Abstract

The broad objective proposed here is to develop and test a magnetic resonance (MR) method that allows functional evaluation of the lung acinar structures by measuring gas exchange. To enhance the signal, the technique uses laser-polarized (129)Xe. Laser polarization increases the signal over thermal (129)Xe by a factor of 10(4)- 10(5). (129)Xe is chosen because it is more than ten times more soluble in tissue than the remaining choice, (3)He, and because the spectral peaks from the gas and dissolved in tissue phases are separated by -200/ppm. This makes the observation of both phases easily observable. The investigators propose to measure the gas exchange rate in acinar structures by observing the relaxation recovery rate of the spectral peaks. The investigators propose to saturate the signal in the tissue (dissolved) phase and observe the signal in this phase due to exchange from the gas spaces. During the 1st year, MR methods will be optimized in phantoms and then rats, where a ventilator will be used to control the lung volume to determine if the exchange is proportional to the lung surface area, which is related to lung volume. Trial experiments on humans will be performed in the 2nd year. The surface of the alveolar septa is the site of gas exchange; its quantification in terms of the local surface to volume ratio is an important determinant of the efficiency of the lung. Derangements at this level include loss of area in destructive diseases such as emphysema, as well as thickening of the blood/gas barrier in interstitial diseases such as pulmonary fibrosis and edema. A major gap in clinical medicine is the failure of all current techniques to evaluate this important parameter noninvasively, or even in vivo. Gas exchange imaging represents a radically new potential for noninvasive evaluation of regional differences in pulmonary function. Early detection of the loss of alveolar surface area is a serious public health imperative, since chronic obstructive pulmonary disease is now the Th leading cause of death in the US.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Center for Research Resources (NCRR)
Type
Exploratory/Developmental Grants (R21)
Project #
1R21RR014297-01A1
Application #
6095985
Study Section
Special Emphasis Panel (ZRR1-BT-1 (01))
Program Officer
Marron, Michael T
Project Start
2000-04-15
Project End
2002-03-31
Budget Start
2000-04-15
Budget End
2001-03-31
Support Year
1
Fiscal Year
2000
Total Cost
$122,799
Indirect Cost

  Institution

Name
Brigham and Women's Hospital
Department
Type
DUNS #
071723621
City
Boston
State
MA
Country
United States
Zip Code
02115

  Publications

Hersman, F William; Ruset, Iulian C; Ketel, Stephen et al. (2008) Large production system for hyperpolarized 129Xe for human lung imaging studies. Acad Radiol 15:683-92
Patz, Samuel; Muradian, Iga; Hrovat, Mirko I et al. (2008) Human pulmonary imaging and spectroscopy with hyperpolarized 129Xe at 0.2T. Acad Radiol 15:713-27
Patz, Samuel; Hersman, F William; Muradian, Iga et al. (2007) Hyperpolarized (129)Xe MRI: a viable functional lung imaging modality? Eur J Radiol 64:335-44
Ruset, I C; Ketel, S; Hersman, F W (2006) Optical pumping system design for large production of hyperpolarized. Phys Rev Lett 96:053002
Mair, R W; Hrovat, M I; Patz, S et al. (2005) 3He lung imaging in an open access, very-low-field human magnetic resonance imaging system. Magn Reson Med 53:745-9
Mair, R W; Sen, P N; Hurlimann, M D et al. (2002) The narrow pulse approximation and long length scale determination in xenon gas diffusion NMR studies of model porous media. J Magn Reson 156:202-12
Butler, J P; Mair, R W; Hoffmann, D et al. (2002) Measuring surface-area-to-volume ratios in soft porous materials using laser-polarized xenon interphase exchange nuclear magnetic resonance. J Phys Condens Matter 14:L297-304
Mair, R W; Hurlimann, M D; Sen, P N et al. (2001) Tortuosity measurement and the effects of finite pulse widths on xenon gas diffusion NMR studies of porous media. Magn Reson Imaging 19:345-51