Nitinol Release of Nickel Under Physiological Conditions: Effects of Surface Oxide, PH, Hydrogen Peroxide, and Sodium Hypochlorite

Overview

Journal Shap Mem Superelasticity

Publisher Springer

Date 2023 Sep 18

PMID 37720627

Authors

Eric M Sussman

Huiyu Shi

Paul A Turner

David M Saylor

Jason D Weaver

David D Simon

Pavel Takmakov

Shiril Sivan

Hainsworth Y Shin

Matthew A Di Prima

Dianne E Godar

Affiliations

Soon will be listed here.

Abstract

Nitinol is a nickel-titanium alloy widely used in medical devices for its unique pseudoelastic and shape-memory properties. However, nitinol can release potentially hazardous amounts of nickel, depending on surface manufacturing yielding different oxide thicknesses and compositions. Furthermore, nitinol medical devices can be implanted throughout the body and exposed to extremes in pH and reactive oxygen species (ROS), but few tools exist for evaluating nickel release under such physiological conditions. Even in cardiovascular applications, where nitinol medical devices are relatively common and the blood environment is well understood, there is a lack of information on how local inflammatory conditions after implantation might affect nickel ion release. For this study, nickel release from nitinol wires of different finishes was measured in pH conditions and at ROS concentrations selected to encompass and exceed literature reports of extracellular pH and ROS. Results showed increased nickel release at levels of pH and ROS reported to be physiological, with decreasing pH and increasing concentrations of hydrogen peroxide and NaOCl/HOCl having the greatest effects. The results support the importance of considering the implantation site when designing studies to predict nickel release from nitinol and underscore the value of understanding the chemical milieu at the device-tissue interface.

Citing Articles

A Predictive Toxicokinetic Model for Nickel Leaching from Vascular Stents.

Giakoumi M, Stephanou P, Kokkinidou D, Papastefanou C, Anayiotos A, Kapnisis K ACS Biomater Sci Eng. 2024; 10(4):2534-2551.

PMID: 38525821 PMC: 11005016. DOI: 10.1021/acsbiomaterials.3c01436.

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