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A small‐scale MRI scanner and complementary imaging method to visualize and quantify xylem embolism formation
Author(s) -
Meixner Marco,
Tomasella Martina,
Foerst Petra,
Windt Carel W.
Publication year - 2020
Publication title -
new phytologist
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 3.742
H-Index - 244
eISSN - 1469-8137
pISSN - 0028-646X
DOI - 10.1111/nph.16442
Subject(s) - xylem , scanner , visualization , biological system , computer science , magnetic resonance imaging , nuclear magnetic resonance , computer vision , artificial intelligence , biomedical engineering , materials science , physics , botany , radiology , biology , medicine
Summary Magnetic resonance imaging (MRI) is a useful tool to image xylem embolism formation in plants. MRI scanners configured to accept intact plants are rare and expensive. Here, we investigate if affordable small‐scale, custom‐built low‐field MRI scanners would suffice for the purpose. A small‐scale, C‐shaped permanent magnet was paired with open, plane parallel imaging gradients. The setup was small enough to fit between leaves or branches and offered open access for plant stems of arbitrary length. To counter the two main drawbacks of the system, low signal to noise and reduced magnetic field homogeneity, a multi‐spin echo (MSE) pulse sequence was implemented, allowing efficient signal acquisition and quantitative imaging of water content and T 2 signal relaxation. The system was tested visualizing embolism formation in Fagus sylvatica during bench dehydration. High‐quality images of water content and T 2 were readily obtained, which could be utilized to detect the cavitation of vessels smaller than could be spatially resolved. A multiplication of both map types yielded images in which filled xylem appeared with even greater contrast. T 2 imaging with small‐scale MRI devices allows straightforward visualization of the spatial and temporal dynamics of embolism formation and the derivation of vulnerability curves.