Non-linear resistance associated to complex geometry at high flow rates in vascular access for hemodialysis

L. Antiga; R. N. Planken; K. Van Canneyt; L. Botti; A. Caroli; B. Ene-Iordache; J. Tordoir; P. Verdonck; A. Remuzzi

doi:https://doi.org/10.1007/978-3-642-03885-3_151

Non-linear resistance associated to complex geometry at high flow rates in vascular access for hemodialysis

L. Antiga, R. N. Planken, K. Van Canneyt, L. Botti, A. Caroli, B. Ene-Iordache, J. Tordoir, P. Verdonck, A. Remuzzi

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

1 Citation (Scopus)

Abstract

Successful maturation and long-term function of a vascular access for hemodialysis relies on the creation and maintenance a low-resistance route between the arterial and the venous system. In this work, we demonstrate how vascular segments characterized by complex geometry can be associated with non-linear resistance behavior at the sustained flow rates required for hemodialysis treatment. Using an image-based computational hemodynamics approach, we determine the relationship between flow rate and pressure drop in two kink geometries obtained from CE-MRA of a native arterio-venous fistula and a synthetic loop graft, respectively. Experimental validation of the predicted pressure drops across the loop graft kink is shows excellent agreement with the computational findings. The increase in pressure drop obtained at the high flow rates required for hemodialysis may lead to the inability for the vascular access to mature or maintain a sufficient flow rate for renal replacement therapy. For this reason, a patient-specific analysis of the relationships between geometry and resistance in realistic vascular access configurations may help at ameliorating the outcomes of vascular access creation and function.

Original language	English
Title of host publication	World Congress on Medical Physics and Biomedical Engineering
Subtitle of host publication	Diagnostic and Therapeutic Instrumentation, Clinical Engineering
Publisher	Springer Verlag
Pages	543-546
Number of pages	4
Edition	7
ISBN (Print)	9783642038846
DOIs	https://doi.org/10.1007/978-3-642-03885-3_151
Publication status	Published - 2009
Event	World Congress on Medical Physics and Biomedical Engineering: Diagnostic and Therapeutic Instrumentation, Clinical Engineering - Munich, Germany Duration: 7 Sept 2009 → 12 Sept 2009

Publication series

Name	IFMBE Proceedings
Number	7
Volume	25

Conference

Conference	World Congress on Medical Physics and Biomedical Engineering: Diagnostic and Therapeutic Instrumentation, Clinical Engineering
Country/Territory	Germany
City	Munich
Period	7/09/2009 → 12/09/2009

Keywords

CFD
Experimental validation
Hemodialysis
Hemodynamics
Vascular access

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https://doi.org/10.1007/978-3-642-03885-3_151

Cite this

Antiga, L., Planken, R. N., Van Canneyt, K., Botti, L., Caroli, A., Ene-Iordache, B., Tordoir, J., Verdonck, P., & Remuzzi, A. (2009). Non-linear resistance associated to complex geometry at high flow rates in vascular access for hemodialysis. In World Congress on Medical Physics and Biomedical Engineering: Diagnostic and Therapeutic Instrumentation, Clinical Engineering (7 ed., pp. 543-546). (IFMBE Proceedings; Vol. 25, No. 7). Springer Verlag. https://doi.org/10.1007/978-3-642-03885-3_151

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title = "Non-linear resistance associated to complex geometry at high flow rates in vascular access for hemodialysis",

abstract = "Successful maturation and long-term function of a vascular access for hemodialysis relies on the creation and maintenance a low-resistance route between the arterial and the venous system. In this work, we demonstrate how vascular segments characterized by complex geometry can be associated with non-linear resistance behavior at the sustained flow rates required for hemodialysis treatment. Using an image-based computational hemodynamics approach, we determine the relationship between flow rate and pressure drop in two kink geometries obtained from CE-MRA of a native arterio-venous fistula and a synthetic loop graft, respectively. Experimental validation of the predicted pressure drops across the loop graft kink is shows excellent agreement with the computational findings. The increase in pressure drop obtained at the high flow rates required for hemodialysis may lead to the inability for the vascular access to mature or maintain a sufficient flow rate for renal replacement therapy. For this reason, a patient-specific analysis of the relationships between geometry and resistance in realistic vascular access configurations may help at ameliorating the outcomes of vascular access creation and function.",

keywords = "CFD, Experimental validation, Hemodialysis, Hemodynamics, Vascular access",

author = "L. Antiga and Planken, {R. N.} and {Van Canneyt}, K. and L. Botti and A. Caroli and B. Ene-Iordache and J. Tordoir and P. Verdonck and A. Remuzzi",

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Antiga, L, Planken, RN, Van Canneyt, K, Botti, L, Caroli, A, Ene-Iordache, B, Tordoir, J, Verdonck, P & Remuzzi, A 2009, Non-linear resistance associated to complex geometry at high flow rates in vascular access for hemodialysis. in World Congress on Medical Physics and Biomedical Engineering: Diagnostic and Therapeutic Instrumentation, Clinical Engineering. 7 edn, IFMBE Proceedings, no. 7, vol. 25, Springer Verlag, pp. 543-546, World Congress on Medical Physics and Biomedical Engineering: Diagnostic and Therapeutic Instrumentation, Clinical Engineering, Munich, Germany, 7/09/2009. https://doi.org/10.1007/978-3-642-03885-3_151

Non-linear resistance associated to complex geometry at high flow rates in vascular access for hemodialysis. / Antiga, L.; Planken, R. N.; Van Canneyt, K. et al.
World Congress on Medical Physics and Biomedical Engineering: Diagnostic and Therapeutic Instrumentation, Clinical Engineering. 7. ed. Springer Verlag, 2009. p. 543-546 (IFMBE Proceedings; Vol. 25, No. 7).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › Academic › peer-review

TY - GEN

T1 - Non-linear resistance associated to complex geometry at high flow rates in vascular access for hemodialysis

AU - Antiga, L.

AU - Planken, R. N.

AU - Van Canneyt, K.

AU - Botti, L.

AU - Caroli, A.

AU - Ene-Iordache, B.

AU - Tordoir, J.

AU - Verdonck, P.

AU - Remuzzi, A.

PY - 2009

Y1 - 2009

N2 - Successful maturation and long-term function of a vascular access for hemodialysis relies on the creation and maintenance a low-resistance route between the arterial and the venous system. In this work, we demonstrate how vascular segments characterized by complex geometry can be associated with non-linear resistance behavior at the sustained flow rates required for hemodialysis treatment. Using an image-based computational hemodynamics approach, we determine the relationship between flow rate and pressure drop in two kink geometries obtained from CE-MRA of a native arterio-venous fistula and a synthetic loop graft, respectively. Experimental validation of the predicted pressure drops across the loop graft kink is shows excellent agreement with the computational findings. The increase in pressure drop obtained at the high flow rates required for hemodialysis may lead to the inability for the vascular access to mature or maintain a sufficient flow rate for renal replacement therapy. For this reason, a patient-specific analysis of the relationships between geometry and resistance in realistic vascular access configurations may help at ameliorating the outcomes of vascular access creation and function.

AB - Successful maturation and long-term function of a vascular access for hemodialysis relies on the creation and maintenance a low-resistance route between the arterial and the venous system. In this work, we demonstrate how vascular segments characterized by complex geometry can be associated with non-linear resistance behavior at the sustained flow rates required for hemodialysis treatment. Using an image-based computational hemodynamics approach, we determine the relationship between flow rate and pressure drop in two kink geometries obtained from CE-MRA of a native arterio-venous fistula and a synthetic loop graft, respectively. Experimental validation of the predicted pressure drops across the loop graft kink is shows excellent agreement with the computational findings. The increase in pressure drop obtained at the high flow rates required for hemodialysis may lead to the inability for the vascular access to mature or maintain a sufficient flow rate for renal replacement therapy. For this reason, a patient-specific analysis of the relationships between geometry and resistance in realistic vascular access configurations may help at ameliorating the outcomes of vascular access creation and function.

KW - CFD

KW - Experimental validation

KW - Hemodialysis

KW - Hemodynamics

KW - Vascular access

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DO - https://doi.org/10.1007/978-3-642-03885-3_151

M3 - Conference contribution

SN - 9783642038846

T3 - IFMBE Proceedings

SP - 543

EP - 546

BT - World Congress on Medical Physics and Biomedical Engineering

PB - Springer Verlag

T2 - World Congress on Medical Physics and Biomedical Engineering: Diagnostic and Therapeutic Instrumentation, Clinical Engineering

Y2 - 7 September 2009 through 12 September 2009

ER -

Antiga L, Planken RN, Van Canneyt K, Botti L, Caroli A, Ene-Iordache B et al. Non-linear resistance associated to complex geometry at high flow rates in vascular access for hemodialysis. In World Congress on Medical Physics and Biomedical Engineering: Diagnostic and Therapeutic Instrumentation, Clinical Engineering. 7 ed. Springer Verlag. 2009. p. 543-546. (IFMBE Proceedings; 7). doi: https://doi.org/10.1007/978-3-642-03885-3_151

Non-linear resistance associated to complex geometry at high flow rates in vascular access for hemodialysis

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Keywords

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