References
Agrawal, Y., Talbot, L., andGong, K. (1978): ‘Laser anemometer study of flow development in circular pipes,’J. Fluid Mech.,85, pp. 497–518.
Back, L. H. (1994): ‘Estimated mean flow resistance increase during coronary artery catheterisation,’J. Biomech.,27, pp. 169–175
Caro, C. G., Pedley, T. J., Schroter, R. C., andSeed, W. A. (1978): ‘The mechanics of the circulation’ (Oxford University Press, New York)
Chang, L. J., andTarbell, J. M. (1985): ‘Numerical simulation of fully developed sinusoidal and pulsatile (physiological) flow in curved tubes,’J. Fluid Mech.,161, pp. 175–198
Dean, W. R. (1928): ‘The stream-line motion of fluid in a curved pipe,’Phil Mag. J. Sci.,V, p. 673
Dean, W. R. (1927): ‘Note on the motion of fluid in a curved pipe,’Phil. Mag. J. Sci.,IV, p. 208
DePaola, N., Gimbrone, Jr., M. A., Davies, P. F., andDewey, Jr., C. F. (1993): ‘Vascular endothelium responds to fluid shear stress gradients,’Arteriosclerosis Thrombosis,13, pp. 1254–1257
Dewey, Jr., C. F., Bussolari, S. R., Gimbrone, Jr., M. A., andDavies, P. F. (1981): ‘The dynamic response of vascular endothelial cells to fluid shear stress,’J. Biomech. Eng.,103, pp. 177–185.
Ebadian, M. A. (1990): ‘Rate of flow in a curved concentric pipe of circular cross-section,’J. Appl. Mech.,57, p. 1073
Fry, D. L. (1968): ‘Acute vascular endothelial changes associated with increased blood velocity gradients,’Circ. Res.,22, p. 165
Hamakiotes, C. C., andBerger, S. A. (1990): ‘Periodic flows through curved tubes: the effects of frequency parameter,’J. Fluid Mech.,210, pp. 353–370
Jayaraman, G., Padmanabhan, N., Singh, M. P., andAnil Kumar (1984): ‘Reversing flow in the aorta—a theoretical model,’J. Biomech.,17, p. 489
Kanai, H., Iizuka, M., andSakamotos, K. (1970): ‘One of the problems in the measurement of blood pressure by catheterinsertion: wave reflection at the tip of the catheter,’Med. Biol. Eng.,28, p. 483
Kapur, J. N., Tyagi, V. P., andSrivastava, R. S. (1965): ‘Streamline flow through a curved annulus,’Appl. Sci. Res., Sect. A,14, (4), p. 253
Karahalios, G. T. (1970): ‘Some possible effects of a catheter on the arterial well,’Med. Phys.,17, (5), p. 922
MacDonald, D. A. (1986): ‘Pulsatile flow in a catheterised artery,’J. Biomech.,19, (3), p. 239
Manjula, K. V., andDevanathan, R. (1988): ‘A theoretical study of catheter probe in stenosed arteries’in:Sahay, K. B., andSaxena, R. K. (Eds.) ‘Biomechanics’ p. 240
Padmanabhan, N., andJayaraman, G. (1984): ‘Flow in a curved tube with constriction—an application to the arterial system,’Med. Biol. Eng. Comput.,22, p. 216
Pedley, T. J. (1980): ‘The fluid mechanics of large blood vessels’ (Cambridge University Press)
Satcher, Jr., Bussolari, S. R., Gimbrone, Jr. M. A., andDewey, Jr., C. F. (1992): ‘The distribution of fluid forces on model arterial endothelium using computational fluid dymamics,’J. Biomech. Eng.,114, pp. 309–316
Soh, W. Y., andBerger, S. A. (1984): ‘Laminar entrance flow in a curved pipe,’J. Fluid. Mech.,148, pl. 109–135
Srivastava, R. S. (1970): ‘On the motion of fluid in a curved annulus,’ Brief Report, Zeitschrift für Angewandte Mathematik und Physik,21, p. 490
Rudolf Roos, R., andLykoudis, P. S. (1970): ‘The fluid mechanics of the ureter with an inserted catheter,’J. Fluid Mech.,46, p. 625
Topakoglu, H. C. (1967): ‘Steady laminar flow of an incompressible visous fluid in curved pipes,’J. Math. Mech.,16, (12)
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Jayaraman, G., Tewari, K. Flow in catheterised curved artery. Med. Biol. Eng. Comput. 33, 720–724 (1995). https://doi.org/10.1007/BF02510793
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DOI: https://doi.org/10.1007/BF02510793