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Utilizing Patient Anatomical Changes to Determine Parotid Mean Dose Changes for H&N Adaptive Planning Decisions: A Machine-Learning Approach

B Wu*, P Zhang , P Zhang , G Mageras , J Tsai , J Mechalakos , M Hunt , Memorial Sloan-Kettering Cancer Center, New York, NY

Presentations

(Thursday, 8/2/2018) 7:30 AM - 9:30 AM

Room: Karl Dean Ballroom C

Purpose: This study proposes and validates a machine-learning approach utilizing patient anatomical changes to predict parotid mean dose changes, thereby facilitating plan adaptation for H&N cancer.

Methods: Parotid mean dose changes are assumed to correlate with patient anatomical changes, quantified by 65 features in three sets: SET1) body shrinkage, resulting in beam path changes to the parotid; SET2) parotid movement with respect to the high-dose region; SET3) parotid volume changes. SET1 is quantified using features measuring the signed-distance between the parotid and skin. SET2 quantifies parotid movement using the signed-distance of the parotid to two PTV position surrogates: C2 dens and basilar tip of the occipital bone. A decision-tree classifier is built from a database of plans from 18 patients (36 parotids) previously treated with adaptive radiotherapy. Inputs are a patient’s features calculated from the initial planning CT and secondary image set (CT/CBCT/MRI). Output is “1� if the predicted parotid mean dose from the secondary image set is x% larger than its original value. During feature selection, leave-one-out cross validation combined with enumerating k-combinations (k=1, 2, 3 and 4) of the 65 features is used to find a feature subset maximizing classifier’s accuracy. Gini-diversity index and maximal number of decision splits=10 are used in the classifier.

Results: When predicting x=5% (or x=10% as shown in the below parentheses) mean dose increase, two SET2 features (one SET1 feature and one SET2 feature) yielded maximal accuracy of 86.1% (86.1%) with 30.5% (19.4%) over prevalence=55.6% (66.7%); TPR=87.5% (75%), TNR=85% (91.7%), PPV=82.3% (81.8%) and NPV=89.5% (88%).

Conclusion: Using specific quantitative features characterizing patient anatomical changes, the classifier effectively predicts x=5% and x=10% parotid mean dose increase with an accuracy of 86.1%.

Keywords

Modeling, Shape Analysis, Treatment Planning

Taxonomy

TH- External beam- photons: adaptive therapy

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