Abstract
Fractal geometry (FG) is a branch of mathematics that instructively characterizes structural complexity. Branched structures are ubiquitous in both the physical and the biological realms. Fractility has therefore been termed nature's design. The fractal properties of the bronchial (airway) system, the pulmonary artery and the pulmonary vein of the human lung generates large respiratory surface area that is crammed in the lung. Also, it permits the inhaled air to intimately approximate the pulmonary capillary blood across a very thin blood–gas barrier through which gas exchange to occur by diffusion. Here, the bronchial (airway) and vascular systems were simultaneously cast with latex rubber. After corrosion, the bronchial and vascular system casts were physically separated and cleared to expose the branches. The morphogenetic (Weibel's) ordering method was used to categorize the branches on which the diameters and the lengths, as well as the angles of bifurcation, were measured. The fractal dimensions (DF) were determined by plotting the total branch measurements against the mean branch diameters on double logarithmic coordinates (axes). The diameter-determined DF values were 2.714 for the bronchial system, 2.882 for the pulmonary artery and 2.334 for the pulmonary vein while the respective values from lengths were 3.098, 3.916 and 4.041. The diameters yielded DF values that were consistent with the properties of fractal structures (i.e. self-similarity and space-filling). The data obtained here compellingly suggest that the design of the bronchial system, the pulmonary artery and the pulmonary vein of the human lung functionally comply with the Hess–Murray law or ‘the principle of minimum work’.
Highlights
Fractals are everywhere [1]Branched or dendritic structures abound in nature [1,2,3,4,5,6,7,8,9]
Fractal geometry (FG) is a branch of mathematics that characterizes the structure of complex structures [2,5,22,23,24]
The casts of the bronchial system, the pulmonary artery and the pulmonary vein which were prepared here displayed the normal morphologies of the human lung [63,64,75,95,106,119,124] which corresponded with those reported by other investigators [42,43,95,124,126]
Summary
Branched or dendritic structures abound in nature [1,2,3,4,5,6,7,8,9]. Fractal geometry (FG) is a branch of mathematics that characterizes the structure of complex structures [2,5,22,23,24]. Utilizing FG based algorithms, Kitaoka & Suki [25] and Kitaoka et al [26] prepared three-dimensional (3D) computational models that resembled the structure of the human lung. Branched structures have aroused human curiosity for a long time. Later corroborated by (among others) Richter [27], Leonardo da Vinci (1452–1519) determined that within each generation, the cross-sectional area of a tree trunk is equal to the sum of the cross-sectional areas of the branches. The advancement of FG from applied mathematics to life sciences [28,29]
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