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Abstract

Background:

The effect of catheter size on distal arterial flow and measured arterial pressure remains underexplored. This study evaluates the relationship between catheter-to-vessel ratio (CVR), distal arterial flow, and measured blood pressures in a controlled pulsatile arterial vessel phantom.

Methods:

Using in vitro data simulating arterial conditions, distal peak systolic velocity, systolic (SBP), and diastolic (DBP) were analyzed across varying catheter sizes and vessel diameters. Pearson correlation and linear regression were used to assess the relationship between CVR and changes in relative distal velocity, SBP, and DBP.

Results:

Relative distal peak systolic velocity exhibited a strong inverse relationship with CVR (r = −0.903, p < 0.001), with linear regression indicating that for every 10% increase in CVR, distal peak systolic velocity decreased by approximately 9.3%. Flow reduced >20% when CVR exceeded 0.6 and <5% when CVR was below 0.4. SBP demonstrated a strong positive correlation with CVR (r = 0.88, p < 0.001). SBP increased by approximately 2.8% for every 10% increase in CVR. SBP increased by >10 mmHg when CVR exceeded 0.6 and <5 mmHg when CVR was below 0.4 Relative DBP showed no significant correlation with CVR (r = 0.13, p = .61).

Conclusions:

Higher CVR in an in vitro model is associated with reduced distal flow and elevated systolic blood pressure in a phantom model. A CVR <0.4 (40%) appears to minimize flow and pressure changes. Appropriate selection of arterial catheter diameter for patient care may reduce risk of arterial catheter injuries and improve accuracy of clinical data.

Keywords

Catheterization peripheral/arterial critical care harm reduction thrombosis monitoring physiologic

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References

Fleury

Arroyo

Couchepin

, et al Impact of intravascular thrombosis on failure of radial arterial catheters in critically ill patients: a nested case-control study. Intensive Care Med 2018; 44(5): 553–563.

Schults

Young

Marsh

, et al Risk factors for arterial catheter failure and complications during critical care hospitalisation: a secondary analysis of a multisite, randomised trial. J Intensive Care 2024; 12(1): 12.

Weber

Nelson

Brennan

, et al Reduced severity of arterial catheter-associated proximal ischemic injuries through a quality improvement initiative. Pediatr Crit Care Med 2025; 26(5): e647–e656.

Romagnoli

Ricci

Quattrone

, et al Accuracy of invasive arterial pressure monitoring in cardiovascular patients: an observational study. Crit Care 2014; 18(6): 644.

Sharp

Cummings

Fielder

, et al The catheter to vein ratio and rates of symptomatic venous thromboembolism in patients with a peripherally inserted central catheter (PICC): a prospective cohort study. Int J Nurs Stud 2015; 52(3): 677–685.

Fabiani

Santoro

Sanson

The catheter-to-vein ratio at the tip level, not the catheter type, as a risk factor for a catheter failure. A retrospective comparative study of polyurethane midline and long peripheral catheters. Heart Lung 2023; 60: 39–44.

Spencer

Mahoney

KJ.

Reducing catheter-related thrombosis using a risk reduction tool centered on catheter to vessel ratio. J Thromb Thrombolysis 2017; 44(4): 427–434.

Imbrìaco

Monesi

Spencer

TR.

Preventing radial arterial catheter failure in critical care—factoring updated clinical strategies and techniques. Anaesth Crit Care Pain Med 2022; 41(4): 101096.

Bardin-Spencer

Spencer

TR.

Arterial insertion method: a new method for systematic evaluation of ultrasound-guided radial arterial catheterization. J Vasc Access 2021; 22(5): 733–738.

10.

Elli

Modaffari

Vellata

, et al Residual flow of the radial artery in the presence of an arterial catheter: a single-centre retrospective observational study. J Vasc Access 2024; 26(4): 1379–1384.

11.

Kim

Prasad

Kim

JK.

Alignment of microbeads using spinning helical minichannel cartridge. J Korean Soc Vis 2016; 14(3): 38–45.

12.

Bocchi

Romagnoli

Resonance artefacts in modern pressure monitoring systems. J Clin Monit Comput 2016; 30(5): 707–714.

13.

Mavarez

Ripat

Char

, et al Evaluation of distal radial artery cross-sectional internal diameter in neonates and infants by ultrasound and adequate selection of an intra-arterial catheter size. Paediatr Anaesth 2021; 31(12): 1350–1356.

14.

Eker

Tuzuner

Yilmaz

, et al The impact of two arterial catheters, different in diameter and length, on postcannulation radial artery diameter, blood flow, and occlusion in atherosclerotic patients. J Anesth 2009; 23(3): 347–352.

15.

Choe

Kim

, et al Intraarterial catheter diameter and dynamic response of arterial pressure monitoring system: a randomized controlled trial. J Clin Monit Comput 2022; 36(2): 387–395.

16.

Kennedy

Angermuller

King

, et al A comparison of hemolysis rates using intravenous catheters versus venipuncture tubes for obtaining blood samples. J Emerg Nurs 1996; 22(6): 566–569.

17.

Dugan

Leech

Speroni

, et al Factors affecting hemolysis rates in blood samples drawn from newly placed IV sites in the emergency department. J Emerg Nurs 2005; 31(4): 338–345.

18.

Schindler

Kowald

Suess

, et al Catheterization of the radial or brachial artery in neonates and infants. Paediatr Anaesth 2005; 15(8): 677–682.

19.

Randel

Tsang

Wung

, et al Experience with percutaneous indwelling peripheral arterial catheterization in neonates. Am J Dis Child 1987; 141(8): 848–851.

20.

Giustivi

Baroni

Di Capua

, et al On-demand use of peripheral arterial catheters outside the intensive care unit: development and retrospective evaluation of an internal protocol for insertion and management. J Vasc Access 2023; 24(6): 1495–1499.

The impact of arterial catheter-to-vessel ratio on distal arterial flow and measured arterial pressures in a pulsatile arterial vessel phantom

Abstract

Background:

Methods:

Results:

Conclusions:

Keywords

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References