Radiopaque FeMnN-Mo Composite Drawn Filled Tubing Wires for Braided Absorbable Neurovascular Devices

Overview

Journal Bioact Mater

Specialty Biomedical Engineering

Date 2024 Jul 4

PMID 38962657

Authors

Adam J Griebel

Petra Maier

Henry Summers

Benjamin Clausius

Isabella Kanasty

Weilue He

Nicholas Peterson

Carolyn Czerniak

Alexander A Oliver

David F Kallmes

Ramanathan Kadirvel

Jeremy E Schaffer

Roger J Guillory 2nd

Affiliations

Soon will be listed here.

Abstract

Flow diverter devices are small stents used to divert blood flow away from aneurysms in the brain, stagnating flow and inducing intra-aneurysmal thrombosis which in time will prevent aneurysm rupture. Current devices are formed from thin (∼25 μm) wires which will remain in place long after the aneurysm has been mitigated. As their continued presence could lead to secondary complications, an absorbable flow diverter which dissolves into the body after aneurysm occlusion is desirable. The absorbable metals investigated to date struggle to achieve the necessary combination of strength, elasticity, corrosion rate, fragmentation resistance, radiopacity, and biocompatibility. This work proposes and investigates a new composite wire concept combining absorbable iron alloy (FeMnN) shells with one or more pure molybdenum (Mo) cores. Various wire configurations are produced and drawn to 25-250 μm wires. Tensile testing revealed high and tunable mechanical properties on par with existing flow diverter materials. In vitro degradation testing of 100 μm wire in DMEM to 7 days indicated progressive corrosion and cracking of the FeMnN shell but not of the Mo, confirming the cathodic protection of the Mo by the FeMnN and thus mitigation of premature fragmentation risk. In vivo implantation and subsequent μCT of the same wires in mouse aortas to 6 months showed meaningful corrosion had begun in the FeMnN shell but not yet in the Mo filament cores. In total, these results indicate that these composites may offer an ideal combination of properties for absorbable flow diverters.

Citing Articles

Evaluation of FeMnN alloy bioresorbable flow diverters in the rabbit elastase induced aneurysm model.

Oliver A, Bilgin C, Cortese J, Bayraktar E, Dai D, Ding Y Front Bioeng Biotechnol. 2025; 13:1522696.

PMID: 40070550 PMC: 11893611. DOI: 10.3389/fbioe.2025.1522696.

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