Abstract
ObjectiveLiver cancer is one of the most commonly diagnosed cancer, and energy-based tumor ablation is a widely accepted treatment. Automatic and robust segmentation of liver tumors and ablation zones would facilitate the evaluation of treatment success. The purpose of this study was to develop and evaluate an automatic deep learning based method for (1) segmentation of liver and liver tumors in both arterial and portal venous phase for pre-treatment CT, and (2) segmentation of liver and ablation zones in both arterial and portal venous phase for after ablation treatment.Materials and Methods252 CT images from 63 patients undergoing liver tumor ablation at a large University Hospital were retrospectively included; each patient had pre-treatment and post-treatment multi-phase CT images. 3D voxel-wise manual segmentation of the liver, tumors and ablation region by the radiologist provided reference standard. Deep learning models for liver and lesion segmentation were initially trained on the public Liver Tumor Segmentation Challenge (LiTS) dataset to obtain base models. Then, transfer learning was applied to adapt the base models on the clinical training-set, to obtain tumor and ablation segmentation models both for arterial and portal venous phase images. For modeling, 2D residual-attention Unet (RA-Unet) was employed for liver segmentation and a multi-scale patch-based 3D RA-Unet for tumor and ablation segmentation.ResultsOn the independent test-set, the proposed method achieved a dice similarity coefficient (DSC) of 0.96 and 0.95 for liver segmentation on arterial and portal venous phase, respectively. For liver tumors, the model on arterial phase achieved detection sensitivity of 71%, DSC of 0.64, and on portal venous phase sensitivity of 82%, DSC of 0.73. For liver tumors >0.5cm3 performance improved to sensitivity 79%, DSC 0.65 on arterial phase and, sensitivity 86%, DSC 0.72 on portal venous phase. For ablation zone, the model on arterial phase achieved detection sensitivity of 90%, DSC of 0.83, and on portal venous phase sensitivity of 90%, DSC of 0.89.ConclusionThe proposed deep learning approach can provide automated segmentation of liver tumors and ablation zones on multi-phase (arterial and portal venous) and multi-time-point (before and after treatment) CT enabling quantitative evaluation of treatment success.
Highlights
Liver cancer is one of the most commonly diagnosed cancer globally in 2018, with about 841.000 new cases and 782.000 deaths annually [1]
We present an automatic method based on deep learning (DL) to realize accurate segmentation of the liver, tumors and ablation zones in multi-phase computed tomography (CT) images of liver cancer patients and make a quantitative efficacy evaluation for radiofrequency ablation (RFA)/microwave ablation (MWA)
The local Institutional Review Board approved this retrospective, single-center study and waived the requirement for written informed consent for the patient cohort. 104 patients were identified, applying the following eligibility criteria: [1] patients (≥ 18 years) who were referred to our radiology department for liver RFA/MWA, [2] pathology proven Hepatocellular carcinoma (HCC) or liver metastases, [3] complete multi-phase CT images, arterial phase and portal venous phase, and [4] CT images of patients with both pre- and post-procedure
Summary
Liver cancer is one of the most commonly diagnosed cancer globally in 2018, with about 841.000 new cases and 782.000 deaths annually [1]. Hepatocellular carcinoma (HCC) is the most frequent primary liver cancer and the third leading cause of cancer death [2]. Given the complexity of liver cancer and many potentially useful treatments, the most appropriate treatment option should be selected for each patient at each tumor stage. Energy-based tumor ablation has become a widely accepted treatment option for patients with early-stage liver cancer in recent years. Several energy-based ablation technologies are currently available, including radiofrequency ablation (RFA), microwave ablation (MWA), laser ablation, and cryoablation. RFA and MWA aim to achieve irreversible cellular injury and cellular death, leading to eradicating the target tumor [6]. The segmentation is a crucial first step that provides a series of quantitative measurements, including volume, shape, localization, and the proportion for liver or lesion
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