• Journal of the Korean Society of Radiology
• /
• v.10 no.2
• /
• pp.73-79
• /
• 2016

The purpose of this analysis is to compare 2D T1 FEE and 3D T1 THRIVE for demonstration of the pancreas. A total of 85(45 men, 40 women; 58 years) PACS network datum were analysis clinically indicated pancreas MRI at 1.5 T. The SNRs and CNRs of 3D T1 THRIVE(SNR: $46.42{\pm}0.67$, CNR: $28.16{\pm}0.50$) showed significantly higher values than those from 2D T1 FEE(SNR: $53.84{\pm}1.20$, CNR: $35.48{\pm}0.70$), p<0.05, The image quality of the 3D T1 THRIVE($2.63 {\pm}0.14$) was significantly superior to that with the 2D T1 FEE($2.2{\pm}0.05$), but 3D T1 THRIVE revealed several artifacts resulting in poor quality. In conclusion, The 3D T1 THRIVE technique with a 1.5 T resulting in improved SNRs, CNRs and image quality was demonstrated.

• Journal of Digital Convergence
• /
• v.11 no.12
• /
• pp.599-606
• /
• 2013

The purpose of this study is to know a clinical usefulness for delineation of articular cartilage compared with 2D TSE-SPIR and 3D FFE-PROSET technique. From January 2013 to september 2013, a total of 30 normal volunteers(12 men and 18 women aged between 35 and 55 years; mean 49.48 years) were studied on a philips 3.0T MRI scanner. As a quantitative analysis, SNRs and CNRs were evaluated by using two methods for delineation of articular cartilage. As a qualitative analysis, image quality was evaluated by special radiological technologist of MRI for image delineation on a three grade. As a results, SNRs and CNRs for articular cartilage were significantly greater for the 3D FFE-PROSET(SNRs: 8.40, 114.02, 9.53, CNRs: 104.49, 139.49) technique compared to 2D TSE-SPIR(SNRs: 4.41, 71.63, 7.34, CNRs: 64.30, 58.41) technique, image quality also was higher for evaluation of 3D FFE-PROSET(2.40) technique(p=0.0021). In conclusion, this study showed that a 3D FFE-PROSET MRI has improved SNRs and CNRs for evaluating of the articular cartilage, these conclusions in the future will be provided useful information in diagnosis of articular cartilage.

• Proceedings of the Korean Society of Medical Physics Conference
• /
• 2003.09a
• /
• pp.79-79
• /
• 2003

심실의 내부는 유두근이나 trabecular와 같은 해부학적 구조물들로 인해 복잡한 형태를 띄고 있다. 그러한 복잡한 구조는 MR 영상을 이용한 심박출량 측정시 오차를 유발시킬 수 있으며, 만약 오차를 줄이기 위해 수작업을 하게 된다면 많은 수고와 시간이 필요하게 될 것이다. 본 연구에서는 threshold 기법을 이용하여 짧은 시간동안에 정확하게 복잡한 구조를 가진 심실의 심박출량을 측정하고자 하였다. 7 명의 환자에 대해 l.5T 급 MR 장치 (INTERA, Philips, Netherlands)를 이용하여 short-axis cardiac MR 영상을 획득하였다. 한 환자에 대해서 8개에서 10개의 슬라이스 영상을 8-10 mm의 두께로, 하나의 심장주기(cardiac cycle)동안 일정한 시간간격으로 25 개의 영상을 획득하였으며, 펄스시퀀스로는 ECG-gated segmented balanced fast field echo (TR/TE = 3ms/1.56ms)를 사용하였다. 획득된 영상은 PC(threshold 기법)와 workstation (기존의 수동 및 자동 segmentation 기법)로 DICOM 형태로 전송되었다. 측정은 IDL을 이용하여 자체 제작된 소프트웨어와 상용화된 소프트웨어 (MASS 5.0, MEDIS, Netherlands)를 이용하여 분석되었다. MR 영상에서 심내벽 부위를 추출하기 위하여 자체제작된 소프트웨어로는 threshold 기법을, 상용 소프트웨어로는 기존의 수동 및 자동 기법을 이용하였다. 심박출량은 최대수축기와 이완기 사이의 용적 차이로써 계산되었으며, 좌심실 및 우심실 모두에 대해 수행되었다. 또한, 해부학적 구조의 복잡도에 따른 측정방법의 정확도를 확인하기 위해 유두근 및 trabecular의 hypertrophy의 정도를 3 단계로 구분하고 측정된 값들을 통계적으로 분석하였다. Hypertrophy가 약한 그룹에서는 기존의 수동방식과 threshold 기법간의 의미있는 차이가 없었으며 (p=0.372), 기존의 수동 및 자동방식 간에도 큰 차이가 없었다 (p=0.298). 그러나, hypertrophy가 심한 그룹에서는 수동방식 및 자동방식 측정치 사이에 통계적으로 유의한 차이를 보임을 알 수 있었다 (p=0.044). 그러나, threshold 기법과 수동방식 사이에는 유의한 차이가 없었다 (p=0.l94). 분석시간은 threshold 기법이 기존의 수동방식에 비해서 두배정도 빠르다는 것을 알 수 있었다, Threshold 기법은 심박출량 측정에 있어서 정확하면서도 빠른 결과의 도출이 가능했으며, 특히 심내벽의 구조가 복잡한 경우에 그 효과가 증대됨을 알 수 있었다.

• Progress in Medical Physics
• /
• v.12 no.2
• /
• pp.113-124
• /
• 2001

For veterinary imaging diagnosis, we obtained MR images of the canine brain, spine, kidney and pelvis from 3T MRI system which was equipped with the world first 3T active shield magnet. Spin echo (SE) and fast Spin Echo (FSE) images were obtained from the canine brain, spine, kidney and pelvis of normal and sick dogs using a homemade birdcage and transverse electromagnetic (TEM) resonators operating in quadrature and tuned to 128 MHz. In addition, we employed a homemade saddle shaped RF coil. Typical common acquisition parameters were as follows: matrix=512$\times$512, field of view (FOV)=20cm, slice thickness=3 w, number of excitations (NEX)=1. For T1-weighted MR images, we used TR=500 ms, TE=10 or 17.4 ms. For T2-weighted MR images, we used TR=4000 ms, TE=108 ms. Signal to noise ratio (SNR) of 3T system was measured 2.7 times greater than that of prevalent 1.57 system. The high resolution images acquired in this study represent more than a 4-fold increase in in-plane resolution relative to conventional images obtained with a 20 cm field of view and a 5 mm slice thickness. MR images obtained from 3T system revealed numerous small venous structures throughout the image plane and provided reasonable delineation between gray and white matter The present results demonstrate that the MR images from 3T system could provide better diagnostic quality of resolution and sensitivity than those of 1.5T system. The elevated SNR observed in the 3T high field magnetic resonance imaging can be utilized to acquire images with a level of resolution approaching the microscopic structural level under in vivo conditions. These images represent a significant advance in our ability to examine small anatomical features with noninvasive imaging methods. Moreover, MRI technique could begin to apply for veterinary medicine in Korea.

• Investigative Magnetic Resonance Imaging
• /
• v.5 no.2
• /
• pp.138-148
• /
• 2001

Purpose : Within a clinically acceptable time frame, we obtained the high resolution MR images of the human brain, knee, foot and wrist from 3T whole-body MRI system which was equipped with the world first 37 active shield magnet. Materials and Methods : Spin echo (SE) and Fast Spin Echo (FSE) images were obtained from the human brain, knee, foot and wrist of normal subjects using a homemade birdcage and transverse electromagnetic (TEM) resonators operating in quadrature and tuned to 128 MHz. For acquisition of MR images of knee, foot and wrist, we employed a homemade saddle shaped RF coil. Topical common acquisition parameters were as follows: matrix=$512{\times}512$, field of view (FOV) =20 cm, slice thickness = 3 mm, number of excitations (NEX)=1. For T1-weighted MR images, we used TR = 500 ms, TE = 10 or 17.4 ms. For T2-weighted MR images, we used TR=4000 ms, TE = 108 ms. Results : Signal to noise ratio (SNR) of 3T system was measured 2.7 times greater than that of prevalent 1.5T system. MR images obtained from 3T system revealed numerous small venous structures throughout the image plane and provided reasonable delineation between gray and white matter. Conclusion The present results demonstrate that the MR images from 3T system could provide better diagnostic quali\ulcorner of resolution and sensitivity than those of 1.5T system. The elevated SNR observed in the 3T high field magnetic resonance imaging can be utilized to acquire images with a level of resolution approaching the microscopic structural level under in vivo conditions. These images represent a significant advance in our ability to examine small anatomical features with noninvasive imaging methods.

• Journal of the Institute of Electronics and Information Engineers
• /
• v.52 no.9
• /
• pp.117-124
• /
• 2015

In this paper, we introduce how to control TR, TE physical MR parameters for managing $H_1$ spin's SI(Signal Intensity) which is combined with gadolinium following administration MR agent in T1 effect for diagnostic usefulness. we used MRI phantom made with 0.5 mol Gadoteridol. This phantom was scanned by FSE sequence with different TR, TE parameters. In this study, to make T1 effect, TR was 200, 250, 300, 350, 400, 450, 500, 550, 600 msec. In addition to, TE was 6.2, 12.4, 18.6, 21.6 msec. The results were as follows ; Each RSP(Reaction Starting Point) was 100, 50, 40, 30 mmol in TE 6.2, 12.4, 18.6, 21.6 msec being irrelevant to TR. In MPSI(Max Peak Signal Intensity), 4 mmol was showed in TR 200 msec while peak signal was decreased to low concentration mol in TR 250-600 msec. In terms of RA(Reaction Area), the highest SI was TE 6.2 msec in TR 200-600msec. According to the study, we are able to recognize it is possible to control enhance rates by managing TR and TE of MR parameters; moreover, we expect that enhanced T1 image in MR clinical field can be performed in a practical way with this quantitative data.