MR Imaging Features of Giant Reservoir Formation in the Orbit: An Unusual Complication of Ahmed Glaucoma Valve Implantation

Case Report

A 22-year-old man presented with a progressive proptosis and pain of the right eye noticed for 1 week. At 14 years of age, he suffered a blunt injury in the right eye necessitating penetrating keratoplasty. Six years later, secondary glaucoma developed, which was refractory to a 3-month trial of meticulous medical treatment, and AGV implantation was performed as described by Coleman et al.⁵ During the 30-month follow-up, until recently, the intraocular pressure had been well maintained below 21 mm Hg by antiglaucoma and antifibrotic medications coupled with digital massage.

An ophthalmologic examination revealed the hyperemic conjunctiva and the peripherally shallow anterior chamber in the right eye. The patient could only count fingers from a distance of 2 ft, when using only the right eye. Left eye evaluation using the standard E chart showed a normal visual acuity of 20/20. The right and left intraocular pressures measured by the Goldmann applanation tonometry were 28–30 mm Hg and 14 mm Hg, respectively. Axial biometry readings were 17.5-mm OD and 15-mm OS.

For identifying the cause of progressive proptosis, MR examination of the orbit was performed using a 3T scanner (Achieva; Philips Medical Systems, Best, the Netherlands), which revealed a 1.7-cm ovoid, thin-walled, cystic lesion in the superotemporal aspect of the right orbit between the lacrimal gland and the globe (Fig 1). The lesion was apparently partitioned by the centrally located curvilinear band showing very dark signal intensity on both T1- and T2-weighted images (Fig 1A, -B). The lesion caused mild indentation of the adjacent superotemporal wall of the globe, which was mildly displaced anteroinferiorly. These MR imaging appearances were thought to correspond with a large fluid collection, so-called giant reservoir, surrounding the endplate of the AGV implant.

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Fig 1.

A 22-year-old man with giant reservoir associated with Ahmed glaucoma valve implantation. A and B, Coronal T1-weighted (A) and fat-suppressed T2-weighted (B) MR images of the orbit show a 1.7-cm ovoid, thin-walled, purely cystic lesion in the superotemporal aspect of the right orbit between the lacrimal gland and the globe (arrows). A dark curvilinear band representing the silicone-made endplate of the implant is seen at the center of the cyst on both T1- and T2-weighted images. Also noted is mild indentation of the adjacent superotemporal wall of the right globe. C, Axial contrast-enhanced fat-suppressed T1-weighted MR image demonstrates no significant enhancement within the lesion.

Discussion

Glaucoma drainage implants are being increasingly used in recent years and have been used successfully for the treatment of complicated glaucomas, including neovascular glaucoma, aphakic and pseudoaphakic glaucoma, postpenetrating keratoplasty glaucoma, pediatric glaucoma, and uveitic glaucoma.^6,7 The implants currently in common use include the AGV implant, the Baerveldt glaucoma implant (Advanced Medical Optics, Santa Ana, Calif), the Krupin slit valve (Hood Laboratories, Pembroke, Mass), and the Molteno implant (Molteno Ophthalmic, Dunedin, New Zealand).

The AGV implant, first introduced in 1993, consists of a drainage tube made of silicone and a scarab-shaped endplate made of either polypropylene or silicone (Fig 2). Fenestrations have been added to the plate of the silicone models. Different sizes (96, 184, and 364 mm²) according to the surface area of the endplate are commercially available.² Implants with a larger surface area and a thin capsule at the endplate will have a greater effect in lowering the patient's intraocular pressure. The endplate rests on the scleral surface after an incision of the conjunctiva and Tenon capsule, usually at the superior equator of the globe between the superior and lateral rectus muscles. The AGV is designed to minimize postoperative hypotony by adding a valve mechanism to an aqueous shunt surgery device to maintain a more predictable intraocular pressure. Moreover, the tube dose not require occlusion with a ligature or obturator, thus simplifying the initial surgery and eliminating the need for an additional procedure to remove the obturator.⁸

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Fig 2.

Ahmed glaucoma valve implant with a surface area of 184 mm². A, Photograph shows the implant composed of 3 parts: 1) drainage tube, 2) valve, and 3) endplate. B, Photograph of the side of the implant shows the crescentic shape of the endplate with a thickness of 0.9 mm.

AGV implantation carries a diverse range of postoperative complications.⁹ The early complications include transient hypotony, shallow anterior chamber, tube blockage, and hemorrhage. The late complications are encapsulated bleb formation, exposure and malposition of tube, corneal decompression, extrusion of implant, and fibrotic reaction around the valve.

An encapsulated bleb (also called a Tenon cyst) is a common postoperative complication after AGV implantation, which develops when Tenon's capsule adheres to the episcleral space forming a high, domed, smooth, 2-layered bleb.⁴ The encapsulated bleb is impervious to the aqueous humor, which results in intraocular pressure elevation.^10,11 The incidence of bleb encapsulation is much higher with the AGV than the other glaucoma drainage implants and has been estimated to be between 40% and 80%,¹² which might be attributed to certain factors of the aqueous humor that stimulate a fibrotic response. Tsai et al¹³ have suggested that immediate aqueous filtration with inflammatory factors may stimulate the fibrotic response in the subconjunctival space when the Ahmed implant is used, and delayed flow with a ligated, nonvalved implant may elicit a less fibrous reaction. The rate of bleb encapsulation has also been reported to be related to differences in the biomaterial, shape, and consistency of the endplate.¹⁴

Sometimes as seen in this case, an unusually large encapsulated bleb, so-called giant reservoir, is formed around the endplate of the AGV implant and can clinically produce proptosis and radiologically mimic other cystic lesions of the orbit, such as a dermoid cyst, which is particularly common around the lacrimal gland fossa. The diagnosis can be even more difficult if the ophthalmologic history is not known. On MR imaging, the giant reservoir associated with AGV implantation is seen as a thin-walled ovoid cyst located at the superotemporal aspect of the orbit near the lacrimal gland fossa. The wall of the cyst is probably formed by the fibrous pseudocapsule. The silicone-made endplate of the implant is seen as a very dark band located at the center of the cyst on both T1- and T2-weighted MR images. Although digital massage and antifibrotic medication can effectively reduce the size of the reservoir in most cases, surgical removal of scar tissues should be considered in resistant cases.²

In conclusion, we report the MR imaging findings of the giant reservoir formed after AGV implantation in a patient with posttraumatic glaucoma. Although other cystic lesions, such as dermoid cyst, can present similar imaging findings, the characteristic morphology and location should lead the radiologist to the correct nature of this cystic lesion.