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==Surgery==
==Surgery==
*Surgery therapy of glaucoma is undertaken when:
*Surgery therapy of glaucoma is undertaken when:
#:medical therapy is not appropriate, not tolerated, not effective, or not properly utilized by a particular patient
:#medical therapy is not appropriate, not tolerated, not effective, or not properly utilized by a particular patient
#:the glaucoma remains uncontrolled with either documented progressivedamage or a very high risk of further damage.
:#the glaucoma remains uncontrolled with either documented progressivedamage or a very high risk of further damage.
*Surgery is usually the primary approach for infantile and pupillary-blockglaucoma.
*Surgery is usually the primary approach for infantile and pupillary-blockglaucoma.
*When surgery is indicated, the clinical setting must guide the selection of the appropriate procedure.
*When surgery is indicated, the clinical setting must guide the selection of the appropriate procedure.
#:trabeculectomy and its variations
:#[[trabeculectomy]] and its variations
#:non-penetrating filtration procedures
:#non-penetrating filtration procedures
#:glaucoma drainage tube implants
:#glaucoma drainage tube implants
#:angle surgery for congenital glaucoma
:#angle surgery for congenital glaucoma
#:ciliary body ablation.
:#ciliary body ablation.
#:iridectomy
:#iridectomy
#:gonioplasty
:#gonioplasty
SURGERY FOR OPEN-ANGLE GLAUCOMA_________________________
===Surgery For Open Angle Glaucoma===
Surgery is indicated when IOP cannot be maintained by nonsurgical therapies at
*Surgery is indicated when [[Intraocular pressure|IOP]] cannot be maintained by nonsurgical therapies at a level considered low enough to prevent further pressure-related damage to theoptic nerve or visual field loss. Surgery has traditionally been considered only
a level considered low enough to prevent further pressure-related damage to the
when medical therapy has failed and is associated with long-term risks of blebassociated problems, cataracts, and infection.
optic nerve or visual field loss. Surgery has traditionally been considered only
*The glaucoma may be uncontrolled for various reasons:
when medical therapy has failed and is associated with long-term risks of blebassociated
:#Maximal medical therapy fails to adequately reduce IOP
problems, cataracts, and infection.
:#The amount of medical therapy necessary to control IOP is not well tolerance or places the patient at unacceptable risk
The glaucoma may be uncontrolled for various reasons:
:#Optic nerve cupping or visual field loss is progressing despite apparent “adequate” reduction of IOP with medical therapy.
1. Maximal medical therapy fails to adequately reduce IOP
:#The patient cannot comply with the necessary medical regimen
2. The amount of medical therapy necessary to control IOP is not well tolerance
====Laser Trabeculoplasty (LTP)<ref name="GeffenAssia2017">{{cite journal|last1=Geffen|first1=Noa|last2=Assia|first2=Ehud I.|last3=Melamed|first3=Shlomo|title=Laser-Assisted Techniques for Penetrating and Nonpenetrating Glaucoma Surgery|volume=59|year=2017|pages=100–112|issn=0250-3751|doi=10.1159/000458490}}</ref>====
or places the patient at unacceptable risk
*'''Mechanism of action'''
3. Optic nerve cupping or visual field loss is progressing despite apparent
:*LTP stimulates the growth of trabecular meshwork endothelial cells → restorestrabecular meshwork function → improves the outflow facility
“adequate” reduction of IOP with medical therapy.
*'''Indications'''
4. The patient cannot comply with the necessary medical regimen
:#Patients with glaucoma on maximum tolerated medical therapy who require lower IOP and in whom the angle is open on gonioscopy.
------------------------LASER TRABECULOPLASTY (LTP) ------------------------
:#LTP effectively reduces IOP in patients with [[Open-angle glaucoma|POAG]], pigmentary glaucoma, and exfoliation syndrome. Aphakic and pseudophakic eyes may respond less favorably than phakic eyes; therefore, LTP may be more effective before than after cataract surgery.
Mechanism of action
:#The role of initial LTP in POAG is at least as effective as medications for the first 2 years. LTP may postpone the need for conventional surgery or additional medications. When effective, LTP is expected to lower IOP 20%-25%.
LTP stimulates the growth of trabecular meshwork endothelial cells → restores
*'''Relative contraindications'''
trabecular meshwork function → improves the outflow facility
:#Inflammatory glaucoma
Indications
:#Membrane in the angle
1. Patients with glaucoma on maximum tolerated medical therapy who require
:#Young patients who have developmental defects.
lower IOP and in whom the angle is open on gonioscopy.
:#The lack of effect in the fellow eye
2. LTP effectively reduces IOP in patients with POAG, pigmentary glaucoma,
*'''Preoperative evaluation'''
and exfoliation syndrome. Aphakic and pseudophakic eyes may respond less
:#Optic nerve evaluation
favorably than phakic eyes; therefore, LTP may be more effective before than
:#Visual field examination
after cataract surgery.
:#Gonioscopy to check that the angle must be open. The amount of pigment in the angle will help determine the laser settings for argon laser; a more pigmented angleresponds to lower laser energy
3. The role of initial LTP in POAG is at least as effective as medications for the
*'''Argon laser procedure'''
first 2 years. LTP may postpone the need for conventional surgery or
:#Set at 300-1000 mW, 50 um, and 0.1 second.Laser beam is focused through a gonio lens at the junction of the anterior unpigmented and the posterior pigmented edge of the trabecular meshwork.
additional medications.
:#Laser energy was applied to the entire circumference (360°) of the trabecular meshwork. End point: blanching of the trabecular meshwork or production of a tiny bubble. If a large bubble appears, the power is reduced.
When effective, LTP is expected to lower IOP 20%-25%.
:#Application to the posterior trabecular meshwork tends to produce inflammation, pigment dispersion, prolonged elevation of IOP, and PAS.
Relative contraindications
:#Diode laser procedure: is similar; set at 600-1000 mW, 75 um, and 0.02second.
1. Inflammatory glaucoma
*'''Complications'''
2. Membrane in the angle
:#Transient rise in IOP (occurs in 20% of patients), usually evident within thefirst 2-4 hours after treatment. Topical medications shown to blunt the IOPspikes include alpha2-agonists, beta blockers, pilocarpine, and topical CAIs. Hyperosmotic agents, oral CAIs, and ice packs may be helpful in eyes with IOP spikes not responsible to topical medication.
3. Young patients who have developmental defects.
:#Low-grade iritis
4. The lack of effect in the fellow eye
:#Persistent elevation of IOP requiring filtering surgery
Preoperative evaluation
:#Hyphema
1. Optic nerve evaluation
:#Formation of PAS
2. Visual field examination
:#Re-treatment of an angle that has been fully treated has a lower success rate and a higher complication rate than does primary treatment. If initial LTP fails tobring IOP under control, a trabeculectomy should be considered.
3. Gonioscopy the angle must be open. The amount of pigment in the angle
 
will help determine the laser settings for argon laser; a more pigmented angle
====Selective Laser Trabeculoplasty<ref name="Schlote2017">{{cite journal|last1=Schlote|first1=Torsten|title=Stellenwert der selektiven Lasertrabekuloplastik (SLT)|journal=Klinische Monatsblätter für Augenheilkunde|year=2017|issn=0023-2165|doi=10.1055/s-0043-102946}}</ref>====
responds to lower laser energy
:*Q-switched 532 nm Nd:YAG laser trabeculoplasty,the laser targets intracellular melanin.
Argon laser procedure
 
1. Set at 300-1000 mW, 50 um, and 0.1 second.
====Incisional Surgery for Open Angle Glaucoma====
2. Laser beam is focused through a goniolens at the junction of the anterior
:#The goal of filtering surgery (fistulizing procedure) is to create a new pathway(fistula) for the bulk flow of aqueous humor from the anterior chamber throughthe surgical defect in the sclera into the subconjunctival and sub-Tenon’s space.
unpigmented and the posterior pigmented edge of the trabecular meshwork.
:#The filtering procedure most commonly used is guarded trabeculectomy.
Laser energy was applied to the entire circumference (360°) of the trabecular
*'''Indications''': a patient with glaucoma on maximum tolerable medical therapy (MTMT) who has had maximal laser benefit and whose optic nerve function is failing or is likely to fail.The physician can determine that the patient is at MTMT only by advancing therapy beyond the tolerated level and documenting intolerance. An alternative concept is core therapy, in which treatment consists of those medications likelyto work well in combination.
meshwork. End point: blanching of the trabecular meshwork or production of
*'''Relative contraindications'''
a tiny bubble. If a large bubble appears, the power is reduced.
:#Blind eye → ciliary body ablation is a better alternative for lowering IOP
3. Application to the posterior trabecular meshwork tends to produce
:#Active anterior segment neovascularization (rubeosis iridis) or active iritis → the underlying problem should be addressed first, or a surgical alternativesuch as tube implant surgery should be considered.
inflammation, pigment dispersion, prolonged elevation of IOP, and PAS.
:#Sustained extensive conjunctival injury or extremely thin sclera fromextensive prior surgery or necrotizing scleritis.
Diode laser procedure: is similar; set at 600-1000 mW, 75 um, and 0.02
:#Younger or aphakic/pseudophakic patients.  
second.
:#Black patients.
Complications
:#Patients with uveitic glaucoma or with previously failed filtration procedures
1. Transient rise in IOP (occurs in 20% of patients) usually evident within the
*'''Preoperative evaluation'''
first 2-4 hours after treatment. Topical medications shown to blunt the IOP
:#The patient must be medically stable for an invasive ocular procedure under local anesthesia.
spikes include alpha2-agonists, beta blockers, pilocarpine, and topical CAIs.
:#Control of preoperative inflammation with corticosteroids helps to reducepostoperative iritis and scarring of the filtering bleb.
Hyperosmotic agents, oral CAIs, and ice packs may be helpful in eyes with
:#Anticholinesterase agents should be discontinued if possible and replacedtemporarily by alternative medications at least 2-3 weeks before surgery toreduce bleeding and iridocyclitis.
IOP spikes not responsible to topical medication.
:#IOP should be reduced as close as possible to normal levels before surgery isperformed, to minimize the risk of expulsive choroidal hemorrhage.
2. Low-grade iritis
:#Antiplatelet medications should be discontinued.
3. Persistent elevation of IOP requiring filtering surgery
:#Systemic hypertension should be controlled.
4. Hyphema
:#Patient should be informed :  
5. Formation of PAS
:::*The purpose and expectations of surgery: to arrest or delay progressive visual loss caused by their glaucoma.
Re-treatment of an angle that has been fully treated has a lower success rate and
:::*Glaucoma surgery alone rarely improves vision.
a higher complication rate than does primary treatment. If initial LTP fails to
:::*Glaucoma medications may still be required postoperatively
bring IOP under control, a trabeculectomy should be considered.
:::*Surgery may fail completely
-------------------SELECTIVE LASER TRABECULOPLASTY --------------------
:::*Vision could be lost as a result of surgery
Q-switched 532 nm Nd:YAG laser trabeculoplasty
:::*Glaucoma may progress despite successful surgery
• The laser targets intracellular melanin
:::*Patients with far advanced visual field loss or field loss that is impinging on fixation are at risk for total loss of central acuity following a surgical procedure. The possible mechanism of this phenomenon include:
--------INCISIONAL SURGERY FOR OPEN-ANGLE GLAUCOMAS --------
::::*Cystoid macular edema
The goal of filtering surgery (fistulizing procedure) is to create a new pathway
::::*Early postoperative IOP spiking
(fistula) for the bulk flow of aqueous humor from the anterior chamber through
::::*Shifting of the lamina, further compromising remaining axons
the surgical defect in the sclera into the subconjunctival and sub-Tenon’s space.
::::*Optic nerve ischemia, possibly related to regional anesthesia
The filtering procedure most commonly used is guarded trabeculectomy.
====Trabeculectomy====
Indications: a patient with glaucoma on maximum tolerable medical therapy
:*A guarded partial-thickness filtering procedure performed by removing ablock of limbal tissue beneath a scleral flap. The scleral flap providesresistance and limits the outflow of aqueous, thereby reducing the complications associated with early hypotony (such as flat anterior chamber, cataract, serous and hemorrhagic choroidal effusion, macular edema, and optic nerve edema)
(MTMT) who has had maximal laser benefit and whose optic nerve function is
:*The use of antifibrotic agents (such as mitomycin-C and 5-fluorouracil),combined with techniques of releasable sutures or laser suture lysis, enhancesthe longevity of guarded procedures.
failing or is likely to fail.
:*Succesful trabeculectomy surgery:
The physician can determine that the patient is at MTMT only by advancing
:#Involves reducing IOP and avoiding or managing complications
therapy beyond the tolerated level and documenting intolerance. An alternative
:#Depends on appropriate and timely postoperative intervention to influencethe functioning of the filter.
concept is core therapy, in which treatment consists of those medications likely
:#Complete healing of the epithelial and conjunctival wound with incompletehealing of the scleral wound is the goal of this procedure.
to work well in combination.
:*'''Trabeculectomy procedure''' :
Relative contraindications
::* Preoperative evaluation
1. Blind eye → ciliary body ablation is a better alternative for lowering IOP
::* Exposure.  
2. Active anterior segment neovascularization (rubeosis iridis) or active iritis →
:::* A corneal traction suture or superior rectus bridle suture can rotate the globe down, giving excellent exposure of the superior sulcus and limbus.
the underlying problem should be addressed first, or a surgical alternative
::* Conjunctival wound.
such as tube implant surgery should be considered.
:::*Fornix-based conjunctival flap → provides better exposure at the limbus; more difficult to achieve a water-tight closure.
3. Sustained extensive conjunctival injury or extremely thin sclera from
:::*Limbal-based conjunctival flap → technically more challenging but allows for a secure closure well away from the limbus.
extensive prior surgery or necrotizing scleritis.
::* Scleral flap (3-4 mm trapezoidal or rectangular flap).
4. Younger or aphakic/pseudophakic patients. Black patients.
:::*The flap is dissected anteriorly into clear cornea.
5. Patients with uveitic glaucoma or with previously failed filtration procedures
::*Paracentesis
Preoperative evaluation
:::*To control the anterior chamber through instillation of BSS or viscoelastic
1. The patient must be medically stable for an invasive ocular procedure under
:::*Allows for gradual lowering of IOP
local anesthesia.
:::*Intraoperative testing of the patency of the filtration site as well as of the integrity of the conjunctival closure.
2. Control of preoperative inflammation with corticosteroids helps to reduce
::*Sclerotomy (with a punch or with sharp dissection).
postoperative iritis and scarring of the filtering bleb.
:::* The size of the ostomy is determined by the scleral flap and the amount of overlap desired by the surgeon.
3. Anticholinesterase agents should be discontinued if possible and replaced
:::*A small amount of tissue should remain at the edges of the ostomy to allow for resistance to outflow from the flap.
temporarily by alternative medications at least 2-3 weeks before surgery to
::* Iridectomy
reduce bleeding and iridocyclitis.
:::*To lessen the risk of iris occluding the ostomy
4. IOP should be reduced as close as possible to normal levels before surgery is
:::*To reduce the risk of pupillary block
performed, to minimize the risk of expulsive choroidal hemorrhage.
::*Closure of scleral flap
5. Antiplatelet medications should be discontinued.
:::*With the advent of laser suture lysis and releasable sutures, many surgeons close the flap relatively tightly to avoid early shallow chambers. After a few days, flap sutures are released to promote filtration.
6. Systemic hypertension should be controlled.
:::*Flow should be tested around the flap before closing the conjunctiva.
7. Patient should be informed:
:::*Leakage around the flap may be adjusted intraoperatively by the placement of additional sutures, removal of sutures, or application of cautery to shrink the wound edges.
The purpose and expectations of surgery: to arrest or delay progressive
::* Closure of conjunctiva
visual loss caused by their glaucoma.
:::*Fornix-based flap → conjunctiva is secured at the limbus
Glaucoma surgery alone rarely improves vision.
:::*Limbal-based flap   conjunctiva and   Tenon’s capsule are   closed separately or in a single layer.
Glaucoma medications may still be required postoperatively
::* Postoperative management
Surgery may fail completely
:::*Topical antibiotics and corticosteroids
Vision could be lost as a result of surgery
:::* Topical cycloplegic agents or mydriatics
Glaucoma may progress despite successful surgery
:::*Sub-Tenon’s corticosteroids or a short course of systemic corticosteroids
Patients with far advanced visual field loss or field loss that is impinging on
::* Antifibrotic agents
fixation are at risk for total loss of central acuity following a surgical
:::* 5-fluorouracil (5-FU), a pyrimidine analogue
procedure. The possible mechanism of this phenomenon include:
::::*5-FU   deoxynucleotide 5-fluoro-2’-deoxyuridine 5’-monophosphate (FdUMP) → interferes with DNA synthesis through its action on thymidylate synthetase
1. Cystoid macular edema
::::* Inhibits fibroblast proliferation; reduces scarring after filtering surgery.
2. Early postoperative IOP spiking
::::*50 mg/ml on a surgical sponge is used intraoperatively.
3. Shifting of the lamina, further compromising remaining axons
::::*A total of 5 mg in 0.1-0.5 cc can be injected postoperatively.
4. Optic nerve ischemia, possibly related to regional anesthesia
:::* Mitomycin-C (MMC), derived from Streptomyces caespitosus
Trabeculectomy
::::* Acts as an alkylating agent after enzyme activation resulting in DNA crosslinking.
1. A guarded partial-thickness filtering procedure performed by removing a
::::*  Most commonly administered intraoperatively by placing a surgical sponge soaked in MMC within the subconjunctival space in contact with sclera at the planned trabeculectomy site.
block of limbal tissue beneath a scleral flap. The scleral flap provides
::::* Concentrations are typically between 0.2 and 0.4 mg/ml with a duration of application from 1 to 4 minutes
resistance and limits the outflow of aqueous, thereby reducing the
:::* They should be used with caution in primary trabeculectomies on young myopic patients because of an increased risk of hypotony.
complications associated with early hypotony (such as flat anterior chamber,
:::* Techniques allowing tighter initial wound closure of the scleral flap help toprevent early postoperative hypotony.
cataract, serous and hemorrhagic choroidal effusion, macular edema, and
::::* The use of releasable flap sutures
optic nerve edema)
::::*The placement of additional sutures that can be cut postoperatively.
2. The use of antifibrotic agents (such as mitomycin-C and 5-fluorouracil),
::::* Laser suture lysis
combined with techniques of releasable sutures or laser suture lysis, enhances
:*'''Early complications''':  
the longevity of guarded procedures.
::#Infection
3. Succesful trabeculectomy surgery:
::#Hypotony
Involves reducing IOP and avoiding or managing complications
::#Flat anterior chamber
Depends on appropriate and timely postoperative intervention to influence
::#Aqueous misdirection
the functioning of the filter.
::#Hyphema
4. Complete healing of the epithelial and conjunctival wound with incomplete
::#Formation or acceleration of cataract
healing of the scleral wound is the goal of this procedure.
::#Transient IOP elevation
Trabeculectomy procedures
::#Cystoid Macular Edema
1. Preoperative evaluation
::#Hypotony maculopathy
2. Exposure. A corneal traction suture or superior rectus bridle suture can rotate
::#Choroidal effusion
the globe down, giving excellent exposure of the superior sulcus and limbus.
::#Suprachoroidal hemorrhage
3. Conjunctival wound.
::#Persistent uveitis
Fornix-based conjunctival flap → provides better exposure at the limbus;
::#Dellen formation
more difficult to achieve a water-tight closure.
::#Loss of vision
Limbal-based conjunctival flap → technically more challenging but allows
:*'''Late complications''':  
for a secure closure well away from the limbus.
::#Leakage or failure of the filtering bleb
4. Scleral flap (3-4 mm trapezoidal or rectangular flap).
::#Cataract
The flap is dissected anteriorly into clear cornea.
::#Blebitis,
5. Paracentesis
::#Endophthalmitis (bleb infection)
To control the anterior chamber through instillation of BSS or viscoelastic
::#Symptomatic bleb (dysesthetic bleb)
Allows for gradual lowering of IOP
::#Bleb migration
Intraoperative testing of the patency of the filtration site as well as of the
::#Hypotony
integrity of the conjunctival closure.
*'''Full Thickness Sclerotomy'''
6. Sclerotomy (with a punch or with sharp dissection).
:#A block of limbal tissue is removed with a punch, trephine, laser or cautery.
The size of the ostomy is determined by the scleral flap and the amount of
:#Advantages: IOP can be lowered and maintained at a lower level for long periods of time.
overlap desired by the surgeon.
:#Disadvantages: higher incidence of postoperative flat anterior chamber, cataract, hypotony, choroidal effusion, leakage of filtering blebs, and endophthalmitis.
A small amount of tissue should remain at the edges of the ostomy to allow
*'''Combined Cataract & Filtering Surgery'''
for resistance to outflow from the flap.
:*Indications
7. Iridectomy
::#Glaucoma that is uncontrollable either medically or after laser trabeculoplasty when visual function is significantly impaired by a cataract
To lessen the risk of iris occluding the ostomy
::#Cataract requiring extraction in a glaucoma patient who has advanced visual field loss
To reduce the risk of pupillary block
::#Cataract requiring extraction in a glaucoma patient requiring medications to control IOP in whom medical therapy is poorly tolerated
8. Closure of scleral flap
::#Cataract requiring extraction in a glaucoma patient who requires multiple medications to control IOP
• With the advent of laser suture lysis and releasable sutures, many surgeons
:*Contraindications
close the flap relatively tightly to avoid early shallow chambers. After a
::#Glaucoma that requires a very low target IOP
few days, flap sutures are released to promote filtration.
::#Advanced glaucoma with uncontrolled IOP and immediate need for successful reduction of IOP, thus Glaucoma surgery alone is preferred.
Flow should be tested around the flap before closing the conjunctiva.
===Surgery for Angle Closure Glaucoma===
Leakage around the flap may be adjusted intraoperatively by the placement
*The first clinical decision point following the diagnosis of ACG is to distinguish between angle closure based on a pupillary block mechanism and angle closure based on another mechanism.
of additional sutures, removal of sutures, or application of cautery to shrink
*The treatment of pupillary-block glaucoma, whether primary or secondary, is a laser or an incisional iridectomy
the wound edges.
*For eyes with secondary angle closure not caused by pupillary block, an attempt should be made to identify and treat underlying conditions.
9. Closure of conjunctiva
====Laser Iridectomy====
Fornix-based flap → conjunctiva is secured at the limbus
*Indications
Limbal-based flap → conjunctiva and Tenon’s capsule are closed
:#The presence of pupillary block
separately or in a single layer.
:#The need to determine the presence of pupillary block
10. Postoperative management
:#To prevent pupillary block in an eye considered at risk, as determined by gonioscopic evaluation or because of an angle-closure attack in the fellow eye:#This procedure provides an alternative route for aqueous trapped in the posterior chamber to enter the anterior chamber, allowing the iris to recede from its occlusion of the trabecular meshwork.
Topical antibiotics and corticosteroids
:*Contraindications: active rubeosis iridis, systemic anticoagulants consumption, angle closure not caused by a pupillary block mechanism
Topical cycloplegic agents or mydriatics
:*Preoperative consideration
Sub-Tenon’s corticosteroids or a short course of systemic corticosteroids
::#The glaucoma attack should be attempted medically, then proceed to surgery.
Antifibrotic agents
::#Care should be taken to keep the iridectomy peripheral and covered by eyelid, if possible, to avoid monocular diplopia.
1. 5-fluorouracil (5-FU), a pyrimidine analogue
::#Pilocarpine may be helpful by stretching and thinning the iris
5-FU → deoxynucleotide 5-fluoro-2’-deoxyuridine 5’-monophosphate
::#Apraclonidine or other agents can help blunt IOP spikes
(FdUMP) → interferes with DNA synthesis through its action on
:*Technique
thymidylate synthetase
::#Set the argon laser at 800-1000 mW, 50 um, 0.02-0.1 second, using a condensing contact lens. There are a number of variations in technique, and iris color dictates which technique is chosen. Complications include localized lens opacity, acute rise in IOP, transient or persistent iritis, early closure of the iridectomy, and corneal and retinal burns
Inhibits fibroblast proliferation; reduces scarring after filtering surgery.
::#Q-switched Nd:YAG laser generally requires fewer pulses and less energy. The effectiveness of this laser is not affected by iris color. With a condensing contact lens, the typical initial laser setting is 2-8 mJ. Complications include corneal burns, disruption of the anterior lens capsule or corneal endothelium, bleeding, postoperative IOP spike, inflammation, and delayed closure of the iridectomy.
50 mg/ml on a surgical sponge is used intraoperatively.
:*Postoperative care
A total of 5 mg in 0.1-0.5 cc can be injected postoperatively.
::#Bleeding → particularly with Nd:YAG laser; compression of the eye with the laser lens will tamponade the vessel, or argon laser can be used to coagulate the vessel.
2. Mitomycin-C (MMC), derived from Streptomyces caespitosus
::#IOP spikes → can be treated as described in the section on LTP
Acts as an alkylating agent after enzyme activation resulting in DNA crosslinking.
::#Inflammation → topical corticosteroids
Most commonly administered intraoperatively by placing a surgical sponge
:*Complications
soaked in MMC within the subconjunctival space in contact with sclera at
::#Focal lens damage. It can be avoided by ceasing the procedure as soon as the iris is penetrated
the planned trabeculectomy site.
::#Retinal detachment is very rare, associated with Nd:YAG laser.
Concentrations are typically between 0.2 and 0.4 mg/ml with a duration of
::#Bleeding and IOP spike
application from 1 to 4 minutes
====Laser Gonioplasty or Peripheral Iridioplasty====
3. They should be used with caution in primary trabeculectomies on young
:*Indications
myopic patients because of an increased risk of hypotony.
::#ACG resulting from plateau iris syndrome and nanophthalmos.
Techniques allowing tighter initial wound closure of the scleral flap help to
::#To open the angle temporarily, in anticipation of a more definitive laser or incisional iridectomy.
prevent early postoperative hypotony.
:*Contraindications: active rubeosis iridis, systemic anticoagulants consumption, angle closure not caused by a pupillary block mechanism
1. The use of releasable flap sutures
:*Technique
2. The placement of additional sutures that can be cut postoperatively.
::#Set the argon laser at 200-500 mW, 200-500 um, 0.1-0.5 second
3. Laser suture lysis
::#Stromal burns are created in the peripheral iris to cause contraction and flattening.
Early complications: infection, hypotony, flat anterior chamber, aqueous
====Incisional Surgery for Angle Closure====
misdirection, hyphema, formation or acceleration of cataract, transient IOP
:*Peripheral iridectomy may be required if a patent iridectomy cannot beachieved with a laser (cloudy cornea, flat anterior chamber, insufficient patient
elevation, cystoid macular edema, hypotony maculopathy, choroidal effusion,
suprachoroidal hemorrhage, persistent uveitis, dellen formation, loss of vision
Late complications: leakage or failure of the filtering bleb, cataract, blebitis,
endophthalmitis (bleb infection), symptomatic bleb (dysesthetic bleb), bleb
migration, hypotony.
• When an initial filtering procedure is not adequate to control the glaucoma and
resumption of medical therapy is not successful, revision of original surgery,
repeat filtering surgery at a new site, and possibly cyclodestructive procedures
may be indicated.
----------------------FULL-THICKNESS SCLERECTOMY -------------------------
• A block of limbal tissue is removed with a punch, trephine, laser or cautery.
• Advantages: IOP can be lowered and maintained at a lower level for long
periods of time.
• Disadvantages: higher incidence of postoperative flat anterior chamber, cataract,
hypotony, choroidal effusion, leakage of filtering blebs, and
endophthalmitis.
-----------COMBINED CATARACT AND FILTERING SURGERY ------------
• Indications
1.Glaucoma that is uncontrollable either medically or after laser trabeculoplasty
when visual function is significantly impaired by a cataract
2. Cataract requiring extraction in a glaucoma patient who has advanced visual
field loss
3. Cataract requiring extraction in a glaucoma patient requiring medications to
control IOP in whom medical therapy is poorly tolerated
4.Cataract requiring extraction in a glaucoma patient who requires multiple
medications to control IOP
• Contraindications
1.Glaucoma that requires a very low target IOP
2.Advanced glaucoma with uncontrolled IOP and immediate need for
successful reduction of IOP
Glaucoma surgery alone is preferred.
SURGERY FOR ANGLE-CLOSURE GLAUCOMA_____________________
The first clinical decision point following the diagnosis of ACG is to distinguish
between angle closure based on a pupillary block mechanism and angle closure
based on another mechanism.
The treatment of pupillary-block glaucoma, whether primary or secondary, is a
laser or an incisional iridectomy
For eyes with secondary angle closure not caused by pupillary block, an attempt
should be made to identify and treat underlying conditions.
---------------------------------LASER IRIDECTOMY-----------------------------------
• Indications
1. The presence of pupillary block
2. The need to determine the presence of pupillary block
3. To prevent pupillary block in an eye considered at risk, as determined by
gonioscopic evaluation or because of an angle-closure attack in the fellow eye
→ This procedure provides an alternative route for aqueous trapped in the
posterior chamber to enter the anterior chamber, allowing the iris to recede
from its occlusion of the trabecular meshwork.
• Contraindications: active rubeosis iridis, systemic anticoagulants consumption,
angle closure not caused by a pupillary block mechanism
• Preoperative consideration
1. The glaucoma attack should be attempted medically, then proceed to surgery.
2. Care should be taken to keep the iridectomy peripheral and covered by eyelid,
if possible, to avoid monocular diplopia.
3. Pilocarpine may be helpful by stretching and thinning the iris
4. Apraclonidine or other agents can help blunt IOP spikes
• Technique
1. Set the argon laser at 800-1000 mW, 50 um, 0.02-0.1 second, using a
condensing contact lens. There are a number of variations in technique, and
iris color dictates which technique is chosen. Complications include localized
lens opacity, acute rise in IOP, transient or persistent iritis, early closure of
the iridectomy, and corneal and retinal burns
2. Q-switched Nd:YAG laser generally requires fewer pulses and less energy.
The effectiveness of this laser is not affected by iris color. With a condensing
contact lens, the typical initial laser setting is 2-8 mJ. Complications include
corneal burns, disruption of the anterior lens capsule or corneal endothelium,
bleeding, postoperative IOP spike, inflammation, and delayed closure of the
iridectomy.
• Postoperative care
1. Bleeding → particularly with Nd:YAG laser; compression of the eye with the
laser lens will tamponade the vessel, or argon laser can be used to coagulate
the vessel.
2. IOP spikes → can be treated as described in the section on LTP
3. Inflammation → topical corticosteroids
• Complications
1. Focal lens damage → can be avoided by ceasing the procedure as soon as the
iris is penetrated
2. Retinal detachment → very rare, associated with Nd:YAG laser.
3. Bleeding and IOP spike
----------LASER GONIOPLASTY or PERIPHERAL IRIDOPLASTY----------
• Indications
1. ACG resulting from plateau iris syndrome and nanophthalmos.
2. To open the angle temporarily, in anticipation of a more definitive laser or
incisional iridectomy.
• Contraindications: same as those for laser iridectomy
• Technique
1. Set the argon laser at 200-500 mW, 200-500 um, 0.1-0.5 second
2. Stromal burns are created in the peripheral iris to cause contraction and
flattening.
----------------INCISIONAL SURGERY FOR ANGLE-CLOSURE---------------
Peripheral iridectomy may be required if a patent iridectomy cannot be
achieved with a laser (cloudy cornea, flat anterior chamber, insufficient patient
cooperation)
cooperation)
Cataract extraction might be considered when pupillary block is associated
:*Cataract extraction might be considered when pupillary block is associated with a visually significant cataract.
with a visually significant cataract.
:*Chamber deepening and goniosynechialysis may break PAS.
Chamber deepening and goniosynechialysis may break PAS.
====Glaucoma Tube Shunt====
-----------------------------GLAUCOMA TUBE SHUNT-------------------------------
:*Types of glaucoma drainage devices
Types of glaucoma drainage devices
::#Resistance (valved) or flow-restricted devices: Krupin, Ahmed
1. Resistance (valved) or flow-restricted devices: Krupin, Ahmed
::#Nonresistance (nonvalved) devices: Molteno, Baelveldt
2. Nonresistance (nonvalved) devices: Molteno, Baelveldt
::#Anterior chamber tube shunt to an encircling band (ACTSEB) – Schocket procedure
3. Anterior chamber tube shunt to an encircling band (ACTSEB) – Schocket
:*Indications
procedure
::#Trabeculectomy failure
Indications
::#Failed trabeculectomy with antifibrotics
1. Trabeculectomy failure
::# Active uveitis
2. Failed trabeculectomy with antifibrotics
::#Neovascular glaucoma
3. Active uveitis
::#Inadequate conjunctiva
4. Neovascular glaucoma
::#Impending need for penetrating keratoplasty
5. Inadequate conjunctiva
::#Others: poor candidate for trabeculectomy, potential for visual acuity, need for lower IOP
6. Impending need for penetrating keratoplasty
:*Contraindications
7. Others: poor candidate for trabeculectomy, potential for visual acuity, need
::#Eyes with very poor visual potential
for lower IOP
::#Patients unable to comply with self-care in the postoperative period.
Contraindications
::# Borderline corneal endothelial function
1. Eyes with very poor visual potential
:*Preoperative considerations
2. Patients unable to comply with self-care in the postoperative period.
::#The status of the conjunctiva
3. Borderline corneal endothelial function
::#The health of the sclera at the anticipated tube and external reservoir sites
Preoperative considerations
::#The location of vitreous in the eye
1. The status of the conjunctiva
:*Technique for implantation:
2. The health of the sclera at the anticipated tube and external reservoir sites
::#The superotemporal quadrant is preferred.
3. The location of vitreous in the eye
::# The extraocular plate or valve mechanism is sutured between the vertical and horizontal rectus muscles posterior to the muscle insertions.
Technique for implantation:
::#The tube is routed anteriorly to enter in the chamber angle or through the pars plana for posterior implantation in eyes that have had a vitrectomy.
1. The superotemporal quadrant is preferred.
::#The tube is covered with tissue such as sclera, pericardium, or dura to help prevent erosion.
2. The extraocular plate or valve mechanism is sutured between the vertical and
:*Postoperative management: topical steroids, antibiotics, and cycloplegics; IOP monitoring
horizontal rectus muscles posterior to the muscle insertions.
:*Complications: tube-corneal touch, flat chamber and hypotony, tube occlusion, tube migration, valve malfunction, tube or plate exposure or erosion
3. The tube is routed anteriorly to enter in the chamber angle or through the pars
====Ciliary Body Ablation Procedures=====
plana for posterior implantation in eyes that have had a vitrectomy.
:*Procedures: cyclocryotherapy, diathermy, therapeutic ultrasound, thermal lasers (continuous Nd:YAG, argon, diode)
4. The tube is covered with tissue such as sclera, pericardium, or dura to help
:*Goal: To reduce aqueous secretion by destroying a portion of the cilary body.
prevent erosion.
:* Indications
Postoperative management: topical steroids, antibiotics, and cycloplegics; IOP
::# Eyes that have poor visual potential or are poor candidates for incisional surgery → generally reserved for eyes that have been or are likely to be unresponsive to other modes of therapy.
monitoring
:*Contraindications: eyes with good vision
Complications: tube-corneal touch, flat chamber and hypotony, tube occlusion,
:*Preoperative evaluation: same as for incisional glaucoma surgery
tube migration, valve malfunction, tube or plate exposure or erosion
:* Postoperative management: analgesics, narcotics
--------------------CILIARY BODY ABLATION PROCEDURES------------------
:*Complications: prolonged hypotony, pain, inflammation, cystoid macular edema, hemorrhage, phthisis bulbi
Procedures: cyclocryotherapy, diathermy, therapeutic ultrasound, thermal lasers
====Cyclodialysis====
(continuous Nd:YAG, argon, diode)
:*Indications: aphakic patients who have not responses to filtering surgery.
Goal: To reduce aqueous secretion by destroying a portion of the cilary body.
:*Techniques
Indications
:#A small scleral incision is made approximately 4 mm from the limbus.
1. Eyes that have poor visual potential or are poor candidates for incisional
:# A fine spatula is passed under the sclera into the anterior chamber.
surgery → generally reserved for eyes that have been or are likely to be
:# This spatula disinserts a portion of the ciliary muscle from the scleral spur and creates a cleft in the angle, providing direct communication between the anterior chamber and the suprachoroidal space.
unresponsive to other modes of therapy.
:*Complications: bleeding, inflammation, cataract, stripping of Descemet’s membrane, profound hypotony.
Contraindications: eyes with good vision
====Non Penetrating Procedures====
Preoperative evaluation: same as for incisional glaucoma surgery
:#Deep sclerectomy with collagen implant
Postoperative management: analgesics, narcotics
:# Deep sclerectomy with injection of viscoelastic into Schlemm’s canal (viscocanalostomy)
Complications: prolonged hypotony, pain, inflammation, cystoid macular
:# Involve creation of a superficial scleral flap and a deeper scleral dissection underneath to leave behind only a thin layer of sclera and Descemet’s membrane.
edema, hemorrhage, phthisis bulbi
 
------------------------------------CYCLODIALYSIS--------------------------------------
==Surgeries for Congenital Glaucoma==
Indications: aphakic patients who have not responses to filtering surgery.
 
Techniques
====Goniotomy & Trabeculectomy====
1. A small scleral incision is made approximately 4 mm from the limbus.
:*Indications: childhood glaucoma
2. A fine spatula is passed under the sclera into the anterior chamber.
:*Contraindications: infants with unstable health, multiple anomalies with poor prognosis and a grossly disorganized eye.
3. This spatula disinserts a portion of the ciliary muscle from the scleral spur
:*Technique
and creates a cleft in the angle, providing direct communication between the
:#The anterior chamber should be filled with viscoelastic to prevent collapse and to tamponade bleeding.
anterior chamber and the suprachoroidal space.
:#Goniotomy → A needle-knife is passed across the anterior chamber, and a superficial incision is made in the anterior aspect of the trabecular meshwork under gonioscopic control.
Complications: bleeding, inflammation, cataract, stripping of Descemet’s
:#Trabeculotomy → A fine wirelike instrument (trabeculotome) is inserted into Schlemm’s canal from an external incision, and the trabecular meshwork is torn by rotating the trabeculotome into the anterior chamber.
membrane, profound hypotony.
:#Goniotomy is possible only in an eye with a relatively clear cornea, whereas trabeculotomy can be performed whether the cornea is clear or cloudy.
------------------------NONPENETRATING PROCEDURES-------------------------
 
1. Deep sclerectomy with collagen implant
2. Deep sclerectomy with injection of viscoelastic into Schlemm’s canal
(viscocanalostomy)
Involve creation of a superficial scleral flap and a deeper scleral dissection
underneath to leave behind only a thin layer of sclera and Descemet’s
membrane.
CONGENITAL OR INFANTILE GLAUCOMA________________________
----------------------GONIOTOMY and TRABECULOTOMY-----------------------
Indications: childhood glaucoma
Contraindications: infants with unstable health, multiple anomalies with poor
prognosis and a grossly disorganized eye.
Technique
1. The anterior chamber should be filled with viscoelastic to prevent collapse
and to tamponade bleeding.
2. Goniotomy → A needle-knife is passed across the anterior chamber, and a
superficial incision is made in the anterior aspect of the trabecular meshwork
under gonioscopic control.
3. Trabeculotomy → A fine wirelike instrument (trabeculotome) is inserted into
Schlemm’s canal from an external incision, and the trabecular meshwork is
torn by rotating the trabeculotome into the anterior chamber.
Goniotomy is possible only in an eye with a relatively clear cornea, whereas
trabeculotomy can be performed whether the cornea is clear or cloudy.
==References==
==References==
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[[Category:Emergency medicine]]
[[Category:Mature chapter]]
[[Category:Mature chapter]]
[[Category:Primary care]]

Latest revision as of 21:53, 29 July 2020

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Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]Associate Editor(s)-in-Chief: Rohan Bir Singh, M.B.B.S.[2]

Overview

Glaucoma is a group of diseases affecting the optic nerve that results in vision loss and is frequently characterized by raised intraocular pressure (IOP). There are many glaucoma surgeries, and variations or combinations of those surgeries, that facilitate the escape of excess aqueous humor from the eye to lower intraocular pressure, and a few that lower IOP by decreasing the production of aqueous.

Surgery

  • Surgery therapy of glaucoma is undertaken when:
  1. medical therapy is not appropriate, not tolerated, not effective, or not properly utilized by a particular patient
  2. the glaucoma remains uncontrolled with either documented progressivedamage or a very high risk of further damage.
  • Surgery is usually the primary approach for infantile and pupillary-blockglaucoma.
  • When surgery is indicated, the clinical setting must guide the selection of the appropriate procedure.
  1. trabeculectomy and its variations
  2. non-penetrating filtration procedures
  3. glaucoma drainage tube implants
  4. angle surgery for congenital glaucoma
  5. ciliary body ablation.
  6. iridectomy
  7. gonioplasty

Surgery For Open Angle Glaucoma

  • Surgery is indicated when IOP cannot be maintained by nonsurgical therapies at a level considered low enough to prevent further pressure-related damage to theoptic nerve or visual field loss. Surgery has traditionally been considered only

when medical therapy has failed and is associated with long-term risks of blebassociated problems, cataracts, and infection.

  • The glaucoma may be uncontrolled for various reasons:
  1. Maximal medical therapy fails to adequately reduce IOP
  2. The amount of medical therapy necessary to control IOP is not well tolerance or places the patient at unacceptable risk
  3. Optic nerve cupping or visual field loss is progressing despite apparent “adequate” reduction of IOP with medical therapy.
  4. The patient cannot comply with the necessary medical regimen

Laser Trabeculoplasty (LTP)[1]

  • Mechanism of action
  • LTP stimulates the growth of trabecular meshwork endothelial cells → restorestrabecular meshwork function → improves the outflow facility
  • Indications
  1. Patients with glaucoma on maximum tolerated medical therapy who require lower IOP and in whom the angle is open on gonioscopy.
  2. LTP effectively reduces IOP in patients with POAG, pigmentary glaucoma, and exfoliation syndrome. Aphakic and pseudophakic eyes may respond less favorably than phakic eyes; therefore, LTP may be more effective before than after cataract surgery.
  3. The role of initial LTP in POAG is at least as effective as medications for the first 2 years. LTP may postpone the need for conventional surgery or additional medications. When effective, LTP is expected to lower IOP 20%-25%.
  • Relative contraindications
  1. Inflammatory glaucoma
  2. Membrane in the angle
  3. Young patients who have developmental defects.
  4. The lack of effect in the fellow eye
  • Preoperative evaluation
  1. Optic nerve evaluation
  2. Visual field examination
  3. Gonioscopy to check that the angle must be open. The amount of pigment in the angle will help determine the laser settings for argon laser; a more pigmented angleresponds to lower laser energy
  • Argon laser procedure
  1. Set at 300-1000 mW, 50 um, and 0.1 second.Laser beam is focused through a gonio lens at the junction of the anterior unpigmented and the posterior pigmented edge of the trabecular meshwork.
  2. Laser energy was applied to the entire circumference (360°) of the trabecular meshwork. End point: blanching of the trabecular meshwork or production of a tiny bubble. If a large bubble appears, the power is reduced.
  3. Application to the posterior trabecular meshwork tends to produce inflammation, pigment dispersion, prolonged elevation of IOP, and PAS.
  4. Diode laser procedure: is similar; set at 600-1000 mW, 75 um, and 0.02second.
  • Complications
  1. Transient rise in IOP (occurs in 20% of patients), usually evident within thefirst 2-4 hours after treatment. Topical medications shown to blunt the IOPspikes include alpha2-agonists, beta blockers, pilocarpine, and topical CAIs. Hyperosmotic agents, oral CAIs, and ice packs may be helpful in eyes with IOP spikes not responsible to topical medication.
  2. Low-grade iritis
  3. Persistent elevation of IOP requiring filtering surgery
  4. Hyphema
  5. Formation of PAS
  6. Re-treatment of an angle that has been fully treated has a lower success rate and a higher complication rate than does primary treatment. If initial LTP fails tobring IOP under control, a trabeculectomy should be considered.

Selective Laser Trabeculoplasty[2]

  • Q-switched 532 nm Nd:YAG laser trabeculoplasty,the laser targets intracellular melanin.

Incisional Surgery for Open Angle Glaucoma

  1. The goal of filtering surgery (fistulizing procedure) is to create a new pathway(fistula) for the bulk flow of aqueous humor from the anterior chamber throughthe surgical defect in the sclera into the subconjunctival and sub-Tenon’s space.
  2. The filtering procedure most commonly used is guarded trabeculectomy.
  • Indications: a patient with glaucoma on maximum tolerable medical therapy (MTMT) who has had maximal laser benefit and whose optic nerve function is failing or is likely to fail.The physician can determine that the patient is at MTMT only by advancing therapy beyond the tolerated level and documenting intolerance. An alternative concept is core therapy, in which treatment consists of those medications likelyto work well in combination.
  • Relative contraindications
  1. Blind eye → ciliary body ablation is a better alternative for lowering IOP
  2. Active anterior segment neovascularization (rubeosis iridis) or active iritis → the underlying problem should be addressed first, or a surgical alternativesuch as tube implant surgery should be considered.
  3. Sustained extensive conjunctival injury or extremely thin sclera fromextensive prior surgery or necrotizing scleritis.
  4. Younger or aphakic/pseudophakic patients.
  5. Black patients.
  6. Patients with uveitic glaucoma or with previously failed filtration procedures
  • Preoperative evaluation
  1. The patient must be medically stable for an invasive ocular procedure under local anesthesia.
  2. Control of preoperative inflammation with corticosteroids helps to reducepostoperative iritis and scarring of the filtering bleb.
  3. Anticholinesterase agents should be discontinued if possible and replacedtemporarily by alternative medications at least 2-3 weeks before surgery toreduce bleeding and iridocyclitis.
  4. IOP should be reduced as close as possible to normal levels before surgery isperformed, to minimize the risk of expulsive choroidal hemorrhage.
  5. Antiplatelet medications should be discontinued.
  6. Systemic hypertension should be controlled.
  7. Patient should be informed :
  • The purpose and expectations of surgery: to arrest or delay progressive visual loss caused by their glaucoma.
  • Glaucoma surgery alone rarely improves vision.
  • Glaucoma medications may still be required postoperatively
  • Surgery may fail completely
  • Vision could be lost as a result of surgery
  • Glaucoma may progress despite successful surgery
  • Patients with far advanced visual field loss or field loss that is impinging on fixation are at risk for total loss of central acuity following a surgical procedure. The possible mechanism of this phenomenon include:
  • Cystoid macular edema
  • Early postoperative IOP spiking
  • Shifting of the lamina, further compromising remaining axons
  • Optic nerve ischemia, possibly related to regional anesthesia

Trabeculectomy

  • A guarded partial-thickness filtering procedure performed by removing ablock of limbal tissue beneath a scleral flap. The scleral flap providesresistance and limits the outflow of aqueous, thereby reducing the complications associated with early hypotony (such as flat anterior chamber, cataract, serous and hemorrhagic choroidal effusion, macular edema, and optic nerve edema)
  • The use of antifibrotic agents (such as mitomycin-C and 5-fluorouracil),combined with techniques of releasable sutures or laser suture lysis, enhancesthe longevity of guarded procedures.
  • Succesful trabeculectomy surgery:
  1. Involves reducing IOP and avoiding or managing complications
  2. Depends on appropriate and timely postoperative intervention to influencethe functioning of the filter.
  3. Complete healing of the epithelial and conjunctival wound with incompletehealing of the scleral wound is the goal of this procedure.
  • Trabeculectomy procedure :
  • Preoperative evaluation
  • Exposure.
  • A corneal traction suture or superior rectus bridle suture can rotate the globe down, giving excellent exposure of the superior sulcus and limbus.
  • Conjunctival wound.
  • Fornix-based conjunctival flap → provides better exposure at the limbus; more difficult to achieve a water-tight closure.
  • Limbal-based conjunctival flap → technically more challenging but allows for a secure closure well away from the limbus.
  • Scleral flap (3-4 mm trapezoidal or rectangular flap).
  • The flap is dissected anteriorly into clear cornea.
  • Paracentesis
  • To control the anterior chamber through instillation of BSS or viscoelastic
  • Allows for gradual lowering of IOP
  • Intraoperative testing of the patency of the filtration site as well as of the integrity of the conjunctival closure.
  • Sclerotomy (with a punch or with sharp dissection).
  • The size of the ostomy is determined by the scleral flap and the amount of overlap desired by the surgeon.
  • A small amount of tissue should remain at the edges of the ostomy to allow for resistance to outflow from the flap.
  • Iridectomy
  • To lessen the risk of iris occluding the ostomy
  • To reduce the risk of pupillary block
  • Closure of scleral flap
  • With the advent of laser suture lysis and releasable sutures, many surgeons close the flap relatively tightly to avoid early shallow chambers. After a few days, flap sutures are released to promote filtration.
  • Flow should be tested around the flap before closing the conjunctiva.
  • Leakage around the flap may be adjusted intraoperatively by the placement of additional sutures, removal of sutures, or application of cautery to shrink the wound edges.
  • Closure of conjunctiva
  • Fornix-based flap → conjunctiva is secured at the limbus
  • Limbal-based flap → conjunctiva and Tenon’s capsule are closed separately or in a single layer.
  • Postoperative management
  • Topical antibiotics and corticosteroids
  • Topical cycloplegic agents or mydriatics
  • Sub-Tenon’s corticosteroids or a short course of systemic corticosteroids
  • Antifibrotic agents
  • 5-fluorouracil (5-FU), a pyrimidine analogue
  • 5-FU → deoxynucleotide 5-fluoro-2’-deoxyuridine 5’-monophosphate (FdUMP) → interferes with DNA synthesis through its action on thymidylate synthetase
  • Inhibits fibroblast proliferation; reduces scarring after filtering surgery.
  • 50 mg/ml on a surgical sponge is used intraoperatively.
  • A total of 5 mg in 0.1-0.5 cc can be injected postoperatively.
  • Mitomycin-C (MMC), derived from Streptomyces caespitosus
  • Acts as an alkylating agent after enzyme activation resulting in DNA crosslinking.
  • Most commonly administered intraoperatively by placing a surgical sponge soaked in MMC within the subconjunctival space in contact with sclera at the planned trabeculectomy site.
  • Concentrations are typically between 0.2 and 0.4 mg/ml with a duration of application from 1 to 4 minutes
  • They should be used with caution in primary trabeculectomies on young myopic patients because of an increased risk of hypotony.
  • Techniques allowing tighter initial wound closure of the scleral flap help toprevent early postoperative hypotony.
  • The use of releasable flap sutures
  • The placement of additional sutures that can be cut postoperatively.
  • Laser suture lysis
  • Early complications:
  1. Infection
  2. Hypotony
  3. Flat anterior chamber
  4. Aqueous misdirection
  5. Hyphema
  6. Formation or acceleration of cataract
  7. Transient IOP elevation
  8. Cystoid Macular Edema
  9. Hypotony maculopathy
  10. Choroidal effusion
  11. Suprachoroidal hemorrhage
  12. Persistent uveitis
  13. Dellen formation
  14. Loss of vision
  • Late complications:
  1. Leakage or failure of the filtering bleb
  2. Cataract
  3. Blebitis,
  4. Endophthalmitis (bleb infection)
  5. Symptomatic bleb (dysesthetic bleb)
  6. Bleb migration
  7. Hypotony
  • Full Thickness Sclerotomy
  1. A block of limbal tissue is removed with a punch, trephine, laser or cautery.
  2. Advantages: IOP can be lowered and maintained at a lower level for long periods of time.
  3. Disadvantages: higher incidence of postoperative flat anterior chamber, cataract, hypotony, choroidal effusion, leakage of filtering blebs, and endophthalmitis.
  • Combined Cataract & Filtering Surgery
  • Indications
  1. Glaucoma that is uncontrollable either medically or after laser trabeculoplasty when visual function is significantly impaired by a cataract
  2. Cataract requiring extraction in a glaucoma patient who has advanced visual field loss
  3. Cataract requiring extraction in a glaucoma patient requiring medications to control IOP in whom medical therapy is poorly tolerated
  4. Cataract requiring extraction in a glaucoma patient who requires multiple medications to control IOP
  • Contraindications
  1. Glaucoma that requires a very low target IOP
  2. Advanced glaucoma with uncontrolled IOP and immediate need for successful reduction of IOP, thus Glaucoma surgery alone is preferred.

Surgery for Angle Closure Glaucoma

  • The first clinical decision point following the diagnosis of ACG is to distinguish between angle closure based on a pupillary block mechanism and angle closure based on another mechanism.
  • The treatment of pupillary-block glaucoma, whether primary or secondary, is a laser or an incisional iridectomy
  • For eyes with secondary angle closure not caused by pupillary block, an attempt should be made to identify and treat underlying conditions.

Laser Iridectomy

  • Indications
  1. The presence of pupillary block
  2. The need to determine the presence of pupillary block
  3. To prevent pupillary block in an eye considered at risk, as determined by gonioscopic evaluation or because of an angle-closure attack in the fellow eye:#This procedure provides an alternative route for aqueous trapped in the posterior chamber to enter the anterior chamber, allowing the iris to recede from its occlusion of the trabecular meshwork.
  • Contraindications: active rubeosis iridis, systemic anticoagulants consumption, angle closure not caused by a pupillary block mechanism
  • Preoperative consideration
  1. The glaucoma attack should be attempted medically, then proceed to surgery.
  2. Care should be taken to keep the iridectomy peripheral and covered by eyelid, if possible, to avoid monocular diplopia.
  3. Pilocarpine may be helpful by stretching and thinning the iris
  4. Apraclonidine or other agents can help blunt IOP spikes
  • Technique
  1. Set the argon laser at 800-1000 mW, 50 um, 0.02-0.1 second, using a condensing contact lens. There are a number of variations in technique, and iris color dictates which technique is chosen. Complications include localized lens opacity, acute rise in IOP, transient or persistent iritis, early closure of the iridectomy, and corneal and retinal burns
  2. Q-switched Nd:YAG laser generally requires fewer pulses and less energy. The effectiveness of this laser is not affected by iris color. With a condensing contact lens, the typical initial laser setting is 2-8 mJ. Complications include corneal burns, disruption of the anterior lens capsule or corneal endothelium, bleeding, postoperative IOP spike, inflammation, and delayed closure of the iridectomy.
  • Postoperative care
  1. Bleeding → particularly with Nd:YAG laser; compression of the eye with the laser lens will tamponade the vessel, or argon laser can be used to coagulate the vessel.
  2. IOP spikes → can be treated as described in the section on LTP
  3. Inflammation → topical corticosteroids
  • Complications
  1. Focal lens damage. It can be avoided by ceasing the procedure as soon as the iris is penetrated
  2. Retinal detachment is very rare, associated with Nd:YAG laser.
  3. Bleeding and IOP spike

Laser Gonioplasty or Peripheral Iridioplasty

  • Indications
  1. ACG resulting from plateau iris syndrome and nanophthalmos.
  2. To open the angle temporarily, in anticipation of a more definitive laser or incisional iridectomy.
  • Contraindications: active rubeosis iridis, systemic anticoagulants consumption, angle closure not caused by a pupillary block mechanism
  • Technique
  1. Set the argon laser at 200-500 mW, 200-500 um, 0.1-0.5 second
  2. Stromal burns are created in the peripheral iris to cause contraction and flattening.

Incisional Surgery for Angle Closure

  • Peripheral iridectomy may be required if a patent iridectomy cannot beachieved with a laser (cloudy cornea, flat anterior chamber, insufficient patient

cooperation)

  • Cataract extraction might be considered when pupillary block is associated with a visually significant cataract.
  • Chamber deepening and goniosynechialysis may break PAS.

Glaucoma Tube Shunt

  • Types of glaucoma drainage devices
  1. Resistance (valved) or flow-restricted devices: Krupin, Ahmed
  2. Nonresistance (nonvalved) devices: Molteno, Baelveldt
  3. Anterior chamber tube shunt to an encircling band (ACTSEB) – Schocket procedure
  • Indications
  1. Trabeculectomy failure
  2. Failed trabeculectomy with antifibrotics
  3. Active uveitis
  4. Neovascular glaucoma
  5. Inadequate conjunctiva
  6. Impending need for penetrating keratoplasty
  7. Others: poor candidate for trabeculectomy, potential for visual acuity, need for lower IOP
  • Contraindications
  1. Eyes with very poor visual potential
  2. Patients unable to comply with self-care in the postoperative period.
  3. Borderline corneal endothelial function
  • Preoperative considerations
  1. The status of the conjunctiva
  2. The health of the sclera at the anticipated tube and external reservoir sites
  3. The location of vitreous in the eye
  • Technique for implantation:
  1. The superotemporal quadrant is preferred.
  2. The extraocular plate or valve mechanism is sutured between the vertical and horizontal rectus muscles posterior to the muscle insertions.
  3. The tube is routed anteriorly to enter in the chamber angle or through the pars plana for posterior implantation in eyes that have had a vitrectomy.
  4. The tube is covered with tissue such as sclera, pericardium, or dura to help prevent erosion.
  • Postoperative management: topical steroids, antibiotics, and cycloplegics; IOP monitoring
  • Complications: tube-corneal touch, flat chamber and hypotony, tube occlusion, tube migration, valve malfunction, tube or plate exposure or erosion

Ciliary Body Ablation Procedures=

  • Procedures: cyclocryotherapy, diathermy, therapeutic ultrasound, thermal lasers (continuous Nd:YAG, argon, diode)
  • Goal: To reduce aqueous secretion by destroying a portion of the cilary body.
  • Indications
  1. Eyes that have poor visual potential or are poor candidates for incisional surgery → generally reserved for eyes that have been or are likely to be unresponsive to other modes of therapy.
  • Contraindications: eyes with good vision
  • Preoperative evaluation: same as for incisional glaucoma surgery
  • Postoperative management: analgesics, narcotics
  • Complications: prolonged hypotony, pain, inflammation, cystoid macular edema, hemorrhage, phthisis bulbi

Cyclodialysis

  • Indications: aphakic patients who have not responses to filtering surgery.
  • Techniques
  1. A small scleral incision is made approximately 4 mm from the limbus.
  2. A fine spatula is passed under the sclera into the anterior chamber.
  3. This spatula disinserts a portion of the ciliary muscle from the scleral spur and creates a cleft in the angle, providing direct communication between the anterior chamber and the suprachoroidal space.
  • Complications: bleeding, inflammation, cataract, stripping of Descemet’s membrane, profound hypotony.

Non Penetrating Procedures

  1. Deep sclerectomy with collagen implant
  2. Deep sclerectomy with injection of viscoelastic into Schlemm’s canal (viscocanalostomy)
  3. Involve creation of a superficial scleral flap and a deeper scleral dissection underneath to leave behind only a thin layer of sclera and Descemet’s membrane.

Surgeries for Congenital Glaucoma

Goniotomy & Trabeculectomy

  • Indications: childhood glaucoma
  • Contraindications: infants with unstable health, multiple anomalies with poor prognosis and a grossly disorganized eye.
  • Technique
  1. The anterior chamber should be filled with viscoelastic to prevent collapse and to tamponade bleeding.
  2. Goniotomy → A needle-knife is passed across the anterior chamber, and a superficial incision is made in the anterior aspect of the trabecular meshwork under gonioscopic control.
  3. Trabeculotomy → A fine wirelike instrument (trabeculotome) is inserted into Schlemm’s canal from an external incision, and the trabecular meshwork is torn by rotating the trabeculotome into the anterior chamber.
  4. Goniotomy is possible only in an eye with a relatively clear cornea, whereas trabeculotomy can be performed whether the cornea is clear or cloudy.

References

  1. Geffen, Noa; Assia, Ehud I.; Melamed, Shlomo (2017). "Laser-Assisted Techniques for Penetrating and Nonpenetrating Glaucoma Surgery". 59: 100–112. doi:10.1159/000458490. ISSN 0250-3751.
  2. Schlote, Torsten (2017). "Stellenwert der selektiven Lasertrabekuloplastik (SLT)". Klinische Monatsblätter für Augenheilkunde. doi:10.1055/s-0043-102946. ISSN 0023-2165.

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