A fractal analysis of the radial distribution of bronchial capillaries around large airways

doi:10.1152/japplphysiol.00801.2004

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J Appl Physiol 98: 850-855, 2005. First published November 12, 2004; doi:10.1152/japplphysiol.00801.2004
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A fractal analysis of the radial distribution of bronchial capillaries around large airways

Joseph C. Anderson,¹ Albert L. Babb,¹ and Michael P. Hlastala²^,3

Departments of ¹Chemical Engineering, ²Medicine, and ³Physiology and Biophysics, University of Washington, Seattle, Washington

Submitted 27 July 2004 ; accepted in final form 10 November 2004

We analyzed published measurements of the bronchial circulationand airway wall (Anderson JC, Bernard SL, Luchtel DL, Babb AL,and Hlastala MP. Respir Physiol Neurobiol 132: 329–339,2002) and determined that the radial distribution of bronchialcapillary cross-sectional area was fractal. We limited our analysisto bronchial capillaries, diameter $≤$ 10 µm, that residedbetween the epithelial basement membrane and adventitia-alveolarboundary, the airway wall tissue. Thirteen different radialdistributions of capillary-to-tissue area were constructed simplyby changing the number of annuli (i.e., the annular size) usedto form each distribution. For the 13 distributions created,these annuli ranged in size from to of the size of the airwaywall area. Radial distributions were excluded from the fractalanalysis if the sectioning procedure resulted in an annuluswith a radial thickness less than the diameter of a capillary.To determine the fractal dimension for a given airway, the coefficientof variation (CV) for each distribution was calculated, andln(CV) was plotted against the logarithm of the relative piecearea. For airways with diameter >2.4 mm, this relationshipwas linear, which indicated the radial distribution of bronchialcapillary cross-sectional area was fractal with an average fractaldimension of 1.27. The radial distribution of bronchial capillarycross-sectional area was not fractal around airways with diameter<1.5 mm. We speculated on how the fractal nature of thiscirculation impacts the distribution of bronchial blood flowand the efficiency of mass transport during health and disease.A fractal analysis can be used as a tool to quantify and summarizeinvestigations of the bronchial circulation.

anatomy; morphometry; vasculature; microcirculation; linear

Address for reprint requests and other correspondence: M. P. Hlastala, Div. of Pulmonary and Critical Care Medicine, Box 356522, Univ. of Washington, Seattle, WA 98195-6522 (E-mail: hlastala{at}u.washington.edu)