| Literature DB >> 28297921 |
L R Buschle1,2, F T Kurz1,2, T Kampf3, W L Wagner4,5, J Duerr5,6, W Stiller4,5, P Konietzke4,5, F Wünnemann4, M A Mall5,6, M O Wielpütz4,5, H P Schlemmer1, C H Ziener1,2.
Abstract
We propose a surface model of spin dephasing in lung tissue that includes both susceptibility and diffusion effects to provide a closed-form solution of the Bloch-Torrey equation on the alveolar surface. The nonlocal susceptibility effects of the model are validated against numerical simulations of spin dephasing in a realistic lung tissue geometry acquired from synchotron-based μCT data sets of mouse lung tissue, and against simulations in the well-known Wigner-Seitz model geometry. The free induction decay is obtained in dependence on microscopic tissue parameters and agrees very well with in vivo lung measurements at 1.5 Tesla to allow a quantification of the local mean alveolar radius. Our results are therefore potentially relevant for the clinical diagnosis and therapy of pulmonary diseases.Entities:
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Year: 2017 PMID: 28297921 DOI: 10.1103/PhysRevE.95.022415
Source DB: PubMed Journal: Phys Rev E ISSN: 2470-0045 Impact factor: 2.529