Abstract
Some human organs are composed of bifurcated structures. Two simple branching modes—monopodial and dipodial—have been proposed. With monopodial branching, child branches extend from the sidewall of the parent branch. With dipodial branching, the tip of the bronchus bifurcates. However, the branching modes of the human bronchial tree have not been elucidated precisely. A total of 48 samples between Carnegie stage (CS) 15 and CS23 belonging to the Kyoto Collection were used to acquire imaging data with phase-contrast X-ray computed tomography. Bronchial trees of all samples were three-dimensionally reconstructed from the image data. We analyzed the lobar bronchus, segmental bronchus, and subsegmental bronchus. After calculating each bronchus length, we categorized the branching mode of the analyzed bronchi based on whether the parent bronchus was divided after generation of the analyzed bronchi. All lobar bronchi were formed with monopodial branching. Twenty-five bifurcations were analyzed to categorize the branching mode of the segmental and subsegmental bronchi; 22 bifurcations were categorized as monopodial branching, two bifurcations were not categorized as any branching pattern, and the only lingular bronchus that bifurcated from the left superior lobar bronchus was categorized as dipodial branching. The left superior lobar bronchus did not shorten during the period from CS17 or CS18, when the child branch was generated, to CS23. All analyzed bronchi that could be categorized, except for one, were categorized as monopodial branching. The branching modes of the lobar bronchus and segmental bronchus were similar in the mouse lung and human lung; however, the modes of the subsegmental bronchi were different. Furthermore, remodeling, such as shrinkage of the bronchus, was not observed during the analysis period. Our three-dimensional reconstructions allowed precise calculation of the bronchus length, thereby improving the knowledge of branching morphogenesis in the human embryonic lung.
Highlights
Many organs, including the lungs and kidneys, have complicated structures resulting from a series of bifurcations
To categorize the branching mode of the lobar bronchus, we analyzed the samples during phases 1 and 3
By comparing the parent branch (PBr) length before and after Child branches (CBr) generation, our results demonstrated that lobar bronchi were formed with the monopodial branching mode
Summary
Many organs, including the lungs and kidneys, have complicated structures resulting from a series of bifurcations. An understanding of branching morphogenesis is essential to the diagnosis and treatment of congenital anomalies. Metzger et al [2] proposed the following three patterns for mouse bronchi: domain branching, planar bifurcation, and orthogonal bifurcation. Child branches (CBr) are generated at the sidewall of the parent branch (PBr) with monopodial branching, whereas the tip of the bronchus is bifurcated with dipodial branching. The former mode corresponds to domain branching, and the latter mode corresponds to planar and orthogonal bifurcation [2]
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