and Relevance Intracranial aneurysms affect a substantial portion of the adult population. They rarely rupture, but intracranial hemorrhage due to a ruptured brain aneurysm has devastating effects with high mortality and disability rates. Since the risk of treatment may exceed the natural risk of rupture, there is an urgent need for a reliable method to identify fragile aneurysms at risk of rupture that require immediate treatment and avoid unnecessary treatment in others. Prior work has largely focused on looking for correlations between rupture and clinically attainable quantities such as geometry, hemodynamics and patient characteristics. However, to date, these efforts have been promising but have not reached their full potential. Our group and others believe this is because the flow dynamics play more than one role in wall degradation and further there are multiple modes of wall failure. Therefore, it is extremely challenging to identify correlations without further information about the wall itself. The proposed research is innovative in our opinion because it seeks to shift the way aneurysm pathology is studied by turning the focus to the clinically relevant vulnerable aneurysm wall and by directly assessing the possibly multiple mechanisms by which hemodynamics alters the wall and studying the mechanisms of structural failure. This approach is possible because we have spent the prior R21 period i) building a collaborative team of world leaders with diverse skills in aneurysm research, ii) acquiring all needed IRB and MTA documents that will enable us to obtain over 350 IA domes during this program, and iii) developing the numerous innovations in methodology that take advantage of access to an array of important experimental facilities. Understanding the factors that discriminate between robust aneurysm walls with well-organized collagen fibers and vulnerable or fragile aneurysm walls with diverse changes to the collagen architecture is essential for effective prediction of aneurysm vulnerability and design of treatments to slow or reverse this change. Specifically, the goals of this project are: 1) determine the characteristics of structurally sound aneurysm walls, 2) determine structural causes of aneurysm wall vulnerability, 3) determine the hemodynamic conditions that promote endothelial dysfunction and wall alteration, and 4) develop a framework for assessing risk of wall fragility. The contribution of the proposed work is significant because it will create a paradigm shift in how cerebral aneurysms are studied. The focus on rupture as the end point will be shifted to wall vulnerability using methods we developed during the R21 period. We will use this data, combined with patient characteristics, to develop a framework for assessing risk of wall vulnerability. These results will provide he basis for a larger multi-national trial using our framework for risk stratification. Clinical relevance of the proposed project: The results of this project will be immediately applicable to the clinical practice, in particular we will provide the community with a scale to grade the risk of an aneurysm of having fragile walls. Additionally, these results will guide future research aiming at developing new clinical imaging techniques and/or contrast agents by providing them with wall changes associated with vulnerable walls. Further by understanding the differences between robust and vulnerable walls, we will provide a target for pharmacological therapies directed at harnessing the natural ability of the wall the maintain a robust collagen structure. These advancements will all contribute to the improvement of patient care.

Public Health Relevance

Because the risk of treatment of intracranial aneurysms may exceed their natural risk of rupture (which has devastating consequences) there is an urgent need to distinguish between fragile aneurysms at risk of rupture that require immediate treatment from robust aneurysms that could be recommended for conservative observation and avoid unnecessary treatments. The objective of this project is to identify the relationship between abnormal flow conditions and changes to the wall that lead to structurally fragile walls in a large cohort of resected aneurysm domes and use this data, combined with patient characteristics, to develop a framework for assessing risk of wall vulnerability. The knowledge generated in this project is expected to positively impact the clinical decision making to improve patient evaluation and care, as well as future research aiming at imaging biomarkers of wall fragility and pharmacological therapies targeting wall weakening processes.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS097457-02
Application #
9301060
Study Section
Neuroscience and Ophthalmic Imaging Technologies Study Section (NOIT)
Program Officer
Koenig, James I
Project Start
2016-07-01
Project End
2021-04-30
Budget Start
2017-05-01
Budget End
2018-04-30
Support Year
2
Fiscal Year
2017
Total Cost
Indirect Cost
Name
University of Pittsburgh
Department
Engineering (All Types)
Type
Biomed Engr/Col Engr/Engr Sta
DUNS #
004514360
City
Pittsburgh
State
PA
Country
United States
Zip Code
15213
Cebral, Juan R; Mut, Fernando; Gade, Piyusha et al. (2018) Combining data from multiple sources to study mechanisms of aneurysm disease: Tools and techniques. Int J Numer Method Biomed Eng 34:e3133
Durka, Michael J; Wong, Isaac H; Kallmes, David F et al. (2018) A data-driven approach for addressing the lack of flow waveform data in studies of cerebral arterial flow in older adults. Physiol Meas 39:015006
Cebral, J; Ollikainen, E; Chung, B J et al. (2017) Flow Conditions in the Intracranial Aneurysm Lumen Are Associated with Inflammation and Degenerative Changes of the Aneurysm Wall. AJNR Am J Neuroradiol 38:119-126