• Journal of Digital Convergence
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• v.10 no.2
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• pp.243-247
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• 2012

Beam hardening artifact happens in the CT image. when a PET/CT is conducted while there is a metallic dental implant. The artifact appears in the CT image can affect the PET image. When the patient with head and neck cancer has a metallic dental implant, Beam hardening artifact which was taken in th CT image can change the PET image and SUV value. Therefore, by Quantitative measure of the SUV according to the change in HU by the metallic dental implant, the appropriacy in the clinical application was assessed. The records of 47 patients with PET/CT August 2011. For the analysis, 2 region of interest were defined in area where CT and PET image. As a result of the experiment, if there in an implant, the HU and the SUV increased and there existed a statistically significant difference(p<0.01). Although this level of increase was not large compared with that in the patient who have no metallic dental implant, when a person has head and neck cancer, it is even more likely to be overestimated when diagnosing the cancer. When conducting PET/CT for the patient who have head and neck cancer, the physical biological parts should be considered in order not to make an error in decoding.

• Proceedings of the Korean Information Science Society Conference
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• 2003.10b
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• pp.646-648
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• 2003

일반적으로 복부 CT 영상에서 간암이나 다른 병변들을 갖고 있는 않은 정상 간은 고른 그레이값 분포 범위를 가지고 있다. 그 그레이값 범위는 대개 90 에서 92 사이의 값이다. 그러나. 복부 CT 영상에서 간암이나 여러 병변들을 가지고 있는 비정상간의 경우는 정상간의 경우와 같이 90 에서 92 사이의 일정 간격의 그레이값들만으로 구성되어 있지 않다. 비정상간의 경우는 병변들로 인하여 건강한 간의 실질 부분의 그레이값만을 나타내지는 못하기 때문이다. 이는 복부 CT 영상에서 간 부분을 세그멘테이션할 때 정상간 부분과 비정상간 부분의 세그멘테이션 방식이 다를 수 있음을 말해준다. 보통 기존에 있는 정상간의 세그멘테이션 기법은 위치 정보와 함께 일정 간격의 그레이값 분포 정보를 이용하여 수월하게 간을 세그멘테이션 했다. 그러나, 이 방식은 비정상간을 세그멘테이션하지 못하는 경우가 대부분이다. 본 연구는 간의 위치 정보, 거리 정보를 이용하고 각도선 조절 기법 등을 사용하여 비정상간을 세그멘테이션하였다. 그리하여, 본 연구는 세그멘테이션이 어려운 간암 보유 복부 CT 영상에 적용되어 효과적인 간의 세그멘테이션을 가능하게 하였다.

• Proceedings of the Korean Information Science Society Conference
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• 2005.11b
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• pp.859-861
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• 2005

X-ray를 이용한 CT(Computed Tomography : 이하 CT)영상은 사물에 대해 회전하면서 X-ray가 투과하여 감약 정도에 따라서 영상을 획득하지만 검사 목적과는 관계없이 발생되는 통계적인 오차로 인해 정확한 CT영상의 구성을 교란하거나 방해하여 영상의 질을 저하시키고 미세 부분의 관찰 능력을 감소시키는 장해 음영인 아티팩트(artifact)라는 노이즈가 발생한다. 이러한 노이즈를 제거하는 필터를 설계 할 때는 두 가지 고려해야 할 사항이 있는데 첫째는 영상내의 노이즈을 정확히 판단하여 효과적으로 제거해야 하며, 둘째로는 원래의 영상에 가깝도록 경계와 같은 세부 영역을 보존해야 한다는 점이다. 기존에는 mean 필터나 median 필터, 그리고 Gaussian 필터 등을 사용했지만 상세한 부분을 보존하기에는 실패하는 단점이 있다. 따라서 본문에서는 wavelet 변환을 하여 영상의 주파수 대역을 저주파 영역과 고주파 영역으로 분리하여 각각의 영역에서 노이즈를 제거할 수 있도록 적합한 필터를 설계하고 방법을 제안하여 그 필터를 CT 3차원 뇌혈관 영상에 적용하여 많은 노이즈를 제거하였고 낮은 Threshold값에서도 작은 혈관을 관찰 할 수 있었다.

• Journal of the Korean Society of Radiology
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• v.15 no.6
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• pp.877-881
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• 2021

Customer satisfaction is a very important factor in the Korean medical system. However, the field of medical imaging is very difficult for the general public to understand. Therefore, in this study, as a way to solve the communication problem between the medical staff and the patient, the PET/CT image was reconstructed using the Volume Rendering technique to increase patient satisfaction. VRT was performed on 360 cancer patients who had undergone PET/CT examination. As a result of a satisfaction survey on 100 patients, all 100 patients showed that the VRT image was superior to the existing image. PET/CT is not a device that observes detailed anatomical shapes, such as CT or MRI, but an image that shows a strong signal of cancer and can easily produce a VRT image. These VRT images can be expressed three-dimensionally so that the general public can easily understand them, so communication between medical staff and patients can be improved more efficiently, and it is expected that the patient's "right to know" will be satisfied.

• Journal of the Korea Computer Graphics Society
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• v.25 no.3
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• pp.123-131
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• 2019

In this study, we modified CT images of femoral head in consideration of anatomically meaningful structure, proposing the method to augment the training data of convolution Neural network for segmentation of femur mesh model. First, the femur mesh model is obtained from the CT image. Then divide the mesh model into meaningful parts by using cluster analysis on geometric characteristic of mesh surface. Finally, transform the segments by using an appropriate mesh deformation algorithm, then create new CT images by warping CT images accordingly. Deep learning models using the data enhancement methods of this study show better image division performance compared to data augmentation methods which have been commonly used, such as geometric conversion or color conversion.

• Investigative Magnetic Resonance Imaging
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• v.12 no.2
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• pp.89-99
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• 2008

Imaging assessment of prostate cancer is one of the most difficult sections of oncology imaging. Detecting, localizing and staging of the primary prostate cancer by preoperative imaging are still challenging for the radiologist. Magnetic resonance (MR) imaging provides excellent soft tissue contrast and is widely used for solid organ imaging, but results of preoperative imaging of the prostate gland with conventional MR imaging is unsatisfactory. Positron emission tomography and computed tomography (PET/CT) is the cornerstone in oncology imaging, but some limitations prohibit the assessment of primary prostate cancer with PET or PET/CT. Recent studies to overcome these insufficient accuracies of imaging evaluation of primary prostate cancers with advanced MR techniques and PET and PET/CT are reported. In this article, we review the imaging findings of prostate cancer on variable modalities, focused on MR imaging and PET/CT.

• Journal of the Korean Society of Radiology
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• v.12 no.6
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• pp.707-712
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• 2018

The number of CT examinations is increasing, and radiation exposure is also increasing. repeated tests can affect the lens and thyroid. In hospitals, there is a tendency to lack interest in major long-term radiation exposure compared to the interest in increasing image information and image quality with head CT. In this study, we analyzed the improvement of image quality by proposed method to the noisy CT images. The proposed denoising method total variance optimization only for the impulsive noise candidate pixels. Experimental results show that edge information is well preserved and impulse noise can be effectively removed. and worked very well for the images according to tube voltage and rotation time. applied to the clinical setting, it can be used as the lowest exposure condition without worrying about the image quality and it will be helpful for the CT application.

• The Korean Journal of Nuclear Medicine Technology
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• v.19 no.2
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• pp.93-101
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• 2015

Purpose In SPECT image, scatter count is the cause of quantitative count error and image quality degradation. Thus, a wide range of scatter correction(SC) methods have been studied and this study is to evaluate the accuracy of CT based SC(CTSC) used in SPECT/CT as the comparison with existing energy window based SC(EWSC). Materials and Methods SPECT/CT images were obtained after filling air in order to acquire a reference image without the influence of scatter count inside the Triple line insert phantom setting hot rod(74.0 MBq) in the middle and each SPECT/CT image was obtained each separately after filling water instead of air in order to derive the influence of scatter count under the same conditions. In both conditions, Astonish(iterative : 4 subset : 16) reconstruction method and CT attenuation correction were commonly applied and three types of SC methods such as non-scatter correction(NSC), EWSC, CTSC were used in images filled with image. For EWSC, 9 sub-energy windows were set additionally in addition to main(=peak) energy window(140 keV, 20%) and then, images were acquired at the same time and five types of EWSC including DPW(dual photo-peak window)10%, DEW(dual energy window)20%, TEW(triple energy window)10%, TEW5.0%, TEW2.5% were used. Under the condition without fluctuations in primary count, total count was measured by drawing volume of interest (VOI) in the images of the two conditions and then, the ratio of scatter count of total counts was calculated as percent scatter fraction(%SF) and the count error with image filled with water was evaluated with percent normalized mean-square error(%NMSE) based on the image filled with air. Results Based on the image filled with air, %SF of images filled with water to which each SC method was applied is NSC 37.44, DPW 27.41, DEW 21.84, TEW10% 19.60, TEW5% 17.02, TEW2.5% 14.68, CTSC 5.57 and the most scattering counts were removed in CTSC and %NMSE is NSC 35.80, DPW 14.28, DEW 7.81, TEW10% 5.94, TEW5% 4.21, TEW2.5% 2.96, CTSC 0.35 and the error in CTSC was found to be the lowest. Conclusion In SPECT/CT images, the application of each scatter correction method used in the experiment could improve the quantitative count error caused by the influence of scatter count. In particular, CTSC showed the lowest %NMSE(=0.35) compared to existing EWSC methods, enabling relatively accurate scatter correction.

• The Korean Journal of Nuclear Medicine Technology
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• v.20 no.2
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• pp.21-26
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• 2016

Purpose Because of many advantages, PET-CT Scanners generally use CT Data for attenuation correction. By using CT based attenuation correction, we can get anatomical information, reduce scan time and make more accurate correction of attenuation. However in case metal artifact occurred during CT scan, CT-based attenuation correction can induce artifacts and quantitative errors that can affect the PET images. Therefore this study infers true SUV of metal artifact region from attenuation corrected image count -to- non attenuation corrected image count ratio. Materials and Methods Micro phantom inserted $^{18}F-FDG$ 4mCi was used for phantom test and Biograph mCT S(40) is used for medical test equipment. We generated metal artifact in micro phantom by using metal. Then we acquired both metal artifact region of correction factor and non metal artifact region of correction factor by using attenuation correction image count -to- non attenuation correction image count ratio. In case of clinical image, we reconstructed both attenuation corrected images and non attenuation corrected images of 10 normal patient($66{\pm}15age$) who examined PET-CT scan in SNUH. After that, we standardize several organs of correction factor by using attenuation corrected image count -to- non attenuation corrected count ratio. Then we figured out metal artifact region of correction factor by using metal artifact region of attenuation corrected image count -to- non attenuation corrected count ratio And we compared standard organs correction factor with metal artifact region correction factor. Results according to phantom test results, metal artifact induce overestimation of correction factor so metal artifact region of correction factors are 12% bigger than the non metal artifact region of correction factors. in case of clinical test, correction factor of organs with high CT number(>1000) is $8{\pm}0.5%$, correction factor of organs with CT number similar to soft tissue is $6{\pm}2%$ and correction factor of organs with low CT number(-100>) is $3{\pm}1%$. Also metal artifact correction factors are 20% bigger than soft tissue correction factors which didn't happened metal artifact. Conclusion metal artifact lead to overestimation of attenuation coefficient. because of that, SUV of metal artifact region is overestimated. Thus for more accurate quantitative evaluation, using attenuation correction image count -to-non attenuation correction image count ratio is one of the methods to reduce metal artifact affect.

• Proceedings of the Korean Institute of Intelligent Systems Conference
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• 2007.04a
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• pp.63-74
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• 2007

간은 인체의 생명을 유지하고 성장할 수 있도록 하는 영양섭취와 매우 밀접한 관계를 가진 중요한 장기이다. 이러한 간의 중요성에도 불구하고 현재 우리나라의 간암 발병률이 세계에서 가장 높은 수치를 기록하고 있으며 이에 따라 간암을 조기 진단하고 예방할 수 있는 방법의 중요성이 확대되고 있다. 따라서 본 논문에서는 영상 의학적 검사 방법 중 하나인 CT 촬영으로 획득된 조영 증강 CT 영상에서 간 영역과 간 종양 영역을 정확히 검출하고 간 종양의 악성도를 판별할 수 있는 방법을 제안한다. 흉부로부터 5mm 간격으로 약 $40\;{\sim}\;50$장 정도로 촬영한 조영 증강 CT 영상에서 명암도와 명암의 분포도를 이용한 양자화 기법과 장기들의 위치 및 형태학적 특징정보, 그리고 흉부와 복부 양방향으로 인접한 CT 영상들의 정보를 분석하여 간 영역을 검출한다. 간 종양 영역은 과혈관성 종양의 특징을 분석하고 간 영역의 검출 방법에 적용하여 추출한다. 추출된 간 종양 영역은 퍼지 기반 SOM 알고리즘을 제안하여 간 종양의 악성도를 분석하는데 적용한다. 제안된 퍼지 기반 SOM 알고리즘은 SOM의 이웃 반경을 동적으로 조정하는데 퍼지 제어 기법을 적용하여 기존의 SOM 알고리즘보다 종양의 악성 정도를 분류하는 정확성을 개선하였다. 제시된 간 영역과 간 종양 검출 및 분석 방법의 결과와 전문의가 진단한 결과를 비교 분석한 결과, 기존의 간 영역 및 간 종양 영역 검출 방법보다 정확성이 향상된 것을 확인할 수 있었다.