled together, the mean dose model had an AUC of 0.75 and the morphological model an AUC of 0.88. We have shown that invariant statistical moments are a good morphometric descriptor and by using Bayesian variable selection we were able to identify models with a substantially higher predictive power than conventional mean-dose models.

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2010 Ninth International Conference on Machine Learning and Applications

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