• 제목/요약/키워드: Multimodal Brain Image

검색결과 13건 처리시간 0.024초

Brain MR Multimodal Medical Image Registration Based on Image Segmentation and Symmetric Self-similarity

  • Yang, Zhenzhen;Kuang, Nan;Yang, Yongpeng;Kang, Bin
    • KSII Transactions on Internet and Information Systems (TIIS)
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    • 제14권3호
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    • pp.1167-1187
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    • 2020
  • With the development of medical imaging technology, image registration has been widely used in the field of disease diagnosis. The registration between different modal images of brain magnetic resonance (MR) is particularly important for the diagnosis of brain diseases. However, previous registration methods don't take advantage of the prior knowledge of bilateral brain symmetry. Moreover, the difference in gray scale information of different modal images increases the difficulty of registration. In this paper, a multimodal medical image registration method based on image segmentation and symmetric self-similarity is proposed. This method uses modal independent self-similar information and modal consistency information to register images. More particularly, we propose two novel symmetric self-similarity constraint operators to constrain the segmented medical images and convert each modal medical image into a unified modal for multimodal image registration. The experimental results show that the proposed method can effectively reduce the error rate of brain MR multimodal medical image registration with rotation and translation transformations (average 0.43mm and 0.60mm) respectively, whose accuracy is better compared to state-of-the-art image registration methods.

Development of a Brain Phantom for Multimodal Image Registration in Radiotherapy Treatment Planning

  • H. S. Jin;T. S. Suh;R. H. Juh;J. Y. Song;C. B. Y. Choe;Lee, H .G.;C. Kwark
    • 한국의학물리학회:학술대회논문집
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    • 한국의학물리학회 2002년도 Proceedings
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    • pp.450-453
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    • 2002
  • In radiotherapy treatment planning, it is critical to deliver the radiation dose to tumor and protect surrounding normal tissue. Recent developments in functional imaging and radiotherapy treatment technology have been raising chances to control tumor saving normal tissues. A brain phantom which could be used for image registration technique of CT-MR and CT-SPECT images using surface matching was developed. The brain phantom was specially designed to obtain imaging dataset of CT, MR, and SPECT. The phantom had an external frame with 4 N-shaped pipes filled with acryl rods, Pb rods for CT, MR, and SPECT imaging, respectively. 8 acrylic pipes were inserted into the empty space of the brain phantom to be imaged for geometric evaluation of the matching. For an optimization algorithm of image registration, we used Downhill simplex algorithm suggested as a fast surface matching algorithm. Accuracy of image fusion was assessed by the comparison between the center points of the section of N-shaped bars in the external frame and the inserted pipes of the phantom and minimized cost functions of the optimization algorithm. Technique with partially transparent, mixed images using color on gray was used for visual assessment of the image registration process. The errors of image registration of CT-MR and CT-SPECT were within 2mm and 4mm, respectively. Since these errors were considered within a reasonable margin from the phantom study, the phantom is expected to be used for conventional image registration between multimodal image datasets..

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뇌팬톰을 이용한 삼차원 다중영상정합의 정확성 평가 (Accuracy Evaluation of Three-Dimensional Multimodal Image Registration Using a Brain Phantom)

  • 진호상;송주영;주라형;정수교;최보영;이형구;서태석
    • 대한의용생체공학회:의공학회지
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    • 제25권1호
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    • pp.33-41
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    • 2004
  • 다양한 의학 영상장비로부터 획득된 영상들간의 정합의 정확성은 방사선치료계획에서 매우 중요한 쟁점 중의 하나이다. 본 연구에서는 수제작된 뇌팬톰(brain phantom)을 이용한 영상정합의 정확성 평가방법을 연구하였다. 다중영상정합을 위해 CT-MR, CT-SPECT간의 Chamfer 정합(Chamfer matching)법을 적용하였다 영상정합의 정회성은 팬톰 내에 삽입된 표적(target)들의 중심정의 비교를 통하여 평가되었다. CT-MR, CT-SPECT간의 삼차원 제곱근평균제곱(root-mean-square) 이동편차는 각각 2.1$\pm$0.8 mm와 2.8$\pm$1.4 mm이었다. 회전편차는 세 직교좌표축에서 2$^{\circ}$이내였다. 이 오차들은 기존의 팬톰연구와 비교하여 합리적인 오차 허용범위 내에 들었다. 중첩한 CT-MR, CT-SPECT영상의 육안검증 또한 좋은 정합 결과를 보였다.

Accuracy of image registration for radiation treatment planning using a brain phantom

  • Jin, Ho-Sang;Suh, Tae-Suk;Song, Ju-Young;Juh, Ra-Hyeong;Kwark, Chul-Eun;Lee, Hyoung-Koo;Choe, Bo-Young
    • 대한자기공명의과학회:학술대회논문집
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    • 대한자기공명의과학회 2002년도 제7차 학술대회 초록집
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    • pp.106-106
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    • 2002
  • Purpose: The purposes of our study are (1) to develop a brain phantom which can be used for multimodal image registration, (2) to evaluate the accuracy of image registration with the home-made phantom. Method: A brain phantom which could be used for image registration technique of CT-MR and CT-SPECT images using chamfer matching was developed. The brain phantom was specially designed to obtain imaging dataset of CT, MR, and SPECT. The phantom had an external frame with 4 N-shaped pipes filled with acryl rods for CT, MR imaging and Pb rods for SPECT imaging. 8 acrylic pipes were inserted into the empty space of the brain phantom to be imaged for geometric evaluation of the matching. Accuracy of image fusion was assessed by the comparison between the center points of the section of N-shaped bars in the external frame and the inserted pipes of the phantom. Technique with partially transparent, mixed images using color on gray was used for visual assessment of the image registration process.

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Magnetic Resonance Imaging Meets Fiber Optics: a Brief Investigation of Multimodal Studies on Fiber Optics-Based Diagnostic / Therapeutic Techniques and Magnetic Resonance Imaging

  • Choi, Jong-ryul;Oh, Sung Suk
    • Investigative Magnetic Resonance Imaging
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    • 제25권4호
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    • pp.218-228
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    • 2021
  • Due to their high degree of freedom to transfer and acquire light, fiber optics can be used in the presence of strong magnetic fields. Hence, optical sensing and imaging based on fiber optics can be integrated with magnetic resonance imaging (MRI) diagnostic systems to acquire valuable information on biological tissues and organs based on a magnetic field. In this article, we explored the combination of MRI and optical sensing/imaging techniques by classifying them into the following topics: 1) functional near-infrared spectroscopy with functional MRI for brain studies and brain disease diagnoses, 2) integration of fiber-optic molecular imaging and optogenetic stimulation with MRI, and 3) optical therapeutic applications with an MRI guidance system. Through these investigations, we believe that a combination of MRI and optical sensing/imaging techniques can be employed as both research methods for multidisciplinary studies and clinical diagnostic/therapeutic devices.

Multimodal Data Fusion for Alzheimers Patients Using Dempster-Shafer Theory of Evidence

  • Majumder, Dwijesh Dutta;Bhattacharya, Nahua
    • 한국지능시스템학회:학술대회논문집
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    • 한국퍼지및지능시스템학회 1998년도 The Third Asian Fuzzy Systems Symposium
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    • pp.713-718
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    • 1998
  • The paper is part of an investigation by the authors on development of a knowledge based frame work for multimodal medical image in collaboration with the All India Institute of Medical Science, new Delhi. After presenting the key aspects of the Dempster-Shafer Evidence theory we have presented implementation of registration and fusion of T₁and T₂ weighted MR images and CT images of the brain of an Alzheimer's patient for minimising the uncertainty and increasing the reliability for dianostics and therapeutic planning.

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Tumor Segmentation in Multimodal Brain MRI Using Deep Learning Approaches

  • Al Shehri, Waleed;Jannah, Najlaa
    • International Journal of Computer Science & Network Security
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    • 제22권8호
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    • pp.343-351
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    • 2022
  • A brain tumor forms when some tissue becomes old or damaged but does not die when it must, preventing new tissue from being born. Manually finding such masses in the brain by analyzing MRI images is challenging and time-consuming for experts. In this study, our main objective is to detect the brain's tumorous part, allowing rapid diagnosis to treat the primary disease instantly. With image processing techniques and deep learning prediction algorithms, our research makes a system capable of finding a tumor in MRI images of a brain automatically and accurately. Our tumor segmentation adopts the U-Net deep learning segmentation on the standard MICCAI BRATS 2018 dataset, which has MRI images with different modalities. The proposed approach was evaluated and achieved Dice Coefficients of 0.9795, 0.9855, 0.9793, and 0.9950 across several test datasets. These results show that the proposed system achieves excellent segmentation of tumors in MRIs using deep learning techniques such as the U-Net algorithm.

표면거리 및 표면곡률 최적화 기반 다중모달리티 뇌영상 정합 (Multimodal Brain Image Registration based on Surface Distance and Surface Curvature Optimization)

  • 박지영;최유주;김민정;태우석;홍승봉;김명희
    • 정보처리학회논문지A
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    • 제11A권5호
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    • pp.391-400
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    • 2004
  • 서로 다른 종류의 영상을 정확하게 연관시켜 복합적인 정보를 제공하는 다중모달리티 의료 영상정합기법 중 표면정보 기반 영상정합에서는 일반적으로 동일 대상에 대한 서로 다른 모달리티에서 추출된 표면 윤곽정보 사이의 거리를 최소화함으로써 매칭이 이루어진다. 그런데 동일대상에 대해 취득되는 서로 다른 두 모달리티는 관심 영역 상의 표면 특성이 서로 유사하다. 그러므로 다중모달리티 영상정합에서 표면거리와 함께 표면의 형태 특성을 고려하여 두 영상을 매칭하는 방법이 정합결과의 정확도를 향상시킬 수 있다. 본 연구에서는 동일 대상의 서로 다른 두 모달리티 뇌영상 간의 표면거리와 표면곡률을 최적화하는 정합기법을 제안한다. 영상정합은 참조영상과 테스트영상에 대한 표면정보 생성과 이 두 개의 표면정보를 최적화하는 단계로 구성된다. 표면정보 생성 단계에서는 두 모달리티로부터 관심영역의 윤곽선을 추출하고, 이 중 참조 볼륨의 윤곽선에 대해서는 표면거리맵과 표면곡률맵을 구성하게 된다. 최적화 단계에서는 표면거리맵과 표면곡률맵을 참조하는 최적화 평가함수(cost function)에 의해 두 객체의 표면거리 차이와 표면곡률 차이를 최소화하는 정합 변환 값이 결정되고, 이것이 테스트영상의 변환에 적용되어 결과적으로 두 영상이 정합 되게 된다. 제안된 최적화 평가함수는 표면거리 정보만을 사용하는 평가함수에 비해 보다 견고한 정합 정확도를 보였으며 또한 본 연구는 정합결과의 볼륨 가시화를 통해 효율적인 영상 분석 수단을 제공하고자 하였다.

뇌기능 양전자방출단층촬영영상 분석 기법의 방법론적 고찰 (Methodological Review on Functional Neuroimaging Using Positron Emission Tomography)

  • 박해정
    • Nuclear Medicine and Molecular Imaging
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    • 제41권2호
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    • pp.71-77
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    • 2007
  • Advance of neuroimaging technique has greatly influenced recent brain research field. Among various neuroimaging modalities, positron emission tomography has played a key role in molecular neuroimaging though functional MRI has taken over its role in the cognitive neuroscience. As the analysis technique for PET data is more sophisticated, the complexity of the method is more increasing. Despite the wide usage of the neuroimaging techniques, the assumption and limitation of procedures have not often been dealt with for the clinician and researchers, which might be critical for reliability and interpretation of the results. In the current paper, steps of voxel-based statistical analysis of PET including preprocessing, intensity normalization, spatial normalization, and partial volume correction will be revisited in terms of the principles and limitations. Additionally, new image analysis techniques such as surface-based PET analysis, correlational analysis and multimodal imaging by combining PET and DTI, PET and TMS or EEG will also be discussed.

A Triple Residual Multiscale Fully Convolutional Network Model for Multimodal Infant Brain MRI Segmentation

  • Chen, Yunjie;Qin, Yuhang;Jin, Zilong;Fan, Zhiyong;Cai, Mao
    • KSII Transactions on Internet and Information Systems (TIIS)
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    • 제14권3호
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    • pp.962-975
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    • 2020
  • The accurate segmentation of infant brain MR image into white matter (WM), gray matter (GM), and cerebrospinal fluid (CSF) is very important for early studying of brain growing patterns and morphological changes in neurodevelopmental disorders. Because of inherent myelination and maturation process, the WM and GM of babies (between 6 and 9 months of age) exhibit similar intensity levels in both T1-weighted (T1w) and T2-weighted (T2w) MR images in the isointense phase, which makes brain tissue segmentation very difficult. We propose a deep network architecture based on U-Net, called Triple Residual Multiscale Fully Convolutional Network (TRMFCN), whose structure exists three gates of input and inserts two blocks: residual multiscale block and concatenate block. We solved some difficulties and completed the segmentation task with the model. Our model outperforms the U-Net and some cutting-edge deep networks based on U-Net in evaluation of WM, GM and CSF. The data set we used for training and testing comes from iSeg-2017 challenge (http://iseg2017.web.unc.edu).