Group creates model of arterial thrombus formation

Under normal circumstances, thrombocytes flow freely in the bloodstream, but if the vascular wall becomes damaged, they start to adhere to one another and to the vascular wall.

The blood also contains proteins required for thrombus formation. Even if there are no thrombocytes, reactions with these proteins are able to help form a clot to block a damaged vessel, and these reactions also occur in the form of autowaves.

Normally, thrombi prevent blood loss in the human body when a blood vessel has become damaged. Sometimes, however, thrombus formation occurs not as a result of an injury with damage to a blood vessel, but as a result of a reaction to a pathological process.

This type of thrombus formation can block a vessel completely and cut off the blood supply to tissues and organs. This, in turn, can lead to myocardial infarction, stroke, or gangrene of the extremities.

The researchers say their new model correctly describes arterial thrombus formation. These particular thrombi consist mainly of thrombocytes, and blood proteins play a relatively small role in the process.

“We have always had difficulty working with arterial blood clots in particular, in terms of developing and implementing computer models, because the subject involves a very difficult combination of mechanics (cell attachments), hydrodynamics with variable geometry, and biochemistry,” Dr Panteleev said.

“In our paper in PLOS ONE, we tried to use the most primitive description of a thrombus as a continuous medium, rather than discrete particles. This approximation is rough in many respects, and it limits the scope of the research, but it is able to give us some common patterns.”

“On the one hand, we plan to continue to apply it to specific tasks, as far as is possible, and on the other hand, we are developing more sophisticated and advanced models with 3-dimensional blood cells, the full mechanics of their interaction, and the proper biochemistry.”