Retinal traction detachment (RTD) or tractional retinal detachment (TRD) is defined as the separation of the neurosensory retina from the retinal pigment epithelium (RPE) due to the traction caused by proliferative membranes present over the retinal surface or vitreous. The proliferative membranes can result from different etiologies of proliferative retinopathies, the most common being proliferative diabetic retinopathy (PDR), which is a complication of prolonged and uncontrolled diabetes mellitus.[1]
The detached retina takes a concave shape in contrast to the convex shape of rhegmatogenous retinal detachment (RRD). In contrast to RRD, which is caused by one or more retinal breaks, RTDs are caused by tractional forces, and there is no retinal break in the area of RTD.
Retinal traction detachment can result from various causes of proliferative retinopathies. These causes can be broadly divided into 2 types, those affecting the adult population and those affecting the pediatric population.
Causes of RTD in adult population include:
Causes of RTD in the pediatric population include:
The exact epidemiology of Retinal traction detachment has not been reported in large scale studies, mainly because of its multifactorial etiology. However, one study by Poulsen et al. reported the incidence of primary RTD in southern Denmark to be 1.25 per 100 000 inhabitants per year.[2] In this study, out of all patients with RTD, 48.7% were male, and 51.4% were female. The mean age was 59.3 years.[2]
Out of all diabetic vitrectomies, RTDs are reported to be 20% in early series and 46% in more recent studies.[3][1][4] According to another report, RTDs were 36.6% of all cases of pars plana vitrectomy RTDs are becoming a major indication for pars plana vitrectomy in patients with diabetic retinopathy.[5]
The pathophysiology of retinal traction detachment is very well described in PDR cases. Hyperglycemia causes capillary closure and ischemia and elevated levels of nitric oxide (NO), which increases the activity of protein kinase C, activates vascular growth factors including vascular endothelial growth factor (VEGF) and several chemokines.[6][7] These growth factors help in the formation of new blood vessels from the existing matured blood vessels, which can breach the internal limiting membrane (ILM) of the retina and grow into the vitreous cavity.[8] The posterior vitreous face can act as a scaffold for the new vessel to grow. Complete posterior vitreous detachment (PVD) from the optic disc reduces the chances of progression to PDR.[9][10]
Subsequently, glial cells encompass these new blood vessels, and fibrous proliferation develops in these places. In PDR, typically, the traction occurs at the temporal arcade vessels due to the infiltration of retinal new vessels into the posterior vitreous face and may form a ring-like appearance around the fovea in late stages. This fibrous tissue causes traction over the retinal surface resulting in detachment of the neurosensory retina from the RPE.[11]
Retinal ischemia can result from a number of other causes, namely retinal vein occlusion, sickle cell retinopathy, ROP, FEVR, and trauma. The pathophysiology of RTD in these conditions can be explained similarly to that of PDR due to retinal new vessels (proliferative retinopathy). Other causes, including penetrating trauma, toxocariasis can cause glial proliferation and retinal traction directly without retinal new vessels.
Types of RTD
Conventionally, TRDs are divided into:
However, other classifications are also described.
Dubey et al. described RTDs to be:
Kroll and coworkers divided RTD into 4 types.[13]
Though there is no consensus regarding the classification, following a classification system before the preoperative workup will help in better decision making in the management of RTDs. The two common anatomical indications for surgery in RTD are RTD threatening macula and RTD involving the macula.
RTD threatening macula: The area of retinal elevation is at least 4 disc diameter, some part of whose is within the 30 degrees of the center of the macula or retinal elevation of less than 4 disc area along with one or more vitreoretinal adhesion causing elevation of the retina within 30 degrees of center of macula in the presence of new vessel or fresh vitreous hemorrhage.
RTD involving macula: Vitreo-retinal traction along the arcade, disc, or along retinal traction lines extending through the fovea and causing vision loss.
The rate of progression of extramacular RTD to involve the macula ranges from 14 to 15% at 1 year and 21 to 23% at the end of 2 years.[14][15]
RTD should be differentiated from the other 2 types of retinal detachments (RD), i.e., rhegmatogenous RD and exudative RD (see figures).
Current spectral-domain optical coherence tomography (OCT) images are reminiscent of histopathology of the retina.[16] Though there are few studies related to the microscopy of the retina in Retinal traction detachment, there are a number of studies describing the OCT features of RTD. The presence of vitreous or epiretinal proliferative membrane and resulting traction is evident as a hyperreflective structure in OCT. There may be the presence of the variable amount of subretinal fluid, as evident by the hypo-reflective area between neurosensory retina and RPE.
Tractional retinoschisis is characterized by intraretinal splitting and intraretinal hyporeflective spaces with vertical tissue septae without the evidence of subretinal fluid in OCT, though some cases may also have subretinal fluid or RTD. Faulborn J et al. studied the histopathological findings of four eyes with PDR and tractional retinoschisis. All eye showed adherence of the vitreous to the retina and traction over the retina. All the four eyes had retinoschisis, and two eyes had an additional detachment of the retina.[17]
Since the etiology of retinal traction detachment is mostly systemic, proper history regarding diabetes, hypertension, renal status, sickle cell retinopathy, trauma is very important. Similarly, in children, perinatal history regarding birth weight, gestational age, maternal infection, and family history is important. Coexisting systemic morbidities like nephropathy, cardiac diseases, and neuropathy should be mentioned in the workup details along with the details of their status (well-controlled or poorly controlled).
The ophthalmic evaluation includes slit-lamp biomicroscopy, fundoscopy, fundus photo, fundus fluorescein angiography (FFA), and OCT scan of the macula.
Ocular alignment should be noted to rule out the presence of strabismus since long-standing chronic Retinal traction detachment can be associated with sensory exotropia, which may denote a poor visual prognosis. Pupillary reflex should be noted to rule out the relative afferent pupillary defect. Inaccurate projection of ray gives a poor visual prognosis.
Iris and angle neovascularization should be looked for in the un-dilated state to find the presence of neovascularization. The presence and grade of cataracts should be noted since this will help in the decision of simultaneous cataract surgery.
The exact localization of the fibrovascular membranes, neovascular tufts, large-caliber neovascularization fronds, areas of tractional detachments, subretinal bands, presence of preretinal and subretinal bleed should be noted in the preoperative workup. In the presence of the RTD, the formation of a break in the retina converts it into a combined retinal detachment (CRD). In the preoperative workup, localization of the break may not be noted, and the clues for combined retinal detachment are convex retinal surface, sudden loss of vision, progression to ora serrata, and relatively less tangential traction. Intraoperatively the break(s) can be usually identified at the base of a proliferation where there is maximum anteroposterior traction. CRD cases should be operated early because a delay in the surgery will result in increased accumulation of subretinal fluid and difficulty in membrane removal due to more approximation of the retina with the membranes and mobility of the retina.
Spectral-domain optical coherence tomography (OCT) imaging is helpful in assessing the level and severity of the membranes than other modalities.[18] OCT can provide clues regarding the location of potential spaces where safe dissection or initiation of membrane removal can be performed. The presence of subretinal bands (SRB) can be detected in OCT scans and helps in the planning of the surgery. Also, it documents the foveal status, including epiretinal membrane, vitreomacular traction, cystoid macular edema, subfoveal fluid, retinoschisis, loss of ellipsoid zone, and the external limiting membrane.
Color photographs, red-free photographs, and wide-angle fundus photographs are helpful in the preoperative workup and documentation of the pathology like location and extent of RTD, SRB, preretinal and subretinal hemorrhages, and ischemic retinal vessels.
Wide-angle fundus autofluorescence (FAF) can help in visualization of the laser free area of the retina where additional PRP can be done preoperatively.
Fundus fluorescein angiography (FFA) can be done in doubtful cases where exact cause to RTD can not be found out due to the absence of clinically evident neovascularization. Also, FFA helps in delineating the areas of peripheral and macular ischemia, which will prognosticate the visual outcome in these cases.
Ultrasound B scan (USG-B scan) is a time tested investigational modality in the preoperative workup of the RTD cases. This helps in identifications of the areas of traction and retinal detachment, state of posterior vitreous detachment (PVD), presence of vitreous, subretinal, or preretinal hemorrhage, especially in the presence of a hazy media. There have been 2 types of description of RTD in ultrasound B scan. The detached retina may be tented by a narrow vitreoretinal adhesion causing an 'x' pattern in USG B scan and a broad vitreoretinal adhesion causing an 'H' shaped pattern in USG B scan.[19][11]
The systemic evaluation includes fasting and postprandial blood sugar, HbA1c, blood urea, serum creatinine, systemic blood pressure measurement, the hemoglobin level, lipid profile, and urinary microalbumin. Along with the ophthalmic evaluation, the patient should receive a tailored approach to all systemic involvements and consult concerned specialists.
The management of TRD can be divided into systemic management and ocular management. Systemic management includes control of the predisposing systemic factor, including diabetes mellitus (DM), systemic hypertension (HTN), nephropathies, and hemoglobinopathies. This should be done as per the advice of the treating physician or specialist.
Ocular management is to be done as per the discretion of the treating vitreoretinal surgeon. The decision to recommend surgery for TRD depends upon many factors, both systemic and ocular. The possible visual outcomes must be discussed with the patient before surgery. Diabetic vitrectomy is one of the most difficult vitreoretinal surgeries which demands the surgeon's expertise and a good understanding of the mechanism of the disease. Fortunately, with the advent of newer vitrectomy machines and with the advantages of small gauge vitrectomy surgeries, both the anatomical and functional outcomes of RTDs have been improved. The anatomical success rate of diabetic vitrectomy surgeries is reported to be in the range of 83% to 94%.[20]
Surgery is usually indicated for RTD of duration less than 6 months and progressive RTD threatening macula. Recent studies also mention RTD of a duration of more than 6 months as one of the indications for surgery.[11]
Role of Preoperative Anti-vascular Endothelial Growth Factor (VEGF) Agents
All types of intravitreal anti-VEGF agents. e.g., bevacizumab, ranibizumab, aflibercept, conbercept, and pegaptanib have been injected preoperatively in diabetic RTDs.[11] Though there is no consensus regarding the indication of these injections, they help reduce intraoperative hemorrhage in the presence of large, active neovascular fronds, and may make surgical dissection easier. The presence of more fibrous than a neovascular component is a risk factor for aggravation of RTD, in case preoperative anti-VEGF agents injected. Usually, the injections are given 3 to 5 days before the surgery. Bevacizumab is more frequently used, which may be due to economic affordability among other agents. Standard dosing of bevacizumab 1.25 mg/0.05 ml may be used, but even lower doses of bevacizumab 0.16 mg and 0.25 mg have been shown to be effective.[11] The preoperative injection of dexamethasone implant is also studied with good results.[21] Systemic control should be optimal before anti-VEGF injection as surgery should be done within 1 week of injection to prevent further worsening of TRD due to the contraction of fibrovascular membranes.[22] In eyes with severe PDR with fibrovascular proliferation but no TRD, bevacizumab has shown to cause progression to TRD as early as 3 days and an average of 13 days after injection.[23]
Role of Preoperative Pan-retinal Photocoagulation (PRP)
Preoperative PRP may be considered in cases with RTD, especially if the eye never received any laser or the previous laser appears inadequate. Though it may help stabilizes the eye in a case of PDR with RTD, it has a potential risk of retinal tear creation (if very high power is used), attributed to laser energy and induced fibrovascular contraction. However, PRP with a safe distance from the base of the fibrous membranes done preoperatively helps in the induction of PVD and better ease of surgery. It may also reduce the time needed to complete endolaser pan-retinal photocoagulation.
Surgical Equipment
Microscope and lenses - Binocular surgical microscope with coaxial illumination equipped with motorized power zoom, power focussing, and X-Y positioning via foot pedals is necessary. A laser filter to permit endophotocoagulation is needed. For fundus visualization, both contact lenses and noncontact viewing systems e.g., Binocular Indirect Ophthalmomicroscope (BIOM), are common in use.
Microinstruments and Illuminations
Twenty gauge systems had become the standard and are still used in some vireo-retina setups. They have the advantage of offering many additional instruments with minimal flexibility.[24] However, recent years have seen a preference towards smaller gauge vitrectomy systems like 23, 25, and 27gauge vitrectomy. These smaller gauge systems offer benefits of sutureless surgery, less postoperative inflammation, and hence less patient discomfort.[25] Also, the cutter mouth of 23G and 25D are very near to the tip of the vitrectomy cutter, allowing the surgeon to go very near to the retina to dissect the membranes.
Vitrectomy Machine Set-Up
The standard set up for vitrectomy consists of a vitrectomy cutter, combined with a suction unit, a fiber optic light pipe, an infusion of balanced salt solution, and an air pump. Additional combinations of diathermy, endophotocoagulation, cryo gas filling, or phacoemulsification modules are present in different vitrectomy setups.
Vitrectomy Cutter
The vitrectomy probe serves to cut and dissect vitreous gel and membranes. Newer probes with port closer to the tip of the probe are significantly safer.
Illumination
Illuminators range from single-function illumination probe to multipurpose illuminated scissors, forceps, or vitrectomy probes. The use of Chandelier illumination allows bimanual dissection. However, endoilluminator induced retinal phototoxicity is a potential side effect.
Membrane Dissection Instruments
A wide variety of tissue scissors, forceps, spatulas, and picks are available to remove vitreous and epiretinal membranes. The vitrectomy probe can also be used for membrane dissection.[26] Vertical scissors can be used for segmentation and horizontal scissors for delamination.
Retinopexy Instruments
Endolaser probes are used for endophotocoagulation. Scleral depression with indentor can be used for peripheral treatment. Endodiathermy can be used for stopping hemorrhage during surgery or for making retinotomy sites.
Dyes
Various vital dyes are used for vitrectomy and identification of membranes for their removal. Triamcinolone acetonide is used for staining of the vitreous cortex and remnant vitreous membranes, the identification, and removal of which ensures complete membrane removal. Trypan blue is more specific for epiretinal membrane removal. Brilliant blue-green (BBG), indocyanine green (ICG), and infracyanine green are more specific for the internal limiting membrane (ILM). Dissection of the posterior vitreous face in cases with vitreomacular traction needs to be done with care to prevent iatrogenic macular hole formation.
Tamponade
Various tamponade agents are used for internal tamponade in vitrectomy surgery for retinal traction detachment. Perfluorocarbon liquid (PFCL) helps intraoperatively during membrane dissection since it gives counter traction and a temporary hemostatic agent due to its mechanical pressure effect. Tamponade agents with effect in the postoperative period include SF6, C3F8, and silicone oil.
Pars Plana Vitrectomy for TRD
Preparation of Entry Sites
Standard 3 port vitrectomy is the common practice. A 6 mm infusion cannula can be used instead of a regular 4 mm canola in cases with anterior displacement of the retina due to severe retinal traction. The infusion port is played in the inferotemporal quadrant. Superior quadrants are used for the vitrectomy probe and endoilluminator probe.
Vitrectomy
Vitreous removal is started behind the crystalline or intraocular lens. Then central vitreous is removed. In RTDs, the vitreous is usually detached in the mid periphery, but multiple attachments remain at the posterior pole, thus forming a vitreous cone. After the removal of central vitreous, its necessary to trim and release 360° of the peripheral vitreous cone. Induction of PVD or membrane dissection before removing peripheral vitreous cone may result in iatrogenic retinotomy. Once the peripheral vitreous has been released, membranes of the posterior pole should be addressed. There are two ways of handling the fibrous tractional membranes: an outside-in or an inside-out technique. In the outside-in technique, dissection of the membranes starts at or posterior to the vascular arcades and comes toward the optic nerve, whereas, in the inside-out technique, dissection starts from the optic nerve and goes toward the periphery.
Membrane Peeling
RTD is most commonly associated with incomplete posterior vitreous detachment (PVD), the presence of pre retinal membranes, and vitreoretinal adhesions.
The vitreoretinal adhesions (VRAs) can be
The latter type is less common in occurrence and probably formed by a large segment of neovascularization. The more common type of broad VRA is formed due to fibrotic posterior hyaloid and associated with underlying retinal folds. There may be an associated epiretinal membrane near the broad VRA. Broad adhesions are more common in the nasal retina.
The traditional methods described to remove the membranes are segmentation, delamination, en-bloc dissection, other methods, and the combination of all these methods.
Remnants of the posterior hyaloid should be diagnosed with the help of staining with dye, minimal stroking with diamond-dusted membrane scraper, intraoperative forceps, or intraoperative optical coherence tomography (OCT) and removed. These remnants are called second membranes, and failure to remove them completely may result in recurrent retinal detachment, vitreous hemorrhage, and subsequent failure of the surgery.[33]
The taut posterior hyaloid membrane is a vitreoretinal interface disorder that causes tangential traction and results in diabetic macular edema (DME). Dye assisted removal of this membrane results in the resolution of DME. The peeling of the ILM (ILMP) in the posterior pole in these cases ensures the removal of all contractile elements. ILMP results in the prevention of astrocyte formation in these areas and hence prevention of recurrence.[34] ILMP also facilitates fluid passage from the retina through the vitreous, thus reducing DME.[35]
Bimanual membrane dissection, with the help of 25 gauge self-retaining chandelier endoilluminator, is a useful method for difficult membranectomy. Forceps, scissors, and vitrectomy probe can be used as per the surgeon's comfort. Newer vitrectomy high-speed cutters (10,000 cuts per minute via a dual pneumatic technology) beveled probe has a beveled-tip design that allows the cutting port to come closer to the retina, which provides additional safety to use the cutter as an instrument for membrane removal.
Control of the intraoperative hemorrhage is very crucial in diabetic vitrectomy. The source of the bleeding points is usually elevated fibrovascular tissue over the attached or detached retina, surface retinal bleed, or over the optic nerve head. Intraoperative bleeders should be immediately managed well. A delay in the hemostasis will cause the blood clot to be thick and formed and thus will make the removal of the clot difficult, as the cleavage plane between the retina and the membrane becomes obliterated. Endodiathermy of the individual bleeding nails, increasing the intraocular pressure, and mechanical pressure with the help of the cutter tip are some of the methods to stop the bleeding. The mechanical effect of the PFCL as a temporary tamponade agent can be helpful in the management of bleeding in some cases. Raised intraocular pressure should be decreased to see any ooze or bleed and if present, should be managed before concluding the case. Adequate hemostasis is very important, as postoperative hypotony may cause early rebleed in the posterior segment.
Intraoperative use of perfluorocarbon liquid (PFCL) is very helpful in stabilizing the retina and removal of the membranes, especially in the presence of combined RTD and rhegmatogenous retinal detachment.
Some eyes with PDR with RTD are associated with lamellar or full-thickness macular hole. The mechanism of MH formation in these eyes is the deroofing of the retinal layers in the region of DME resulting from tangential and anteroposterior traction from the vitreous membranes. Complete removal of the membranes and peeling of ILM should be done in these eyes.
Iatrogenic retinotomies or breaks are unwanted complications of diabetic vitrectomy. If created, these retinotomies should be made free of membranes near them and lasered adequately.
Photocoagulation
Panretinal photocoagulation (PRP) in eyes with preoperative incomplete PRP and without PRP need to be completed with endophotocoagulation. Endophotocoagulation probe with curved tip is preferred, especially in phakic patients. Laser marks should be as light as possible and spaced one laser mark apart. Care should be taken to avoid the 3- and 9-o'clock hours to prevent damage to the ciliary nerves and avoid postoperative loss of accommodation.
Tamponade
Relatively uncomplicated cases and cases without retinotomy are managed with either filtered air or gasses like SF6 or C3F8. However, silicone oil is the tamponade of choice in complicated cases and cases needing longer tamponade. Different silicone oils are available from 1000 to 10000 centistokes. They also act as a protective shield to prevent neovascular growth factors and cytokines from affecting the ocular tissues. They are usually removed after 3-6 months or as soon as silicone oil-related complications appear.
In a case of pure TRD, the goal of the surgery is the safe removal of all reactions. After this is done, the surgery is concluded. Though the subretinal fluid (SRF) may remain during the end of the surgery, the SRF usually resolves with time due to the pump function of the RPE.[36] However, some cases with thick SRF from chronic TRD may take more than 6 months to resolve.[37]
An intravitreal anti-VEGF agent may be injected after surgery to prevent recurrent hemorrhage.
The differentials of retinal traction detachment include taut posterior hyaloid (TPH), and vitreomacular traction syndrome (VMTS).
The planning of the treatment of Retinal traction detachment needs to be done with the help of other specialty doctors. Since the mortality is high, especially in associated renal failure, nephrologist referral is needed in cases with abnormal renal parameters. Perioperative use of anticoagulants and antiplatelet agents are associated with increased intraoperative and postoperative vitreous hemorrhage. However, the results are inconclusive.[11] Systemic management includes control of the predisposing systemic factor e.g., DM, HTN, hemoglobinopathies, etc., as per the advice of the treating physician. Ocular management is to be done as per the discretion of the treating vitreoretinal surgeon. The possible visual outcomes must be discussed with the patient before surgery.[38]
The prognosis of Retinal traction detachment depends upon a number of systemic and ocular factors. Systemic factors include control of DM, renal parameters, HTN, and sickle cell hemoglobinopathy.
Instrumentation gauge, surgical time, methods of membranectomy, tamponade agent, and the experience of the operating surgeon are the surgical variables with the potential to affect postoperative outcomes.[20] Some studies have found that eyes treated with silicone oil as a tamponade agent at the end of diabetic vitrectomy achieve less favorable outcomes. This bad outcome may be due to the fact that silicon oil is needed in complex RTD cases, which are having more structural damage to the retinal tissue preoperatively. Long term success rates have been highly variable in eyes with RTD undergoing vitrectomy and largely depend upon the control of the systemic factors, e.g., diabetes mellitus.
A study on the influence of demographic patterns on outcomes of RTDs reported that blacks lost vision postoperatively, while whites and Asians gained vision. This may be due to the presence of more extensive vitreoretinal adhesions in RTDs in people of African descendants. [39] There is mention of low-income Latinos having more advanced RTD at presentation and poor compliance with postoperative positioning and follow-up.[11]
Diabetic TRDs are the late stage of diabetic retinopathy, and patients should be explained about the advanced situation of the disease and grave visual prognosis. The goal of surgery is the anatomical attachment of the retina and to maintain the vision or to prevent further visual decline.[20] In some of the cases, the vision continues to decline and may even lose the perception of light.[11]
The causes of poor visual outcomes include chronically neglected and advanced disease, longer duration and increased height of macular detachment, optic atrophy, ischemic optic neuropathy, macular thinning, macular hole, macular ischemia, persistent SRF, outer retinal, and photoreceptor damage, and global retinal ischemia.
The complications of Retinal traction detachment include progressive retinal ischemia and atrophy of the photoreceptor layer. Progressive retinal ischemia may result in neovascularisation of iris (NVI), neovascularisation of angle (NVA), and neovascular glaucoma (NVG). Complications of the vitrectomy for RTD include vitreous hemorrhage (VH), secondary ocular hypertension, recurrent retinal detachment, cataract formation, and NVG.
Postoperative complications:
Dispersed vitreous hemorrhage (VH):
The reported incidence of postoperative vitreous hemorrhage after TRD repair ranges from 5% to 55%.[11] This complication is less common with silicone oil tamponade and more with gas tamponade. Immediate postoperative dispersed VH may resolve with conservative management. However, persistent VH needs vitreous lavage, removal of remnant membranes, and silicone oil tamponade. Port site neovascularisation or anterior hyaloidal proliferation may need cryotherapy to the port sites.
A secondary increase in intraocular pressure (IOP):
Elevated IOP in the postoperative period may be related to inflammation, hemorrhage, and tamponade. Initially, this is managed with topical anti-glaucoma medications and steroid drops. Nonresponding cases may need glaucoma drainage devices.
Recurrent retinal detachment post PPV for RTD:
Recurrent RD after vitrectomy for diabetic RTD is reported in 5-15% cases and carries a worse prognosis.[11] Intraoperative occult retinotomy, incomplete membrane removal, anterior vitreous cortex proliferation are some of the risk factors for the same. The presence of minimal subretinal fluid (SRF) may be resolved with time in some cases, and these cases need regular to follow up with OCT evaluation. Cases with non-resolving SRF need repeat vitrectomy, complete membrane removal, and long term silicone oil tamponade.
Cataract after vitrectomy for RTD:
The intraoperative touch of the phakic lens is reported to be 1-4%. However, postoperative cataract formation and progression is very common. The type of cataract is nuclear sclerosis and posterior subcapsular cataract.[40] The extraction of cataracts with implantation of the intraocular lens is needed if the cataract development is visually significant. The cataract surgeon must be aware of the lens touch, if any, which may harbor a preexisting posterior capsular rent.
Neovascular glaucoma (NVG) after PPV for diabetic RTD:
After diabetic vitrectomy, VEGF levels increase inside the eye. This poses a risk for anterior segment neovascularisation, especially if pars plana lensectomy is combined. Studies have reported the incidence of NVG to be 1-7% after modern diabetic vitrectomies.[41][42][43]
The risk factors include preoperative NVI, other eye NVG, ocular hypertension, and young males.[42] Anti-VEGF injections can be used intracamerally or intravitreally in these NVG eyes. Postoperative NVG may be the initial sign of recurrent retinal detachment (RD), and conversely, recurrent RD can be associated with NVG. Though these eyes need repeat vitrectomy, the prognosis is poor. For the management of increased intraocular pressure in NVG eyes, glaucoma drainage devices are preferred by glaucoma surgeons.
Postoperatively, topical steroids, antibiotics, and cycloplegic drops are routinely used. Postoperative complications, if any, should be managed as per the indications. Depending upon the location of the retinal break(s) and other factors, the patient may be advised some specific posture in the early postoperative period. Proper systemic care is of utmost importance.
Endocrinologist and physician consultation is needed for proper systemic control. Neonatologist care is needed for management of in cases with ROP.
The delay in the diagnosis of TRD carries a worse prognosis. Diabetic patients should be educated for regular ophthalmic evaluation and prompt management of TRD at the earliest. Babies with risk factors of ROP, e.g., prematurity, low birth weight (LBW), and septicemia, should be promptly screened for ROP so that they can be diagnosed in early stages. Patients with hemoglobinopathies should consult ophthalmologist at regular intervals to rule out retinopathy.
Retinal traction detachment is an ocular complication of many systemic disorders, including DM, HTN, sickle cell disease, and premature birth. The visual prognosis depends largely on the systemic control of the parameters. Coordination of the ophthalmologist with the physician, endocrinologist, nephrologist, neurologist, cardiologist, hematologist, and neonatologist is very important. Coordination of the nursing staff for the preoperative surgical preparation and preoperative systemic stabilization is essential. Since these patients have a guarded visual prognosis, psychological counseling may be needed for the management of depression.
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