Continuum topological derivative - A novel application tool for segmentation of CT and MRI images

Q4 Neuroscience Neuroimage. Reports Pub Date : 2024-08-01 DOI:10.1016/j.ynirp.2024.100215
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Abstract

Introduction

Computed Tomography (CT) and Magnetic Resonance Imaging (MRI) are essential tools for unraveling anatomical and tissue properties, particularly in the head and brain. CT provides high-contrast images, particularly valuable in cases such as cerebral bleeds, and also aids in estimating cranial deformities and organ shape deviations. MRI, on the other hand, offers excellent imaging of cerebral artery regions, allowing analysis of various cerebral pathologies through different sequences. Beyond detecting common head and brain disorders, these modalities play a crucial role in identifying abnormalities in orbits, middle cerebral artery territories, brain ventricles, soft tissues, and bones. A unique aspect of brain MRI is its ability to produce multiplanar brain assessments. Both head/brain CT and MRI are invaluable for studying haemorrhage cases, with segmentation of affected areas providing detailed images for further analysis. This study explores the application of a novel mathematical technique, continuum topological derivative (CTD), for CT and MR image segmentation.

Methods

The initial stage of Continuum Topological Derivative (CTD) segmentation involves preprocessing CT and MR images due to their susceptibility to inherent noises, such as quantum mottle, and Gaussian and Rayleigh noises, respectively. In this study, we have implemented the CTD denoising algorithm to produce denoised CT/MR images, serving as ground truth for subsequent segmentation steps. Validation of the denoised CTD CT/MR images was conducted through minimal residual value computation across all case studies. Following this, segmentation of the region of interest was performed using the CTD technique, with comparisons made against Discrete Topological Derivatives (DTD), k-mean clustering and Adaptive Threshold methods. Evaluation of the proposed CTD algorithm's effectiveness in segmentation involved calculating performance metrics such as Jaccard and dice indices to assess spatial overlap of segmented images.

Results

The CTD technique yields excellent segmentation results, not only for the delineated region of interest but also for volume-based cerebral blood areas and anomalies in the middle cerebral artery (MCA) and its territorial areas, which are substantiated through performance metrics and visual inspection by trained radiologist. This aids in determining the severity of stroke in affected patients. Additionally, a unique attempt is made to apply CTD to Electrical Impedance Tomography (EIT) images of the lungs for precise estimation of the breathing cycle. CTD successfully generates standardized images, demonstrating attenuation and density characteristics for cerebral cisterns, arteries, and ventricles.

Discussion

The denoised images obtained through CTD facilitate thorough analysis of both normal and pathological conditions, providing radiologists with enhanced capabilities to identify subtle details, particularly in areas such as abnormal cerebral artery territories, haemorrhage cases, cisterns, ventricles and arteries. Results clearly demonstrate that the combination of CTD denoising and segmentation outperforms the other three established methods in terms of both efficiency and accuracy in delineating diseased or affected areas, as evidenced by the various case studies conducted in this research. In summary, the proposed CTD method aims to delineate boundaries and contours of the region of interest, facilitating precise estimation of size and shape for accurate detection of the extent of diseased or affected areas.

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连续拓扑导数--用于 CT 和 MRI 图像分割的新型应用工具
导言计算机断层扫描(CT)和磁共振成像(MRI)是揭示解剖和组织特性的重要工具,尤其是在头部和脑部。CT 可提供高对比度图像,在脑出血等情况下尤为重要,还有助于估计颅骨畸形和器官形状偏差。另一方面,核磁共振成像可提供出色的脑动脉区域成像,通过不同的序列分析各种脑部病变。除了检测常见的头部和脑部疾病外,这些模式还在识别眼眶、大脑中动脉区域、脑室、软组织和骨骼的异常方面发挥着重要作用。脑部核磁共振成像的独特之处在于它能够进行多平面脑部评估。头部/脑部 CT 和核磁共振成像对研究出血病例非常有价值,对受影响区域的分割可提供详细的图像供进一步分析。方法由于 CT 和 MR 图像容易受到量子斑纹、高斯和瑞利噪声等固有噪声的影响,因此 CT 和 MR 图像分割的初始阶段需要对 CT 和 MR 图像进行预处理。在这项研究中,我们采用 CTD 去噪算法生成去噪 CT/MR 图像,作为后续分割步骤的基本真相。通过计算所有案例研究的最小残值,对去噪 CTD CT/MR 图像进行了验证。之后,使用 CTD 技术对感兴趣区进行分割,并与离散拓扑衍生物 (DTD)、k-均值聚类和自适应阈值方法进行比较。结果 CTD 技术不仅对划定的感兴趣区,而且对基于容积的脑血区域和大脑中动脉 (MCA) 及其区域的异常都产生了出色的分割结果,这些结果通过性能指标和训练有素的放射科医生的目视检查得到了证实。这有助于确定受影响患者的中风严重程度。此外,还进行了一次独特的尝试,将 CTD 应用于肺部电阻抗断层扫描(EIT)图像,以精确估计呼吸周期。讨论通过 CTD 获得的去噪图像有助于全面分析正常和病理情况,为放射科医生提供了更强的能力来识别微妙的细节,尤其是在异常脑动脉区域、出血病例、脑室、脑室和动脉等区域。研究结果清楚地表明,CTD 去噪和分割相结合的方法在划定病变或受影响区域的效率和准确性方面均优于其他三种已确立的方法,本研究中进行的各种案例研究也证明了这一点。总之,所提出的 CTD 方法旨在划定感兴趣区域的边界和轮廓,便于精确估计大小和形状,从而准确检测病变或受影响区域的范围。
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来源期刊
Neuroimage. Reports
Neuroimage. Reports Neuroscience (General)
CiteScore
1.90
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审稿时长
87 days
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