dc.contributor.author |
Tutwiler V. |
|
dc.contributor.author |
Singh J. |
|
dc.contributor.author |
Litvinov R.I. |
|
dc.contributor.author |
Bassani J.L. |
|
dc.contributor.author |
Purohit P.K. |
|
dc.contributor.author |
Weisel J.W. |
|
dc.date.accessioned |
2021-02-25T20:56:29Z |
|
dc.date.available |
2021-02-25T20:56:29Z |
|
dc.date.issued |
2020 |
|
dc.identifier.uri |
https://dspace.kpfu.ru/xmlui/handle/net/162758 |
|
dc.description.abstract |
© 2020 The Authors. Fibrin is the three-dimensional mechanical scaffold of protective blood clots that stop bleeding and pathological thrombi that obstruct blood vessels. Fibrin must be mechanically tough to withstand rupture, after which life-threatening pieces (thrombotic emboli) are carried downstream by blood flow. Despite multiple studies on fibrin viscoelasticity, mechanisms of fibrin rupture remain unknown. Here, we examined mechanically and structurally the strain-driven rupture of human blood plasma-derived fibrin clots where clotting was triggered with tissue factor. Toughness, i.e., resistance to rupture, quantified by the critical energy release rate (a measure of the propensity for clot embolization) of physiologically relevant fibrin gels was determined to be 7.6 ± 0.45 J/m2. Finite element (FE) simulations using fibrin material models that account for forced protein unfolding independently supported this measured toughness and showed that breaking of fibers ahead the crack at a critical stretch is the mechanism of rupture of blood clots, including thrombotic embolization. |
|
dc.title |
Rupture of blood clots: Mechanics and pathophysiology |
|
dc.type |
Article |
|
dc.relation.ispartofseries-issue |
35 |
|
dc.relation.ispartofseries-volume |
6 |
|
dc.collection |
Публикации сотрудников КФУ |
|
dc.source.id |
SCOPUS-2020-6-35-SID85090872547 |
|