Chin. Phys. Lett.  2008, Vol. 25 Issue (1): 325-328    DOI:
Original Articles |
Interleaving Gradient Magnetic Field Method for Diffusion Weighted Spectroscopy
GAO Song1,2;ZU Zhong-Liang2;BAO Shang-Lian2
1Department of Medical Physics, Health Science Center, Peking University, Beijing 1000832Beijing City Key Lab of Medical Physics and Engineering, School of Physics, Peking University, Beijing 100871
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GAO Song, ZU Zhong-Liang, BAO Shang-Lian 2008 Chin. Phys. Lett. 25 325-328
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Abstract Diffusion-weighted magnetic resonance spectroscopy (DWS) has considerable potential in clinical and research applications. However, it is seldom implemented in conventional magnetic resonance imaging (MRI) scanners due to the strict hardware requirements. We propose an interleaving gradient magnetic field (IGMF) method based on point resolved spectroscopy (PRESS). Four interlaced powerful diffusion sensitive gradient magnetic fields are positioned around the two π refocusing rf pulses in the PRESS sequence. This method utilizes the interval time in the PRESS pulse sequence, doubles the duration time of the diffusion sensitive gradient magnetic field and decreases the detrimental effect of the induced eddy current. The results of theoretical analysis and experimental observation demonstrate that the IGMF method is suitable for conventional MRI scanners
Keywords: 87.59.Pw      32.30.Dx     
Received: 10 May 2007      Published: 27 December 2007
PACS:  87.59.Pw  
  32.30.Dx (Magnetic resonance spectra)  
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https://cpl.iphy.ac.cn/       OR      https://cpl.iphy.ac.cn/Y2008/V25/I1/0325
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GAO Song
ZU Zhong-Liang
BAO Shang-Lian
[1] Bykowski J L, Latour L L and Warach S 2004 Stroke 35 1100
[2] Gao S, Wang X Y and Bao S L 2006 Progress in NatureScience 16 706
[3] Inglis B A, Bossart E L , Buckley D L, Wirth E D and Mareci TH 2001 Magne. Reson. Med. 45 580
[4] Michael N, Erfurth A, Ohrmann P, Arolt V,Heindel W and Pfleiderer B 2003 Neuropsychopharmacology 28 720
[5] Nicolay K, Braun K P, de Graaf R A,Dijkhuizen R M and Kruiskamp M J 2001 NMR Biomed. 14 94
[6] Pfeuffer J, Fl\"ogel U and Leibfritz D 1998 NMR Biomed. 11 11
[7] Pfeuffer J, Tkac I and Gruetter R 2000 J.Cereb. Blood Flow Metab. 20 736
[8] David N G, Raymond F S and Morris H B 2003 NMR Biomed. 16 468
[9]Yaniv A and Yoram C 1999 NMR Biomed. 12 335
[10] Valette J, Guillermier M, Besret L, Boumezbeur F, Hantraye Pand Lebon V 2005 NMR Biomed. 18 527
[11] Matt A B,Kevin F K and Zhou X H 2004 Handbook of MRIPulse Sequence (Boston: Elsevier) p844
[12] Donald W M, Elizabeth A M and Martin R P 2003 MRI From Picture to Proton (Cambridge: Cambridge University Press)p305
[13] Zu DL 2004 Magnetic Resonance Imaging(Beijing: Higher Education Press) p251
[14] De Graaf R A, Braun K P and Nicolay K 1999 Magn.Reson. Med. 1999 1827
[15] Haacke E M, Robert W B, Ramesh V and Michael R TMagnetic Resonance Imaging: Physical Principles and Sequence Designp325
[16] McKnight T R, Noworolski S M, Vigneron D B and Nelson S J2001 J. Magn. Reson. Imag. 13 167
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