OBTURATOR HOOK SIGN — WHEN THE COMMON ILIAC VEIN DISAPPEARANCE ELUDES VISUAL DETECTION

Authors

  • Andreia Coelho Centro Hospitalar de Vila Nova de Gaia e Espinho; Faculdade de Medicina da Universidade do Porto, Portugal
  • Gerard O'Sullivan Galway University Hospitals

DOI:

https://doi.org/10.48750/acv.233

Keywords:

Computed Tomography Angiography [MeSH], Postthrombotic Syndrome [MeSH], Diagnosis, Differential [MeSH], May-Thurner Syndrome [MeSH];

Abstract

Introduction: Diagnosis of chronic iliac venous outflow obstruction is challenging, and no ideal imaging method has yet been defined. Even with imaging with superb detail, common iliac vein disappearance as occurs in Post-Thrombotic Syndrome (PTS) may be missed even by the most experienced radiologist. This scanning error occurs due to psychophysiological factors of human visual perception.

The purpose of this paper is to report on the “obturator hook sign”, evidencing obturator vein engorgement as a collateral pathway and hence a marker for hemodynamically significant chronic iliac venous outflow lesion, supporting this diagnosis.

Methods: Retrospective review of Indirect and Direct Computed Tomography Venography (CTV) and Magnetic Resonance Venography (MRV) imaging of the obturator hook sign and comprehensive literature review regarding iliac vein outflow obstruction diagnosis focusing on collateral vein development.

Results : The obturator hook sign is identified in Direct CTV, Indirect CTV and MRV of patients with chronic iliac venous outflow obstruction. The sign was never identified in imaging studies with no chronic iliac obstruction, suggesting high specificity.

Discussion: Venous collateralization is poorly understood, but it has been shown that when the main venous path is stenosed or occluded and the venous pressure rises, flow is side-tracked through alternative pathways. When the main venous path lesion is stented, flow once again takes the lower resistance pathway and the collaterals withdraw.

The obturator hook sign can be easily recognisable in CTV and MRV due to its peculiar anatomy and immediately points us towards hemodynamically significant chronic iliac venous outflow obstruction.

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References

1. Abdalla G, Fawzi Matuk R, Venugopal V, Verde F, Magnuson TH, Schweitzer MA, et al. The diagnostic accuracy of magnetic resonance venography in the detection of deep venous thrombosis: a systematic review and meta-analysis. Clin Radiol. 2015;70(8):858-71.
2. Pinto A, Brunese L. Spectrum of diagnostic errors in radiology. World J Radiol. 2010;2(10):377-83.
3. Kurstjens RL, van Vuuren TM, de Wolf MA, de Graaf R, Arnoldussen CW, Wittens CH. Abdominal and pubic collateral veins as indicators of deep venous obstruction. J Vasc Surg Venous Lymphat Disord. 2016;4(4):426-33.
4. Fraser DG, Moody AR, Morgan PS, Martel A. Iliac compression syndrome and recanalization of femoropopliteal and iliac venous thrombosis: a prospective study with magnetic resonance venog- raphy. Journal of vascular surgery. 2004;40(4):612-9.
5. Mahnken AH, Thomson K, de Haan M, O'Sullivan GJ. CIRSE standards of practice guidelines on iliocaval stenting. Cardiovascular and inter- ventional radiology. 2014;37(4):889-97.
6. Reichert M, Henzler T, Krissak R, Apfaltrer P, Huck K, Buesing K, et al. Venous thromboembolism: additional diagnostic value and radia- tion dose of pelvic CT venography in patients with suspected pulmo- nary embolism. European journal of radiology. 2011;80(1):50-3.
7. Shi WY, Wang LW, Wang SJ, Yin XD, Gu JP. Combined Direct and Indi- rect CT Venography (Combined CTV) in Detecting Lower Extremity Deep Vein Thrombosis. Medicine (Baltimore). 2016;95(11):e3010.
8. Min SK, Kim SY, Park YJ, Lee W, Jung IM, Lee T, et al. Role of three-di- mensional computed tomography venography as a powerful navigator for varicose vein surgery. Journal of vascular surgery. 2010;51(4):893-9.
9. Gagne PJ, Tahara RW, Fastabend CP, Dzieciuchowicz L, Marston W, Vedantham S, et al. Venography versus intravascular ultrasound for diagnosing and treating iliofemoral vein obstruction. J Vasc Surg Venous Lymphat Disord. 2017;5(5):678-87.
10. Arnoldussen CW, de Graaf R, Wittens CH, de Haan MW. Value of magnetic resonance venography and computed tomographic venography in lower extremity chronic venous disease. Phlebology. 2013;28 Suppl 1:169-75.
11. Umeoka S, Koyama T, Togashi K, Kobayashi H, Akuta K. Vascular dilatation in the pelvis: identification with CT and MR imaging. Radio- graphics. 2004;24(1):193-208.
12. Heijmen RH, Bollen TL, Duyndam DA, Overtoom TT, Van Den Berg JC, Moll FL. Endovascular venous stenting in May-Thurner syndrome. The Journal of cardiovascular surgery. 2001;42(1):83-7.
13. Ferris EJ, Lim WN, Smith PL, Casali R. May-Thurner syndrome. Radiology. 1983;147(1):29-31.
14. Raju S, Neglen P. High prevalence of nonthrombotic iliac vein lesions in chronic venous disease: a permissive role in pathogenicity. Journal of vascular surgery. 2006;44(1):136-43; discussion 44.
15. Neglen P, Raju S. Intravascular ultrasound scan evaluation of the obstructed vein. Journal of vascular surgery. 2002;35(4):694-700.
16. Brown SC, Gewillig M. Ever heard of the obturator vein? Catheter- ization and cardiovascular interventions : official journal of the Society for Cardiac Angiography & Interventions. 2010;75(3):416-9.
17. Kurstjens RL, van Vuuren TM, de Wolf MA, de Graaf R, Arnoldussen CW, Wittens CH. Abdominal and pubic collateral veins as indicators of deep venous obstruction. J Vasc Surg Venous Lymphat Disord. 2016;4(4):426-33.

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Published

2019-12-27

How to Cite

1.
Coelho A, O’Sullivan G. OBTURATOR HOOK SIGN — WHEN THE COMMON ILIAC VEIN DISAPPEARANCE ELUDES VISUAL DETECTION. Angiol Cir Vasc [Internet]. 2019 Dec. 27 [cited 2024 Nov. 24];15(3):196-9. Available from: https://acvjournal.com/index.php/acv/article/view/233

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Section

Review Article