Synthetic contrast-enhanced computed tomography generation using a deep convolutional neural network for cardiac substructure delineation in breast cancer radiation therapy: a feasibility study

Jaehee Chun; Jee Suk Chang; Caleb Oh; InKyung Park; Min Seo Choi; Chae-Seon Hong; Hojin Kim; Gowoon Yang; Jin Young Moon; Seung Yeun Chung; Young Joo Suh; Jin Sung Kim

doi:10.1186/s13014-022-02051-0

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Synthetic contrast-enhanced computed tomography generation using a deep convolutional neural network for cardiac substructure delineation in breast cancer radiation therapy: a feasibility study

Authors: Jaehee Chun ; Jee Suk Chang ; Caleb Oh ; InKyung Park ; Min Seo Choi ; Chae-Seon Hong ; Hojin Kim ; Gowoon Yang ; Jin Young Moon ; Seung Yeun Chung ; Young Joo Suh ; Jin Sung Kim

Citation: RADIATION ONCOLOGY, Vol.17(1) : 83, 2022-04

Journal Title: RADIATION ONCOLOGY

Issue Date: 2022-04

MeSH: Breast Neoplasms* / diagnostic imaging ; Breast Neoplasms* / radiotherapy ; Feasibility Studies ; Female ; Heart Diseases* ; Humans ; Neural Networks, Computer ; Retrospective Studies ; Tomography, X-Ray Computed / methods

Keywords: Breast cancer ; Contrast-enhanced computed tomography ; Deep learning ; Radiation therapy ; Radiation-induced heart disease

Abstract: Background: Adjuvant radiation therapy improves the overall survival and loco-regional control in patients with breast cancer. However, radiation-induced heart disease, which occurs after treatment from incidental radiation exposure to the cardiac organ, is an emerging challenge. This study aimed to generate synthetic contrast-enhanced computed tomography (SCECT) from non-contrast CT (NCT) using deep learning (DL) and investigate its role in contouring cardiac substructures. We also aimed to determine its applicability for a retrospective study on the substructure volume-dose relationship for predicting radiation-induced heart disease.

Methods: We prepared NCT-CECT cardiac scan pairs of 59 patients. Of these, 35, 4, and 20 pairs were used for training, validation, and testing, respectively. We adopted conditional generative adversarial network as a framework to generate SCECT. SCECT was validated in the following three stages: (1) The similarity between SCECT and CECT was evaluated; (2) Manual contouring was performed on SCECT and CECT with sufficient intervals and based on this, the geometric similarity of cardiac substructures was measured between them; (3) The treatment plan was quantitatively analyzed based on the contours of SCECT and CECT.

Results: While the mean values (± standard deviation) of the mean absolute error, peak signal-to-noise ratio, and structural similarity index measure between SCECT and CECT were 20.66 ± 5.29, 21.57 ± 1.85, and 0.77 ± 0.06, those were 23.95 ± 6.98, 20.67 ± 2.34, and 0.76 ± 0.07 between NCT and CECT, respectively. The Dice similarity coefficients and mean surface distance between the contours of SCECT and CECT were 0.81 ± 0.06 and 2.44 ± 0.72, respectively. The dosimetry analysis displayed error rates of 0.13 ± 0.27 Gy and 0.71 ± 1.34% for the mean heart dose and V5Gy, respectively.

Conclusion: Our findings displayed the feasibility of SCECT generation from NCT and its potential for cardiac substructure delineation in patients who underwent breast radiation therapy.