Retinal Nerve Fibre Layer Thickness Change After CO2 Laser-Assisted Deep Sclerectomy Surgery

Chapter 3 Treatment Principles and Options 3.1 - General Principles of Glaucoma Treatment The purpose of this chapter is to give a summary overview and it is not meant to be an all-inclusive text Figure 3.1. THE WHOM -TO -TREAT GRAPH The rate of ganglion cell loss and resulting functional decay is very different among different glaucoma eyes. Quality of life is clearly reduced when visual field defects become severe, cf. the severe functional impairment. Line A represents the effect of aging alone. In glaucoma loss of visual function is often much more rapid. An older patient, diagnosed late in life, with a moderate rate of progression (B) has a much lower risk of developing severe functional impairment than a younger patient with the same amount of field loss at diagnosis and rate of progression (C). A very slow rate of progression may be tolerated by the patient and treatment left unchanged (D), while a rapid rate of progression (E) needs a considerably lower target pressure. It needs to be remembered that it is the extent of binocular visual field or the field of the better eye that largely determines the patient’s quality of life, while the rates of progression of each eye separately are needed to determine treatment. © European Glaucoma Society To assess the likely Rate of Progression (RoP) is an important part of patient management and the measured rate is a very important factor that should determine target pressure and treatment intensity (See Ch. Introduction) [I.D]. Many studies have found that progression is usually linear1-4, but the goal of intensifying treatment is to decrease rate of progression. Please observe that perimetric printouts of progression using the MD or VFI indices are age-corrected, so that a normal eye would not show any age-related deterioration over time. The goal of glaucoma treatment is to maintain the patient’s visual function and related quality of life, at a sustainable cost. The cost of treatment in terms of inconvenience and side effects as well as financial implications for the individual and society requires careful evaluation (See Ch. Introduction). Quality of life is closely linked with visual function and, overall, patients with early to moderate glaucoma damage have good visual function and modest reduction in quality of life, while quality of life is considerably reduced if both eyes have advanced visual function loss. Glaucoma is still a leading cause of blindness in Europe. A considerable percentage of glaucoma patients become blind in both eyes or encounter serious field loss in both eyes5-7. Major risk factors for glaucoma blindness are the severity of the disease at presentation and life expectancy8,9. A 60-year-old patient with bilateral moderate visual function damage at diagnosis has a greater risk of blindness than an 85-year-old patient with a similar amount of damage. Similarly a young patient with mild bilateral damage is at much larger risk of disability in his lifetime than an 80-year-old patient with moderate unilateral disease Thus, treatment must be individualised to the needs and rate of progression (RoP) of each patient (See Fig. 1 Ch. Introduction) [I,D]. The risk of ever encountering loss of quality of life from glaucoma should determine target pressure, intensity of treatment, and frequency of follow-up [I,D]. Thus, patients with severe functional loss or younger patients with manifest disease should have more aggressive treatment and closer follow-up than patients with little or no risk, e.g., very old patients with early field loss or unilateral disease [I,D]. Glaucoma suspects, e.g., patients with elevated IOP and otherwise normal findings, have even smaller risks. In most patients with advanced glaucoma and reasonable life expectancy, aggressive IOP lowering treatment might be recommended10,11 [I,D]. Very old patients with mild loss, relatively low IOP levels and significant health problems, might prefer being followed without treatment (See also Ch. Introduction) [II,D]. When treatment options are discussed with a patient, his general health status and personal preferences must be considered and respected. It is also important to ensure that patients are able to comply and persist with therapy [I,D]. Disease progression rates (RoP) in POAG, the most common form of glaucoma differ very much between patients, from rapid to very slow12-16. This makes it necessary to determine the RoP in patients with manifest glaucoma (See Fig. 1 Ch. Introduction) [I,D]. Many patients with POAG/NTG show no or only small deterioration despite years of follow-up17,18, while rapid progression is common in others, e.g. in exfoliation glaucoma18. Glaucoma patients may continue to show progression despite treatment, even with IOP levels within the statistically normal range. Relying on tonometry alone for glaucoma follow-up is, therefore, insufficient regardless of IOP level17,18. Determining the rate of visual field progression is a new standard in glaucoma care. The EGS recommends three visual field tests per year for the first two years after diagnosis to make it possible to identify rapidly progressing patients [II,D]. After two years of perimetric monitoring without progression being detected the frequency of tests may be reduced [II,D]. Once the progression rate has been determined the target pressure is re-evaluated and be based on the measured rate of progression and IOP values measured during the follow-up time [II,D]. Risk factors are then less important than at diagnosis (See Ch. 2.2). Individualized glaucoma treatment aims at providing glaucoma management tailored to the individual needs of the patient; patients with severe functional loss or younger patients with manifest disease should have more aggressive treatment and closer follow-up than patients with little or no risk, e.g., patients with ocular hypertension or elderly patients with mild field loss and low IOP levels19-23 [I,D]. (See FC VI) In most Western countries approximately half of patients with manifest glaucoma are undiagnosed24-27, and glaucoma is often diagnosed late8. Improved case finding and possibly screening of high risk groups are necessary to allow diagnosis at earlier disease stages. Screening options for high risk groups should be evaluated. To discover and treat those at risk of losing functionally significant vision is a more important goal for effective glaucoma management than widespread treatment of patients with ocular hypertension. Currently, the only approach proven to be efficient in preserving visual function is lowering IOP28-31 (See Ch. Introduction and FC VI to XI) [I,A]. Other possible treatment areas have been investigated, including ocular blood flow and neuroprotection. There are experimental as well population based studies indicating that perfusion pressure may be relevant in glaucoma31-37 but very difficult to measure38 a specific glaucoma phenotype characterised by vascular dysregulation has been described32,33. An increase of IOP will lead to a reduction of perfusion pressure. Blood pressure levels may also be important in glaucoma17,36,37. However, there is no conclusive evidence to support the idea that perfusion pressure can be increased by manipulating blood pressure or ocular blood flow in glaucoma patients. Neuroprotection can be defined as a “therapeutic approach” aiming to directly prevent, hinder and, in some cases, reverse neuronal cell damage. Since glaucoma patients can continue deteriorating in spite of an apparently well controlled IOP, the need for effective non-IOP related treatments is widely acknowledged. Several compounds have been shown to be neuroprotective in animal models of experimental glaucoma39-43. So far, no compound has reached a sufficient level of evidence to be considered as a neuroprotectant in humans. A large long-term randomized trial using a neuroprotective agent, memantine, was analysed several years ago, but with negative results. A more recent study claiming that topical brimonidine might haven neuro-protective properties in glaucoma patients, has been questioned in a systematic review on neuroprotection in glaucoma44,45. In most western countries, approximately half of patients with manifest glaucoma are undiagnosed24-27. 3.2 - Target Iop and Quality of Life 3.2.1 Target Intraocular Pressure (Target IOP) Therapy in glaucoma management aims to lower IOP to slow the rate of visual field deterioration. Target IOP is the upper limit of the IOP estimated to be compatible with a rate of progression sufficiently slow to maintain vision-related quality of life in the expected lifetime of the patient. It should be re-evaluated regularly and, additionally, when progression of disease is identified or when ocular or systemic comorbidities develop [II,D]. There is no single Target IOP level that is appropriate for every patient, so the Target IOP needs to be estimated separately for each eye of every patient (See FC IX and X) [II,D]. Factors to consider when setting the Target IOP include19,28,46 [II,D]: Stage of glaucoma The greater the pre-existing glaucoma damage, the lower the Target IOP should be IOP level before treatment The lower the untreated IOP levels, the lower the Target IOP should be Age and life expectancy Whilst younger age implies greater life expectancy and, therefore, a lower Target IOP, older age is a risk factor for more rapid progression Rate of progression during follow-up The faster the rate of progression, the lower the Target IOP should be The presence of other risk factors, e.g., exfoliation syndrome The side effects and risks of treatment Patient preference When taking the IOP reading, it is advisable to consider CCT [I,C]. Several clinical studies have identified that worse initial visual field loss is the most important predictor of blindness from glaucoma7,47-49. When considering the Target IOP for one eye, the vision status of the other eye should be taken into account. In a newly-diagnosed patient, the rate of progression is unknown and Target IOP is based on risk factors for progression (See Ch. 2.2.2.1). After sufficient follow-up and with sufficient visual field tests to reliably determine the progression status, usually 2-3 years, the importance of the risk factors for decision-making decreases and importance of the measured rate of progression increases; the rate of progression should be used to adjust the Target IOP, taking into account IOP levels over the observation period, life expectancy, and current levels of visual function damage (See FC X)22. 3.2.1.1 Setting the Target IOP There is little evidence base to support any particular algorithm to set the Target IOP, but data from clinical trials may be used as a guide. As clinical trials have shown that progression occurs in eyes that have an IOP within the statistically normal range ( 21 mmHg. Treatment “B” red dots. Eyes n 1 and n 2 show a slight increase and a slight decrease of IOP, respectively; eye n 3 shows a very large effect, as well as eye n 4, both remaining below the 15 mmHg line. Assess each eye individually when deciding the most appropriate therapy. It is essential to involve patients as informed partners in decisions regarding the management of their condition. The least amount of medication (and consequent inconvenience, costs and side effects) to achieve the therapeutic response should be a consistent goal. A therapeutic medical trial on one eye first can be useful to determine the IOP lowering efficacy, although not always logistically feasible or advisable (e.g., very high IOP or advanced disease). Usually there is no need to start treatment until all baseline diagnostic data are collected, unless the IOP is very high and there is severe damage. After diagnosis it is advisable to measure untreated IOP more than once before initiating IOP-lowering treatment The following pages outline the most frequently used anti-glaucoma medications, and emphasize their mode of action, dosage and side effects. A complete list of all possible medications is beyond the scope of the Guidelines. Antiglaucoma drugs have been available since 1875. The following diagram shows the chronology of the introduction of topical intraocular pressure-lowering medications (Fig. 3.3). Figure 3.3. IOP lowering molecules and year of first clinical use. FC: fixed combination. In black: monotherapy. There are six classes of topical antiglaucoma drugs. The following tables contain only the most common classes and compounds, their most common side effects and contraindications. They are listed in order of first and second line drugs. The seventh category is systemically administered osmotics. The use of some compounds like epinephrine and dipivefrin has decreased significantly since drugs with better efficacy and fewer side effects became available. The text should be considered as a general guide, and cannot be all-inclusive. Table 3.3 Class: PROSTAGLANDIN ANALOGUES Compound Mode of action IOP reduction Contra-indications Side effects Prostaglandin analogues Latanoprost 0.005% Tafluprost 0.0015% Travoprost 0.003% - 0.004% Increase in uveo-scleral outflow 25-35% Contact lenses (unless reinserted 15 minutes following administration of the drugs) Local: Conjunctival hyperaemia, burning stinging, foreign body sensation, itching, increased pigmentation of periocular skin, periorbital fat atrophy, eyelash changes. Increased iris pigmentation, (in green-brown, blue/ grey-brown or yellow-brown irides). Cystoid macular oedema (aphakic/pseudophakic patients) with posterior lens capsule rupture or in eyes with known risk factors for macular oedema, reactivation of herpes keratitis, uveitis Prostamide Bimatoprost 0.03% Bimatoprost 0.01% Increase in uveo-scleral outflow 25-35% Systemic: Dyspnea, chest pain/angina, muscle-back pain, exacerbation of asthma Table 3.4 Class: Beta-RECEPTOR ANTAGONISTS Compound Mode of action IOP reduction Contra-indications Side effects Nonselective Timolol 0.1-0.25-0.5% Levobunolol 0.25% Metipranolol 0.1-0.3% Carteolol 0.5-2.0% Befunolol 0.5% Decreases aqueous humour production 20-25% Asthma, history of COPD, sinus bradycardia ( brimonidine) Brimonidine 0.2% Decreases aqueous humour production and increases uveo-scleral out?ow Alpha-2- selective Clonidine 0.125 -0.5% Decreases aqueous humour production 18-25% Oral monoamine oxidase (MAO) inhibitor users Pediatric age Very low body weight in adults Systemic: Dry mouth and nose (apraclonidine). Systemic hypotension, bradycardia (clonidine), fatigue, sleepiness (brimonidine) Table 3.7 Class: NON SELECTIVE ADRENERGIC AGONISTS Compound Mode of action IOP reduction Contra-indications Side effects Non- selective Epinephrine 0.25-2.0% Dipivefrin 0.1% Decreases aqueous humour production and may increases uveo-scleral outflow 15-20% Occludable angles (iridotomy needed) Aphakic patients (macular oedema) Local: Conjunctival hyperemia, conjunctival pigmentation. Burning, stinging, ocular pain, blurred vision, macular oedema Systemic: systemic hypertension, headache, anxiety, confusion, chest pain, shortness of breath, tachycardia, sweating Table 3.8 Class: PARASYMPATHOMIMETICS (CHOLINERGIC DRUGS) Compound Mode of action IOP reduction Contra-indications Side effects Direct- acting Pilocarpine 0.5-4% Carbachol 0.75-3% Facilitates aqueous out?ow by contraction of the ciliary muscle, tension on the scleral spur and traction on the trabecular meshwork 20-25% Post-operative inflammation, uveitis neovascular glaucoma. Patient at risk for retinal detachment, spastic gastrointestinal disturbances, peptic ulcer, pronounced bradycardia, hypotension, recent myocardial infarction, epilepsy, Parkinsonism Local: Reduced vision due to miosisand accommodative myopia, conjunctival, hyperaemia, retinal detachment, lens opacities, precipitation of angle closure, iris cysts Systemic: Intestinal cramps, bronchospasm, headache Indirect- acting Demecarium bromide 0.125-0.25% Ecothiophate iodide 0.03% Diisopropyl ?uorophosphates 0.025-0.1% 15-25% Same as direct acting drugs Local and systemic: Side effects are similar but more pronounced than with direct acting compounds Table 3.8 Class: PARASYMPATHOMIMETICS (CHOLINERGIC DRUGS) Compound Mode of action IOP reduction Contra-indications Side effects Oral Glycerol Isosorbide Alcohol Dehydration and reduction in vitreous volume Posterior movement of the iris-lens plane with deepening of the AC 15-20% Cardiac or renal failure Nausea, Vomiting, dehydration (special caution in diabetic patients). Increased diuresis, hyponatremia when severe may lead to lethargy, obtundation, seizure, coma. Possible increase of bood glucose. Acute oliguric renal failure. Hypersensitivity reaction Intravenous Mannitol Urea 15-30% 3.3.3 First Line Drugs 3.3.4 Second Line Drugs 3.3.4.1 Prostaglandin Analogues Since their development in the 1990s, prostaglandin derivatives (latanoprost, travoprost, bimatoprost and tafluprost) (Table 3.3) have progressively replaced beta-blockers as first-choice/first line therapy. This is mainly because they are the most effective IOP- lowering agents54, lack relevant systemic side effects and require just once-daily administration. Recently, a number of latanoprost generics as well as preservative-free and BAC-free prostaglandin formulations have entered the glaucoma market. The primary mechanism of action of prostaglandins is to increase uveoscleral outflow, reducing IOP by 25%-35%. Reduction of IOP starts approximately 2-4 h after the first administration, with the peak effect within approximately 8-12 h. Thus, IOP measurements taken in the morning represent the peak effect of the prostaglandin analogues for patients administering the drug in the evening. Clinical trials that measured 24-hour IOP suggested that evening administration is generally preferable because it gave a better circadian IOP profile68-70 [II, B]. These studies also reported that eyes treated with PG derivatives have reduced short-term IOP variability as compared to eyes treated with other classes of drugs71. Maximum IOP lowering is often achieved 3-5 weeks from commencement of treatment. Differences among drugs within this class in the capability of reducing IOP did not exceed 1 mmHg72. When combined with most of the other antiglaucoma drug classes, prostaglandin agents provide additive IOP lowering. Non-responders to prostaglandin analogues (e.g. eyes with IOP reductions of less than 10% or 15% from baseline) are fewer than 10%73,74. Some reports indicate that poor responders to one prostaglandin agent might respond to another agent within the same class75,76. Conjunctival hyperemia, generally mild, is a common finding with slight difference in frequency and level among agents within this drug class. It usually decreases over time. Other PG side effects are reported in Table 3.3. Details on the mode of action, IOP lowering effect, contraindications and side effects of other first line drugs (□-blockers, carbonic anhydrase inhibitors, alpha-2 selective adrenergic agonists) and second line drugs are listed in Tables 3.5-3.10. 3.3.5 Local Toxicity of Topical IOP - Lowering Treatment. The Role of Preservatives Long-term topical glaucoma medications may cause and/or exacerbate pre-existing ocular surface disease (OSD), such as dry eye, meibomian gland dysfunction and chronic allergy77, which, in glaucoma patients, has a much higher prevalence than in the general population63,64,78. OSD may follow chronic use of antiglaucoma medication and/or the preservative benzalkalonium chloride (BAC). BAC, a quaternary ammonium compound is the most frequently used preservative agent in eye drops and its usage correlates well with the signs and symptoms of OSD63,64,79-82. Such signs and symptoms can diminish if BAC-preserved drops are substituted with non-preserved drops63. An unwanted effect of BAC is a reduction in the success rate of filtering surgery83-85. In vitro studies suggest that alternative preservatives are significantly less toxic than BAC86-91. Other therapeutic possibilities are the use of preservative-free or BAC-free medication, decreasing the number of preserved eyedrops i.e. by using fixed combinations; treating the ocular surface with unpreserved tear substitutes and performing earlier laser or surgery. When considering OSD four factors have to be considered: the active compound, the specific preservative, the ability of the patient to use single-dose preparations and the patient’s ocular surface. The European Medicines Agency (EMEA) has suggested that the use of preservatives should be avoided in “patients who do not tolerate eye drops with preservatives” and in those on long-term treatment, or to use “concentration at the minimum level consistent with satisfactory antimicrobial function in each individual preparation”, with a specific indication to avoid mercury containing preparations92. Not all patients are sensitive to preservatives and not all the local side effects observed with topical antiglaucoma medications are induced by preservatives. Particular attention should be paid to glaucoma patients with pre-existing OSD or to those developing dry eye or ocular irritation over time. This can be done by careful assessment of redness of the eyelid margin, positive corneal and conjunctival fluorescein staining or reduced tear break-up time [I,D]. 3.3.6 Generic IOP - Lowering Topical Medications By definition a generic drug is identical to a brand name drug in dosage, strength, route of administration, performance characteristics and intended use. For the purposes of drug approval, the interchangeability of a generic drug and the corresponding brand-name drug is based on the criterion of “essential similarity”. In ophthalmology this concept is problematic, because it is difficult to prove “essential similarity” in clinical studies. With systemic drugs bioequivalence studies are performed using blood samples to determine whether the plasma concentration within certain limits equals the branded drug. With topical eye drops such studies obviously cannot be performed. No clinical studies are usually required for generic approval in ophthalmology, and a 10% difference between the concentration of the active principle between the generic and the branded products is considered acceptable. Whereas the active principle is assumed to be equal, the adjuvants can vary considerably. This is a critical issue because different adjuvants may alter the viscosity, osmolarity and pH of the eye drops and therefore have an impact on both tolerability and corneal penetration. Nevertheless anti-glaucoma generics drugs are currently prescribed at a large scale, as many drugs are becoming off patent. For latanoprost, the generic share is more than 65% in most European countries. To which degree these generics are similar in efficacy and tolerability is not well studied. Only few clinical studies have compared the effect of generic and brand IOP lowering medications in glaucoma, with variable results depending on the type of generic drug93,94. Other studies have shown a difference between the branded and the generic preparations concerning the size and amount of drops in the bottle, the structure of the bottle and the bottle tips95-98. Safety issues with corneal epithelial disorders have also been described with generics, due to an additional stabiliser compound99. When switching patients from branded to generic drugs, the IOP should be closely monitored [I,D]. 3.3.7 Dietary Supplementation and Glaucoma Although there is no clinical evidence for clinical benefits arising from the use of dietary supplements in glaucoma, a recent survey has found that 1 in 9 glaucoma patients were using complementary and alternative medicine (CAM). Most were using herbal medicines (34.5%), dietary modifications (22.7%) or dietary supplements (18.8%)100. Based on the fact that some glaucoma patients continue to progress at low IOPs, there is much room for hypotheses, preclinical experiments, clinical trials and speculation. Some data from experimental studies suggest that dietary supplementation may reduce oxidative stress101, or that the omega 3 polyunsaturated fatty acids (PUFAs) decrease IOP in rats102. At the present time there is no robust interventional dietary supplementation study demonstrating the positive effect of such a treatment in glaucoma patients. Observational studies have suggested a reduced risk for glaucoma with higher fruit and vegetable intake103 or higher omega 3 PUFAs consumption in selected populations104. Conversely there is evidence that some of these compounds may cause harm, such as an increased intake of magnesium associated with a higher incidence of glaucoma105. DIETARY SUPPLEMENTATION At the present time there is no robust interventional dietary supplementation study demonstrating the positive effect of such a treatment in glaucoma patients 3.3.8 Management of Glaucoma During Pregnancy and Breast-feeding Pregnancy-related changes in ocular physiology can influence IOP as well as the reliability of its measurements. Changes in hormonal levels, are thought to induce an IOP-lowering effect that increases throughout pregnancy (but particularly during the 24th-30th week) and can last for months after delivery106-108. The most sensitive period is the first trimester due to concerns relating teratogenicity, as the majority of IOP-lowering medications are within class C (See Table 3.10) meaning that adverse effects have been seen in animals or that there are no human or animal data (See Table 3.11). Therefore, for a woman with glaucoma who is of child bearing age, who might wish to conceive, the treatment strategy during pregnancy should be discussed [I,D]. The patient should be instructed to inform the ophthalmologist when pregnancy occurs. The potential risks to the fetus (and neonate) of continuing anti-glaucoma medications must be balanced against the risk of vision loss in the mother [I,D]. As IOP levels generally decrease during pregnancy, temporary treatment discontinuation can be considered under strict follow-up in some patients. However, if continuation of treatment is mandated, the lowest effective dosage of medication should be used. Moreover, systemic absorption should be reduced by punctal occlusion, eyelid closure, and blotting excess drops away during administration109 [I,D]. Drugs are classified in Classes A to X for use during pregnancy based on a hierarchy of estimated fetal risk (See Tables 3.10-3.11)110. Although very similar, some countries (e.g., Sweden, Australia, the Netherlands, Switzerland, and Denmark) have their own classification systems. Table 3.10 Drug classification for use of drugs during pregnancy Class A Controlled studies show no risk. Adequate well-controlled studies in pregnant women have failed to demonstrate risk to the foetus Class B No evidence of risk in humans. Either animal findings show risk, but human findings do not or, if no adequate human studies have been done, animal findings are negative Class C Risk cannot be ruled out. Human studies are lacking, and animal studies are either positive for foetal risk or lacking as well. However, potential benefits may justify the potential risk Class D Positive evidence of risk. Investigational or post-marketing data show risk to the foetus. Nevertheless, potential benefits may outweigh the potential risk Class X Contraindicated in pregnancy. Studies in animals or human, or investigational or (FDA Classification of Drugs for Teratogenic Risk. Teratology society public affairs committee. Teratology 1994: 49:446-447). Brimonidine is a Class B medication: however, there are reports of central nervous system side effects in young children111. The ability of this drug to cross the placenta and the lack of well controlled human studies during pregnancy do not allow ruling out possible adverse effects on the fetus. Betaxolol is also in class B and is characterized by a larger volume of distribution in the fetal circulation, high binding to proteins and therefore fewer central nervous systemic effects on the fetus. Timolol although class C, is available in low dosage (0.1%), in slow-release preparations which can be used once daily. Although these formulations are thought to reduce systemic absorption, strong evidence to support this is still lacking. Once-a-day timolol 0.1% gel may be a valid option if a beta-blocker is considered [I,D]. Prostaglandin-analogues should be considered with caution because of the theoretical risk of increased uterine contractility in pregnancy. If premature contractions appear PG should be discontinued immediately [I,D]. There have been no reports on any fetal complications related to the use of topical carbonic anhydrase inhibitors in humans, but animal studies have shown that high systemic doses, are associated with low weight offspring (Manufacturer’s Information: Azopt product monograph. Fort Worth, Texas, Alcon Ophthalmics, 1998 Manufacturer’s Information: Trusopt product monograph. West Point, Pennsylvania, Merck Inc., 1999). At clinically used concentrations, BAC has no known impact on the fetus112. Table 3.11 summarizes known adverse effects of anti-glaucoma drugs during pregnancy and breast-feeding. Although results from animal studies are worrisome, the overall level of evidence for the risk of giving anti-glaucoma drugs to pregnant women is low. Laser trabeculoplasty is considered to be a safe alternative113 except in patients with angle dysgenesis. However, IOP lowering success is lower in younger patients, such as in women of childbearing age114. Laser cyclodestruction, in spite of having been suggested as a valid option should be considered with caution because of risk of sight-threatening complications115. If surgery is planned, there are a number of considerations to be made. A supine position should be avoided116. For intervention under local anesthesia, topical, subconjuntival or retrobulbar, lidocaine is considered to be a safe option117. The use of anti-metabolites is strictly contraindicated, due to the mutagenic related risk. Depending on previous ocular surgeries and the age of patient, filtering surgery, including tube shunt implantation, can be considered112 [II,D]. Topical prednisolone and erythromycin have been shown to cross the placenta to a lesser extent than other medications of their classes, and can therefore be chosen as postoperative medication117,118 [II,D]. Special attention should be paid also during breast-feeding. Carbonic anhydrase inhibitors and beta-blockers may be used in nursing mothers as suggested by the American Academy of Pediatricians119. These are also the first line choices in infants with congenital glaucoma when medical therapy is being considered. Fixed combinations are all class C. Prescribing physicians should separately consider each of the drugs involved [I,D]. Table 3.11 Adverse effects of IOP-lowering medications during pregnancy/breast-feeding Class Pregnancy Breast-feeding Animal Studies Human Theoretical risk Reported cases Parasympathetic agents C Teratogenic Teratogenicity Dysregulation of placental perfusion Meningism in newborn Seizures, fever, diaphoresis Sympathetic agents • brimonidine B No significant effect Delay in labor/ uterine hypotony No reported side-effects CNS depression, hypotension andapnea Prostaglandin analogs C High incidence of miscarriage Uterine contractions One case of miscarriage No reported side-effects Beta-blockers C Delayed fetal ossification, fetal resorption Teratogenicity (1st trimester) Cardiac rhythm changes Respiratory Arrhythmia and bradycardia Impaired respiratory control in newborns Controversy overconcentrations inbreast milk. Apnea and bradycardia Carbonic anhydrase inhibitors • Topical C Decreased weight gain Vertebral body malformation Lower fetal weight No reported side-effects No reported side-effects • Oral C Forelimb anomalies Limb malformations Onecase of teratoma No reported side-effects 3.3.8 Neuroprotection and Glaucoma Treatment Neuroprotection can be defined as a “therapeutic approach” aiming to directly prevent or significantly hinder neuronal cell damage. Since glaucoma patients can continue deteriorating in spite of an apparently well controlled IOP, the need for effective non-IOP related treatments is widely acknowledged. Several compounds have been neuroprotectant in preclinical studies120. Only two have reached large scale clinical trials: a large long-term RCT using an NMDA antagonist, memantine, was analysed in 2008 with negative results. More recently, the results from a multi-center RCT of adults with low-pressure glaucoma (Low-pressure Glaucoma Treatment Study, LoGTS) has been claimed to show that brimonidine may have neuroprotective properties in comparison to Timolol44. No direct comparison has been done with other substances such as PG. However, the authors of the study and a systematic literature review have (both?) suggested that more substantial evidence is needed121,122. 3.3.9 Practical Considerations Related to Topical Medical Treatment The majority of topically applied drugs, particularly if lipophilic, penetrate the eye via the cornea, in a lesser amount via the conjunctiva and thereafter the sclera. On average, the total tear film volume is around 7 µl and the rate of tear film turnover is approximately 15% (±1 µl) per minute but can double (washout effect) after the application of a topical drop with a volume estimated at 30-50 µl123. Although the cul- de-sac and tear film compartment can expand transiently after instillation of a drop it still cannot accommodate this whole volume and less than 5% manages to enter the eye; the rest will run down the cheek or will be drained through the nasolacrimal duct where an individually variable systemic absorption takes place through the highly vascularised nasal mucosa124. Once the medication is instilled into the conjunctival sac, the spontaneous tear flow will cause complete washout within 5 minutes. The washout effect depends not only on the increased tear fluid turnover, but also on the addition of a second drop within a short period. Therefore when poly-drug regimen is used, a minimum time span between different drops should be respected. When two drugs are instilled only 30 seconds apart, almost 50% of the first drug will be washed out. The recommended delay between drops is 5 minutes with a washout effect of less than 15%61,62 [I,B]. Blinking also may influence washout and allow only 15% of a topically applied drug to remain in the eye approximately five minutes after instillation. As drugs absorbed through the highly vascularised nasal mucosa avoid hepatic first- pass metabolism this might lead to systemic side effects. The instillation of one drop of timolol 0.5% for example may lead to a serum concentration of timolol that equals the intake of an oral 10 mg non-selective beta-blocker125. There is no evidence that nasolacrimal duct obstruction may increase the efficacy of a topical drug126 however it may reduce systemic side effects particularly from beta-blockers by minimizing the drainage into the highly vascularised nasopharyngeal mucosa109,127,128 [I,D]. Patients should be advised to shake the bottle before use as micro-suspensions tend to settle to the bottom of the bottle leaving the vehicle at the surface. Thus, patients may be simply applying mainly vehicle to the eye, rather than the active drug ingredient [I,D]. GENERAL RECOMMANDATIONS [L,D]: Monotherapy is the first choice when initiating therapy Baseline IOP should be considered when evaluating the efficacy of a therapy Fixed Combination therapy should be considered when patients fail to achieve their individualized intraocular pressure (IOP) targets with monotherapy The prescription of more than two bottles of IOP lowering eye drops for simultaneous use should be avoided as it can lead to noncompliance Fixed combination preparations may be preferable to the use of separate instillation of two agents However Fixed Combination are not first-line medications and they are only indicated in patients who need adjunctive therapy, when IOP is not sufficiently controlled by one single agent Ocular surface should be evaluated and considered in clinical management of glaucoma patients. In case of ocular surface disease, preservative-free formulations should be considered Generic drops can differ from brand drops and it may be necessary to monitor patients more closely after switching During pregnancy, the potential risks of continuing anti-glaucoma medications to the fetus (and neonate) must be balanced against the risk of vision loss in the mother See FC IX to 3.4 - Adherence, Compliance and Persistence in Glaucoma Glaucoma is a chronic progressive disease that requires continuous long-term cooperation of the patient with the glaucoma management proposed by the doctor. 3.4.1 Terminology The commonly used term “compliance” has been increasingly replaced in recent times by the term “adherence”. Both are defined as the ‘cooperation of the patient with the recommendations given by the doctor’. However, the former is more passive ("I am taking the medication”), while the latter implies the active part of the patient in the process (“I am taking the medication exactly as you told me”). “Persistence” is defined as the length of time during which the patient is taking the medication as prescribed129. Finally three terms should be mentioned: – “White coat compliance” means that the patient’s adherence rises a week before the consultation and drops quickly afterwards130 – “Dyscompliance” is used when physical problems of a patient, like arthritis, lead to difficulties in correctly applying a therapy – “Alliance” is a special form of adherence meaning that the people around the patient ensure the correct application of the medication131 3.4.2 Measured Adherence Despite easier medication schemes (for example drugs which require application once- daily) and more information for the patients about the disease, the rate of non-adherence has remained almost the same over the last 25 years; between 30%-70%. It is important to mention that the patients themselves overestimate their adherence and persistence rate (GAPS)132. 3.4.3 Factors Associated with Non-Adherence Four groups of factors encountered as common obstacles to glaucoma medication adherence have been described133: Situational / environmental (for example a major event in the patients life, unsteady life-style with many travels) Medication (for example costs of the drugs, side effects, complicated dosing regimen) Patients (for example comorbidity, poor understanding of the disease) Provider (for example lacking communication with the doctor) Other influencing factors: – Gender (men are more likely to be non adherent) – Stage of the disease (patients with a less advanced disease tend to be less adherent) 3.4.4 Types of Non-Adherence Every patient is different and there are several types of non-adherence134. – Failure to take the medication as prescribed (including under- and overdosing, inadequate doses and wrong timing of dosages) – Failure to use the correct medication (including the application of the wrong medication or the self administration of not prescribed drugs) – Failure to apply the medication correctly (including incorrect self administration of the medication) – Failure to continue applying the medication (including problems with side-effects, issue of costs and missed refills) 3.4.5 Improving Adherence There are different ways for improving the adherence of patients. The most important measures are informing the patient about his/her disease and finding a therapeutic regimen which fits into the patient’s life-style135 [I,D]. Other factors which should improve adherence [I,D]: – The therapy should be simple i.e. not more than two bottles and an application not more than twice a day – The patient should be instructed how to apply the drops correctly. If necessary, hints reminders should be given like a daily routine which the patient can connect to the application of the drops. If a patient has physical problems applying the drops as arthritis of the fingers, the therapy should be adjusted accordingly or switched to laser/surgery – The doctor should inquire at every visit if the patient has side effects of the medication and switch if necessary. A patient who complains about side effects is usually not adherent to therapy. The patient’s cooperation, described as adherence and persistence, with the prescribed glaucoma management is mandatory to obtain effective IOP lowering and to prevent glaucoma progression. No drug can work unless it is taken. 3.5 - Laser Surgery 3.5.1 Laser Iridotomy>136-139 Indications: [I,C] Clinically relevant or suspected pupillary block. Potential prevention of acute and chronic angle closure (See FC X and XI). Preoperative preparation: To reduce iris thickness and facilitate perforation instil 1 drop of Pilocarpine 2%-4% [I,D]. If the cornea is edematous, like acute angle closure, use topical glycerin 10% if available, systemic acetazolamide, intravenous mannitol or oral hyperosmotic agents (See FC XI). For prevention of IOP spikes use topical alpha 2 agonist 1 hour prior to the procedure and immediately afterwards [I,B]. Procedure: After instillation of topical anesthetic a contact lens with contact lens fluid is placed onto the cornea. The lens keeps the eyelids open, stabilizes the eye, provides additional magnification, focuses the laser beam and acts as a heat sink. Lenses used are: Abraham (+66 diopters), Wise (+103 diopters) or CGI©LASAG CH lens. Iridotomy site [II,D] is usually chosen in the superior quadrants of the iris well covered by the upper eyelid (to reduce visual symptoms), in a thin looking area or an iris crypt. Whole thickness perforation of the iris is assumed when pigment, mixed with aqueous, flows from the posterior into the anterior chamber. Once a full thickness hole has been made, it should be enlarged horizontally to achieve an adequate size. Iridotomy size [II,D] should be sufficient for patency inspite of iris oedema, pigment epithelial proliferation and pupil dilation. Transillumination through the iridotomy is not a reliable indicator of success [II,D]. Lasers parameters for Nd:YAG laser iridotomy Power 1-6 mJ Spot size 50-70 μm (constant for each laser model) Pulses per burst 1-3 Recommendations Set defocus to zero Focus the beam within the iris stroma rather than on the surface of the iris* Avoid any apparent iris vessels Use the least amount of energy that is effective139 Lens capsule damage is possible above 2 mJ energy With most Lasers less than 5 mJ per pulse is required Lasers parameters for Nd:YAG laser iridotomy In case of thick dark irides, to reduce total Nd:YAG energy, pretreatment with argon laser in 2 stages may be considered141 [II,B]. In the first stage a low power argon of 90-250 mW, duration 0.05 sec, spot size 50mm is applied, followed by the high power argon of 700 mW, duration 0.1 sec, spot size 50 mm to create a punched-out crater appearance. Laser iridotomy is completed with Nd:YAG laser. Laser parameters for continuous-wave Argon laser iridotomy When no Nd:YAG laser is available, Argon laser may be used [II,D]. Laser parameters should be individualized to each patient and adjusted appropriately during the procedure. The following parameters are suggested [II,D]: Medium brown irides Preparatory stretch burns Spot size 200-500 μm Exposure time 0.2-0.6 sec Power 200-600 mW Penetration burns [II,D] Spot size 50 μm Exposure time 0.1-0.2 sec Power 700-1500 mW (average 1000 mW) Pale blue or hazel irides 1st step: to obtain a gas bubble Spot size 50 μm Exposure time 0.5 sec Power Up to 1500 mW 2nd step: penetration through the gas bubble Spot size 50 μm Exposure 0.05 sec Power 1000 mW Thick, dark brown irides (chipping technique) Spot size 50 μm Exposure time 0.02 sec Power 1500 mW Complications: Intraoperative complications Bleeding from the iridotomy site; this can usually be stopped by gentle pressure applied to the eye with the contact lens. With the argon laser corneal epithelial and/ or endothelial burns may develop. Postoperative Visual disturbances occur in 6-12% (glare, blurring, ghost images, halo, crescent) are less likely to occur when the iridotomy is completely covered by the eyelid142,143. Transient elevation of the IOP is the most common complication in the early period. Elevation of IOP at 1 hour after iridotomy occurs in approximately 10% of primary angle closure suspect eyes144. Acute and (chronic) rise in IOP is more likely to occur in eyes with peripheral anterior synechiae in whom the small amount of trabecular meshwork not closed is likely to have compromised outflow function (and is secondarily closed by the iris pigment and tissue generated by the iridotomy). Postoperative inflammation is transient and mild, rarely resulting in posterior synechiae. Closure of the iridotomy may occur during the first few weeks after the procedure, due to accumulation of debris and pigment granules. Rare complications include sterile hypopyon, cystoid macular oedema, retinal haemorrhages and malignant glaucoma145,146. Postoperative management: Check the IOP after 1-3 hours [II,D]. Topical corticosteroids for 4-7 days instilled 3-4 times a day. Check the angle regularly with gonioscopy, and the patency of peripheral iridotomy. If the patency is uncertain check with gonioscopy, reconsider the mechanism, perform ultrasound biomicroscopy (UBM) / anterior segment-optical coherence tomography (AS-OCT) if available and/or repeat the iridotomy. Retroillumination alone for judging the patency is insufficient. 3.5.2 Laser Trabeculoplasty (LT)147-154 Indications: [I,D] Lowering of IOP in primary open-angle, exfoliative and pigmentary glaucoma, high risk ocular hypertension (OH): When IOP is not satisfactorily controlled with medications (i.e. efficacy, tolerability and adherence) As initial treatment (See FC VII) Preoperative preparation: [I,B] For prevention of IOP spikes instillation of topical alpha 2 agonist (apraclonidine 1% or brimonidine) 1 hour prior to the procedure and immediately afterwards is optional. Use topical anesthesia. Procedure: Most frequently used lasers are: – Argon continuous-wave laser (green or blue/green) - argon laser trabeculoplasty (ALT) – Q-switched, short pulsed, frequency–doubled Nd:YAG (532 nm) laser - selective laser trabeculoplasty (SLT) Lenses: Goldmann type gonioscopy lens, Ritch trabeculoplasty lens©, CGA©, Meridian, Latina (SLT), Magnaview. Identify angle landmarks after inspection of all quadrants and place the laser burns between the anterior pigmented trabecular meshwork (TM) and the non-pigmented trabecular meshwork over 180° or 360°. Laser parameters for laser trabeculoplasty Laser parameters [I, D] ALT SLT Spot size 50 μm 400 μm Exposure 0.1 sec 3 nsec (fixed) Power 500-1200 mW according to the reaction on the TM; with heavily pigmented TM low power is sufficient 0.4 to 1.2 mJ according to the desired reaction; in heavily pigmented TM start with low levels e.g. 0.4 mJ Optimal reaction Transient bleaching or small gas bubble formation The power is titrated until the appearance of tiny air bubbles, »champagne bubbles«, at the site of the laser burn, then the power is reduced by increments of 0.1 mJ until there are no visible bubbles* Number of spots 50-100 evenly spaced spots over 180-360° 50-100 non-overlapping spots spaced over 180 -360° some continue with the power that causes champagne bubble formation Complications: Transient elevation of IOP155,156 Inflammation (mild) Peripheral anterior synechiae (after ALT) Corneal endothelial damage in corneas with pigment on endothelium (after SLT)157. Post-operative management: [II,D] Check IOP in selected patients (e.g. with advanced glaucomatous damage, one- eyed patients, high pre-laser IOP, exfoliation syndrome, heavily pigmented trabecular meshwork). Use of topical corticosteroids or non-steroidal anti-inflammatory medication 3-4 times daily for 4-7 days. Effectiveness of laser trabeculoplasty: ALT and SLT have the same efficacy153,158. Laser trabeculoplasty is initially effective in 80 to 85% of treated eyes with a mean IOP reduction of 20 to 25% (of 6 to 9 mmHg). The effect wears off over time, for both ALT and SLT159. LT versus medication: In the Glaucoma Laser Trial, after 7 years of follow-up, patients with ALT had lower IOP (1.2 mmHg) than patients on medical treatment, and no difference in progression of glaucoma160. SLT has shown to decrease IOP to a degree similar to that of prostaglandin analogues after 9 to 12 months follow-up161 and appears to be repeatable30,31. Predictors of efficacy: Higher baseline IOP is associated with greater IOP reduction after SLT and ALT162,163. The effectiveness of ALT is influenced by the treating surgeon, and success is better when surgeons have more experience in ALT163,164. Pigmentation of the trabecular meshwork (TM) is important. ALT is less successful in eyes with no pigmentation of TM. SLT seems to be independent of the pigmentation of TM. Younger subjects (less than 40 years old) usually respond less to ALT165. 3.5.3 Laser Iridoplasty166,167 Main Indication: [II,D] Plateau iris syndrome confirmed by a patent iridotomy; the purpose is to enlarge the peripheral angle approach after iridotomy, to decrease the chance of progressive synechial closure. Lasers: Different types of continuous wave lasers can be used for photocoagulation, most frequently: argon laser, diode laser (810 nm), and the frequency-doubled Nd:YAG laser (532 nm). Preoperative preparation: [II,D] Instillation of Pilocarpine followed by the same preoperative preparation as for laser trabeculoplasty. Lens: Abraham (+66 diopters), Wise (+103 diopters), CGI©LASAG CH lens or the central non-mirrored part of the Goldmann lens. Contraindications: [I,D] Flat anterior chamber Extensive peripheral anterior synechiae. Laser parameters for laser Iridoplasty [II,D] Laser parameters [II,D] Contraction burns (long duration-low power-large spot size) Spot size 200-500 μm Exposure 0.3-0.6 sec Power 200-400 mW Location Aiming beam should be directed at the most peripheral part of the iris Optimal reaction Visible contraction of the peripheral iris with flattening of the iris curvature (without bubble formation or pigment release) Number of spots 20-24 spots over 360° leaving 2 beam diameters between each spot and avoiding visible radial vessels Complications: Mild iritis Corneal endothelial burns Transient elevation of IOP Post-operative synechiae of the pupil Permanent pupil dilation Iris atrophy Non-dilatable pupil Post-operative management: Topical corticosteroids or non-steroidal anti-inflammatory medication instilled for 4-7 days Prevention of IOP spikes 3.5.4 Cyclophotocoagulation168-170 Indications: [II,D] When filtration surgery or tubes are likely to fail, have failed, or are not feasible As an alternative to drainage devices Lasers used: Diode laser (810 nm); Argon laser Modes of laser delivery are: trans-scleral, endoscopic and transpupillary Trans-scleral cyclophotocoagulation: Laser diode cyclophotocoagulation with the G probe is the cyclodestructive procedure of choice because of the reduced incidence of complications compared with other cyclodestructive procedures [I,D]. Ultrasonic cyclodestruction: Ultrasonic circular cyclocoagulation using high-intensity focused ultrasound delivered by a circular miniaturized device was reported as a safe and effective technique to reduce intraocular pressure in patients with refractory glaucoma171,172. Anesthesia Retrobulbar or peribulbar injection of a 50:50 mixture of 2% lidocaine and 0.75% bupivicaine with hyaluronidase G probe positioning The G probe footplate is placed on the conjunctiva with the short side adjacent to the limbus, which positions the fiberoptic tip 1.2 mm behind the limbus. The ciliary body should be identified with transillumination as its position may vary and the placement of the G probe is adjusted accordingly173 Scleral transillumination The fibre optic light source is directed approx. 4 mm posterior to corneoscleral limbus to identify ciliary body by transillumination. The dark demarcation line indicates the anterior margin of the ciliary body Settings Recommended setting: duration of 2 sec., from 1500 mW for dark to 2000 mW for light-coloured irides and increase the energy until an audible »pop« is heard indicating tissue disruption. If a »pop« sound occurs during two sequential subsequent laser applications, the power is reduced by 150 mW and treatment completed at this power174 Applications 10-20 over 180°, energy 5-6 J per pulse, total treatment per session up to 270° of circumference avoiding 3 and 9 o'clock positions (to avoid long posterior ciliary nerves). Some surgeons prefer to use low energy and more applications. Retreatments are often needed, but the incidence of severe complications is low [II,D]. Technique: [II,D] Endoscopic cyclophotocoagulation: Endoscopic techniques combined with laser technology allow the photocoagulation of ciliary processes not visible via the transpupillary route. The approach can be limbal or through pars plana. Recently, endoscopic cyclophotocoagulation is most commonly performed in conjunction with cataract surgery in cases with early glaucoma175. Transpupillary cyclophotocoagulation: This procedure is limited to eyes in which a sufficient number of ciliary processes can be visualized gonioscopically, as in cases of aniridia, through a large surgical iridectomy or when broad anterior synechiae cause anterior displacement of the iris. New technology using ultra-sound cyclodestruction is currently under investigation. Complications:169,176 Rates of complications are higher in neovascular glaucoma and with treatment protocols using more than 80 J per session. Persistent inflammation Hyphaema Corneal decompensation Vision loss Hypotony and phthisis Post-operative management: [II,D] Consider analgesia. Topical corticosteroids and atropine instillation for 2-3 weeks. In the immediate postoperative period IOP should be monitored and the anti-glaucoma medication tapered accordingly. The effectiveness of treatment is assessed after 4 weeks. 3.6 - Incisional Surgery 3.6.1 General Principles The different techniques of incisional surgery have different indications depending on the type of glaucoma. Their adoption depends on: [I,D] the target IOP chosen for the individual situation the previous history (surgery, medications, degree of visual field loss) the risk profile (i.e. single eye, occupation, refractive status) the preferences and experience of the surgeon the patient opinion, expectation and postoperative compliance The decision to recommend glaucoma surgery should be made in the light of published clinical trials54,177. In the individual patient, a multitude of factors must be taken into account when deciding treatment including compliance, stage of glaucoma etc. Nevertheless, surgery should be considered whenever medical or laser treatment would appear unlikely to maintain sight in the glaucomatous eye [I,D]. It should not be left as a last resort (See Ch. 3.1). Angle-closure glaucoma is usually initially approached by laser iridotomy or peripheral iridectomy. Primary congenital glaucoma is usually treated with surgery, likely trabeculotomy or goniotomy, or combinations of filtration surgery with antifibrotic agents. For repeated surgery, cyclodestructive procedures and tube implants are more commonly used (See FC VI). 3.6.2 Techniques Since glaucoma surgery is successfully practiced in different ways by different ophthalmologists, a detailed description of surgical techniques is not within the scope of this text. The primary goal of surgery is to achieve a Target IOP without additional medication. Additional medications can be used if a Target IOP is not reached by surgery alone. Success rates of a surgical method in terms of IOP lowering can be best evaluated in the absence of adjunctive medical treatment. The number of preoperative versus postoperative medications may also depend on the variable compliance of the individual patient before and after surgery. Also, it is useful to count the percentage of “successes” below a defined IOP level as in Fig. 3.3. It is also important to consider not just the IOP but complications rates and, most importantly, functional outcomes. 3.6.2.1 Penetrating Glaucoma Surgery 3.6.2.1.1 Trabeculectomy The most widely used surgical procedure in OAG is the trabeculectomy, which produces a ‘guarded’ fistula between the anterior chamber and the subconjunctival space178,179. The introduction of improved operating microscopes, instruments and suture materials, has led to numerous modifications and refinements of the original operation180. Modifications include the size, shape and thickness of the scleral flap, limbal or fornix based conjunctival flaps, fixed, releasable or adjustable sutures and the use of antimetabolites and other antiscarring agents delivered in different ways to reduce wound healing181,182. In the hands of experts the long-term success rate of filtering surgery alone, or with adjunctive medical therapy in a previously unoperated eye has been reported at up to 90%178; there are large differences however in the criteria used for the definition of success and in the final success rates observed 183-192. The use of stainless steel implants as facilitators for performing filtration surgery should be weighted against the cost of the devices193-196. Long-term IOP control is achieved in many cases, although some patients do require further therapy or repeat surgery178,197,198. The alternatives to trabeculectomy in OAG include non-penetrating surgeries and drainage devices196,199-205. Indications: [II,D] In cases where other forms of therapy, like medicines or laser, have failed. In cases where other forms of therapy are not suitable (e.g. where compliance or side-effects are a problem) or appropriate medical treatment is not available. In cases where a Target Pressure is required to prevent clinically significant disease progression that cannot be reached with topical medications and/or laser. In cases which have such advanced glaucoma and high IOP at presentation that other forms of treatment are unlikely to be successful. Some studies have indicated that in terms of field survival, primary trabeculectomy was superior to medical treatment, but these studies may not be relevant to current medical practice as the evaluation of visual field was not done using todays analyses, and the medical treatment options were very limited206. More recent studies suggest that visual field progression is not significantly different whether initial treatment is medication or trabeculectomy207,208. The ophthalmologist must assess the risks and benefits of early surgery in each individual case. Long-term risks of trabeculectomy: Accelerated progression of senile cataracts is frequently seen after filtration surgery209,210. Patients undergoing trabeculectomy should be advised on the symptoms of a developing blebitis/endophthalmitis including red eye, tearing, discharge or decreased vision, and should be warned to immediately seek the help of an ophthalmologist if any of these symptoms develop in the operated eye211 [I,D]. Endophthalmitis is more common if the bleb is thin and cystic - a situation more commonly found with the use of a small treatment area of antimetabolites or full thickness filtration procedures. A long-tube drainage device should be used if the bleb cannot be sited beneath the upper lid [I,D]. 3.6.2.1.2 Trabeculotomy Trabeculotomy, alone or combined with trabeculectomy, is generally used for congenital and paediatric glaucoma and is less effective in adults212-214 [I,B]. It also may decrease the need for further filtering and shunting procedures215. A novel glaucoma procedure of trabeculotomy by internal approach was recently introduced183,216,217. 3.6.2.2 Non-Penetrating Glaucoma Surgery 3.6.2.2.1 Deep Sclerectomy In this technique, a deep lamella of corneosclera underneath the scleral flap is excised thus removing the outer wall of Schlemm’s canal. The outer layer of the inner wall of Schlemm’s canal is frequently also removed. Percolation of aqueous occurs through the porosity of the remaining trabecular meshwork, possibly through micro-perforations. When the scleral flap is repositioned, a “scleral lake” is created. A collagen implant or a hyaluronic acid device is often used to keep this scleral lake open. In a number of cases, a filtration bleb forms; long-term IOP levels appear higher than with trabeculectomy218-228. 3.6.2.2.2 Viscocanalostomy In this technique, hyaluronic acid is injected into Schlemm’s canal in addition to the dissection and excision of a deep lamella. The mechanism claimed to increase the outflow is the widening of Schlemm’s canal and of the collector channels as well as diffusion of aqueous from the “scleral lake”186,229,230. The majority of randomised controlled trials suggests that the pressure lowering of non-penetrating glaucoma surgery is not as marked as with trabeculectomy231-234. 3.6.2.2.3 Canaloplasty Canaloplasty is a non-penetrating, bleb-independent, glaucoma surgery that combines a 2-flap dissection to the trabeculo-Descemet’s membrane, like in viscocanalostomy methods, with a circumferential catheterization and viscodilation of Schlemm’s canal. In addition, a 10-0 polypropylene suture is placed within the canal to tension the inner wall and the associated trabecular meshwork with the intention of preventing the Schlemm’s canal collapse thus in theory restoring natural trabeculocanalicular aqueous outflow229,235-238. This technique is indicated in POAG, pigmentary glaucoma and pseudoexfoliative glaucoma and permits combined procedures with cataract surgery [II,D]. Contraindications to canaloplasty are primary or secondary ACG, neovascular glaucoma or cases needing a low target IOP. Intraoperative or postoperative complications (hyphema, hypotony secondary to a break in the trabeculo-descemetic window, hypertension, cataract, endophthalmitis) have a lower incidence than trabeculectomy239-242. Arguments in favour of non-penetrating glaucoma surgery: minimal postoperative care (no bleb management) reduced incidence of hypotony-related complications and cataract reduced incidence of intraoperative complications (iris prolapse, expulsive haemorrhage) Arguments against non-penetrating glaucoma surgery: less efficient in IOP reduction (mean IOP 2-4 mmHg higher) than after trabeculectomy difficult technique (learning curve) Nd:YAG laser goniopuncture often needed for IOP control Anatomical unpredictability Arguments in favour of trabeculectomy: lower long-term postoperative IOP fewer lOP-lowering medications needed postoperatively Arguments against trabeculectomy: possible higher rate of cataract formation postoperative bleb complications higher risk of postoperative hypotony and related complications (choroidal detachment) 3.6.3 Methods of Preventing Filtering Bleb Scarring 3.6.3.1 Antimetabolites Wound healing is one of the main determinants of the long-term intraocular pressure control after filtering surgery243,244. Excessive wound healing or repair leads to scar formation in the conjunctiva. Risk factors for conjunctival scarring are young age, afro- caribbean/hispanic race, inflammatory eye disease (e.g. uveitis, ocular pemphigoid, Stevens-Johnson syndrome), long-term multiple topical medical therapy, aphakia by intracapsular surgery, recent intraocular surgery (<3 months), previous conjunctival incisional surgery, previous failed glaucoma filtration surgery, neovascular glaucoma188,245. Antimetabolites such as 5-fluorouracil (5-FU) and mitomycin-C (MMC) are frequently used in patients undergoing glaucoma filtration surgery in order to reduce postoperative conjunctival scarring and improve drainage [I,A]. The use of these substances continues to be refined. Indications and techniques need to be carefully considered, particularly the use of larger antimetabolite treatment areas to minimise thin cystic blebs246,247 [I,D]. The risk of corneal epithelial erosions, epitheliopathy, late hypotony, bleb leaks, and blebitis/endophthalmitis must be considered [I,D]. The use of antimetabolites, especially MMC, is potentially hazardous, and requires careful surgical technique to prevent over drainage and hypotony, or a thin focal drainage bleb with a higher risk of infection [I,D]. New antifibrotic agents and techniques are under investigation to more specifically target and modulate the biological processes of wound healing after filtration surgery, aiming for a lower risk of complications243,248-250. 3.6.3.1.1 General Precautions The use of antimetabolites will enhance the unfavourable effect of any imprecision during surgery. It is important to assess each individual case for risk factors, and/or for the need of low target IOP and titrate the substance and dosage used accordingly based on local experience. If aqueous flow is not well controlled persistent hypotony will occur. Strategies to increase control of flow include smaller sclerostomies, larger and/or thicker scleral flaps, tighter suturing of the scleral flap, and releasable or adjustable sutures [II,D]. Research studies suggest that a large surface area of cytotoxic treatment together with large scleral flaps and accurately sutured fornix-based conjunctival flaps lead to more diffuse, posteriorly extended non-cystic blebs giving a considerable reduction in bleb- related complications such as blebitis and endophthalmitis197,247,251,252 [I,B]. It is advisable for a surgeon not familiar with these drugs to start with weaker agents (e.g. 5-FU rather than MMC) or lower concentrations of MMC [II,D]. Antimetabolites should not enter the eye [I,D]. 5-FU has a pH of 9.0 and one drop (0.05 ml) of MMC is enough to cause irreversible endothelial damage: precautions for use and disposal of cytotoxic substances should be observed [I,D]. 5-FU and MMC are not officially approved for ocular applications. Their use in many cases as adjunctive in filtration surgery, however, has become standard clinical practice. 3.6.3.1.2 Administration 5-Fluorouracil: Intraoperative use [II,D] Concentration: 25 or 50 mg/ml undiluted solution. Administration: intraoperatively on a filter paper or a sponge. Time of exposure: usually 5 minutes (shorter time has minimal effect). Rinse: with at least 20 ml of balanced salt solution. Postoperative use [II,D] Relative contraindication if epithelial problems present. Concentration: 0.1 ml injection of 50 mg/ml undiluted solution. Administration: adjacent to but not into bleb (pH 9), with a small calibre needle (e.g. 30 G needle on insulin syringe). Reflux from the injection site over the ocular surface should be prevented253. Repeated injections are often necessary. Mitomycin C: Intraoperative use [II,D] Concentration: 0.1-0.5 mg/ml (care must be taken in diluting it to the desired concentration). Administration: intraoperatively on a filter paper or a sponge. Avoid contact with cut edge of conjunctive flap. Time of exposure: 1-5 minutes. Rinse: with at least 20 ml of balanced salt solution. Postoperative use [II,D] Concentration: 0.1 ml injection of 0.02 mg/ml solution. Administration: adjacent to but not into bleb, with a small calibre needle (e.g. 30 G needle on insulin syringe). Reflux from the injection site over the ocular surface should be prevented253. A very small amount of MMC entering the eye will irreversibly damage the endothelium. It is useful for some needling procedures but recommended only in experienced hands. 3.6.3.2 Alternative Methods of Preventing Filtering Bleb Scarring Irradiation, PDT and inhibition of growth factors have been used, but no long-term clinical studies to support their use are yet available243,249. Alternative Glaucoma Surgery New alternative surgical techniques with the aim obtaining a higher safety profile than filtration surgery were proposed during the last several years. Under the acronym of M.I.G.S. “Minimally Invasive Glaucoma Surgery” are now collectively grouped both ab-interno and ab-externo procedures, not necessarily involving the use of an implantable device, not always bleb-independent for efficacy. The general aim would be to entail significantly less tissue manipulation than filtration surgery, with less side effects and sizeable IOP-lowering efficacy. There are no well controlled comparative trials available to support the superiority among any of these procedures nor versus trabeculectomy, for both safety and efficacy254,255. These techniques are currently performed in selected glaucoma patients with early to moderate disease and preferably in combination with cataract surgery [II,D]. ALTERNATIVE GLAUCOMA SURGERY (*) Based on subconjunctival filtration – trans-scleral filtration, ab-interno device (AqueSys Xen) – trans-scleral filtration, ab-externo device (InnFocus Microshunt) Based on suprachoroidal drainage – suprachoroidal stents, ab-interno (Glaukos iStent Supra, Transcend CyPass) Based on Schlemm’s canal drainage/bypass/expansion – trabecular bypass stents/canal expanders (Glaukos iStent, Ivantis Hydrus) – ab-Interno trabeculectomy (Trabectome) – ab-externo canaloplasty/trabeculotomy (iScience catheter) (*) THIS LIST IS NOT ALL INCLUSIVE. The EGS does not endorse any product or procedures. 3.6.4 Complex Cases Complicated glaucoma cases such as those that have failed previous surgery, secondary glaucomas, congenital glaucomas, et cetera require specialist treatment. In addition to trabeculectomy, other forms of therapy may be necessary such as drainage devices and ciliary body ablation. 3.6.5 Long-Tube Drainage Devices The use of long-tube drainage devices such as those described by Molteno256-263, Krupin264-266 , Baer veldt 267-272, Ahmed268, 273-280 or Schocket 281-284 are generally reserved for patients with risk factors for a poor result with trabeculectomy with antimetabolite [II,D], although recent trials established their efficacy and safety as a primary surgical procedure258,285 [II,B]. Factors that decrease the chances of successful trabeculectomies and, therefore, make tube surgery attractive, include previous failed filtering surgery with antimetabolites, excessive conjunctival scarring due to previous ocular surgery with severe conjunctival or surface disease, active neovascular disease, paediatric aphakia, or where filtration surgery is going to be technically difficult286,287 [II,D]. 3.7 - Cataract and Glaucoma Surgery When glaucoma surgery is indicated and there is a visually significant cataract the two procedures can be performed combined or sequentially. The decision is to be made according to the clinical findings, after discussing with the patients advantages and disadvantages of each approach [I,D]. In case of angle closure or narrow angle approach, it is important to evaluate the lens as a component of the raised IOP [I,D] (See also Ch 2.4) Small-incision phacoemulsification cataract extraction is one of the most relevant surgical advances for our glaucoma patients. It allows faster and better visual recovery, and with appropriate techniques it is safely applicable in cases with small pupil, shallow AC or pre-existing filtering blebs. Futhermore it can be combined effectively and safely with filtering procedures, including trabeculectomy, miniature drainage implants and deep sclerectomy205,288-290. Different new glaucoma surgical techniques which can be combined with phacoemulsification (i.e endoscopic cyclophotocoagulation, trabecular bypass stents, ab interno trabeculectomy and canaloplasty) have been proposed in the last years291. Randomized clinical trials are presently needed to clarify this topic. Despite the improved results of small incision phacoemulsification and of filtration surgery with anti-metabolites there is no evidence to support a generalized switch from sequential to combined surgery and viceversa [I,D]. In summary: Modern phacoemulsification with clear cornea incisions does not interfere with subsequent glaucoma surgical procedures292 The development or worsening of a visually significant cataract is common after glaucoma surgery209 Cataract surgery performed after trabeculectomy can affect the IOP control209,293 Cataract surgery alone may be of limited benefit in lowering the IOP in open angle glaucoma and the effect appears to be proportional to the preoperative IOP values; such effect may be greater in angle closure glaucoma / narrow angles and appears to be proportional to the degree of anterior chamber opening294-296 Combined procedures allow for greater IOP reduction and fewer IOP spikes in the immediate postoperative period than phacoemulsification alone297-299 The success rate of combined phacoemulsification and filtration surgery is usually not as favourable as filtration surgery alone and the use of antimetabolites is recommended in all cases.

To compare the change in lamina cribrosa (LC) displacement in response to intraocular pressure (IOP) lowering in patients with open-angle glaucoma (OAG) using spectral-domain optical coherence tomography (SD-OCT). Observational case series. One hundred eyes of 100 patients with OAG in whom IOP at the follow-up examination had decreased by at least 20% compared with the baseline IOP. Serial horizontal B-scan images of the optic nerve head (ONH) were obtained from each eye using enhanced depth imaging SD-OCT. Approximately 65 B-scans covering the optic discs were obtained before and 3 to 6 months after lowering IOP. The baseline and follow-up LC depths (the distance from the Bruch's membrane opening plane to the level of the anterior LC surface) were measured in B-scan images from each eye. The mean and maximum amount of reductions in LC depth measured in the 7 selected B-scan images. Intraocular pressure decreased from 21.2±9.1 to 10.5±2.6 mmHg. The percent of IOP reduction was significantly related to the untreated IOP (P < 0.001). There was a significant decrease in the LC depth at the follow-up examination compared with the baseline value (P < 0.001). The magnitude of LC depth reduction was significantly associated with younger age, higher untreated IOP, higher baseline IOP, and greater percent of IOP reduction (all P < 0.02). Reversal of the LC displacement was observed after IOP-lowering treatment in OAG. The degree of LC displacement reversal was related to the amount of IOP lowering. Copyright © 2013 American Academy of Ophthalmology. Published by Elsevier Inc. All rights reserved.

To determine the effect of intraocular pressure (IOP) lowering on the optic disc in patients of the Collaborative Initial Glaucoma Treatment Study (CIGTS) after 5 years. Randomized clinical trial. The baseline and 5-year stereoscopic optic disc photographs of 348 eyes (patients) randomized to medical or surgical treatment of open-angle glaucoma (OAG) were assessed by 2 independent readers for change in a masked side-by-side comparison, and confirmed by an independent committee. Three hundred and three (87.1%) eyes showed no change, 22 (6.3%) showed enlargement of the cup along any meridian (progression), and 23 (6.6%) showed a reduction in the cup along any meridian (reversal of cupping). Incidence of optic disc progression was higher (P = .007) in the medicine group, 18/185 (10%) than in the surgical group 4/163 (3%); and the incidence of reversal of cupping was higher (P < .001) in the surgical group, 21/163 (13%), than the medicine group, 2/185 (1%), (P < .001). Visual field (VF) worsening (mean deviation) was significantly associated with progression of optic disc cupping (P < .001). Reversal of cupping was also associated with lower postoperative IOP (P < .001). Reversal of cupping was not associated with improvement of either visual acuity or central VFs. Surgery prevents or delays glaucomatous progression as measured by optic disc criteria in patients with early OAG. Reversal of cupping occurs more frequently in the surgical group than in the medical treatment group. Reversal is associated with lower IOP, but is not associated with improved visual function.