Ressa Gaia, Levi Riccardo, Savini Giovanni, Raspagliesi Luca, Clerici Elena, Bellu Luisa, Cappellini Luca A, Grimaldi Marco, Pancetti Saverio, Bono Beatrice, Franzini Andrea, Riva Marco, Fernandez Bethania, Niyazi Maximilian, Pessina Federico, Minniti Giuseppe, Navarria Pierina, Scorsetti Marta, Politi Letterio S
Department of Biomedical Sciences, Humanitas University, Via Rita Levi Montalcini 4, Pieve Emanuele, 20072 Milan, Italy.
Neuroradiology Unit, IRCCS Humanitas Research Hospital, Via Alessandro Manzoni 56, Rozzano, 20089 Milan, Italy.
Neuro Oncol. 2025 Apr 2. doi: 10.1093/neuonc/noaf090.
Differentiating radionecrosis from neoplastic progression after stereotactic radiosurgery (SRS) for brain metastases is a diagnostic challenge. Previous studies have often been limited by datasets lacking histologically confirmed diagnoses. This study aimed to develop automated models for distinguishing radionecrosis from disease progression on brain MRI, utilizing cases with definitive histopathological confirmation.
This multi-center retrospective study included patients who underwent surgical resection for suspected brain metastasis progression after SRS. Presurgical FLAIR and post-contrast T1 (T1w-ce) were segmented using a convolutional neural network (CNN) and compared with manual segmentation by means of Dice score. Radiomics features were extracted from each lesion, and a Random Forest model was trained on 70% of the internal dataset and evaluated on the remaining 30% and the complete external dataset. A 3DResNet-CNN was trained on the same split dataset. Validation was performed on the external dataset. Post-surgical histology was available for all cases.
124 brain metastases were included (104 from center 1 and 20 from center 2). Sole radionecrosis was histologically detected in 34 cases (27.4%).In the internal dataset, univariate and multivariate analysis identified 131 significantly different radiomics features, including GLDM_DNUN and GLDM_SDE within the enhancing area on the T1w-ce. On the external test dataset, the Random Forest model and the 3DResNet-CNN yielded accurate results in terms of accuracy (80.0%, 85.0%), AUROC (0.830, 0.893) and sensitivity (92.8%, 100%) in radionecrosis prediction, respectively.
Artificial intelligence could be employed to differentiate between radionecrosis and brain metastasis progression upon SRS, potentially reducing unnecessary surgical interventions.
在立体定向放射外科治疗(SRS)脑转移瘤后,鉴别放射性坏死与肿瘤进展是一项诊断挑战。以往研究常受限于缺乏组织学确诊诊断的数据集。本研究旨在利用具有明确组织病理学确诊的病例,开发用于在脑MRI上区分放射性坏死与疾病进展的自动化模型。
这项多中心回顾性研究纳入了在SRS后因疑似脑转移瘤进展而接受手术切除的患者。术前液体衰减反转恢复序列(FLAIR)和增强后T1加权像(T1w-ce)通过卷积神经网络(CNN)进行分割,并通过Dice系数与手动分割进行比较。从每个病变中提取放射组学特征,并在内部数据集的70%上训练随机森林模型,在其余30%和完整的外部数据集上进行评估。在相同的分割数据集上训练3D残差神经网络(3DResNet-CNN)。在外部数据集上进行验证。所有病例均有术后组织学检查结果。
共纳入124例脑转移瘤(中心1有104例,中心2有20例)。组织学检测到单纯放射性坏死34例(27.4%)。在内部数据集中,单变量和多变量分析确定了131个显著不同的放射组学特征,包括T1w-ce上强化区域内的灰度共生矩阵离散度归一化(GLDM_DNUN)和灰度共生矩阵标准差熵(GLDM_SDE)。在外部测试数据集上,随机森林模型和3DResNet-CNN在放射性坏死预测的准确性(80.0%,85.0%)、曲线下面积(AUROC,0.830,0.893)和敏感性(92.8%,100%)方面分别产生了准确的结果。
人工智能可用于鉴别SRS后的放射性坏死与脑转移瘤进展,可能减少不必要的手术干预。
