Department of Radiation Oncology, Universitätsklinikum Erlangen, Friedrich-Alexander-Universität Erlangen-Nürnberg (FAU), Erlangen, Germany.
Comprehensive Cancer Center Erlangen-EMN (CCC ER-EMN), Erlangen, Germany.
Med Phys. 2022 Sep;49(9):5773-5786. doi: 10.1002/mp.15863. Epub 2022 Jul 22.
Brain metastases (BM) occur frequently in patients with metastatic cancer. Early and accurate detection of BM is essential for treatment planning and prognosis in radiation therapy. Due to their tiny sizes and relatively low contrast, small BM are very difficult to detect manually. With the recent development of deep learning technologies, several res earchers have reported promising results in automated brain metastasis detection. However, the detection sensitivity is still not high enough for tiny BM, and integration into clinical practice in regard to differentiating true metastases from false positives (FPs) is challenging.
The DeepMedic network with the binary cross-entropy (BCE) loss is used as our baseline method. To improve brain metastasis detection performance, a custom detection loss called volume-level sensitivity-specificity (VSS) is proposed, which rates metastasis detection sensitivity and specificity at a (sub)volume level. As sensitivity and precision are always a trade-off, either a high sensitivity or a high precision can be achieved for brain metastasis detection by adjusting the weights in the VSS loss without decline in dice score coefficient for segmented metastases. To reduce metastasis-like structures being detected as FP metastases, a temporal prior volume is proposed as an additional input of DeepMedic. The modified network is called DeepMedic+ for distinction. Combining a high-sensitivity VSS loss and a high specificity loss for DeepMedic+, the majority of true positive metastases are confirmed with high specificity, while additional metastases candidates in each patient are marked with high sensitivity for detailed expert evaluation.
Our proposed VSS loss improves the sensitivity of brain metastasis detection, increasing the sensitivity from 85.3% for DeepMedic with BCE to 97.5% for DeepMedic with VSS. Alternatively, the precision is improved from 69.1% for DeepMedic with BCE to 98.7% for DeepMedic with VSS. Comparing DeepMedic+ with DeepMedic with the same VSS loss, 44.4% of the FP metastases are reduced in the high-sensitivity model and the precision reaches 99.6% for the high-specificity model. The mean dice coefficient for all metastases is about 0.81. With the ensemble of the high-sensitivity and high-specificity models, on average only 1.5 FP metastases per patient need further check, while the majority of true positive metastases are confirmed.
Our proposed VSS loss and temporal prior improve brain metastasis detection sensitivity and precision. The ensemble learning is able to distinguish high confidence true positive metastases from metastases candidates that require special expert review or further follow-up, being particularly well-fit to the requirements of expert support in real clinical practice. This facilitates metastasis detection and segmentation for neuroradiologists in diagnostic and radiation oncologists in therapeutic clinical applications.
脑转移(BM)在转移性癌症患者中很常见。早期、准确地检测 BM 对于放射治疗的治疗计划和预后至关重要。由于其体积小且对比度相对较低,因此手动检测小 BM 非常困难。随着深度学习技术的最新发展,一些研究人员在自动脑转移检测方面取得了有希望的结果。然而,检测灵敏度对于微小 BM 来说仍然不够高,并且将其整合到区分真正转移与假阳性(FP)的临床实践中具有挑战性。
使用具有二项交叉熵(BCE)损失的 DeepMedic 网络作为我们的基线方法。为了提高脑转移检测性能,提出了一种名为体积水平灵敏度特异性(VSS)的自定义检测损失,该损失按(子)体积级别评估转移检测的灵敏度和特异性。由于灵敏度和精确度总是相互权衡的,因此通过调整 VSS 损失中的权重,可以在不降低分割转移的骰子评分系数的情况下,为脑转移检测获得高灵敏度或高精度。为了减少将类转移结构检测为 FP 转移,提出了一个时间先验体积作为 DeepMedic 的附加输入。修改后的网络称为 DeepMedic+以进行区分。将高灵敏度的 VSS 损失与 DeepMedic+相结合,大多数真正的阳性转移都以高特异性确认,而在每个患者中都有更多的转移候选者以高灵敏度标记,以进行详细的专家评估。
我们提出的 VSS 损失提高了脑转移检测的灵敏度,将灵敏度从使用 BCE 的 DeepMedic 的 85.3%提高到使用 VSS 的 DeepMedic 的 97.5%。或者,使用 BCE 的 DeepMedic 的精确度从 69.1%提高到使用 VSS 的 DeepMedic 的 98.7%。将 DeepMedic+与具有相同 VSS 损失的 DeepMedic 进行比较,在高灵敏度模型中减少了 44.4%的 FP 转移,而在高特异性模型中达到了 99.6%的精确度。所有转移的平均骰子系数约为 0.81。使用高灵敏度和高特异性模型的集成,平均每个患者只需要检查 1.5 个 FP 转移,而大多数真正的阳性转移都得到了确认。
我们提出的 VSS 损失和时间先验提高了脑转移检测的灵敏度和精确度。集成学习能够区分高置信度的真正阳性转移与需要特殊专家审查或进一步随访的转移候选者,非常适合真实临床实践中专家支持的要求。这有利于神经放射学家在诊断和放射肿瘤学家在治疗临床应用中的转移检测和分割。
