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179 

Original Article 

 

Clinical Presentations of Benign Intraconal 
Tumors 
 
Asad Raza Jafri, Muhammad Saeed Iqbal, Memon Muhammad Khan, Partab Rai 

 
Pak J Ophthalmol 2008, Vol. 24 No. 4 

 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .  . .  
See end of article for 
authors affiliations 
 
…  ………………………   
 
Correspondence to: 
Asad Raza Jafri 
Flat # 105/1, 
Asaish Apartment, Block-16, 
Gulistan-e-Johar, 75290 
Karachi 
 
 
 
 
 
 
 
 
 
 

Received for publication 
March’ 2008 
…  ………………………   

Purpose: To determine the clinical presentations of benign intraconal orbital 
tumors for early diagnosis and prompt treatment. 

Material and Methods: This study was conducted in the Department of 
Ophthalmology, Jinnah Post graduate Medical Centre, Karachi from March 2004 
to February 2006.Total 30 patients of all age groups with axial proptosis and 
mass in the intraconal region seen on CT scan or MRI were included and 
followed for one year. Patients’ presenting complains and clinical examination 
(ocular/systemic) were noted. Diagnosis of disease was confirmed on the 
histopathology of excised mass. 

Results: The commonest clinical presentation was axial proptosis in all (100%) 
cases followed by decreased visual acuity in 18 (60%) cases, corneal exposure 
in 5 (16.66%) cases, choroidal folds in 4 (13.33%) cases and complete loss of 
vision in 3 (10%) cases caused by compression of optic nerve. 

Histopathology showed Lymphangioma in 11 (36.66%) cases, Cavernous 
heamangioma in 9 (30%), Neurofibroma in 4 (13.33%), Schwannoma in 3 (10%), 
Heamangiopericytoma in 2 (6.66%) and Optic nerve glioma in 1 (3.33%) case. 

Conclusion: Early diagnosis on the basis of clinical presentation, imaging and 
histopathologically can prevent lose of vision and other complications. 

 



180 

rbit is a closed cavity with compact arrange-
ment of different tissues derived from all 
three germinal layers, containing the globe, 

extra-ocular muscles, fat, vascular tissue, nerves, 
glandular and connective tissue which are essential for 
ocular functions. A wide variety of pathologies and 
space occupying lesions can be seen in any age, sex 
and race1. 

Sub-dividing the orbit into intra and extra-conal 
compartment is clinically correct but is not formulated 
on anatomic ground because no structure separates 
these two areas. Major fibrous septa connect the extra-
ocular muscles to the periosteum and do not form a 
continuous inter-muscular membrane in the orbit2,3. 

Intra-conal space refers to an area bounded by the 
four recti muscles extending from the posterior surface 
of the globe to the annulus of Zinn at the apex of the 
orbit. 

Tumors within the muscle cone lead to an axial 
proptosis in most cases, which by compressing the 
optic nerve may cause a decrease in the visual acuity4 
and may also cause limitation of extraocular 
movements. 

These are usually benign growths specially 
cavernous haemangioma5, which is the most common 
arising from a preexisting but non-patent vascular 
malformations6. Others include haemangiopericy-
toma7, lymphangioma, schwannoma8, optic nerve 
glioma and optic nerve sheath meningioma. 

Assessment of the space-occupying lesion within 
the muscle cone needs certain modalities of 
radiological imaging such as plain x-ray orbit, 
ophthalmic B-scan ultrasonography, computed 
tomography (CT scan) and magnetic resonance 
imaging (MRI) of orbit and brain9. 

If the intra-conal lesion is causing compressive 
effects over the optic nerve, it requires immediate 
treatment so that vision can be saved. Restoration of 
the eyeball to its normal position with the preservation 
of vision, ocular motor functions and cosmesis are the 
main goals of surgical intervention. 

The purpose of the study was to highlight the 
importance of early presentation and early referral of 
patients with intraconal tumors to the respective 
departments which can help to prevent both visual 
and more importantly physical morbidity. 
 
MATERIAL AND METHODS 

This study was conducted at the Department of 
Ophthalmology, Jinnah Postgraduate Medical Centre, 
Karachi, during the period of two years from March 
2004 till February 2006. Total 30 cases were included in 
this study and followed for duration of one year. The 
data was recorded in SPSS version 10. 

Inclusion criteria were any patient with axial 
proptosis and patient with mass in intraconal region 
on CT scan or MRI. Patients presenting with non axial 
proptosis and patients with mass extending outside 
the intraconal region on imaging were not included in 
the study. 

All patients were admitted in eye ward JPMC. A 
detailed history was obtained on a printed proforma. 
Particular attention was given to the history of any 
existing or previous ocular disorder, past history of 
trauma and any previous ocular or orbital surgery. All 
patients were inquired about any systemic illness 
especially diabetes mellitus, hypertension, and 
hyperthyroidism. 

The ocular examination was started with 
assessment of best corrected far and near visual acuity 
for each eye. Anterior segment was examined with slit 
lamp biomicroscope, giving special emphasis on the 
condition of the cornea and pupil abnormalities like 
RAPD. IOP was recorded with applanation tonometer 
in primary and up gaze. Retinal examination was 
performed by the indirect ophthalmoscope using 
+20D lens and on slit lamp biomicroscopy with +90D 
lens. In orbital examination, axial proptosis was 
measured with Hertel exophthalmometer10 and any 
associated horizontal and vertical displacements were 
measured with the help of scale. Ocular motility defect 
associated with any diplopia was also recorded. 

Ear, nose and throat examination was done in all 
patients to rule out the presence of any para-nasal 
sinuses or nasopharyngeal mass which could be the 
possible etiological factor in producing proptosis10. 

The systemic examination (especially chest and 
abdomen) was performed to search for primary 
neoplasm elsewhere in the body10 and vice versa. 
Following investigations were done: 

• Complete Blood and ESR 
• Serum TSH, T3, T4 
• X-ray orbits 
• Ophthalmic B-scan ultrasonography (USG). 
• CT scan/MRI (orbit and brain) 
• X-ray chest 
• Abdominal USG 

O 



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Excisional biopsy and then histopathological studies 
assisted to reach the final diagnosis. 
 
RESULTS 
Of these 30 patients 18 (60%) were male and 12 (40%) 
were female (Fig. 1) with a mean age of 35 years 
(ranging from 10–60 years). 

All these 30 patients (100%) presented with axial 
proptosis. Beside this, second common presentation 
was decreased visual acuity in 18 (60%) cases followed 
by corneal exposure in 5 (16.66%) cases, choroidal 
folds in 4 (13.33%) cases and complete loss of vision in 
3 (10%) cases (Table 1). 

Defective vision of these patients was 
documented. Twelve patients (40%) presented with 
best corrected vision of 6/18 or better, 02 patients 
(6.67%) presented with vision of 6/60 to 6/36, vision 
of 12 patients (40%) was between 1/60 to 5/60, 01 
patient (3.3%) had perception of only hand movement 
while 03 patients (10%) had absence of projection of 
light (Table 2). 

In addition to clinical presentation, diagnosis of all 
cases was confirmed as intraconal tumors on the basis 
of ultrasonography and CT/MRI scan imaging (Fig. 2). 
Each case was treated surgically and histopathological 
studies further confirmed the diagnosis. 
 
Table 1: Clinical presentation of intraconal tumors   

n = 30 

Clinical Presentation No. of  Patients n (%) 

Axial proptosis 30 (100) 

Decreased visual acuity 18 (60) 

Corneal exposure 5 (16.7) 

Choroidal folds 4(13.3) 

Complete loss of vision 3 (10) 
 
Table 2:  Visual acuity at the time of presentation        

n= 30 

Best corrected visual acuity  No. of patients n (%) 

Projection of light absent 3 (10) 

Projection of light present 0 (0) 

Hand movement perceived 1(3) 

Between 1/60-3/60 7(23) 

Between 4/60-5/60 5 (17) 

Between 6/60-6/34 2 (7) 

Between 6/18-6/9 12(40) 
 
Table 3 Histopathological diagnosis n = 30 

Histopathological 
Diagnosis 

No. of patients n (%) 

 Lymphangioma 11 (37) 

Cavernous haemangioma 9 (30) 

 Neurofibroma 4 (3) 

 Schwanoma 3 (10) 

 Haemangiopericytoma 2 (7) 

 Optic nerve glioma 1 (3) 
 

Histopathological studies reported that the most 
common intraconal tumor is Lymphangioma (Fig. 3) 
which was found in 11 (36.66%) cases. Nine (30%) 
cases were proved to be Cavernous haemangioma 
(Fig. 4). Neurofibroma was present in 04 (13.33%) 
cases, Schwanoma in 03 (10%) cases, 
Haemangiopericytoma in 02 (6.66%) and optic nerve 
glioma in 1 (3.33%) case (Table 3). 
 

12 / 40%

18 / 60%

Female

Male

 
Male: Female = 1.5: 1 
 

Fig. 1: Sex distribution n = 30 

 



182 

 
 

Fig. 2:  Axial view – showing multiple intraconal cystic 
lesions 

 
DISCUSSION 
The orbital tumors increase orbital volume and cause a 
mass effect. Although a mass may be histologically 
benign but it can invade intraorbital or adjacent orbital 
structures and can cause significant damage. A wide 
variety of pathological processes and space occupying 
lesions can be seen in any age, sex and race1. 

When dealing with the benign intraconal orbital 
tumors one must keep in mind that they are slow 
growing usually presenting with the forward displac-
ement of globe11, because of their tendency to lead 
irreversible loss of vision due to the mass effect on the 
optic nerve. Direct optic nerve compression, globe 
indentation with induced hyperopia, or increased 
intracranial pressure with optic nerve compression 
may be responsible for visual symptoms12. Christante13 
in his study reported that out of 57 patients, proptosis 
was the main presenting complaint in 80% of cases 
while 40% had visual deterioration. Zhang14 in his 
study reported 17 (77.27%) out of 22 patients with 
visual impairment as the first presenting symptom. 
Thorn-Kany15 in his study of 8 patients reported that 
seven cases presented with a painless proptosis and in 
one case with a failing of visual acuity of the 
concerned eye. Selva D16, in his study of 5 cases has 
reported that all cases presents with a history of 
progressive painless proptosis and CT scan revealed 
homogenous intraconal mass. In our study the most 
common clinical presentation was axial proptosis in all 
the 30 (100%) cases while visual loss was found in 
18(60%) of cases. Early surgery for removal of the 
tumor was favored after onset of symptoms. 

 

 
 

Fig. 3: Lymphangioma 
 

 
 

Fig. 4: Cavernous haemangioma 
 

Shields JA17, reported the most commonly 
diagnosed intraconal tumors were lymphoid tumor 
(139 cases; 11%), cavernous haemangioma (77 cases; 
6%), lymphangioma (54 cases; 4%) and optic nerve 
glioma (48 cases; 4%). Wright18 suggested that 
lymphangiomas are variants of venous malformations 
but clinical, haemodynamic and histopathologic 
studies strongly suggest that lymphangiomas are 
distinct orbital hamartomas19. These are benign 
tumors and often present during childhood, the 
largest reported series by Jones20 involving 62 cases. 

We have 2 cases of cavernous haemangioma and 1 
case of neurofibroma. It was easy to reach at exact 
tissue diagnosis after histopathological opinion except 
in the cases of lymphangioma where the multiple 
cystic lesions were found on CT scan and preopera-
tively. When tissue specimens were reviewed by 
histopathologist, different vascular channels and cystic 
spaces filled with blood or fluid were noted. On the 
basis of clinical, radiological and histopathological 
findings, we were able to label these patients as 
lymphangioma. 
 
CONCLUSION 
The most common clinical presentation of intraconal 
tumors is axial proptosis but there are some 
uncommon presentations which can lead to 
misdiagnosis of such orbital masses. Tumor location 
and radiological findings can provide important 
information regarding the diagnosis of a tumor prior 
to biopsy or tumor resection. This will help in the 
determination of treatment strategy. Prompt referral of 
the patient to the department with facility for arbital 
surgery plays crucial role in this regard. 



183 

 
Author’s affiliation 
Dr. Asad Raza Jafri 
Senior Registrar Ophthalmology 
Karachi Medical & Dental College 
North Nazimabad, Karachi 

Dr. Muhammad Saeed Iqbal 
Assistant Professor Ophthalmology 
Sir Syed College of Medical Sciences Hospital 
Qayyumabad, Korangi Raod, Karachi 

Dr. Memon Mohammad Khan 
Assistant Professor Ophthalmology 
Kulsoom Bai Valika Hospital, 
S.I.T.E., Karachi 
Dr. Partab Rai 
Assistant Professor Ophthalmology 
Chandka Medical College and Hospital 
Larkana 
 
REFERENCE 
1. Munir-ul-haq M. A statistical analysis of 581 primary orbital 

tumors in Pakistan. Pak J Ophthalmol. 1987; 3: 111-20. 
2. Whitnall SE. Anatomy of human organs and accessory organs 

of vision. 2nd ed. London: Oxford University Press. 1932. 
3. Koorneff L. New insight in the human orbital connective: 

results of new anatomic approach. Arch Ophthalmol. 1977; 95: 
1269. 

4. Shields JA, Blackwell B, Augsburger JJ. Classification and 
incidence of space-occupying lesions of the orbit. A survey of 
654 biopsies. Arch Ophthalmol. 1984; 102: 1606-11. 

5. Hood CI. Cavernous hemangioma of the orbit. A consideration 
of pathogenesis with an illustrative case. Arch Ophthalmol. 
1970; 83: 49-53. 

6. Cabrera Vargas ME, Perez AJ, Diaz AC, et al. Orbital 
hemangiopericytoma: a case with involvement of the 
intraconal space. Arch Soc Esp Oftalmol. 2000; 75: 701-4. 

7. Tsuzuki N, Katoh H, Ohnuki A, et al. Cystic Schwannoma of 
the orbit: case report. Surg Neurol. 2001; 5: 384. 

8. Asif M, Shafiq K, Ahmed M, et al. Orbital masses: incidence 
and clinical presentation. Pak J Ophthalmol. 1998; 14:149-152. 

9. Fafowora OF, Cookey-gam AI, Obajimi MO. Radiological 
evaluation of orbital tumors in Ibadan, Nigeria. Afr J Med Sci. 
1996; 25: 361-4. 

10. Khurana AK. Investgations of orbital space occupying lesions, 
In modern Ophthalmology by LC Datta. Jaypee Brothers 
Publishers, New Delhi, 1st edition. 1994: 89-102. 

11. Geoffrey J, Gladstone, Frank A, John DS. Intraconal tumors of 
the orbit. 4th edition W.B. Saunders Company. 1994; 13: 99. 

12. Cockerham KP, Cockerham GC, Stutzman R, et al. The 
clinical spectrum of schwannomas presenting with visual 
dysfunction: a clinico-pathologic study of three cases. Surv 
Ophthalmol.1994; 44: 226-34. 

13. Cristane L. Surgical treatment of meningioma of the orbit and 
optic canal: A retrospective study with particular attention to 
visual outcome. Acta Neuroarchiv. 1994; 126; 27-32. 

14. Zhang CH, Zhang TC, Zhong JS, et al. Early diagnosis of the 
tumors in orbital apex and optic nerve. Zhongua Yan Ke Za 
Zhi. 2004; 40: 34-6. 

15. Thorn-Kany M, Arrue P, Delisle MB, et al. Cavernous 
hemangiomas of the orbit: MR imaging. Neuroradiol. 1999; 26: 
79-86. 

16. Selva D, Strianeses D, Bonavolonta G, et al. Orbital venous 
lymphatic malformations (Lymphangiomas) mimicking 
cavernous hemangiomas. Am J Ophthalmol. 2001; 131: 364-70. 

17. Shields JA, Shields CL, Scartozzi R. Survey of 1264 patients 
with orbital tumors and simulating lesions. Ophthalmology. 
2004; 111: 997-1008. 

18. Wright JE. Orbital vascular anamolies. Trans Am Acad 
Ophthalmol Otolaryngol. 1974; 78: 606. 

19. Rootman J, Hay E, Grace D. Orbital adnexal lymphangioma: A 
spectrum of haemodynamically isolated vascular hamartoma. 
Ophthalmol. 1986; 93: 1558. 

20. Jones IS. Lymphangioma of ocular adnexa. An analysis of 62 
cases. Trans Am Ophthalmol Soc 1959; 57: 602.