{"title":"基于深度图像和原始强度轮廓特征检索的知识数据库医学卷数据传输函数设计","authors":"Younhyun Jung, Jim Kong, Bin Sheng, Jinman Kim","doi":"10.1007/s11390-024-3419-7","DOIUrl":null,"url":null,"abstract":"<p>Direct volume rendering (DVR) is a technique that emphasizes structures of interest (SOIs) within a volume visually, while simultaneously depicting adjacent regional information, e.g., the spatial location of a structure concerning its neighbors. In DVR, transfer function (TF) plays a key role by enabling accurate identification of SOIs interactively as well as ensuring appropriate visibility of them. TF generation typically involves non-intuitive trial-and-error optimization of rendering parameters, which is time-consuming and inefficient. Attempts at mitigating this manual process have led to approaches that make use of a knowledge database consisting of pre-designed TFs by domain experts. In these approaches, a user navigates the knowledge database to find the most suitable pre-designed TF for their input volume to visualize the SOIs. Although these approaches potentially reduce the workload to generate the TFs, they, however, require manual TF navigation of the knowledge database, as well as the likely fine tuning of the selected TF to suit the input. In this work, we propose a TF design approach, CBR-TF, where we introduce a new content-based retrieval (CBR) method to automatically navigate the knowledge database. Instead of pre-designed TFs, our knowledge database contains volumes with SOI labels. Given an input volume, our CBR-TF approach retrieves relevant volumes (with SOI labels) from the knowledge database; the retrieved labels are then used to generate and optimize TFs of the input. This approach largely reduces manual TF navigation and fine tuning. For our CBR-TF approach, we introduce a novel volumetric image feature which includes both a local primitive intensity profile along the SOIs and regional spatial semantics available from the co-planar images to the profile. For the regional spatial semantics, we adopt a convolutional neural network to obtain high-level image feature representations. For the intensity profile, we extend the dynamic time warping technique to address subtle alignment differences between similar profiles (SOIs). Finally, we propose a two-stage CBR scheme to enable the use of these two different feature representations in a complementary manner, thereby improving SOI retrieval performance. We demonstrate the capabilities of our CBR-TF approach with comparison with a conventional approach in visualization, where an intensity profile matching algorithm is used, and also with potential use-cases in medical volume visualization.</p>","PeriodicalId":50222,"journal":{"name":"Journal of Computer Science and Technology","volume":"38 1","pages":""},"PeriodicalIF":1.2000,"publicationDate":"2024-05-10","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"A Transfer Function Design for Medical Volume Data Using a Knowledge Database Based on Deep Image and Primitive Intensity Profile Features Retrieval\",\"authors\":\"Younhyun Jung, Jim Kong, Bin Sheng, Jinman Kim\",\"doi\":\"10.1007/s11390-024-3419-7\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Direct volume rendering (DVR) is a technique that emphasizes structures of interest (SOIs) within a volume visually, while simultaneously depicting adjacent regional information, e.g., the spatial location of a structure concerning its neighbors. In DVR, transfer function (TF) plays a key role by enabling accurate identification of SOIs interactively as well as ensuring appropriate visibility of them. TF generation typically involves non-intuitive trial-and-error optimization of rendering parameters, which is time-consuming and inefficient. Attempts at mitigating this manual process have led to approaches that make use of a knowledge database consisting of pre-designed TFs by domain experts. In these approaches, a user navigates the knowledge database to find the most suitable pre-designed TF for their input volume to visualize the SOIs. Although these approaches potentially reduce the workload to generate the TFs, they, however, require manual TF navigation of the knowledge database, as well as the likely fine tuning of the selected TF to suit the input. In this work, we propose a TF design approach, CBR-TF, where we introduce a new content-based retrieval (CBR) method to automatically navigate the knowledge database. Instead of pre-designed TFs, our knowledge database contains volumes with SOI labels. Given an input volume, our CBR-TF approach retrieves relevant volumes (with SOI labels) from the knowledge database; the retrieved labels are then used to generate and optimize TFs of the input. This approach largely reduces manual TF navigation and fine tuning. For our CBR-TF approach, we introduce a novel volumetric image feature which includes both a local primitive intensity profile along the SOIs and regional spatial semantics available from the co-planar images to the profile. For the regional spatial semantics, we adopt a convolutional neural network to obtain high-level image feature representations. For the intensity profile, we extend the dynamic time warping technique to address subtle alignment differences between similar profiles (SOIs). 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引用次数: 0
摘要
直接体积渲染(DVR)是一种在视觉上强调体积内感兴趣的结构(SOIs),同时描绘相邻区域信息的技术,例如,一个结构与其相邻结构的空间位置。在 DVR 中,传递函数(TF)起着关键作用,它能以交互方式准确识别 SOI,并确保其适当的可见性。TF 生成通常需要对渲染参数进行非直观的试错优化,既耗时又低效。为了减少这种手动过程,人们尝试使用由领域专家预先设计的 TF 组成的知识数据库。在这些方法中,用户通过浏览知识数据库来找到最适合其输入体积的预设计 TF,从而实现 SOI 可视化。虽然这些方法有可能减少生成 TF 的工作量,但它们需要对知识数据库进行手动 TF 导航,还可能需要对选定的 TF 进行微调以适应输入。在这项工作中,我们提出了一种 TF 设计方法--CBR-TF,其中我们引入了一种新的基于内容的检索(CBR)方法来自动导航知识数据库。我们的知识数据库不包含预先设计的 TF,而是包含带有 SOI 标签的卷。给定一个输入卷,我们的 CBR-TF 方法会从知识数据库中检索相关卷(带 SOI 标签);然后利用检索到的标签生成和优化输入的 TF。这种方法在很大程度上减少了人工 TF 导航和微调。在 CBR-TF 方法中,我们引入了一种新颖的容积图像特征,其中包括沿 SOI 的局部原始强度剖面和从共平面图像到剖面的区域空间语义。对于区域空间语义,我们采用卷积神经网络来获得高级图像特征表示。对于强度剖面,我们扩展了动态时间扭曲技术,以解决相似剖面(SOIs)之间微妙的配准差异。最后,我们提出了一种两阶段 CBR 方案,以互补的方式使用这两种不同的特征表示,从而提高 SOI 检索性能。我们将 CBR-TF 方法与可视化领域的传统方法(使用强度剖面匹配算法)以及医学体量可视化领域的潜在用例进行了比较,从而展示了 CBR-TF 方法的能力。
A Transfer Function Design for Medical Volume Data Using a Knowledge Database Based on Deep Image and Primitive Intensity Profile Features Retrieval
Direct volume rendering (DVR) is a technique that emphasizes structures of interest (SOIs) within a volume visually, while simultaneously depicting adjacent regional information, e.g., the spatial location of a structure concerning its neighbors. In DVR, transfer function (TF) plays a key role by enabling accurate identification of SOIs interactively as well as ensuring appropriate visibility of them. TF generation typically involves non-intuitive trial-and-error optimization of rendering parameters, which is time-consuming and inefficient. Attempts at mitigating this manual process have led to approaches that make use of a knowledge database consisting of pre-designed TFs by domain experts. In these approaches, a user navigates the knowledge database to find the most suitable pre-designed TF for their input volume to visualize the SOIs. Although these approaches potentially reduce the workload to generate the TFs, they, however, require manual TF navigation of the knowledge database, as well as the likely fine tuning of the selected TF to suit the input. In this work, we propose a TF design approach, CBR-TF, where we introduce a new content-based retrieval (CBR) method to automatically navigate the knowledge database. Instead of pre-designed TFs, our knowledge database contains volumes with SOI labels. Given an input volume, our CBR-TF approach retrieves relevant volumes (with SOI labels) from the knowledge database; the retrieved labels are then used to generate and optimize TFs of the input. This approach largely reduces manual TF navigation and fine tuning. For our CBR-TF approach, we introduce a novel volumetric image feature which includes both a local primitive intensity profile along the SOIs and regional spatial semantics available from the co-planar images to the profile. For the regional spatial semantics, we adopt a convolutional neural network to obtain high-level image feature representations. For the intensity profile, we extend the dynamic time warping technique to address subtle alignment differences between similar profiles (SOIs). Finally, we propose a two-stage CBR scheme to enable the use of these two different feature representations in a complementary manner, thereby improving SOI retrieval performance. We demonstrate the capabilities of our CBR-TF approach with comparison with a conventional approach in visualization, where an intensity profile matching algorithm is used, and also with potential use-cases in medical volume visualization.
期刊介绍:
Journal of Computer Science and Technology (JCST), the first English language journal in the computer field published in China, is an international forum for scientists and engineers involved in all aspects of computer science and technology to publish high quality and refereed papers. Papers reporting original research and innovative applications from all parts of the world are welcome. Papers for publication in the journal are selected through rigorous peer review, to ensure originality, timeliness, relevance, and readability. While the journal emphasizes the publication of previously unpublished materials, selected conference papers with exceptional merit that require wider exposure are, at the discretion of the editors, also published, provided they meet the journal''s peer review standards. The journal also seeks clearly written survey and review articles from experts in the field, to promote insightful understanding of the state-of-the-art and technology trends.
Topics covered by Journal of Computer Science and Technology include but are not limited to:
-Computer Architecture and Systems
-Artificial Intelligence and Pattern Recognition
-Computer Networks and Distributed Computing
-Computer Graphics and Multimedia
-Software Systems
-Data Management and Data Mining
-Theory and Algorithms
-Emerging Areas