Towards a concept of thrombosis in accelerated flow: Rheology, fluid dynamics, and biochemistry

Issue title: Special Issue for the Conference Proceedings Euromech 186. Part I. Nancy, France, 17–19 September 1984

Guest editors: M. Lucius and J.F. Stoltz

Article type: Research Article

Authors: Wurzinger, L.J.^a | Blasberg, P.^b | Schmid-Schönbein, H.^b

Affiliations: [a] Abteilung Anatomie, der RWTH, Schneebergweg 211, D-5100 Aachen, F.R.G. | [b] Abteilung Physiologie, der RWTH, Schneebergweg 211, D-5100 Aachen, F.R.G.

Note: [] Accepted by: Guest Editor J.F. Stoltz

Abstract: The predilection sites of arterial thrombosis are characterized by local increase in wall shear stress, flow separation with eddy formation and stagnation point flow. The defenders of high shear, as well as those of low shear theory of thrombogenesis, point to correlations of predilection sites and the respective flow abnormalities. Experimental evidence is provided, that high shear rates can damage both red cells and platelets, that lysed red cells constitute a potent platelet stimulant, due to their content of adenine nucleotides, and that platelets do not adhere to surfaces unless transported onto them by convective motion, the effectiveness of the platelet-wall interaction being enhanced by platelet activation. Based on these facts, a resolution of the contrast between high and low shear theory of thrombosis is attempted in a way, that the different flow regimens, with blood cells sequentially passing them, are each considered important and interdependent steps on the way to thrombosis.

Keywords: thrombogenesis, blood rheology, platelet-red cell interaction, platelet adhesion, platelet activation, fluid dynamics

DOI: 10.3233/BIR-1985-22507

Journal: Biorheology, vol. 22, no. 5, pp. 437-450, 1985