Tracking geometric and hemodynamic alterations of an arteriovenous fistula through patient-specific modelling

•Arteriovenous Fistulas have highly complex hemodynamics in the anastomotic region, which is highly prone to vascular disease.•Tracked 3D ultrasound scanning allows for safe and inexpensive geometry acquisition for realistic CFD modelling.•An all-in-one method was devised to scan patients and proces...

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Bibliographic Details
Published in:Computer methods and programs in biomedicine 2020-04, Vol.186, p.105203-105203, Article 105203
Main Authors: Carroll, John E., Colley, Eamonn S., Thomas, Shannon D., Varcoe, Ramon L., Simmons, Anne, Barber, Tracie J.
Format: Article
Language:English
Subjects:
Aged
Aged, 80 and over
Algorithms
Arteriovenous fistula
Arteriovenous Fistula - physiopathology
Dialysis
Hemodynamics
Humans
Male
Patient-Specific Modeling
Regional Blood Flow
Surveillance
Ultrasound
Vascular access
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Summary:•Arteriovenous Fistulas have highly complex hemodynamics in the anastomotic region, which is highly prone to vascular disease.•Tracked 3D ultrasound scanning allows for safe and inexpensive geometry acquisition for realistic CFD modelling.•An all-in-one method was devised to scan patients and process these scans into flow models through a custom data pipeline.•Patient tracking with realistic flow modelling can be used to identify the presence of disease and the affected flow field.•Follow-up scanning after surgical restoration with stenting allows for comparison across models to determine the outcome of the procedure and its degree of success. Background and objective: The use of patient-specific CFD modelling for arteriovenous fistulae (AVF) has shown great clinical potential for improving surveillance, yet the use of imaging modes such as MRI and CT for the 3D geometry acquisition presents high costs and exposure risks, preventing regular use. We have developed an ultrasound based procedure to bypass these limitations. Methods: A scanning procedure and processing pipeline was developed specifically for CFD modelling of AVFs, using a freehand ultrasound setup combining B-mode scanning with 3D probe motion tracking. The scanning procedure involves sweeping along the vasculature to create a high density stack of B-mode frames containing the lumen geometry. This stack is converted into a continuous volume and transient flow waveforms are recorded at the boundaries, synchronised with ECG and automatically digitised, forming realistic boundary conditions for the CFD models. This is demonstrated on a diseased patient-specific AVF. Results: The three scans obtained using this procedure varied in geometry and flow behaviour, with regions of disease located in the first two scans. The outcome of the second procedure seen in the third scan indicated successful restoration with no sites of disease and higher flow. The models gave insight into the lumenal changes in diameter for both the artery and vein segments, as well as characterising hemodynamic behaviours in both the diseased and restored states. Vascular segment resistances obtained from the CFD models indicate a significant reduction once disease was removed, resulting in much higher flows enabling the patient to resume dialysis. Conclusion: The methodology described in this study allowed for a multifaceted analysis and high level tracking in terms of both geometry and flow behaviours for a patient case, demo
ISSN:0169-2607
1872-7565
DOI:10.1016/j.cmpb.2019.105203