amerihealth
Advanced Search

Aqueous Shunts, Microstents, Viscocanalostomy, and Canaloplasty for the Treatment of Glaucoma
MA11.105j

Policy

When services can be administered in various settings, the Company reserves the right to reimburse only those services that are furnished in the most appropriate and cost-effective setting that is appropriate to the member’s medical needs and condition. This decision is based on the member’s current medical condition and any required monitoring or additional services that may coincide with the delivery of this service.

AQUEOUS SHUNTS

MEDICALLY NECESSARY
Ab externo aqueous shunts, approved by the US Food and Drug Administration (FDA) (e.g., Ahmed, Baerveldt, Molteno, Ex-Press Mini Glaucoma Shunt), are considered medically necessary and, therefore, covered for the reduction of elevated intraocular pressure (IOP) in adult individuals diagnosed with glaucoma when medical therapy has failed to adequately control IOP.

Aqueous shunts, approved by the FDA and inserted with an external approach, are medically necessary and, therefore, covered when primary goniotomy or trabeculectomy have failed to adequately reduce IOP to an acceptable level (e.g., <21 mm Hg) in individuals with congenital or pediatric glaucoma.

EXPERIMENTAL/INVESTIGATIONAL
The use of an ab externo aqueous shunt for all other conditions, including individuals with glaucoma when the IOP is controlled by medication, is considered experimental/investigational and, therefore, not covered because the available published peer-reviewed literature does not support their use in the treatment of illness or injury.

The use of more than one ab externo aqueous shunt is considered experimental/investigational and, therefore, not covered, because the safety and/or effectiveness of this service cannot be established by review of the available published peer-reviewed literature.

AQUEOUS STENTS

MEDICALLY NECESSARY
Ab interno aqueous stents, approved by the FDA (e.g., XEN Glaucoma Treatment System), are considered medically necessary and, therefore, covered as a method to reduce IOP in adult individuals diagnosed with glaucoma when medical therapy has failed to adequately control IOP.

Implantation of one or two FDA-approved ab interno stents per eye (e.g., iStent, iStent inject, XEN Glaucoma Treatment System, Hydrus Microstent) in conjunction with cataract surgery is considered medically necessary and, therefore, covered for the reduction of elevated IOP in adult individuals with mild-to-moderate open-angle glaucoma currently treated with ocular hypotensive medication.

EXPERIMENTAL/INVESTIGATIONAL
The use of an ab interno aqueous stent for all other conditions, including individuals with glaucoma when the IOP is controlled by medication, is considered experimental/investigational and, therefore, not covered because the available published peer-reviewed literature does not support their use in the treatment of illness or injury.

The use of more than two ab interno stents per eye is considered experimental/investigational and, therefore, not covered, because the safety and/or effectiveness of this service cannot be established by review of the available published peer-reviewed literature.

CANALOPLASTY FOR THE TREATMENT OF GLAUCOMA

MEDICALLY NECESSARY
Canaloplasty is considered medically necessary and, therefore, covered as a method to reduce IOP in individuals with chronic primary open-angle glaucoma when all of the following criteria are met:
  • Medical therapy (e.g., topical and/or oral medications, laser therapy) has failed to adequately control IOP (e.g., >20 mm Hg) for at least 2 months.
  • The individual is not a candidate for any other IOP-lowering procedure (e.g., trabeculectomy or glaucoma drainage implant) due to a high risk for complications.
EXPERIMENTAL/INVESTIGATIONAL
All other uses for canaloplasty, including angle-closure glaucoma, are considered experimental/investigational and, therefore, not covered because their safety and/or effectiveness cannot be established by review of the available published peer-reviewed literature.

VISCOCANALOSTOMY FOR THE TREATMENT OF GLAUCOMA

Viscocanalostomy is considered experimental/investigational and, therefore, not covered because the safety and/or efficacy of this service cannot be established by the available published peer-reviewed literature.

REQUIRED DOCUMENTATION

The individual's medical record must reflect the medical necessity for the care provided. These medical records may include, but are not limited to: records from the professional provider's office, hospital, nursing home, home health agencies, therapies, and test reports.

The Company may conduct reviews and audits of services to our members, regardless of the participation status of the provider. All documentation is to be available to the Company upon request. Failure to produce the requested information may result in a denial for the service.

BILLING REQUIREMENTS

Claims submitted for implantation of ab interno stents (CPT codes 66989, 66991, or 0474T) when used in conjunction with cataract surgery must include:
  • A diagnosis code listed in Attachment A for cataract AND a diagnosis code for mild-to-moderate open-angle glaucoma

Guidelines

DEFINITION FOR MILD AND MODERATE GLAUCOMA DAMAGE (SUPPORTED BY RELEVANT PEER-REVIEWED LITERATURE, MEDICAL SOCIETIES, AND CLINICAL INPUT):

MILD DAMAGE
  • One or more of the following in the worst eye:
    • Intraocular pressure >20 mm Hg
    • Symmetric or vertically elongated cup enlargement, neural rim intact, cup/disc ratio >0.4
    • Focal optic disc notch
    • Optic disc hemorrhage or history of optic disc hemorrhage
    • Nasal step or small paracentral or arcuate scotoma
    • Mild constriction of visual field isopters
MODERATE DAMAGE
  • One or more of the following in the worst eye:
    • Enlarged optic cup with neural rim remaining but sloped or pale, cup/disc ratio >0.5 but <0.9
    • Definite focal notch with thinning of the neural rim
    • Definite glaucoma visual field defect (arcuate/paracentral scotoma), nasal step, pencil wedge, constriction of isopters
CONTRAINDICATIONS

The iStent inject Trabecular Micro-Bypass Stent is contraindicated for individuals under the following circumstances or conditions:
  • In eyes with angle closure glaucoma
  • In eyes with traumatic, malignant, uveitic, or neovascular glaucoma or discernible congenital anomalies of the anterior chamber (AC) angle
  • In patients with retrobulbar tumor, thyroid eye disease, Sturge-Weber syndrome or any other type of condition that may cause elevated episcleral venous pressure
This policy is consistent with Medicare's coverage determination. The Company's reimbursement methodology may differ from Medicare.

BENEFIT APPLICATION

Subject to the terms and conditions of the applicable Evidence of Coverage, ab externo aqueous shunt devices are covered under the medical benefits of the Company’s Medicare Advantage products when the medical necessity criteria listed in this medical policy are met.

Subject to the terms and conditions of the applicable Evidence of Coverage, ab interno stents are covered under the medical benefits of the Company’s Medicare Advantage products when the medical necessity criteria listed in this medical policy are met.

Subject to the terms and conditions of the applicable Evidence of Coverage, canaloplasty is covered under the medical benefits of the Company’s Medicare Advantage products when the medical necessity criteria listed in this medical policy are met.

Subject to the terms and conditions of the applicable Evidence of Coverage, viscocanalostomy is not eligible for payment under the medical benefits of the Company’s Medicare Advantage products because the service is considered experimental/investigational and, therefore, not covered.

Services that are experimental/investigational are excluded for the Company’s Medicare Advantage products. Therefore, they are not eligible for reimbursement consideration.

Description

Intraocular pressure (IOP) is the fluid pressure inside the eye and is measured by the use of a tonometer during an eye examination. In the general population, normal IOP is between 10 mm Hg and 20 mm Hg, with an average value of IOP at 15.5 mm Hg, with fluctuations of about 2.75 mm Hg.

Glaucoma is a disorder that causes damage to the optic nerve of the eye, which carries visual information to the brain. Most cases of glaucoma are caused by increased IOP due to poor filtration of aqueous humor, a clear, watery fluid that flows between and nourishes the lens and the cornea. Because of this increased IOP and/or loss of blood flow to the optic nerve, the nerve fibers of the optic disc begin to die. This causes the center portion of the optic disc, known as the "cup," to become larger in comparison to the optic disc. Individuals with glaucoma tend to have a greater cup-to-disc ratio. Undetected glaucoma leads to permanent optic nerve damage, with resulting visual field loss, which will progress to blindness. Once lost, this damaged visual field cannot be recovered. The World Health Organization (WHO) reports that glaucoma is the second leading cause of blindness after cataracts. Additionally, the National Eye Institute indicates that glaucoma is the leading cause of blindness among African-Americans.

The two main types of glaucoma are open-angle and closed-angle. Open-angle glaucoma (OAG), which accounts for most of the US glaucoma cases, is chronic and tends to progress slowly; the individual may not even notice the loss of vision until there has been significant disease progression. It is caused by the slow clogging of the drainage canals, resulting in increased IOP. Closed-angle glaucoma typically appears suddenly, is very painful, and visual loss can progress quickly; however, the discomfort associated with closed-angle glaucoma usually will prompt an individual to seek medical attention before permanent damage can occur. It is caused by blocked drainage canals, which result in a sudden rise in IOP.

GLAUCOMA IN ADULTS

In the treatment of OAG, the goal is to reduce the risk of damage to the optic nerve by keeping IOP from rising above a certain target pressure level. The target pressure is based on the degree of optic nerve damage, the amount of visual field loss and, to a lesser degree, the initial pressure in the eye and how widely it varies each time it is measured. This pressure will vary from person to person. The ability to maintain the target pressure may help slow the progression of glaucoma by reducing the risk of optic nerve damage. Laser procedures, such as laser trabeculoplasty, can be used in most types of OAG, and laser peripheral iridectomy can often lower pressure in chronic and acute-angle glaucoma. When medication or laser treatment, if indicated, are not effective in reducing the IOP, guarded filtration surgery (e.g., trabeculectomy) may be indicated. Trabeculectomy, the most established glaucoma surgery procedure, allows aqueous humor drainage from within the eye to underneath the conjunctiva, where it is absorbed. However, trabeculectomy can result in the development of filtering blebs on the eye (a vesicular outpocketing of the scleral membrane), and is associated with numerous complications (e.g., leaks or bleb-related endophthalmitis) and long-term failure of IOP reduction. Other surgical interventions for glaucoma may include aqueous shunting, minimally invasive glaucoma surgeries (MIGS), canaloplasty or viscocanalostomy.

GLAUCOMA IN CHILDREN

Glaucoma in infants and children, while unusual, is a significant cause of blindness and includes congenital and pediatric glaucoma. Primary congenital glaucoma results from abnormal development of the ocular drainage system and occurs in about one of 10,000 births in the United States. It is the most common form of glaucoma in infants. About 10% of congenital glaucoma is present at birth, with most of the remaining congenital glaucoma diagnosed before 1 year of age. Secondary glaucoma results from other disorders of the body or the eye and may or may not be genetic. Both primary and secondary glaucoma can be associated with other medical conditions or syndromes.

Pediatric glaucoma typically presents when the child is in the primary grades and is frequently discovered at the time of school vision screening. The presentation is not acute, and the child may appear quite comfortable despite a very high IOP at the time of diagnosis. The term "pediatric glaucoma" is not limited to a singular cause of an increased IOP, as there are several angle closure variants in pediatric glaucoma, as well as secondary causes, including inflammation and trauma. Moreover, one variant, called juvenile OAG, believed to be inherited from one parent, presents from age 7 up to age 30, and can create diagnostic confusion with adult glaucoma.

For glaucoma occurring within the first few years of life, initial surgical therapy is generally more effective than medical treatment, which is utilized as a temporizing measure. Angle surgery (either goniotomy, if trabecular meshwork is visible, or trabeculotomy ab externa, if the cornea is not clear and angle structures cannot be clearly seen) is the initial procedure indicated. As noted in Current Opinion in Ophthalmology, trabeculectomy and goniotomy have success rates of 75% to 90%; however, within a few years, 20% will fail to maintain IOP at an acceptable level. Thus, if angle incision operations fail to provide adequate control of IOP, filtering surgery (involving trabeculectomy with an antifibrotic agent or implantation of a drainage device) is justified. Cyclodestructive procedures (i.e., contact and noncontact transcleral cyclophotocoagulation, endoscopic ciliary ablation) are indicated when all other methods have failed or when vision is extremely poor.

AQUEOUS SHUNTS AND STENTS

In addition to laser trabeculoplasty and trabeculectomy, aqueous shunts and stents can be implanted to increase the outflow of fluid and reduce the IOP via procedures performed outside the eye (ab externo) or inside the eye (ab interno).

AB EXTERNO AQUEOUS SHUNTS
Insertion of shunts from outside the eye (ab externo) is another surgical option to lower IOP. Aqueous shunts are placed in the anterior or posterior chamber to facilitate drainage of aqueous humor between the anterior chamber and the suprachoroidal space. Examples of ab externo devices cleared by the FDA include the Ahmed, Baerveldt, Molteno, and Ex-Press Mini-Shunt. These devices differ by explant surface areas, shape, plate thickness, presence or absence of a valve, and details of surgical installation. The primary indication for aqueous shunts is for failed medical or surgical therapy, although some ophthalmologists have advocated their use as a primary surgical intervention, particularly for selected conditions such as congenital glaucoma, trauma, chemical burn, or pemphigoid.

For individuals who have refractory OAG who receive ab externo aqueous shunts, the evidence includes randomized controlled trials (RCTs), retrospective studies, and systemic reviews. Relevant outcomes are change in disease status, functional outcomes, medication use, and treatment-related morbidity. RCTs assessing FDA-approved shunts have shown that the use of large externally placed shunts reduces IOP to slightly less than standard filtering surgery (trabeculectomy). Reported shunt success rates show that these devices are noninferior to trabeculectomy in the long term. FDA-approved shunts have different adverse event profiles and avoid some of the most problematic complications of trabeculectomy. Two trials have compared the Ahmed and Baerveldt shunts. Both found that eyes treated with the Baerveldt shunt had slightly lower average IOP at 5 years than eyes treated with the Ahmed, but the Baerveldt also had a higher rate of serious hypotony-related complications. The evidence is sufficient to determine that the technology results in a meaningful improvement in the net health outcome.

AB INTERNO AQUEOUS STENTS
For individuals who have refractory OAG who receive ab interno aqueous stents, the evidence includes a nonrandomized retrospective comparative study and several single-arm studies. Relevant outcomes are change in disease status, functional outcomes, medication use, and treatment-related morbidity. The comparative study reported that individuals receiving the stent experienced similar reductions in IOP and medication use as individuals undergoing trabeculectomy. The single-arm studies, with 12-month follow-up results, consistently showed that individuals receiving the stents experienced reductions in IOP and medication use. Reductions in IOP ranged from 4 mm Hg to over 15 mm Hg. In addition, the FDA has given clearance to the XEN gel stent based on equivalent IOP and medication use reductions as seen with ab externo shunts. Clearance for the stent was based on a review in which the FDA concluded that while there were technical differences between the stent and predicate devices (shunts), the differences did not affect safety and effectiveness in lowering IOP and medication use. The evidence is sufficient to determine that the technology results in a meaningful improvement in the net health outcome.

MINIMALLY INVASIVE GLAUCOMA SURGERIES

MIGS are alternative, less invasive techniques that are being developed and evaluated. The objective of MIGS is to lower IOP by improving outflow of eye fluid; however, MIGS, which use microscopic-sized equipment and smaller incisions, involves less surgical manipulation of the sclera and the conjunctiva compared with other surgical techniques. There are several categories of MIGS, such as miniaturized trabeculectomy, trabecular bypass, milder laser photocoagulation, and totally internal or suprachoroidal stents (ab interno).

Examples of ab interno devices either approved or given marketing clearance by the FDA include the iStent, which is a 1-mm long stent inserted into the end of the Schlemm canal through the cornea and anterior chamber; the CyPass suprachoroidal stent; and XEN gelatin stent. It has been proposed that stents such as the iStent, CyPass, and Hydrus Microstent may be useful in individuals with early-stage glaucoma to reduce the burden of medications and problems with compliance. One area of investigation is individuals with glaucoma who require cataract surgery. An advantage of ab interno stents is that they may be inserted into the same incision and at the same time as cataract surgery. Also, most devices do not preclude subsequent trabeculectomy if needed. It may also be possible to insert more than one stent to achieve desired IOP. Therefore, health outcomes of interest are the IOP achieved, reduction in medication use, ability to convert to trabeculectomy, complications, and device durability.

AQUEOUS MICROSTENTS WITH CATARACT SURGERY
Several stents have the FDA approval for use in conjunction with cataract surgery. The iStent inject device is preloaded with two stents. An additional stent, the CyPass, had FDA approval but was voluntarily recalled by the manufacturer in 2018, as follow-up data had shown significant endothelial cell loss among individuals receiving the CyPass in conjunction with cataract surgery compared with individuals receiving cataract surgery alone.

Aqueous microstents (minimally invasive glaucoma surgical devices) drain aqueous humor from the anterior chamber into the Schlemm canal, the suprachoroidal or subconjunctival space. For individuals who have mild-to-moderate OAG who receive aqueous microstents during cataract surgery, the evidence includes RCTs. Relevant outcomes are change in disease status, functional outcomes, medication use, and treatment-related morbidity. Implantation of one or two microstents has received FDA approval for use in conjunction with cataract surgery for reduction of IOP in adults with mild-to-moderate OAG currently treated with ocular hypotensive medication. RCTs have been conducted in individuals with cataracts and less advanced glaucoma, where IOP is at least partially controlled with medication. Study results have shown that IOP may be lowered below baseline with decreased need for medication through the first 2 years. The evidence is sufficient to determine that the technology results in a meaningful improvement in the net health outcome.

AQUEOUS SHUNTS OR MICROSTENTS FOR GLAUCOMA TREATMENT OTHER THAN CATARACT SURGERY OR REFRACTORY OPEN-ANGLE GLAUCOMA

For individuals with indications for glaucoma treatment other than cataract surgery or refractory OAG who are treated with aqueous shunts or microstents, the evidence includes an RCT and an observational study. Relevant outcomes are change in disease status, functional outcomes, medication use, and treatment-related morbidity. Several RCTs have evaluated the use of multiple microstents, but comparators differed. One RCT compared a single microstent with multiple microstents. This study reported no difference on the primary outcome (percentage of individuals with ≥20% reduction in IOP); secondary outcomes favored the multiple microstent groups. An observational study described implantation of two or three stents, at the discretion of the operating surgeon. The evidence is insufficient to determine the effects of the technology on health outcomes.

CANALOPLASTY

Canaloplasty is a surgical procedure that involves dilation and tension of Schlemm’s canal with a suture loop between the inner wall of the canal and the trabecular meshwork. This ab externo procedure accesses and dilates the entire length of Schlemm’s canal to pass the suture loop through the canal.

In 2017, the National Institute for Health and Care Excellence (NICE) updated its 2008 guidance on canaloplasty for primary OAG (POAG). The current recommendation is that the “evidence on the safety and efficacy of ab externo canaloplasty for primary open-angle glaucoma is adequate is support the use of this procedure.…”

In a prospective study, Grieshaber et al. (2010) examined the safety and efficacy of canaloplasty (360º viscocanalostomy) in 60 individuals with POAG. Individuals were followed for a mean of 30.6 ± 8.4 months. The mean preoperative IOP was 45.0 ± 12.1 mm Hg. The mean IOP at 12 months was 15.4 ± 5.2 mm Hg (n=54), 16.3 ± 4.2 mm Hg (n=51) at 12 months, and 13.3 ± 1.7 mm Hg (n=49) at 36 months; 77.5% of individuals had an IOP ≤21 mm Hg. Cox regression analysis showed that preoperative IOP (HR=1.003; 95% confidence interval [CI], 0.927–1.085; P=0.94), age (HR=1.000, CI, 0.938–1.067; P=0.98), and sex (HR=3.005; CI, 0.329–27.448; P=0.33) were all not significant predictors of IOP reduction to ≤21 mm Hg. Complications included Descemet’s detachment (n=2), elevated IOP (n=1), and false passage of the catheter (n=2), though the overall complication rate was low. The authors concluded that canaloplasty resulted in a sustained reduction of IOP in individuals with POAG, independent of preoperative IOP. Limitations of the study include its small sample size and short-term follow-up period.

In a multicenter prospective study, Bull et al. (2011) evaluated the safety and efficacy of canaloplasty to treat individuals with OAG. The study included 109 adult individuals with historical IOPs of at least 21 mm Hg with or without medical therapy and preoperative IOPs of at least 16 mm Hg who underwent canaloplasty or combined cataract and canaloplasty surgery. Individuals with successful suturing were followed for 3 years. Primary outcome measures included postoperative IOP, glaucoma medication usage, and the number of adverse events. Individuals treated with canaloplasty had a mean baseline IOP of 23.0 ± 4.3 mm Hg and mean glaucoma medication usage of 1.9 ± 0.7 medications, which decreased to a mean IOP of 15.1 ± 3.1 mm Hg on 0.9 ± 0.9 medications at 3 years postoperatively. Individuals treated with combined cataract and canaloplasty surgery had a mean baseline IOP of 24.3 ± 6.0 mm Hg on 1.5 ± 1.2 medications, which decreased to a mean IOP of 13.8 ± 3.2 mm Hg on 0.5 ± 0.7 medications at 3 years. Postoperative IOP and medication use for all individuals significantly decreased from baseline (P<0.00001). Late postoperative complications included cataracts (19.1%) and transient IOP elevation (1.8%). The authors concluded that canaloplasty was a safe and effective procedure, demonstrating significant and sustained IOP reductions in adult individuals with OAG. Limitations of the study include its small sample size and heterogeneous patient group, short-term follow-up period, and patient loss to follow-up.

In a nonrandomized, retrospective study, Ayyala et al. (2011) compared the operative outcomes of individuals after canaloplasty (n=33) and trabeculectomy (n=46). Individuals were followed up for 12 months. Outcome measurements included changes in IOP and the number of postoperative medications used. Failure was defined as IOP greater than 18 mm Hg or less than 4 mm Hg at 1-year follow-up or the need for a subsequent operative procedure. The mean percent reduction in IOP was not significantly different between the groups, reducing 32% for the canaloplasty group compared with 43% for the trabeculectomy group at 1-year follow-up (P=0.072). The median reduction in the number of medications needed was 2 in the canaloplasty group and 3 in the trabeculectomy group at 1-year follow-up. A higher percentage of individuals treated with canaloplasty than trabeculectomy (36% vs. 20%) required postoperative medications, although this was not statistically significant. Failure based on IOP was 12.1% (n=4) for the canaloplasty group and 4.3% (n=2) for the trabeculectomy group. There was no statistically significant difference in failure rates between the two groups. The authors concluded that both canaloplasty and trabeculectomy achieved significant reduction in IOP at 12 months. The study is limited in its small sample size and short-term follow-up period.

In a multicenter prospective study, Lewis et al. (2011) evaluated the safety and efficacy of canaloplasty to treat individuals with OAG. The study included 157 adult eyes with historical IOPs of at least 21 mm Hg with or without medical therapy and preoperative IOPs of at least 16 mm Hg who underwent canaloplasty or combined cataract and canaloplasty surgery. Individuals were followed up for 3 years. Primary outcome measures included postoperative IOP, glaucoma medication usage, and the number of adverse events. At 3-year follow-up, all study eyes had a mean IOP of 15.2 ± 3.5 mm Hg and mean glaucoma medication use of 0.8 ± 0.9 compared with a baseline preoperative mean IOP of 23.8 ± 5.0 mm Hg on 1.8 ± 0.9 medications. Eyes with combined cataract and canaloplasty surgery had a mean IOP of 13.6 ± 3.6 mm Hg on 0.3 ± 0.5 medications compared with a baseline mean IOP of 23.5 ± 5.2 mm Hg on 1.5 ± 1.0 medications. IOP and medication use were significantly decreased from baseline at every follow-up period (P<0.001). Late postoperative complications included cataract (12.7%), transient IOP elevation (6.4%), and partial suture extrusion through the trabecular meshwork (0.6%). The authors concluded that canaloplasty was a safe and effective procedure, leading to significant and sustained IOP reduction in adult individuals with OAG. Limitations of the study include its small sample size and heterogeneous patient group, short-term follow-up period, and loss to follow-up.

In a review, Grieschaber (2012) indicated that canaloplasty is a valuable alternative to glaucoma filtration surgery as it targets the abnormally high resistance to outflow in the trabecular meshwork and re-establishes the physiologic outflow system. IOP reduction to the lower teens can be expected and the majority of complications seen in filtering surgery are largely eliminated by the nonpenetrating and bleb-independent approach. Moreover, postoperative care is minimal and contributes to a high safety profile as bleb management is required and hypotony-related complications are largely avoided.

Three-year follow-up from an independent series of 214 individuals treated with canaloplasty in Europe was reported by Brusini (2014). Mean IOP was reduced from 29.4 mm Hg at baseline to 17.0 mm Hg, after excluding 17 (7.9%) individuals who later underwent trabeculectomy. At 3 years, IOP was 21 mm Hg or lower in 86.2% of individuals, 18 mm Hg or lower in 58.6%, and 16 mm Hg or lower in 37.9%. There was a decrease in mean medication use, from 3.3 at baseline to 1.3 at follow-up. Complications, which included hyphema, Descemet membrane detachment, IOP spikes, and hypotony, were fewer than typically seen with trabeculectomy. Several disadvantages of the procedure were noted, including the inability to complete the procedure in 16.4% of eyes.

Voykov et al (2015) reported on 5-year follow-up on individuals (20 eyes) with OAG who underwent canaloplasty at a single center in Germany. Mean IOP decreased from 25.7 mm Hg at baseline (n=33) to 15.5 mm Hg (n=19) at 1 year, 15.1 mm Hg (n=18) at 3 years, and 14.2 mm Hg (n=18) at 5 years. At each time point, reductions in mean IOP were statistically significant versus baseline (P<0.001). Mean number of medications used was 3.4 at baseline, 1.5 at 1 year, 1.6 at 3 years, and 1.7 at 5 years. At each time point, medication use was significantly lower than baseline (P<0.001). Thirteen (65%) of 20 eyes underwent another surgical procedure due to inadequate IOP control. Median length of time before additional surgery was 24 months (95% CI, 1–51 months). The complication rate was low, with the most common being hyphema (7/20 [35%] eyes). No sight-threatening complications were reported.

In a prospective, randomized clinical trial, Matlach et al. (2015) evaluated the comparability of canaloplasty to the gold standard, trabeculectomy, in the treatment of OAG. Sixty-two individuals were randomly assigned to receive either trabeculectomy (n=32) or canaloplasty (n=30) and were followed-up for 2 years. Primary outcome measures included complete (without medication) and qualified (with or without medication) success defined as an IOP of less than or equal to 18 mm Hg for a complete success and an IOP less than or equal to 21 mm Hg and greater than or equal to 20% IOP reduction for a qualified success. Any success also required no vision loss and no further glaucoma surgery. IOP was reduced in both groups after 2 years of follow-up (P<0.001). Complete success was achieved in 74.2% and 39.1% (P=0.01) and qualified success was achieved in 67.7% and 39.1% (P=0.04) of the trabeculectomy and canaloplasty groups, respectively. Mean IOP reduction was 10.8 ± 6.9 mm Hg and 9.3 ± 5.7 mm Hg, and mean IOP was 11.5 + 3.4 mm Hg and 14.4 + 4.2 mm Hg in the trabeculectomy and canaloplasty groups, respectively. The trabeculectomy group experienced a more frequent rate of complications including late hypotony (18.8%), choroidal detachment (12.5%), and elevated IOP (25.0%); however, these rates were not found to be significantly more frequent than the rates that occurred in the canaloplasty group. The authors concluded that while trabeculectomy is associated with larger rates of complete and qualified success, there may be a greater risk of complications. The authors also noted that canaloplasty may be an appropriate treatment for OAG in those individuals for whom only a moderate IOP reduction is required.

In summary, the available peer-reviewed literature and recommendations from medical guidelines indicate that in individuals diagnosed with POAG, canaloplasty provides successful outcomes, particularly in individuals in whom previous medical therapy has failed. Recent studies provide mid-term results (e.g., up to 3 years) that suggest canaloplasty provides modest IOP reductions with minimal intraoperative or postoperative complications.

VISCOCANALOSTOMY

Viscocanalostomy is a variant of deep sclerectomy and is an ab externo procedure that unroofs and dilates Schlemm's canal without penetrating the trabecular meshwork or anterior chamber. A high-viscosity viscoelastic solution, such as sodium hyaluronate, is used to open the canal and create a passage from the canal to a scleral reservoir. Viscocanalostomy has been performed in conjunction with cataract removal. An important difference between viscocanalostomy and canaloplasty is that viscocanalostomy attempts to open just one section of Schlemm’s canal, whereas canaloplasty attempts to open the entire length of Schlemm’s canal. While viscocanalostomy is able to open just 120º of Schlemm’s canal, limiting its efficacy and enhancing the procedure’s potential failure, canaloplasty uses a 360º tensioning suture, which attempts to maintain increased permeability of the inner wall region, increase outflow facility, and reduce the risk of re-collapse.

According to the Preferred Practice Guidelines published by the American Academy of Ophthalmology (AAO) in 2010, viscocanalostomy is a nonpenetrating type of glaucoma surgery. The rationale for nonpenetrating glaucoma surgery is that by avoiding a continuous passageway from the anterior chamber to the subconjunctival space, the incidence of complications such as bleb-related problems and hypotony can be reduced. However, according to the AAO, “randomized clinical trials comparing viscocanalostomy with trabeculectomy generally suggest greater IOP reduction with trabeculectomy, but more complications with viscocanalostomy.”

In a prospective RCT, Yalvac et al. (2004) compared the safety and efficacy of viscocanalostomy and trabeculectomy in individuals with POAG. Individuals were randomly assigned to have viscocanalostomy (n=25) or trabeculectomy (n=25). Individuals were followed for 3 years. Outcome measurements included postoperative IOP and the number of postoperative complications. Successful outcomes were defined as qualified (IOP between 6 and 21 mm Hg with medication) or complete (IOP between 6 and 21 mm Hg without medication). At 3-year follow-up, the mean IOP was 16.0 ± 7.07 mm Hg in the trabeculectomy group and 17.8 ± 4.6 mm Hg in the viscocanalostomy group. Complete success was achieved in 66.2% of eyes at 6 months and 55.1% at 3 years in the trabeculectomy group and in 52.9% and 35.3%, respectively, in the viscocanalostomy group. Qualified success was achieved in 95.8% of eyes at 6 months and 79.2% at 3 years in the trabeculectomy group and in 90.7% and 73.9%, respectively, in the viscocanalostomy group. There were no statistically significant differences between the two groups with either outcome measurement. Postoperative hypotony and cataract formation occurred more frequently in the trabeculectomy group than in the viscocanalostomy group (P=0.002). The authors concluded that in individuals with POAG, trabeculectomy resulted in a greater IOP reduction than with viscocanalostomy. The study is limited in its small sample size and short-term follow-up period.

In a noncomparative, prospective study, Stangos et al. (2007) evaluated the safety and efficacy of combined viscocanalostomy and phacoemulsification (cataract) surgery to treat 50 eyes of 50 individuals with medically uncontrolled OAG and a concomitant age-related cataract. Individuals were followed up for a mean of 29.02 ± 7.09 months. Outcome measurements included IOP reduction greater than or equal to 30% compared to preoperative IOP and postoperative IOP less than 21 mm Hg with medications (qualified success), postoperative IOP less than 21 mm Hg without medications (complete success), and the number of adverse events. Mean preoperative IOP significantly decreased from 23.51 ± 4.48 mm Hg to 14.06 ± 1.64 mm Hg at the last follow-up (P<0.001). The overall success was 94% at 12 months, 92% at 24 months, and 82% at 36 months. Complete success was 74% at 12 months and 67% at 24 and 36 months. No serious complications were documented. The authors concluded that phacoviscocanalostomy can be considered a safe and effective alternative surgical treatment for individuals with medically uncontrolled OAG and a concomitant age-related cataract. The study is limited in its small sample size, short-term follow-up, and lack of a comparison group. The authors called for larger, randomized, comparative studies to provide stronger evidence for the safety and efficacy of phacoviscocanalostomy.

In a nonrandomized, prospective study, David et al. (2008) examined the success rates and complications associated with viscocanalostomy. Forty-six eyes of 46 individuals with medically uncontrolled primary and secondary OAG underwent viscocanalostomy. Individuals were followed up for a mean of 60 months. Outcome measurements included postoperative IOP less than 21 mm Hg with medications (qualified success), postoperative IOP less than 21 mm Hg without medications (complete success), and the number of adverse events. At 60 months, qualified success was achieved in 82% (n=37) of individuals and complete success was achieved in 54% (n=25). No sight-threatening complications were observed in these individuals. The authors concluded that viscocanalostomy appeared to be a safe and effective treatment in lowering IOP in eyes with POAG and certain types of secondary OAG. The study is limited in its small sample size, short-term follow-up period, and heterogeneity of the individual population.

In a prospective RCT, Gilmour et al. (2009) compared the safety and efficacy of viscocanalostomy with trabeculectomy in the management of POAG. Individuals were randomly assigned to have viscocanalostomy (n=25) or trabeculectomy (n=25). Individuals were followed up for a mean of 40 months (6–60 months). Outcome measurements included postoperative IOP and the number of postoperative complications. Postoperative IOP less than 18 mm Hg without treatment was deemed a successful outcome; 42% (n=10) of the individuals in the trabeculectomy group had a successful outcome at their last follow-up visit, compared to 21% (n=5) in the viscocanalostomy group. Mean IOP was lower in the trabeculectomy group when compared to the viscocanalostomy group, with differences being statistically significant at 12, 24, and 36 months (P<0.001), and at 48 months (P=0.018). The trabeculectomy group required less postoperative IOP medications (P=0.011) when compared to the viscocanalostomy group. The authors concluded that trabeculectomy was more effective at lowering IOP than viscocanalostomy in individuals with POAG. The study is limited in its small sample size and short-term follow-up period.

In a meta-analysis, Chai and Loon (2010) compared the efficacy and safety profile of viscocanalostomy when compared with trabeculectomy in medically uncontrolled glaucoma. Ten RCTs were selected and included in the analysis, with a total of 458 eyes in 397 individuals with medically uncontrolled glaucoma. Outcome measurements included mean IOP difference at 6 months, 12 months, and 24 months, mean difference in the number of postoperative medications, and relative risk of adverse events. Mean IOP difference was 2.25 mm Hg at 6 months (95% CI, 1.38–3.12), 3.64 mm Hg at 12 months (95% CI, 2.74–4.54), and 3.42 mm Hg at 24 months (95% CI, 1.80–5.03). Trabeculectomy was found to have a significantly better pressure-lowering outcome (P<0.00001). The relative risk of having an adverse event such as an intraoperative perforation of Descemet's membrane when having a viscocanalostomy was 7.72 times the risk when having a trabeculectomy (95% CI, 2.37–25.12). The trabeculectomy group did have a statistically significantly larger number of postoperative adverse events (P<0.008). The authors concluded that trabeculectomy had a greater pressure-lowering effect when compared with viscocanalostomy. However, viscocanalostomy had a significantly better risk profile. The study was limited in its short-term follow-up period and the heterogeneity of the patient populations as patients across the included studies had different types of medically uncontrolled glaucoma.

In a retrospective study, Kay et al. (2011) examined the outcomes in 39 eyes of 24 consecutive pediatric individuals with childhood glaucoma. Surgical success was defined as a postoperative IOP of less than 23 mm Hg with or without glaucoma medication and without further surgical intervention. The mean age at the time of surgery was 66 ± 66 months, with a mean preoperative IOP of 40.4 ± 10.2 mm Hg. Surgical success was achieved in 69% (n=27) of eyes with an average follow-up of 22 months. In individuals without history of previous surgery but with a diagnosis of congenital or juvenile glaucoma, surgical success was achieved in 89% (n=17) of eyes with an average follow-up of 20 months. There were no serious complications associated with the procedure. The authors concluded that viscocanalostomy appeared to be a safe and effective procedure to lower IOP in individuals with congenital or juvenile glaucoma. The study is limited in its small sample size, short-term follow-up period, and the heterogeneity of the patient population.

In a comparative case study, Eid and Tantawy (2011) compared combined viscocanalostomy-trabeculectomy to trabeculectomy alone for the management of advanced glaucoma. Eighteen individuals with bilateral advanced glaucoma underwent the combined procedure in the right eye and trabeculectomy alone in the left eye. Successful outcome measurements included postoperative IOP less than 14 mm Hg or greater than 30% lowering of IOP without devastating complications. At 1-week and 3-month follow-up, mean IOP was statistically significantly lower after the combined procedure with viscocanalostomy when compared to trabeculectomy alone. However, there was no significant difference at the final follow-up (9 months) and no significant difference in the number of glaucoma medicines used. There were more hypotony-related complications after trabeculectomy alone. Target IOP was achieved in 83.3% of the individuals who had the combined procedure compared to 55.6% of the individuals who had trabeculectomy alone. The authors concluded that combined viscocanalostomy and trabeculectomy was at least as effective as trabeculectomy alone in reducing IOP for individuals with advanced glaucoma. Individuals undergoing the combined procedure also had a better safety profile. The study is limited in its small sample size and short-term follow-up period. These results are also only generalizable to individuals with advanced glaucoma in both eyes.

In a retrospective study, Yu et al. (2012) evaluated the clinical effect of viscocanalostomy in 51 eyes of 42 individuals with primary congenital glaucoma. Outcome measurements included postoperative IOP, corneal diameter, cup-to-disc ratio, and adverse events. Individuals were followed 1 week, 1 month, 3 months, 6 months, and 12 months after surgery. The results revealed that postoperative IOP decreased from 38.57 ± 13.61 mm Hg preoperatively to 10.53 ± 3.91 mm Hg, 14.89 ± 5.26 mm Hg, 15.42 ± 5.11 mm Hg, 13.82 ± 3.46 mm Hg, and 13.16 ± 5.29 mm Hg, at each respective time point postoperatively 
(P< 0.001). The postoperative corneal diameter also had a statistically significant reduction (P=0.002). There was no statistically significant difference in cup-to-disc ratio, but there was a low number of adverse events. The authors concluded that viscocanalostomy improved outcomes in individuals with primary congenital glaucoma, resulting in higher success rates, lower postoperative mean IOP, and fewer complications. The study is limited in its lack of a comparative group, small sample size, and short-term follow-up period. These results are also only generalizable to individuals with primary congenital glaucoma.

In a comparative case study, Koerber (2012) evaluated the safety and efficacy of canaloplasty when compared with viscocanalostomy when performed in both eyes of individuals with bilateral OAG. Thirty eyes of 15 adult individuals with bilateral OAG had canaloplasty performed in one eye and viscocanalostomy performed in the contralateral eye. The requirement for preoperative IOP was at least 18 mm Hg with a historical IOP of at least 21 mm Hg. Primary outcome measures included IOP, glaucoma medication usage, and incidence of adverse events. Individuals were followed up for 18 months. Both the canaloplasty and viscocanalostomy groups showed statistically significant reductions in mean IOP (P<0.01) and the number of IOP medications (P<0.01) when compared to preoperative values. In the canaloplasty group, eyes had a mean IOP of 14.5 ± 2.6 mm Hg on 0.3 ± 0.5 medications at 18 months postoperatively when compared to preoperative levels of 26.5 ± 2.7 mm Hg on 2.1 ± 1.0 medications. In the viscocanalostomy cohort, eyes had a mean IOP of 16.1 ± 3.9 mm Hg on 0.4 ± 0.5 medications at 18 months when compared to preoperative levels of 24.3 ± 2.8 mm Hg on 1.9 ± 0.8 medications (P=0.02). Significant complications were not reported in either group. The authors concluded that canaloplasty and viscocanalostomy were safe and effective in the surgical management of OAG, with canaloplasty demonstrating superior efficacy to viscocanalostomy in the reduction of IOP (P=0.02). This study design is unique in that each individual underwent both procedures for each respective eye. However, the study is limited in its small sample size and short-term follow-up period.

Stangos et al. (2012) reported the effect of the learning curve on the surgical outcome of viscocanalostomy from a retrospective series of 180 consecutive cases performed by two surgeons at a single center in Europe. Overall success (no visual field deterioration with an IOP ≤20 mm Hg) and IOP reduction of 30% or more compared with baseline values improved from 64% to 91% when comparing the first and the last 45 cases of the series. Complete success (no medications required) improved from 38% to 73%. Surgical complications did not differ significantly between the first and last 45 cases (16 vs 10, respectively).

A Cochrane review on the effectiveness of nonpenetrating trabecular surgery, specifically viscocanalostomy or deep sclerectomy, compared with conventional trabeculectomy in participants with OAG was published in 2014. Five randomized and quasirandomized controlled studies with a total of 311 eyes (247 participants) were included in the systematic review. There were 160 eyes that had trabeculectomy compared with 151 eyes that had nonpenetrating glaucoma surgery, of which 101 eyes had deep sclerectomy and 50 eyes had viscocanalostomy. The findings from this review suggest that trabeculectomy is better in terms of achieving total success (pressure controlled without eyedrops) than nonpenetrating filtering procedures. The analysis for the outcome of partial success (pressure controlled with additional eyedrops) was more imprecise, and the results could not exclude one surgical approach being better than the other. The authors concluded that the trials demonstrate the lack of use of quality of life outcomes and the need for higher methodological quality RCTs to address these issues.

Grieshaber et al. (2015) reported long-term results of viscocanalostomy in a series of 726 individual​s. Mean IOP before surgery was 42.6 mm Hg. Mean IOP was 15.4 mm Hg at 5 years, 15.5 mm Hg at 10 years, and 16.8 mm Hg at 15 years. Qualified success (with or without medications) at 10 years (≤ of 18 mm Hg) was 40% in the European population and 59% in the African population. Laser goniopuncture was performed postoperatively on 127 (17.7%) eyes. Fifty-three (7.3%) eyes were considered failures and required reoperation. There were no significant complications.

In summary, the available peer-reviewed literature and recommendations from medical guidelines indicate that the current evidence is insufficient for viscocanalostomy. There exist few high-level studies that compare viscocanalostomy with trabeculectomy. Meta-analysis of these trials indicates that trabeculectomy has a greater pressure-lowering effect than viscocanalostomy. Studies are limited in their short-term follow-up and heterogeneity in design and patient populations.

References


Agrawal PP, Bradshaw SS. Systematic Literature Review of Clinical and Economic Outcomes of Micro-Invasive Glaucoma Surgery (MIGS) in Primary Open-Angle Glaucoma. Ophthalmol Ther. 2018;7(1):49-73.​

Ahmed IIK, Fea A, Au L, et al. A Prospective Randomized Trial Comparing Hydrus and iStent Microinvasive Glaucoma Surgery Implants for Standalone Treatment of Open-Angle Glaucoma: The COMPARE Study. Ophthalmology. 2020;127(1):52-61.

Al Yousef Y, Strzalkowska A, Hillenkamp J, et al. Comparison of a second-generation trabecular bypass (iStent inject) to ab interno trabeculectomy (Trabectome) by exact matching. Graefes Arch Clin Exp Ophthalmol. 2020;258(12):2775-2780.

American Academy of Ophthalmology. EyeWiki™. Glaucoma Drainage Devices. Last modified 02/09/2024. Available at: http://eyewiki.aao.org/Glaucoma_Drainage_DevicesAccessed April 1, 2024.

American Glaucoma Society. Position statement on new glaucoma surgical procedures. [American Glaucoma Society Web site]. Original: 10/23/2009. (Revised: 02/29/2012). Available at: https://higherlogicdownload.s3.amazonaws.com/AMERICANGLAUCOMASOCIETY/4ca07187-fb0f-4dc3-a19c-33093862484d/UploadedImages/Documents/242_newglaucsurgproc_surgicaltrialspolicystatement_agsbodapproved02_29_12.pdf​. Accessed April 1, 2024.

Ayyala RS, Chaudhry AL, Okogbaa CB, et al. Comparison of surgical outcomes between canaloplasty and trabeculectomy at 12 months' follow-up. Ophthalmology. 2011;118(12):2427-2433.

Arriola-Villalobos P, Martínez-de-la-Casa JM, Díaz-Valle D, et al. Combined iStent® trabecular micro-bypass stent implantation and phacoemulsification for coexiStent® open-angle glaucoma and cataract: a long-term study. Br J Ophthalmol. 2012;96(5):645-649.

Bahler CK, Hann CR, Fjield T, et al. Second-generation trabecular meshwork bypass stent (iStent® inject) increases outflow facility in cultured human anterior segments. Am J Ophthalmol. 2012;153(6):1206-1213.

Belovay GW, Naqi A, Chan BJ, et al. Using multiple trabecular micro-bypass stents in cataract patients to treat open-angle glaucoma. J Cataract Refract Surg. 2012;38(11):1911-1917.

Berdahl J, Voskanyan L, Myers JS, et al. Implantation of two second-generation trabecular micro-bypass stents and topical travoprost in open-angle glaucoma not controlled on two preoperative medications: 18-month follow-up. Clin Exp Ophthalmol. 2017;45(8):797-802.

Berdahl J, Voskanyan L, Myers JS, et al. iStent inject trabecular micro-bypass stents with topical prostaglandin as standalone treatment for open-angle glaucoma: 4-year outcomes. Clin Exp Ophthalmol. 2020;48(6):767-774.

Bo W, Dai D, Sun F. Observation of curative effects of Ex-PRESS and AGV implantation in the treatment of refractory glaucoma. Exp Ther Med. 2018;15(5):4419-4425.

Boland MV, Ervin AM, Friedman D, et al. Treatment for glaucoma: comparative effectiveness. Comparative Effectiveness Review No. 60 (AHRQ Publication No. 12-EHC038-EF). Rockville, MD: Agency for Healthcare Research and Quality; 2012.

Brusini P. Canaloplasty in open-angle glaucoma surgery: a four-year follow-up. ScientificWorldJournal. 2014;2014:469609.

Buchacra O, Duch S, Milla E, et al. One-year analysis of the iStent® trabecular microbypass in secondary glaucoma. Clin Ophthalmol. 2011;5:321-326.

Budenz DL, Barton K, Gedde SJ, et al. Five-year treatment outcomes in the Ahmed Baerveldt comparison study. Ophthalmology. 2015;122(2):308-316.

Budenz DL, Feuer WJ, Barton K, et al. Postoperative complications in the Ahmed Baerveldt comparison study during five years of follow-up. Am J Ophthalmol. 2016;163:75-82 e73.

Bull H, von Wolff K, Korber N, et al. Three year canaloplasty outcomes for the treatment of open-angle glaucoma: European study results. Graefes Arch Clin Exp Ophthalmol. 2011;249(10):1537-1545.

Centers for Medicare & Medicaid Services (CMS). Medicare Benefit Policy Manual. Chapter 14: Medical devices. §20.2: Payment for items and services in category A and B IDE studies. [CMS Web site]. 11/06/14. Available at: https://www.cms.gov/Regulations-and-Guidance/Guidance/Manuals/downloads/bp102c14.pdf. Accessed April 1, 2024.

Chai C, Loon SC. Meta-analysis of viscocanalostomy versus trabeculectomy in uncontrolled glaucoma. J Glaucoma. 2010;19(8):519-527.

Chang DF, Donnenfeld ED, Katz LJ, et al. Efficacy of two trabecular micro-bypass stents combined with topical travoprost in open-angle glaucoma not controlled on two preoperative medications: 3-year follow-up. Clin Ophthalmol. 2017;11:523-528.

Christakis PG, Kalenak JW, Tsai JC, et al. The Ahmed versus Baerveldt study: five-year treatment outcomes. Ophthalmology. 2016;123(10):2093-2102.

Christakis PG, Tsai JC, Zurakowski D, et al. The Ahmed versus Baerveldt study: design, baseline patient characteristics, and intraoperative complications. Ophthalmology. 2011;118(11):2172-2179.

Christakis PG, Zhang D, Budenz DL, et al. Five-year pooled data analysis of the Ahmed Baerveldt comparison study and the Ahmed versus Baerveldt Study. Am J Ophthalmol. 2017;176:118-126.

Clement CI, Howes F, Ioannidis AS, et al. One-year outcomes following implantation of second-generation trabecular micro-bypass stents in conjunction with cataract surgery for various types of glaucoma or ocular hypertension: multicenter, multi-surgeon study. Clin Ophthalmol. 2019;13:491-499.

Craven ER, Katz LJ, Wells JM, et al. Cataract surgery with trabecular micro-bypass stent implantation in patients with mild-to-moderate open-angle glaucoma and cataract: Two-year follow-up. J Cataract Refract Surg. 2012;38(8):1339-1345.

Dahan E, Ben Simon GJ, Lafuma A. Comparison of trabeculectomy and Ex-PRESS implantation in fellow eyes of the same patient: a prospective, randomised study. Eye (Lond). 2012;26(5):703-710.

David VP, Kutty KG, Somasundaram N, et al. Five-year results of viscocanalostomy. Eur J Ophthalmol. 2008;18(3):417-422.

De Gregorio A, Pedrotti E, Russo L, et al. Minimally invasive combined glaucoma and cataract surgery: clinical results of the smallest ab interno gel stent. Int Ophthalmol. 2018;38(3):1129-1134.

de Jong L. The Ex-PRESS glaucoma shunt versus trabeculectomy in open-angle glaucoma: a prospective randomized study. Adv Ther. 2009;26(3);336-345.

de Jong L, Lafuma A, Aguade AS, et al. Five-year extension of a clinical trial comparing the EX-PRESS glaucoma filtration device and trabeculectomy in primary open-angle glaucoma. Clin Ophthalmol. 2011;5:527-533.

Dib Bustros Y, Fechtner R, Khouri AS. Outcomes of Ex-PRESS and trabeculectomy in a glaucoma population of african origin: one year results. J Curr Glaucoma Pract. 2017;11(2):42-47.

Dietlein TS, Jordan JF, Schild A, et al. Combined cataract-glaucoma surgery using the intracanalicular Eyepass glaucoma implant: first clinical results of a prospective pilot study. J Cataract Refract Surg. 2008;34(2):247-252.

Donnenfeld ED, Solomon KD, Voskanyan L, et al. A prospective 3-year follow-up trial of implantation of two trabecular microbypass stents in open-angle glaucoma. Clin Ophthalmol. 2015;9:2057-2065.

Ehlers JP, Shah CP. The Wills Eye Manual: Office and Emergency Room Diagnosis and Treatment of Eye Disease. 5th ed. Philadelphia: Wolters Kluwer/Lippincott Williams & Wilkins; 2008.

Eid TM, Tantawy WA. Combined viscocanalostomy – trabeculectomy for management of advanced glaucoma – a comparative study of the contralateral eye: a pilot study. Middle East Afr J Ophthalmol. 2011;18(4):292-297.

Eldaly MA, Bunce C, Elsheikha OZ, et al. Non-penetrating filtration surgery versus trabeculectomy for open-angle glaucoma. Cochrane Database Syst Rev. 2014;2:CD007059.

European Glaucoma Society. Terminology and Guidelines for Glaucoma. 4th ed. Savona, Italy: PubiComm;2014.

European Glaucoma Society Terminology and Guidelines for Glaucoma, 4th Edition - Chapter 3: Treatment principles and options Supported by the EGS Foundation: Part 1: Foreword; Introduction; Glossary; Chapter 3 Treatment principles and options. Br J Ophthalmol. 2017;101(6):130-195.

Fea AM. Phacoemulsification versus phacoemulsification with micro-bypass stent implantation in primary open-angle glaucoma: randomized double-masked clinical trial. J Cataract Refract Surg. 2010;36(3):407-412.

Fea AM, Ahmed, II, Lavia C, et al. Hydrus microstent compared to selective laser trabeculoplasty in primary open angle glaucoma: one year results. Clin Exp Ophthalmol. 2017;45(2):120-127.

Fea AM, Belda JI, Rekas M, et al. Prospective unmasked randomized evaluation of the iStent inject (®) versus two ocular hypotensive agents in patients with primary open-angle glaucoma. Clin Ophthalmol. 2014;8:875-882.

Fea AM, Consolandi G, Zola M, et al. Micro-bypass implantation for primary open-angle glaucoma combined with phacoemulsification: 4-year follow-up. J Ophthalmol. 2015;2015:795357.

Fellman RL, Mattox C, Singh K, et al. American Glaucoma Society Position Paper: Microinvasive Glaucoma Surgery. Ophthalmol Glaucoma. 2020;3(1):1-6.

Ferguson T, Swan R, Ibach M, et al. Evaluation of a trabecular microbypass stent with cataract extraction in severe primary open-angle glaucoma. J Glaucoma. 2018;27(1):71-76.

Fernández-Barrientos Y, García-Feijoó J, Martínez-de-la-Casa JM, et al. Fluorophotometric study of the effect of the glaukos trabecular microbypass stent on aqueous humor dynamics. Invest Ophthalmol Vis Sci. 2010;51(7):3327-3332.

Francis BA. IOP-lowering procedures for cataract surgeons: a look at both traditional and newer ideas in combination therapy. Ophthalmology Management. August 1, 2010. Available at: https://ophthalmologymanagement.com/issues/2010/august/iop-lowering-procedures-for-cataract-surgeons/. Accessed April 1, 2024.

Francis BA, Minckler D, Dustin L, et al. Combined cataract extraction and trabeculotomy by the internal approach for coexisting cataract and open-angle glaucoma: initial results. J Cataract Refract Surg. 2008;34(7):1096-1103.

Francis BA, Singh K, Lin SC, et al. Novel glaucoma procedures: a report by the American Academy of Ophthalmology. Opthalmology. 2011;118 (7):1466-1480.

Freedman J. What is new after 40 years of glaucoma implants. J Glaucoma. 2010;19(8):504-508.

Gabbay IE, Goldberg M, Allen F, et al. Efficacy and safety data for the Ab interno XEN45 gel stent implant at 3 Years: A retrospective analysis. Eur J Ophthalmol. 2021:11206721211014381.

Galal A, Bilgic A, Eltanamly R, et al. XEN glaucoma implant with mitomycin C 1-year follow-up: result and complications. J Ophthalmol. 2017;2017:5457246.

Gedde S, Schiffman J, Feuer W, et al. Three-year follow-up of the tube verses trabeculectomy study. Am J Ophthalmol. 2009;148(5):670-684.

Gedde S, Schiffman J, Feuer W, et al. Treatment outcomes in the tube versus trabeculectomy study after one year of follow-up. Am J Ophthalmol. 2007;143(1):9-22.

Gedde SJ, Schiffman JC, Feuer WJ, et al. Treatment outcomes in the tube versus trabeculectomy study after five years of follow-up. Am J Ophthalmol. 2012;153(5):789-803 e2.

Gilmour DF, Manners TD, Devonport H, et al. Viscocanalostomy versus trabeculectomy for primary open angle glaucoma: 4-year prospective randomized clinical trial. Eye (Lond). 2009;23(9):1802-1807.

Glaukos Corporation (GC). Glaukos Corporation iStent inject Trabecular Micro-Bypass System. Available at: https://www.accessdata.fda.gov/cdrh_docs/pdf17/P170043c.pdf. Accessed April 1, 2024.

Goldberg, Leslie Canaloplasty: A Promising New Extension to Non-Penetrating Surgery. Ophthalmology Management. 10(3), March 2006.

Gonnermann J, Bertelmann E, Pahlitzsch M, Maier-Wenzel AB, Torun N, Klamann MK. Contralateral eye comparison study in MICS & MIGS: Trabectome(R) vs. iStent inject(R). Graefes Arch Clin Exp Ophthalmol. 2017;255(2):359-365.

Gonzalez-Rodriguez JM, Trope GE, Drori-Wagschal L, et al. Comparison of trabeculectomy versus Ex-PRESS:3-year follow-up. Br J Ophthalmol. 2016;100(9):1269-1273.

Grieshaber MC. Ab externo Schlemm’s canal surgery: viscocanalostomy and canaloplasty. Dev Ophthalmol. 2012;50:109-24.

Grieshaber MC, Peckar C, Pienaar A, et al. Long-term results of up to 12 years of over 700 cases of viscocanalostomy for open-angle glaucoma. Acta Ophthalmol. 2015;93(4):362-367.

Grieshaber MC, Pienaar A, Olivier J, et al. Canaloplasty for primary open-angle glaucoma: long-term outcome. Br J Ophthalmol. 2010;94(11):1478-1482.

Grover DS, Flynn WJ, Bashford KP, et al. Performance and safety of a new ab interno gelatin stent in refractory glaucoma at 12 months. Am J Ophthalmol. 2017;183:25-36.

Guedes RAP, Gravina DM, Lake JC, et al. Intermediate Results of iStent or iStent inject Implantation Combined with Cataract Surgery in a Real-World Setting: A Longitudinal Retrospective Study. Ophthalmol Ther. 2019;8(1):87-100.

Healey PR, Clement CI, Kerr NM, et al. Standalone iStent Trabecular Micro-bypass Glaucoma Surgery: A Systematic Review and Meta-Analysis. J Glaucoma. 2021;30(7):606-620.

Hengerer FH, Auffarth GU, Riffel C, et al. Prospective, Non-randomized, 36-Month Study of Second-Generation Trabecular Micro-Bypass Stents with Phacoemulsification in Eyes with Various Types of Glaucoma. Ophthalmol Ther. 2018;7(2):405-415.

Hengerer FH, Kohnen T, Mueller M, et al. Ab interno gel implant for the treatment of glaucoma patients with or without prior glaucoma surgery: 1-year results. J Glaucoma. 2017;26(12):1130-1136.

Hooshmand J, Rothschild P, Allen P, et al. Minimally invasive glaucoma surgery: Comparison of iStent with iStent inject in primary open angle glaucoma. Clin Experiment Ophthalmol. 2019;47(7):898-903.

Jacobs DS. Open-angle glaucoma: Epidemiology, clinical presentation, and diagnosis. 09/19/2022. Up to Date. [UpToDate Web site]. Available at: http://www.uptodate.com/home/index.html. [via subscription only]. Accessed April 1, 2024.

Jacobs DS. Open angle glaucoma: Treatment. 01/29/2024. Up to Date.[UpToDate Web site]. Available at: http://www.uptodate.com/home/index.html. [via subscription only]. Accessed April 1, 2024.

Katz LJ, Erb C, Carceller Guillamet A, et al. Long-term titrated IOP control with one, two, or three trabecular micro-bypass stents in open-angle glaucoma subjects on topical hypotensive medication: 42-month outcomes. Clin Ophthalmol. 2018;12:255-262.

Katz LJ, Erb C, Carceller GA, et al. Prospective, randomized study of one, two, or three trabecular bypass stents in open-angle glaucoma subjects on topical hypotensive medication. Clin Ophthalmol. 2015;9:2313-2320.

Kay JS, Mitchell R, Miller J. Dilation and probing of Schlemm’s canal and viscocanalostomy in pediatric glaucoma. J Pediatr Ophthalmol Strabisus. 2011;48(1):30-37.

Klink T, Sauer J, Korber NJ, et al. Quality of life following glaucoma surgery: canaloplasty versus trabeculectomy. Clin Ophthalmol. 2015;9:7-16.

Kobayashi H, Kobayashi K, Okinami S. A comparison of the intraocular pressure-lowering effect and safety of viscocanalostomy and trabeculectomy with mitomycin C in bilateral open-angle glaucoma. Graefes Arch Clin Exp Ophthalmol. 2003;241(5):359-366.

Koerber NJ. Canaloplasty in one eye compared with viscocanalostomy in the contralateral eye in patients with bilateral open-angle glaucoma. J Glaucoma. 2012;21(2):129-134.

Konopinska J, Byszewska A, Saeed E, et al. Phacotrabeculectomy versus Phaco with Implantation of the Ex-PRESS Device: Surgical and Refractive Outcomes-A Randomized Controlled Trial. J Clin Med. 2021;10(3):424.

Kotecha A, Feuer WJ, Barton K, et al. Quality of Life in the Tube Versus Trabeculectomy Study. Am J Ophthalmol. 2017;176:228-235.

Kurji K, Rudnisky CJ, Rayat JS, et al. Phaco-trabectome versus phaco-iStent in patients with open-angle glaucoma. Can J Ophthalmol. 2017;52(1):99-106.

Le JT, Bicket AK, Wang L, et al. Ab interno trabecular bypass surgery with iStent for open-angle glaucoma. Cochrane Database Syst Rev. Mar 28 2019;3:CD012743.

Lewis RA, von Wolff K, Tetz M, et al. Canaloplasty: circumferential viscodilation and tensioning of Schlemm's canal using a flexible microcatheter for the treatment of open-angle glaucoma in adults: interim clinical study analysis. J Cataract Refract Surg. 2007;33(7):1217-1226.

Lewis RA, von Wolff K, Tetz M, et al. Canaloplasty: circumferential viscodilation and tensioning of Schlemm canal using a flexible microcatheter for the treatment of open-angle glaucoma in adults: two-year interim clinical study results. J Cataract Refract Surg. 2009;35(5):814-824.

Lewis RA, von Wolff K, Tetz M, et al. Canaloplasty: three-year results of circumferential viscodilation and tensioning of Schlemm canal using a microcatheter to treat open-angle glaucoma. J Cataract Refract Surg. 2011;37(4):682-690.

Lindstrom R, Sarkisian SR, Lewis R, et al. Four-Year Outcomes of Two Second-Generation Trabecular Micro-Bypass Stents in Patients with Open-Angle Glaucoma on One Medication. Clin Ophthalmol. 2020;14:71-80. 

Mandal AK, Chakrabarti D. Update on congenital glaucoma. Indian J Ophthalmol. 2011;59:S148-S157.

Mansouri K, Guidotti J, Rao HL, et al. Prospective evaluation of standalone XEN gel implant and combined phacoemulsification-XEN gel implant surgery: 1-year results. J Glaucoma. 2018;27(2):140-147.

Matlach J, Dhillon C, Hain J, et al. Trabeculectomy versus canaloplasty (TVC study) in the treatment of patients with open-angle glaucoma: a prospective randomized clinical trial. Acta Ophthalmol. 2015;93(8):753-761.

Mayo Clinic Staff. Glaucoma. [Mayo Clinic Web site]. Available at: https://www.mayoclinic.org/diseases-conditions/glaucoma/symptoms-causes/syc-20372839. Accessed April 1, 2024.

Minckler DS, Francis BA, Hodapp EA, et al. Aqueous shunts in glaucoma: a report by the American Academy of Ophthalmology. Ophthalmology. 2008;115(6):1089-1098.

Minckler DS, Mosaed S, Dustin L, et al. Trabectome (trabeculectomy-internal approach): additional experience and extended follow-up. Trans Am Ophthalmol Soc. 2008;106:149-159.

Minckler DS, Vedula SS, Li TJ, et al. Aqueous shunts for glaucoma. Cochrane Database Syst Rev. 2006;(2):CD004918.

Mosaed S, Dustin L, Minckler DS. Comparative outcomes between newer and older surgeries for glaucoma. Trans Am Ophthalmol Soc. 2009;107:127-133.

Myers JS, Masood I, Hornbeak DM, et al. Prospective evaluation of two iStent® Trabecular Stents, one iStent Supra® Suprachoroidal Stent, and postoperative prostaglandin in refractory glaucoma: 4-year outcomes. Adv Ther. 2018;35(3):395-407.

National Institute for Health and Clinical Excellence (NICE). Ab externo canaloplasty for primary open-angle glaucoma [IPG591]. [NICE Web site]. September 2017. Available at: https://www.nice.org.uk/guidance/ipg591. Accessed April 1, 2024.

National Institute for Health and Clinical Excellence (NICE). Glaucoma: diagnosis and management [NG81]. [NICE Web site]. January 2022. Available at: https://www.nice.org.uk/guidance/NG81. Accessed April 1, 2024.

National Institute for Health and Clinical Excellence (NICE). Microinvasive subconjunctival insertion of a trans-sceral gelatin stent for primary open-angle glaucoma. [IPG612]. [NICE Web site]. April 2018. Available at: https://www.nice.org.uk/guidance/ipg612/chapter/1-Recommendations. Accessed April 1, 2024.

National Institute for Health and Clinical Excellence (NICE). Trabecular stent bypass microsurgery for open-angle glaucoma [IPG575]. [NICE Web site]. February 2017. Available at: https://www.nice.org.uk/guidance/ipg575. Accessed April 1, 2024.

National Institute of Health (NIH). Healthy Vision --- Glaucoma. [National Eye Institute Web site]. Available at: http://www.nei.nih.gov/glaucoma. Accessed April 1, 2024.

Netland PA, Sarkisian SR, Jr., Moster MR, et al. Randomized, prospective, comparative trial of EX-PRESS glaucoma filtration device versus trabeculectomy (XVT study). Am J Ophthalmol. 2014;157(2):433-440.e3.

Novitas Solutions, Inc. Local Coverage Article (LCA): Micro-Invasive Glaucoma Surgery (MIGS) (A56633). [Novitas Solutions, Inc. Web site]. Revised: 10/07/2023​. Available at: https://www.cms.gov/medicare-coverage-database/view/article.aspx?articleId=56633&ver=47​. Accessed April 1, 2024.

Novitas Solutions, Inc. Local Coverage Determination (LCD): Micro-Invasive Glaucoma Surgery (MIGS) (L38223). [Novitas Solutions, Inc. Web site]. Revised: 12/30/2019. Available at: https://www.cms.gov/medicare-coverage-database/view/lcd.aspx?lcdId=38223&ver=19. Accessed April 1, 2024.

Olitsky SE. Primary infantile glaucoma. International Opthalmology Clin. 2010;50(4):57-66.

Omatsu S, Hirooka K, Nitta E, Ukegawa K. Changes in corneal endothelial cells after trabeculectomy and EX-PRESS shunt: 2-year follow-up. BMC Ophthalmol. 2018;18(1):243.

Otarola F, Virgili G, Shah A, et al. Ab interno trabecular bypass surgery with Schlemms canal microstent (Hydrus) for open angle glaucoma. Cochrane Database Syst Rev. Mar 09 2020;3:CD012740.

Ozal SA, Kaplaner O, Basar BB, et al. An innovation in glaucoma surgery: XEN45 gel stent implantation. Arq Bras Oftalmol. 2017;80(6):382-385.

Perez-Torregrosa VT, Olate-Perez A, Cerda-Ibanez M, et al. Combined phacoemulsification and XEN45 surgery from a temporal approach and 2 incisions. Arch Soc Esp Oftalmol. 2016;91(9):415-421.

Pfeiffer N, Garcia-Feijoo J, Martinez-de-la-Casa JM, et al. A randomized trial of a Schlemm's canal microstent with phacoemulsification for reducing intraocular pressure in open-angle glaucoma. Ophthalmology. 2015;122(7):1283-1293.

Prum BE Jr, Rosenberg LF, Gedde SJ, et al. Primary Open-Angle Glaucoma Preferred Practice Pattern® Guidelines. Ophthalmology2016;123(1):P41-P111.

Razeghinejad MR, Fudemberg SJ, Spaeth GL. The changing conceptual basis of trabeculectomy: a review of past and current surgical techniques. Surv Opthalmol. 2012;57(1):1-25.

Razeghinejad MR, Spaeth GL. A history of the surgical management of glaucoma. Optometr Visi Sci. 2011;88(1):E39-47.

Reynolds JD, Reynolds AL. Overview of glaucoma in infants and children. 01/09/2023. Up to Date. [UpToDate Web site]. Available at: http://www.uptodate.com/home/index.html. [via subscription only]. Accessed April 1, 2021​​.

Saheb H, Ahmed, II. Micro-invasive glaucoma surgery: current perspectives and future directions. Curr Opin Ophthalmol. 2012;23(2):96-104.

Salimi A, Watt H, Harasymowycz P. Three-Year Outcomes of Second-generation Trabecular Micro-bypass Stents (iStent inject) With Phacoemulsification in Various Glaucoma Subtypes and Severities. J Glaucoma. 2021;30(3):​266-275.

Samuelson TW, Chang DF, Marquis R, et al. A Schlemm Canal Microstent for Intraocular Pressure Reduction in Primary Open-Angle Glaucoma and Cataract: The HORIZON Study. Ophthalmology. 2019;126(1):29-37.

Samuelson TW, Katz LJ, Wells JM, et al. Randomized evaluation of the trabecular micro-bypass stent with phacoemulsification in patients with glaucoma and cataract. Ophthalmology. 2011;118(3):459-467.

Samuelson TW, Sarkisian SR Jr, Lubeck DM, et al. Prospective, Randomized, Controlled Pivotal Trial of iStent inject Trabecular Micro-Bypass in Primary Open-Angle Glaucoma and Cataract: Two-Year Results. Ophthalmology. 2019;126(6):811-821.

Schlenker MB, Gulamhusein H, Conrad-Hengerer I, et al. Efficacy, safety, and risk factors for failure of standalone ab interno gelatin microstent implantation versus standalone trabeculectomy. Ophthalmology. 2017;124(11):1579-1588.

Shingleton B, Tetz M, Korber N. Circumferential viscodilation and tensioning of Schlemm canal (canaloplasty) with temporal clear corneal phacoemulsification cataract surgery for open-angle glaucoma and visually significant cataract: one-year results. J Cataract Refract Surg. 2008;34(3):433-440.

Spiegel D, Garcia- Feijoó J, García-Sánchez J, et al. Coexistent primary open-angle glaucoma and cataract: preliminary analysis of treatment by cataract surgery and the iStent® trabecular micro-bypass stent. Adv Ther. 2008;25(5):453-464.

Spiegel D, Wetzel W, Haffner DS, Hill RA. Initial clinical experience with the trabecular micro-bypass stent in patients with glaucoma. Adv Ther. 2007;24(1):161-70.

Stangos AN, Mavropoulos A, Leuenberger PM, et al. The effect of learning curve on the surgical outcome of viscocanalostomy. J Glaucoma. 2012;21(6):408-414.

Stangos AN, Mavropoulos, A, Sunaric-Megevand G. Phacoviscocanalostomy for open-angle glaucoma with concomitant age-related cataract. Clin Ophtalmol. 2007;1(4):497-504.

Stoner AM, Capitena Young CE, SooHoo JR, et al. A Comparison of Clinical Outcomes After XEN Gel Stent and EX-PRESS Glaucoma Drainage Device Implantation. J Glaucoma. 2021;30(6):481-488.

Swaminathan SS, Jammal AA, Kornmann HL, et al. Visual Field Outcomes in the Tube Versus Trabeculectomy Study. Ophthalmology. 2020;127(9):1162-1169.

Tan SZ, Walkden A, Au L. One-year result of XEN45 implant for glaucoma: efficacy, safety, and postoperative management. Eye (Lond). 2018;32(2):324-332.

Tanimoto SA, Brandt JD. Options in pediatric glaucoma after angle surgery has failed. Curr Opin Ophthalmol. 2006;17:132-137.

Tanito M, Chihara E. Safety and effectiveness of gold glaucoma micro shunt for reducing intraocular pressure in Japanese patients with open angle glaucoma. Jpn J Ophthalmol. 2017;61(5):388-394.

Tseng VL, Coleman AL, Chang MY, et al. Aqueous shunts for glaucoma. Cochrane Database Syst Rev. 2017;7:CD004918.

U.S. Food and Drug Administration (FDA). Center for Devices and Radiological Health. Ahmed Glaucoma Valve Implant. 510(k) summary. [FDA Web site]. 11/12/1993. Available at: https://www.accessdata.fda.gov/scripts/cdrh/cfdocs/cfPMN/pmn.cfm?ID=K925636. Accessed April 1, 2024.

U.S. Food and Drug Administration (FDA). Center for Devices and Radiological Health. Baerveldt Glaucoma Implant. 510(k) Premarket Notification Database. [FDA Web site]. 02/11/1991. Available at: https://www.accessdata.fda.gov/scripts/cdrh/cfdocs/cfpmn/pmn.cfm?id=k905129. Accessed April 1, 2024.

U.S. Food and Drug Administration (FDA). Center for Devices and Radiological Health. Glaukos iStent® Trabecular Micro-Bypass Stent. Premarket approval letter. [FDA Web site]. 06/25/2012. Available at: https://www.accessdata.fda.gov/cdrh_docs/pdf8/P080030A.pdf. Accessed April 1, 2024.

U.S. Food and Drug Administration (FDA). Center for Devices and Radiological Health. Express Mini Glaucoma Shunt. 510(k) summary. [FDA Web site]. 03/13/2003. Available at: https://www.accessdata.fda.gov/cdrh_docs/pdf3/K030350.pdf. Accessed April 1, 2024.

U.S. Food and Drug Administration (FDA). Center for Devices and Radiological Health. Krupin eye valve with disk. 510(k) Premarket Notification Database. [FDA Web site]. 03/15/1991. Available at: https://www.accessdata.fda.gov/scripts/cdrh/cfdocs/cfpmn/pmn_template.cfm?id=k905703. Accessed April 1, 2024.

U.S. Food and Drug Administration (FDA). Center for Devices and Radiological Health. Krupin eye valve with scleral buckle. 510(k) Premarket Notification Database. [FDA Web site]. 01/24/1989. Available at: https://www.accessdata.fda.gov/scripts/cdrh/cfdocs/cfpmn/pmn_template.cfm?id=k885125. Accessed April 1, 2024.

U.S. Food and Drug Administration (FDA). Center for Devices and Radiological Health. Molteno Implant. 510(k) Premarket Notification Database. [FDA Web site]. 02/27/1989. Available at: https://www.accessdata.fda.gov/scripts/cdrh/cfdocs/cfpmn/pmn_template.cfm?id=k890598. Accessed April 1, 2024.

U.S. Food and Drug Administration (FDA). Center for Devices and Radiological Health. Optimed Glaucoma Pressure Regulator. 510(k) Premarket Notification Database. [FDA Web site]. 10/16/1990. Available at: https://www.accessdata.fda.gov/scripts/cdrh/cfdocs/cfpmn/pmn_template.cfm?id=k903462. Accessed April 1, 2024.

U.S. Food and Drug Administration (FDA). Center for Devices and Radiological Health. Xen Glaucoma Treatment System. 510(k) summary. [FDA Web site]. 11/21/2016. Available at: http://www.accessdata.fda.gov/cdrh_docs/pdf16/K161457.pdf. Accessed April 1, 2024.

Vlasov A, Kim WI. The efficacy of two trabecular bypass stents compared to one in the management of openangle glaucoma. Mil Med. 2017;182(S1):222-225.

Vold S, Ahmed, II, Craven ER, et al. Two-year COMPASS trial results: supraciliary microstenting with phacoemulsification in patients with open-angle glaucoma and cataracts. Ophthalmology. 2016;123(10):2103-2112.

Vold SD, Voskanyan L, Tetz M, et al. Newly diagnosed primary open-angle glaucoma randomized to 2 trabecular bypass stents or prostaglandin: outcomes through 36 months. Ophthalmol Ther. 2016;5(2):161-172.

Voykov B, Blumenstock G, Leitritz MA, et al. Treatment efficacy and safety of canaloplasty for open-angle glaucoma after 5 years. Clin Experiment Ophthalmol. 2015;43(8):768-771.

Wagner FM, Schuster AK, Emmerich J, et al. Efficacy and safety of XEN(R)-Implantation vs. trabeculectomy: Data of a "real-world" setting. PLoS One. 2020;15(4):e0231614.

Wagschal LD, Trope GE, Jinapriya D, et al. Prospective randomized study comparing Ex-PRESS totrabeculectomy: 1-year results. J Glaucoma. 2015;24(8):624-629.

Wang X, Khan R, Coleman A. Device-modified trabeculectomy for glaucoma. Cochrane Database Syst Rev. ​2015;12:CD010472.

Weizer JS. Angle-closure glaucoma. 12/14/2018. Up to Date. [UpToDate Web site]. Available at: http://www.uptodate.com/home/index.html. [via subscription only]. Accessed April 25, 2022​​.

Yalvac IS, Sahin M, Eksioglu U, et al. Primary viscocanalostomy versus trabeculectomy for primary open-angle glaucoma: three-year prospective randomized clinical trial. J Cataract Refract Surg. 2004;30(10):2050-7.

Yu Y, Liu ZL, Cao L, Nie QZ. Clinical effect of improved viscocanalostomy for the treatment of primary congenital glaucoma. Int J Ophthalmol. 2012;5(4):466-468.​


Coding

CPT Procedure Code Number(s)
MEDICALLY NECESSARY

THE FOLLOWING CODES ARE USED TO REPRESENT THE INSERTION OF AQUEOUS SHUNTS:

66179, 66180, 66183, 66184, 66185

THE FOLLOWING CODES ARE USED TO REPRESENT THE IMPLANTATION OF AQUEOUS STENTS:

66989, 66991, 0253T, 0449T, 0450T, 0474T, 0671T


THE FOLLOWING CODES ARE USED TO REPRESENT CANALOPLASTY:

66174, 66175

EXPERIMENTAL/INVESTIGATIONAL

THE FOLLOWING CODES ARE USED TO REPRESENT VISCOCANALOSTOMY:

66174, 66175

ICD - 10 Procedure Code Number(s)
N/A

ICD - 10 Diagnosis Code Number(s)
Please see Attachment A.

HCPCS Level II Code Number(s)
MEDICALLY NECESSARY

C1783 Ocular implant, aqueous drainage assist device

L8612 Aqueous shunt

Revenue Code Number(s)
N/A



Coding and Billing Requirements


Policy History

1/1/2023
12/30/2022
5/29/2024
MA11.105
Medical Policy Bulletin
Medicare Advantage
{"1090": {"Id":1090,"MPAttachmentLetter":"A","Title":"ICD-10 Codes","MPPolicyAttachmentInternalSourceId":8592,"PolicyAttachmentPageName":"c47da178-16d6-48ea-a433-139702744bf4"},}
No