Application of magnetic resonance imaging (MRI) technology in the characterization of microstructure and moisture content of young Moso bamboo

doi:10.13287/j.1001-9332.202301.040

Abstract

Abstract: Bamboo nodes play a key role in the hollow structure and the rapid growth of bamboo culm. Studying on the anatomical structure of bamboo is helpful to understand its growth mechanism. Taking the noninvasive, high-resolution and accurate technical advantages of magnetic resonance imaging (MRI), we conducted cross-sectional high-resolution MRI scanning on the tip of young Moso bamboo culm (removed shoot sheath) and extracted the gray value of the MRIs by using MATLAB software to explore the differences of water distribution in nodes, proximal nodes, and internodes. The results showed that numerous vascular bundles were repeatedly twisted and rotated horizontally at the nodal diaphragms and inner wall near the nodal diaphragms of the young bamboo, forming an intricate and highly connected network. The structure protected important tissues from mechanical stress by allocating axial loads, and enabled to laterally transport water and nutrients, which was an important basis for the rapid growth of Moso bamboo in relatively short term. The signal value (also known as brightness value) of MRIs indicated that water content of vascular bundles in young bamboo culm was much higher than that of surrounding parenchyma tissues. The mean value and standard deviation of water content between pixels of internodes were significantly higher than that of nodes, and the values of that in the proximal nodes were intermediate. The development of MRI would play a significant role in the studies of bamboo anatomy, physiology, and biochemistry.

Key words: young bamboo node, magnetic resonance imaging, vascular system, water.

HUANG Wei-wei, YANG Yu-ying, FU He-ling, DING Yu-long. Application of magnetic resonance imaging (MRI) technology in the characterization of microstructure and moisture content of young Moso bamboo[J]. Chinese Journal of Applied Ecology, 2023, 34(1): 83-91.

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