论文信息 - Mechanics of Distension of Dog Veins and Other Very Thin‐Walled Tubular Structures

Mechanics of Distension of Dog Veins and Other Very Thin‐Walled Tubular Structures

We present first phenomenological characterizations of the pressure-volume relationships (a) in veins excised from dogs under anesthesia and (b) in thinwalled latex tubes. We measured their cross-sectional areas and perimeters from cinefluorographic enlargements during distension. From flattened to circular cross sections, the perimeter of latex tubes remained constant while the area increased exclusively by bending of the walls. Compliance was large in this regime. After circular cross sections were reached, further increases in area were associated with increments in perimeter and there was stretching of the wall. Compliance declined sharply. Veins did not show a distinct two-regime behavior but a combination of bending and stretching which extended the region of large compliance to values of transmural pressure of physiological interest. Using classical theory of elasticity, we propose mathematical relationships describing the proportionality between the pressure and the curvature of the wall during the regime where bending is the primary controlling mechanism. We mechanized these relationships on an analog computer and correlated the solutions with the physical experiments. We conclude that no modulus of elasticity, alone, can relate the pressure and the volume when bending is predominant. In this regime the significant quantity is the modulus of flexural rigidity.

[1] H. W. Ryder,et al. THE INFLUENCE OF THE COLLAPSIBILITY OF VEINS ON VENOUS PRESSURE, INCLUDING A NEW PROCEDURE FOR MEASURING TISSUE PRESSURE. , 1944, The Journal of clinical investigation.

[2] A. G. Greenhill. The Elastic Curve, under uniform normal pressure , 1899 .

[3] S. BRODETSKY,et al. Theory of Plates and Shells , 1941, Nature.

[4] S. Magder,et al. Venous Return , 1957, British journal of anaesthesia.

[5] A Noordergraaf,et al. A mathematical model for the pressure-flow relationship in a segment of vein. , 1969, IEEE transactions on bio-medical engineering.

[6] S. Timoshenko,et al. THEORY OF PLATES AND SHELLS , 1959 .

[7] R. Courant,et al. Introduction to Calculus and Analysis , 1991 .

[8] Edward Noah Kresch. DESIGN OF A NONLINEAR ELECTRICAL MODEL FOR VEINS , 1968 .

[9] A I Katz,et al. An integrated approach to the study of the venous system with steps toward a detailed model of the dynamics of venous return to the right heart. , 1969, IEEE transactions on bio-medical engineering.

[10] R. Riley,et al. HEMODYNAMICS OF COLLAPSIBLE VESSELS WITH TONE: THE VASCULAR WATERFALL. , 1963, Journal of applied physiology.

[11] D. L. Fry,et al. Pulmonary mechanics. A unified analysis of the relationship between pressure, volume and gasflow in the lungs of normal and diseased human subjects. , 1960, The American journal of medicine.

[12] G. M.,et al. A Treatise on the Mathematical Theory of Elasticity , 1906, Nature.