Abstract: SA-PO054
Fluid Dynamics Analysis by CT Imaging Technique of Hollow Fiber Dialyzer with Medium Cut-Off Membrane
Session Information
- Engineering-Based Approaches to Problems in Nephrology
November 09, 2019 | Location: Exhibit Hall, Walter E. Washington Convention Center
Abstract Time: 10:00 AM - 12:00 PM
Category: Bioengineering
- 300 Bioengineering
Authors
- Lorenzin, Anna, IRRIV, Vicenza, Italy
- Godi, Ilaria, Universitá degli studi di Padova, Padova, Italy
- Mari, Gaia, IRRIV, Vicenza, Italy
- de Cal, Massimo, San Bortolo Hospital, Vicenza, Italy
- Ronco, Claudio, University of Padova, IRRIV, San Bortolo Hospital, Vicenza, Italy
Background
Inadequate removal of molecules between 5and50KDa,due to their restriction in diffusibility, may cause long-term complication in chronic hemodialysis patients. Medium Cut-off(MCO) is a new class of membranes with enhanced sieving properties and negligible albumin loss, thanks to its high molecular weight(MW) retention onset and MW cut-off value lower than albumin MW. MCO membrane used in HD allows to perform expanded hemodialysis (HDx), a technique based on high internal filtration(IF). Our previous study quantified the IF of Theranova dialyzer leveraging a nuclear imaging technique.
In order to characterize the local distribution of the IF, an in vitro study assessing the fluid dynamics inside Theranova dialyzer was conducted through CT imaging technique.
Methods
Dialyzer Theranova400(Baxter, Deerfield, USA) was placed in vertical position in the CT gantry. Blood and dialysate compartments were analyzed separately. Dye solution was circulated through blood compartment at 300ml/min and through dialysate one at 500ml/min. Longitudinal sections, 0.5cm thick, were recorded for 60seconds.
Results
In blood compartment, dye solution immediately after its entrance in the dialyzer demonstrates homogeneous progression, while different velocity profiles were observed among the fibers proceeding to the outlet port (Fig b). In dialysate compartment, dye solution is distributed in the periphery first (Fig d), then seeps in the fibers bundle and reaches the complete compartment filling.
Conclusion
The homogeneous dye profile immediately after its entrance in blood compartment demonstrated a good design of the inlet port; the optimal dye distribution reached in both blood and dialysate compartments ensure that IF phenomenon is equally achieved in both central and peripheral regions of the dialyzer.