Literature DB >> 17534926

Short data-acquisition times improve projection images of lung tissue.

Dean O Kuethe1, Natalie L Adolphi, Eiichi Fukushima.   

Abstract

MR images of laboratory rat lungs that resolve the thin membranes that separate lung lobes are presented. It appears that the capabilities of in vivo small-animal pulmonary MRI may rival those of in vivo small-animal X-ray CT. Free induction decay (FID)-projection imaging was employed with particular attention to the choice of acquisition time. For a given nominal resolution, one obtains optimal point discrimination when the acquisition time T(acq) normalized by the signal decay time constant T(2)(*) is approximately 0.8-0.9, although a better signal-to-noise ratio (SNR) is obtained when this quotient is 1.6. Currently available equipment should be able to even exceed the results presented herein.

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Year:  2007        PMID: 17534926     DOI: 10.1002/mrm.21230

Source DB:  PubMed          Journal:  Magn Reson Med        ISSN: 0740-3194            Impact factor:   4.668


  23 in total

1.  Ultrashort echo time MRI of pulmonary water content: assessment in a sponge phantom at 1.5 and 3.0 Tesla.

Authors:  Francesco Molinari; Ananth J Madhuranthakam; Robert Lenkinski; Alexander A Bankier
Journal:  Diagn Interv Radiol       Date:  2014 Jan-Feb       Impact factor: 2.630

2.  Imaging mouse lung allograft rejection with (1)H MRI.

Authors:  Jinbang Guo; Howard J Huang; Xingan Wang; Wei Wang; Henry Ellison; Robert P Thomen; Andrew E Gelman; Jason C Woods
Journal:  Magn Reson Med       Date:  2014-06-20       Impact factor: 4.668

3.  Ultra-short echo time (UTE) MR imaging of the lung: comparison between normal and emphysematous lungs in mutant mice.

Authors:  Masaya Takahashi; Osamu Togao; Makoto Obara; Marc van Cauteren; Yoshiharu Ohno; Shigehiro Doi; Makoto Kuro-o; Craig Malloy; Connie C Hsia; Ivan Dimitrov
Journal:  J Magn Reson Imaging       Date:  2010-08       Impact factor: 4.813

4.  Regional ventilation changes in severe asthma after bronchial thermoplasty with (3)He MR imaging and CT.

Authors:  Robert P Thomen; Ajay Sheshadri; James D Quirk; Jim Kozlowski; Henry D Ellison; Rhonda D Szczesniak; Mario Castro; Jason C Woods
Journal:  Radiology       Date:  2014-08-19       Impact factor: 11.105

5.  Longitudinal free-breathing MRI measurement of murine lung physiology in a progressive model of lung fibrosis.

Authors:  Jinbang Guo; William D Hardie; Zackary I Cleveland; Cynthia Davidson; Xuefeng Xu; Satish K Madala; Jason C Woods
Journal:  J Appl Physiol (1985)       Date:  2019-02-07

6.  Image-guided drug delivery in lung cancer.

Authors:  Timothy S Wiedmann; Tanmoy Sadhukha; Bruce E Hammer; Jayanth Panyam
Journal:  Drug Deliv Transl Res       Date:  2012-02       Impact factor: 4.617

7.  Phase imaging in brain using SWIFT.

Authors:  Lauri Juhani Lehto; Michael Garwood; Olli Gröhn; Curtis Andrew Corum
Journal:  J Magn Reson       Date:  2015-01-03       Impact factor: 2.229

8.  Simultaneous MRI of lung structure and perfusion in a single breathhold.

Authors:  Laura C Bell; Kevin M Johnson; Sean B Fain; Andrew Wentland; Randi Drees; Rebecca A Johnson; Grzegorz Bauman; Christopher J Francois; Scott K Nagle
Journal:  J Magn Reson Imaging       Date:  2013-12-20       Impact factor: 4.813

9.  Short echo-time 3D radial gradient-echo MRI using concurrent dephasing and excitation.

Authors:  Jang-Yeon Park; Steen Moeller; Ute Goerke; Edward Auerbach; Ryan Chamberlain; Jutta Ellermann; Michael Garwood
Journal:  Magn Reson Med       Date:  2011-06-23       Impact factor: 4.668

10.  Assessment of regional lung function with multivolume (1)H MR imaging in health and obstructive lung disease: comparison with (3)He MR imaging.

Authors:  Francesca Pennati; James D Quirk; Dmitriy A Yablonskiy; Mario Castro; Andrea Aliverti; Jason C Woods
Journal:  Radiology       Date:  2014-06-15       Impact factor: 11.105
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