Padmaja Jonnalagedda , Brent Weinberg , Taejin L. Min , Shiv Bhanu , Bir Bhanu
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While the tumor mass is the most significant feature, the impacted tissue surrounding the tumor is also a significant biomarker contributing to the visual manifestation of mutations — which has not been studied as extensively. The pattern of tumor growth impacts the surrounding tissue accordingly, which is a reflection of tumor properties as well. Modeling how the tumor growth impacts the surrounding tissue can reveal important information about the patterns of tumor enhancement, which in turn has significant diagnostic and prognostic value. This paper presents the first work to automate the computational modeling of the impacted tissue surrounding the tumor using generative deep learning. The paper isolates and quantifies the impact of the Tumor Invasion (TI) on surrounding tissue based on change in mutation status, subsequently assessing its prognostic value. Furthermore, a TI Generative Adversarial Network (TI-GAN) is proposed to model the tumor invasion properties. 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引用次数: 0
摘要
对于多形性胶质母细胞瘤等发病率较高的疾病,预后和治疗计划流水线需要对成像、临床和分子数据进行综合分析。研究表明,许多突变与患者的中位生存率和治疗反应密切相关。研究表明,这些突变在核磁共振成像等肿瘤成像模式中表现为特定的视觉生物标志物。为了最大限度地减少对患者进行侵入性手术的次数,并优化预后和治疗计划过程中的整体资源,成像和分子特征的相关性已引起广泛关注。虽然肿瘤肿块是最重要的特征,但肿瘤周围受影响的组织也是一个重要的生物标志物,有助于突变的直观表现--这一点尚未得到广泛研究。肿瘤的生长模式会对周围组织产生相应的影响,这也是肿瘤特性的一种反映。对肿瘤生长如何影响周围组织进行建模,可以揭示肿瘤增强模式的重要信息,这反过来又具有重要的诊断和预后价值。本文首次介绍了利用生成式深度学习对肿瘤周围受影响组织进行自动计算建模的工作。本文根据突变状态的变化,分离并量化了肿瘤入侵(TI)对周围组织的影响,随后评估了其预后价值。此外,还提出了一种 TI 生成对抗网络(TI-GAN)来模拟肿瘤入侵特性。通过广泛的定性和定量分析、跨数据集测试和放射科医生盲测,证明了 TI-GAN 能够在医疗数据集的实际挑战(如数据有限和类内异质性高)下真实地模拟肿瘤侵袭。
Computational modeling of tumor invasion from limited and diverse data in Glioblastoma
For diseases with high morbidity rates such as Glioblastoma Multiforme, the prognostic and treatment planning pipeline requires a comprehensive analysis of imaging, clinical, and molecular data. Many mutations have been shown to correlate strongly with the median survival rate and response to therapy of patients. Studies have demonstrated that these mutations manifest as specific visual biomarkers in tumor imaging modalities such as MRI. To minimize the number of invasive procedures on a patient and for the overall resource optimization for the prognostic and treatment planning process, the correlation of imaging and molecular features has garnered much interest. While the tumor mass is the most significant feature, the impacted tissue surrounding the tumor is also a significant biomarker contributing to the visual manifestation of mutations — which has not been studied as extensively. The pattern of tumor growth impacts the surrounding tissue accordingly, which is a reflection of tumor properties as well. Modeling how the tumor growth impacts the surrounding tissue can reveal important information about the patterns of tumor enhancement, which in turn has significant diagnostic and prognostic value. This paper presents the first work to automate the computational modeling of the impacted tissue surrounding the tumor using generative deep learning. The paper isolates and quantifies the impact of the Tumor Invasion (TI) on surrounding tissue based on change in mutation status, subsequently assessing its prognostic value. Furthermore, a TI Generative Adversarial Network (TI-GAN) is proposed to model the tumor invasion properties. Extensive qualitative and quantitative analyses, cross-dataset testing, and radiologist blind tests are carried out to demonstrate that TI-GAN can realistically model the tumor invasion under practical challenges of medical datasets such as limited data and high intra-class heterogeneity.
期刊介绍:
The purpose of the journal Computerized Medical Imaging and Graphics is to act as a source for the exchange of research results concerning algorithmic advances, development, and application of digital imaging in disease detection, diagnosis, intervention, prevention, precision medicine, and population health. Included in the journal will be articles on novel computerized imaging or visualization techniques, including artificial intelligence and machine learning, augmented reality for surgical planning and guidance, big biomedical data visualization, computer-aided diagnosis, computerized-robotic surgery, image-guided therapy, imaging scanning and reconstruction, mobile and tele-imaging, radiomics, and imaging integration and modeling with other information relevant to digital health. The types of biomedical imaging include: magnetic resonance, computed tomography, ultrasound, nuclear medicine, X-ray, microwave, optical and multi-photon microscopy, video and sensory imaging, and the convergence of biomedical images with other non-imaging datasets.