Abstract
Convolutional neural networks (CNNs) have been shown to be powerful tools to assist with object detection and-like a human observer-may be trained based on a relatively small cohort of reference subjects. Rapid, accurate organ recognition in medical imaging permits a variety of new quantitative diagnostic techniques. In the case of therapy with targeted radionuclides, it may permit comprehensive radiation dose analysis in a manner that would often be prohibitively time-consuming using conventional methods. An automated image segmentation tool was developed based on three-dimensional CNNs to detect right and left kidney contours on non-contrast CT images. Model was trained based on 89 manually contoured cases and tested on a cohort of patients receiving therapy with 177Lu-prostate-specific membrane antigen-617 for metastatic prostate cancer. Automatically generated contours were compared with those drawn by an expert and assessed for similarity based on dice score, mean distance-to-agreement, and total segmented volume. Further, the contours were applied to voxel dose maps computed from post-treatment quantitative SPECT imaging to estimate renal radiation dose from therapy. Neural network segmentation was able to identify right and left kidneys in all patients with a high degree of accuracy. The system was integrated into the hospital image database, returning contours for a selected study in approximately 90 s. Mean dice score was 0.91 and 0.86 for right and left kidneys, respectively. Poor performance was observed in three patients with cystic kidneys of which only few were included in the training data. No significant difference in mean radiation absorbed dose was observed between the manual and automated algorithms. Automated contouring using CNNs shows promise in providing quantitative assessment of functional SPECT and possibly PET images; in this case demonstrating comparable accuracy for radiation dose interpretation in unsealed source therapy relative to a human observer.
Highlights
In comparison to other radiation oncology modalities, personalized dosimetry assessment in unsealed source therapies is relatively uncommon
We have demonstrated the feasibility of performing image-based dosimetry to create three-dimensional voxel dose maps [2]
A deep learning segmentation model was trained for detection and accurate delineation of kidneys on non-contrast, low-dose CT scans
Summary
In comparison to other radiation oncology modalities, personalized dosimetry assessment in unsealed source therapies is relatively uncommon. The process involves the measurement of regional uptake and pharmacokinetics followed by some calculation of radiation transport [1]. Integration of pharmacokinetic data and multiplication of organ or voxel dose factors are trivial mathematical operations. Employing these techniques often requires manual input with a degree of time and expertise that precludes their widespread use. We have demonstrated the feasibility of performing image-based dosimetry to create three-dimensional voxel dose maps [2]. This is an automated process that may be applied to any radionuclide treatment where sequential follow-up imaging is available. In the case of therapy with targeted radionuclides, it may permit comprehensive radiation dose ana lysis in a manner that would often be prohibitively timeconsuming using conventional methods
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