Multimodal Imaging in the Elastase-Induced Aneurysm Model in Rabbits: A Comparative Study Using Serial DSA, MRA and CTA

A. Doerfler; W. Becker; I. Wanke; S. Goericke; N. Oezkan; M. Forsting

doi:10.1055/s-2004-812753

RöFo - Fortschritte auf dem Gebiet der Röntgenstrahlen und der bildgebenden Verfahren, Table of Contents

Rofo 2004; 176(4): 590-596
DOI: 10.1055/s-2004-812753

Experimentelle Radiologie

Multimodal Imaging in the Elastase-Induced Aneurysm Model in Rabbits: A Comparative Study Using Serial DSA, MRA and CTA

Multimodale Bildgebung am tierexperimentellen AneurysmamodellA. Doerfler¹ , W. Becker¹ , I. Wanke¹ , S. Goericke¹ , N. Oezkan¹ , M. Forsting¹

¹Department of Neuroradiology, Institute of Diagnostic and Interventional Radiology, University of Essen Medical School, Essen, Germany

Abstract

Zusammenfassung

Ziel: Evaluierung der Wertigkeit verschiedener Bildgebungsmodalitäten in der Bestimmung der Aneurysmagröße am Elastase-Aneurysmamodell am Kaninchen. Material/Methode: Bei 8 Chinchilla-Kaninchen wurde durch endoluminale Elastaseinkubation ein Aneurysma induziert. Alle Tiere wurden mit intravenöser DSA (IVDSA), kontrastverstärkter (CEMRA) und „time-of-flight”-MRA (TOF) nach 14 Tagen, 4 Wochen und 3 Monaten untersucht und es wurde jeweils die Aneurysmagröße (Höhe: H, Weite: W, Halsweite: N) bestimmt. Nach 3 Monaten wurden zusätzlich eine intraarterielle DSA (IADSA) und eine CT-Angiographie durchgeführt. Ergebnisse: In der IVDSA nach 2 Wochen betrugen die mittlere Aneurysmahöhe (H) 6,2 mm, -weite (W) 2,8 mm und Halsweite (N) 2,7 mm. Es zeigte sich keine statistisch signifikante Änderung der Aneurysmagröße nach 4 Wochen (CEMRA: H: 5,4, W: 2,4, N: 2,4; TOF: H: 5,7, W: 2,4, N: 2,7) bzw. 3 Monaten (CEMRA: H: 5,8, W: 2,6, N: 2,6; TOF: H: 6,9, W: 2,8, N: 3,0). Die Aneurysmagröße betrug in der IADSA (H: 6,2, W: 3,0, N: 2,7) mit guter Korrelation zur CTA (r = 0,94). Die TOF-MRA war in der Darstellung der Aneurysmawand überlegen. Schlussfolgerungen: Verlaufskontrollen mit DSA, MRA und CTA sind am experimentellen Aneurysmamodell möglich und zeigen eine gute Korrelation. MRA und CTA eignen sich im Rahmen der nicht-invasiven präinterventionellen Therapieplanung zur Bestimmung der Aneurysmagröße.

Abstract

Background and Purpose: The elastase-induced aneurysm model in rabbits has proved to be suitable for testing new endovascular occlusion devices. The purpose of this study was to evaluate different imaging modalities for the depiction of anatomy and size of elastase-induced aneurysms and for serial follow-up imaging. Materials and Methods: Elastase-induced aneurysms were created in eight Chinchilla bastard rabbits by endoluminal incubation of porcine elastase. Serial imaging was performed using intravenous DSA (IVDSA), contrast-enhanced MRA (CEMRA), and time-of-flight MRA (TOF) 14 days, 4 weeks and 3 months after aneurysm creation. Intraarterial DSA (IADSA) and CT angiography (CTA) were performed after 3 months. Aneurysm size and geometry (height H, width W, neck width N) were compared. Results: On IVDSA after two weeks mean aneurysm height was 6.2 mm (range 2.8 - 11.0 mm), mean aneurysm width was 2.8 mm (range 2.0 - 4.2 mm) and mean aneurysm neck width was 2.7 mm (range 2.0 - 4.2 mm). We did not observed any statistically significant change in aneurysm dimensions during follow-up at 4 weeks (CEMRA: H: 5.4, W: 2.4, N: 2.4; TOF: H: 5.7, W: 2.4, N: 2.7) and 3 months (CEMRA: H: 5.8, W: 2.6, N: 2.6; TOF: H: 6.9, W: 2.8, N: 3.0). Aneurysm dimensions could be best seen on IADSA (H: 6.2, W: 3.0, N: 2.7) with good correlation to CTA (r = 0.94; H: 6.1, W: 2.8, N: 2.6), CE-MRA (r = 0.92), and TOF (r = 0.97). TOF was superior to CEMRA in delineating the aneurysm wall. Conclusions: Serial imaging using MRA, CTA or intravenous and intraarterial angiography is feasible in the elastase-induced aneurysm model. Contrast-enhanced MRA, TOF-MRA and CTA showed good correlation to IADSA and are all suitable for non-invasive pretherapeutic measurement of aneurysm size.

Key words

Aneurysm - animal - intracranial - CT - MR

Full Text

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Arnd Doerfler, M.D.

Department of Neuroradiology, Institute of Diagnostic and Interventional Radiology, University of Essen Medical School

Hufelandstraße 55

45122 Essen

Germany

Email: arnd.doerfler@uni-essen.de