1Department of Radiology, Oman Medical Specialty Board, Muscat, Oman; Departments of 2Radiology and 4Ophthalmology, Sultan Qaboos University 
Hospital, Muscat, Oman; 3Department of Radiology, Al Nahdha Hospital, Muscat, Oman; 5Department of Ophthalmology, Sultan Qaboos University, 
Muscat, Oman
*Corresponding Author’s e-mail: ath-obaidani@hotmail.com

تشوه األوعية الدموية احلجاجية
عذاري عبد اهلل العبيدانية، �سمري رانيجا، اأمين احلديدي، بثينة �سبت، عبد اهلل املجيني

Orbital Vascular Malformation
*Athari A. Al-Obaidani,1 Sameer Raniga,2 Ayman Al Hadidi,3 Buthaina Sabt,4 Abdullah Al-Mujaini4,5

Sultan Qaboos University Med J, February 2021, Vol. 21, Iss. 1, pp. e139–140, Epub. 15 Mar 21
Submitted 10 Jun 20
Revision Req. 11 Aug 20; Revision Recd. 26 Aug 20
Accepted 16 Sep 20

A 56-year-old male patient, known to have hypertension, presented to the Sultan Qaboos University Hospital in 2019 with 
a six-year history of gradually increasing left eye 
protrusion associated with reduced vision in the left 
eye. Ophthalmic examination revealed a significant 
proptosis in the left eye with an inferior displacement 
of the globe [Figure 1]. The best-corrected visual acuity 
was 6/9 and 6/24 in the right and left eye, respectively. 
Afferent pupillary defect was noted in the left eye, 
but slit-lamp biomicroscopy was unremarkable on 
both sides. Dilated fundus examination of the left 
eye showed an elevated optic disc with hazy borders. 
Left eye proptosis secondary to retrobulbar mass was 
the most likely aetiology and a magnetic resonance 
imaging (MRI) scan was performed.

The MRI scan showed an oval-shaped retro- 
bulbar intraorbital lesion measuring 3.0 × 2.7 × 3.1 
cm (anteroposterior  × craniocaudal × transverse) in 
size, displacing the orbit anteriorly, the optic nerve 
inferomedially and the superior and lateral rectus 

muscles peripherally [Figure 2]. The lesion showed 
high signal intensity in T2- and isointense signal in 
T1-weighted images with progressive enhancement 
starting as a patchy enhancement at the late arterial 
phase with a complete enhancement of the lesion in 
the delayed images [Figure 3]. Findings were consistent 
with orbital slow-flow vascular malformation which 
was likely a cavernous malformation. 

Informed consent was obtained from the patient 
for the publication of these images.

Comment

Vascular lesions of the orbits are rare; the various 
types are charcterised by their growth, histopathology 
and flow. According to a system proposed by Mulliken 
and Glowacki, they are classified as capillary haeman- 
giomas, venous vascular malformations, venous lymphatic 
malformations, arterial and arteriovenous lesions or 
neoplasms.1

This work is licensed under a Creative Commons Attribution-NoDerivatives 4.0 International License.

https://doi.org/10.18295/squmj.2021.21.01.022

interesting medical image

 
Figure 1: Photograph of the eyes of a 56 year-old male patient showing the left eye protruding outward (proptotic).

https://creativecommons.org/licenses/by-nd/4.0/


Orbital Vascular Malformation

e140 | SQU Medical Journal, February 2021, Volume 21, Issue 1

Cavernous malformations are the most common 
orbital lesions in adults and account for 6% of all 
orbital masses.2 These lesions are slow-growing and 
often manifest with progressive, painless proptosis. 
They tend to be septate, well-circumscribed and do 
not involute.1 These lesions are usually located in the 
lateral aspect of intraconal retrobulbar space and are 
rarely found in the conal or extraconal spaces.3 Bone 
remodelling can be seen as well as calcifications. 
Associations with Maffucci syndrome and blue rubber 
bleb nevus syndrome have been reported.1

Cavernous malformations have a fibrous pseudo-
capsule and appear circumscribed on imaging. 
They usually appear hyperattenuated on computed 
tomography scan and occasionally contain phleboliths. 
In addition, they displace adjacent structures without 
invading them and may cause expansion of the orbital 
walls. On MRI, they appear isointense to the muscle 

in T1- and hyperintense to the muscle in T2-weighted 
images. In the early arterial phase, they show poor 
enhancement due to their slow flow nature with 
progressive accumulation of contrast material in the 
late phase dynamic and delayed images.

The management of these lesions should be 
individualised and determined by size, location 
and patient symptoms. Conservative management 
is advised if there are no or minimal symptoms. 
Sclerotherapy with ethanol injection is advised for an 
extensive facial with orbital/periorbital involvement. 
Other options include surgical excision for localised 
lesions or surgical resection for more extensive and 
deep lesions.4 All available measures and their risks 
and benefits should be discussed with the patient 
during peri-operative counselling.

References
1.  Smoker WR, Gentry LR, Yee NK, Reede DL, Nerad JA. Vascular 

lesions of the orbit: More than meets the eye. Radiographics 
2008; 28:185–204. https://doi.org/10.1148/rg.281075040. 

2.  Xian J, Zhang Z, Wang Z, Li J, Yang B, Chen Q, et al. Evaluation of 
MR imaging findings differentiating cavernous haemangiomas 
from schwannomas in the orbit. Eur Radiol 2010; 20:2221–8. 
https://doi.org/10.1007/s00330-010-1774-y.

3.  Anand R, Deria K, Sharma P, Narula M, Garg R. Extraconal 
cavernous hemangioma of orbit: A case report. Indian J Radiol 
Imaging 2008; 18:310–12. https://doi.org/10.4103/0971-3026.43849.

4.  Benoiton LA, Chan K, Steiner F, FitzJohn T, Tan ST. Management 
of orbital and periorbital venous malformation. Front Surg 
2017; 4:27. https://doi.org/10.3389/fsurg.2017.00027. 

 
Figure 2: Multi-sequential multi-planar magnetic resonance images of the head (orbits with intravenous contrast) of a 
56-year-old male patient. A & B: Axial and coronal T2-weighted images showing an oval-shaped lesion (asterisk) in the 
retrobulbar intraconal space of the left orbit displacing the glob anteriorly (arrowhead), the optic nerve inferomedially 
(white arrow) and the superior and lateral rectus muscles (red arrows) peripherally. The lesion shows homogenous 
intermediate to high signal intensity in T2-weighted images. C: Sagittal precontrast T1-weighted image showing that the 
lesion is isointense to the cerebral cortex (asterisk). 

 
Figure 3: Axial T1-weighted post-intravenous Gado- 
linium-enhanced images in the (A) late arterial and (B) 
delayed phase showing progressive enhancement (solid 
white arrows). The lesion is almost completly enhanced 
on the delayed images.

https://doi.org/10.1148/rg.281075040
https://doi.org/10.1007/s00330-010-1774-y
https://doi.org/10.4103/0971-3026.43849
https://doi.org/10.3389/fsurg.2017.00027