so uninvolved conjunctiva is not available for grafting. Mucous membrane transplantation using buccal and even nasal mucosa (if possible, because of the systemic nature of some diseases) or amniotic membrane is an option for ocular surface replacement in such instances (discussed later in this chapter).

Pterygium Excision

Indications for pterygium excision include persistent discomfort, vision distortion and induction of irregular astigmatism, significant (>3–4 mm) and progressive growth toward the corneal center/visual axis, and restricted ocular motility. The aim of microsurgical excision of a pterygium is to achieve a normal, topographically smooth ocular surface. The procedure is performed on an outpatient basis using topical anesthesia and, in some cases, peribulbar or retrobulbar anesthetic, especially in recurrent cases complicated by scarring. A traction suture (eg, 6-0 silk or polyglycolic acid on a spatulated needle) placed at the 12 o’clock position, which can then be clamped down in various positions to the surgical drape, facilitates maximal exposure of the pterygium and the graft site. A common surgical technique is to remove the pterygium using a flat blade or an angled crescent blade, which allows a smooth plane of dissection toward the limbus. Although it is preferable to dissect down to bare sclera at the limbus, the surgeon should be careful when dissecting Tenon tissue medially, as doing so can sometimes lead to bleeding and later scarring from inadvertent trauma to subjacent muscle tissue and muscle check ligaments. After excision, light cautery is usually applied to the sclera for hemostasis. It is important to remove as much of the fibrovascular scar tissue as possible. If the medial rectus muscle is restricted, it must be isolated and carefully freed of all scar tissue. A smooth surface at the site of dissection is a desirable endpoint. With the eye rotated to expose the involved quadrant, the size of the defect is measured with calipers. Options for wound closure include the following (Fig 14-2; Table 14-2 lists the recurrence rate of pterygium with some of these options):

Bare sclera. No sutures or fine, absorbable sutures are used to appose the conjunctiva to the superficial sclera in front of the rectus tendon insertion, leaving an area of exposed sclera. Note that this technique has an unacceptably high recurrence rate and is therefore strongly not recommended.

Simple closure. The free edges of the conjunctiva are secured together (effective only when the conjunctival defect is very small).

Sliding flap. An L-shaped incision is made adjacent to the wound to allow a conjunctival flap to slide into place.

Rotational flap. A U-shaped incision is made adjacent to the wound to form a tongue of conjunctiva that is rotated into place.

Autologous conjunctival transplantation. As mentioned previously, this is a free graft, usually from the superior bulbar conjunctiva. The graft is excised to correspond to the size of the wound and is then moved and either sutured into place or fixated with a tissue adhesive (fibrin sealant made from pooled human plasma). This technique is described in more detail below.

Autologous conjunctival–limbal transplantation. This is also a free graft, but it includes limbal stem cells in addition to the conjunctival graft. (See below for surgical technique.)

Amniotic membrane transplantation. A free amniotic membrane graft may be an alternative to conjunctival autograft, although free conjunctival grafting is still more successful and is the preferred technique. Amniotic membrane is indicated particularly when there is a shortage of autologous conjunctiva. These grafts may be most useful with large pterygia, where a wide

excision is needed. There are insufficient data to comment on the efficacy of amniotic membrane grafting as an adjuvant in pterygium surgery.

Figure 14-2 Surgical wound closures following pterygium excision. A, Bare sclera. B, Simple closure with fine, absorbable sutures. C, Sliding flap that is closed with interrupted and/or continuous suture. D, Rotational flap from the superior bulbar conjunctiva. E, Conjunctival autograft that is secured with interrupted and/or continuous suture. (Reproduced with permission from

Gans LA. Surgical treatment of pterygium. Focal Points: Clinical Modules for Ophthalmologists. San Francisco: American Academy of Ophthalmology; 1996, module 12. Illustration by Christine Gralapp.)

Table 14-2

If autologous conjunctival transplantation is to be performed, then the eye is turned down to expose the superior bulbar conjunctiva, and the area to be harvested is marked with a surgical pen. The most important aspect of the harvesting is to procure conjunctival tissue with only minimal or no Tenon included. This may be facilitated by injection of a small amount of anesthetic between the conjunctiva and Tenon capsule. Some surgeons make a special point of harvesting limbal stem cells along with the conjunctiva and orienting the donor material in the host bed so that the stem cells are adjacent to the site of corneal lesion excision. It is best to allow a little extra tissue for grafting, so the harvested tissue should be approximately 0.5–1.0 mm larger than the size of the defect in the area of the excised pterygium.

The donor site is usually left bare. After the graft is freed, it is transferred to the recipient bed and secured to adjacent conjunctiva (with or without incorporating episclera) with 7-0 to 10-0 polyglycolic acid (absorbable) or nylon (nonabsorbable) suture or with tissue adhesive. Many authors have described the use of commercially available fibrin tissue adhesive to fixate the conjunctival autograft, thereby eliminating the need for suture fixation. Elimination of sutures decreases postoperative pain and reduces surgical time as well as the recurrence rate, compared with bare sclera techniques (see Table 14-2). Fibrin tissue adhesive mimics natural fibrin formation, ultimately resulting in the formation of a fibrin clot. Several fibrin sealants have been approved by the US Food and Drug Administration (FDA) and are commercially available and distributed by US companies, including Tisseel Fibrin Sealant (Baxter Healthcare Corporation, Westlake Village, CA), Evicel Fibrin Sealant (Ethicon, Inc, Somerville, NJ), and BioGlue Surgical Adhesive (CryoLife, Inc, Kennesaw, GA). There is also the CryoSeal FS System (ThermoGenesis Corp, Rancho Cordova, CA), which can be used in the automated preparation of fibrin sealant from the patient’s own plasma. Currently, use of these products in pterygium surgery is considered off-label. Also, because both pooled human plasma and bovine products are used to obtain some components of these products, careful consideration should be given to the potential for disease transmission with their use.

If the defect created following dissection of scar tissue is considerably larger than what can be covered with an autologous conjunctival graft, then an amniotic membrane graft may be used in conjunction with a conjunctival graft to cover the entire area of resection. Several authors have noted that this decreases postoperative inflammation and speeds reepithelialization of the surface.

There is evidence that the use of mitomycin C (MMC) with conjunctival autografting reduces the recurrence rate of pterygium after surgical excision (see Table 14-2). However, further studies are necessary to determine the optimal route of administration and dose for MMC, as well as the duration of treatment with MMC and its long-term effects. In studies, the concentration of intraoperative MMC,

administered locally for 3 to 5 minutes, varies from 0.002% to 0.04%. The concentration of postoperative MMC eyedrops, administered 2–4 times a day, varies from 0.02% to 0.04%. It is important to note that any use of topical MMC can be toxic and may cause visually significant complications such as aseptic scleral necrosis and infectious sclerokeratitis. These complications may occur months, or even years, after use of the drug. If surgery is being performed in a case of recurrent pterygium and MMC use is being considered, it is safer to apply this agent intraoperatively than to give it to the patient for postoperative topical application; in the latter case, overuse may be a problem.

Postoperatively, topical antibiotic–corticosteroid eyedrops are administered frequently for approximately 4–6 weeks, until inflammation subsides. The surgeon should emphasize to the patient that adherence to this regimen will minimize the chance of recurrence.

The use of bevacizumab in primary pterygium excision apparently has no effect on the recurrence rate of this condition.

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Complications

Self-limited problems include conjunctival graft edema, corneoscleral dellen, and epithelial cysts. Pyogenic granuloma due to incomplete removal of subconjunctival fibrovascular tissue may also occur, as well as chronic nonhealing wounds. Cases of recurrent pterygium after conjunctival autografting may be substantially improved by a second autologous conjunctival transplantation, modified limbal autografting, or lamellar keratoplasty. Diplopia resulting from severe scarring