It is widely thought that intracranial saccular aneurysms rupture when wall stress exceeds wall strength. Yet, the rupture-potential of these lesions is still judged primarily by their maximum dimension, which of course does not explain why some small lesions rupture whereas many larger ones do not. The underlying hypothesis of this proposal is that it is the 3-D geometry, material properties and loading conditions--not the maximum dimension--that governs the rupture-potential of saccular aneurysms. Because every lesion is biomechanically unique, however, it is unreasonable to expect that statistics alone can delineate improved predictors of rupture-potential based on pathological examinations or clinical studies. Rather, there is a need to first identify specific characteristics that are the determinants of rupture, and thereby identify classes of lesions for statistical comparisons. Toward this end, we will be the first to: (1) measure the regional, multiaxial mechanical properties of human saccular aneurysms, (2) correlate these properties with the underlying 3-D collagen orientations and cross-linking, and (3) perform literally hundreds of numerical experiments that will identify those parameters (e.g., lesion size, 3-D shape, thickness, stiffness, anisotropy, heterogeneity, loading conditions, etc) that give rise to the highest multiaxial stresses (particularly in the fundus where rupture tends to occur), and by inference, the highest rupture-potential. Our results will thereby provide much needed guidance for future statistically-based retrospective and prospective studies wherein rupture can be correlated directly with clinically measurable lesion characteristics. Our research is an essential means, not an end, toward rational management of unruptured aneurysms.

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL054957-03
Application #
2727390
Study Section
Surgery and Bioengineering Study Section (SB)
Project Start
1997-04-01
Project End
2000-03-31
Budget Start
1998-04-01
Budget End
1999-03-31
Support Year
3
Fiscal Year
1998
Total Cost
Indirect Cost
Name
Texas Engineering Experiment Station
Department
Biomedical Engineering
Type
Schools of Engineering
DUNS #
847205572
City
College Station
State
TX
Country
United States
Zip Code
77845
Banatwala, M; Farley, C; Feinberg, D et al. (2005) Parameterization of the shape of intracranial saccular aneurysms using Legendre polynomials. Comput Methods Biomech Biomed Engin 8:93-101
Seshaiyer, Padmanabhan; Humphrey, Jay D (2003) A sub-domain inverse finite element characterization of hyperelastic membranes including soft tissues. J Biomech Eng 125:363-71
Rowe, Andrea J; Finlay, Helen M; Canham, Peter B (2003) Collagen biomechanics in cerebral arteries and bifurcations assessed by polarizing microscopy. J Vasc Res 40:406-15
Taber, L A; Humphrey, J D (2001) Stress-modulated growth, residual stress, and vascular heterogeneity. J Biomech Eng 123:528-35
Humphrey, J D (2001) Stress, strain, and mechanotransduction in cells. J Biomech Eng 123:638-41
Seshaiyer, P; Humphrey, J D (2001) On the potentially protective role of contact constraints on saccular aneurysms. J Biomech 34:607-12
Shah, A D; Humphrey, J D (1999) Finite strain elastodynamics of intracranial saccular aneurysms. J Biomech 32:593-9
Shah, A D; Naff, N; Humphrey, J D et al. (1999) Mechanical behavior of a vein pouch saccular aneurysm model. Neurol Res 21:569-73
Humphrey, J D (1999) An evaluation of pseudoelastic descriptors used in arterial mechanics. J Biomech Eng 121:259-62
Ryan, J M; Humphrey, J D (1999) Finite element based predictions of preferred material symmetries in saccular aneurysms. Ann Biomed Eng 27:641-7

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