Multidisciplinary approach to orbital decompression. A review.

Introduction

Orbital decompression may be indicated for patients with orbital abscess, periorbital or orbital hematoma, neoplasm, cosmesis in patients with proptosis for other reasons, but the most common indication for orbital decompression is represented by Thyroid Eye Disease (TED), also called Graves’ Orbitopathy (GO).

Unfortunately reaching the cure of GO, defined as both restoration of normal quality of life and complete regression of aesthetic and functional ocular impairment, is a rare occurrence in real-life patients, treated with medical therapy. Although the effort of preventive, immunosuppressive and novel targeted treatment, considering the complex pathogenesis and natural history of GO, the rate of patients that need ocular surgery is still elevated, making surgery a valid and often necessary therapeutic option in the multidisciplinary management of GO [1].

In 1990 Kennedy et al. introduced the transnasal endoscopic approach for orbital decompression.

Since then, endoscopic orbital surgery has become a highly evolving multidisciplinary surgical field thanks to development in technical skills and cooperation of ophthalmologists and otolaryngologists [2].

These advances expanded the clinical applications of endoscopic transnasal orbital decompression technique in the management of TED and compressive optic neuropathy (CON), leading to a growing body of literature in the otolaryngology and ophthalmology communities. In his first study, Kennedy reported a mean improvement of 4.7 mm in Hertel exophtalmometry measurement after inferior-medial wall decompression with transnasal endoscopic technique [2]. However, several early reports of endoscopic decompression described new-onset diplopia in up to 45% of cases [3]. The consequent technical refinement was represented by the preservation of an inferior-medial orbital bone strut in endoscopic orbital decompression that resulted in a considerable reduction in this complication [4]. This technical evolution was the result of a multidisciplinary team-work, as described by Goldberg, Shorr and Cohen in 1992 [5]. In fact, the expertise of otolaryngologist and ophthalmologist permitted to understand the importance of the orbital strut and suspensory ligament complex to preserve globe position after endoscopic surgery. The subsequent step has been represented by the preservation of a medial periorbital strip to reduce the medial rectus muscle prolapse into nasal cavity [6].

What the ophthalmologists earned from endoscopic approach, for example, was the improvement in visualization of the posterior medial wall, limiting the risk of optic nerve injury and maximizing the extent of decompression at the orbital apex: this is of paramount importance in case of rapidly progressive thyroid disease-related optic neuropathy. What the otolaryngologist learned from the oculoplastic surgeon was the direct visualization of the infra-orbital nerve that permits extensive (both medial and lateral to the nerve) inferior wall decompression in case of external transconjunctival and lateral canthal approach. This approach enables simultaneous three-wall decompression also, addressing a balancing effect because both the inferior-medial and lateral wall are decompressed, reducing the incidence of new-onset postoperative diplopia.

Thyroid Eye Disease

Orbital involvement in Graves’ disease has a complex pathophysiology, resulting from the deposition of immune complexes that cause oedema and fibrosis of the extraocular muscles and orbital fat. The retro-orbital pressure increases and causes proptosis and exophthalmos, threatening the vision due to vascular impairment or stretching of the optic nerve.

GO, which is the main extra-thyroidal manifestation of Graves’ disease, is a rare pathology and still represents a clinical and therapeutic challenge [7].

Although the role of TSH receptor activating autoantibodies (TSHRAb) on orbital adipogenesis has been widely demonstrated in literature, the complex pathogenesis of GO is not clear yet. A new promising pathogenetic mechanism has been recently discovered, based on an active “cross-talk” between TSH-R and IGF-1R in thyrocytes and orbital fibroblast, which lead to activation of an IGF-1R-dependent downstream intracellular pathway. Although GO is present in about 25% of Graves’ Disease cases, fortunately, the sight-threatening variant is a rare occurrence [8].

Therapeutic management of TED

According to the recent Guidelines, the therapy of GO has to be gauged on two main parameters, Severity and Activity, which can be evaluated through validated scores, such as NOSPECS and Clinical Activity Score (CAS) [9]. The EUGOGO classification defines disease severity as sight-threatening, moderate-to-severe, and mild Graves’ Orbitopathy [10] (Tab. I).

Table I.

Severity classification in Graves’ Orbitopathy, recommendations and levels of evidence (from EUGOGO [10]).

Classification	Recommendation	Level of evidence
Sight-threatening GO: DON and/or corneal breakdown	Immediate intervention	IV, C
Moderate-to-severe GO: eye disease with sufficient impact on daily life (lid retraction ≥ 2 mm, exophthalmos ≥ 3 mm, moderate or severe soft tissue involvement)	Active: immunosuppressionInactive: surgical intervention	IV, C
Mild GO: minor impact on daily life (minor lid retraction< 2 mm, exophthalmos < 3 mm, mild soft tissue involvement, transient or no diplopia, corneal exposure responsive to lubricants)	Local measures to alleviate symptoms	IV, C

DON: Dysthyroid Optic Neuropathy; GO: Graves’ Orbitopathy.

In case of mild GO, an oral daily dose of 200 mcg of Selenium appears to be effective as maintenance therapy, although its role in preventing orbitopathy has still to be clarified [11]. Furthermore, local measures, such as teardrops, ointments or gel, appear to be useful, particularly in alleviating ocular dryness or foreign body sensation. If diplopia impacts on the quality of life, using corrective prisms may be a valid option. Botulin injection has been tested too, with apparently transient benefits in reducing eyelid retraction [12].

Intravenous high-dose glucocorticoids represent the therapeutic cornerstone of Active GO. Indeed, in moderate-to-severe active GO, the first line approach consists in intravenous methylprednisolone, administrated weekly at initial dose of 0.5 g for 6 weeks, then 0.25 for other 6 weeks (4.5 g cumulative dose). This therapeutic scheme appears to have higher efficacy and fewer adverse effect then glucocorticoids oral administration. The optimal cumulative dose appears to be 4.5-5 g of methylprednisolone, but higher doses (up to 8 g) can be used for more severe forms [13]. Patients with sight-threatening GO, due to Dysthyroid Optic Neuropathy (DON) or severe corneal exposure, should be rapidly treated with high doses of intravenous glucocorticoids as first-line treatment. A commonly used regimen consists of giving 1 g of intravenous methylprednisolone for three consecutive days, that can be repeated on the subsequent week. It is important to strictly control clinical conditions because in case of absent or poor response, the patient should undergo orbital decompression within two weeks [9] (Fig. 1, Tab. II).

Figure 1.

63-year-old female patient, smoker, affected by active, sight-threatening GO, treated with administration of 1 g of intravenous methylprednisolone for three consecutive days. (A) Patient before therapy. (B) Two weeks after therapy. After thyroidectomy, a better control of hormonal levels was achieved. (C) Two months later, her visual acuity worsts to right eye: 4/20 left eye: 3/20 with anomalous colour vision test (dysthyroid optic neuropathy). (D-E) On CT-scans images, all the EOMs are enlarged with apex crowding. (F) After endoscopic bilateral endonasal optic nerve and medial wall decompression the visual acuity has greatly improved, and a 4 mm of proptosis reduction.

Table II.

Glucocorticoids and orbital decompression in Dysthyroid Optic Neuropathy (from EUGOGO [10]).

Management of DON	Level of evidence
GCs and surgical decompression are effective in patients with DON	III, B
High-dose i.v. GCs is the preferred first-line treatment for DON	III, B
If the response to GCs is absent after 1-2 weeks, prompt orbital decompression should be carried out	IV, C
Orbital decompression should be performed promptly in case of DON o corneal breakdown in patients who cannot tolerate GCs	III, B

DON: Dysthyroid Optic Neuropathy; GCs: Glucocorticoids; i.v.: intravenous.

However, to achieve the reduction of relapse rates and the optimization of the final results, it seems necessary to resort to combinations of other current therapies, as the active disease could last 1-2 years and often a relapse occurs upon withdrawal of glucocorticoids [14].

Radiotherapy

Orbital radiotherapy, usually with a cumulative dose of 10 to 20 Gy per orbit, can be used as second-line therapy, when GO results to be still active after glucocorticoids treatment, particularly in case of diplopia and motility disorders. In randomized clinical trials, radiotherapy appeared to be as effective as oral glucocorticoid therapy and may have a synergic effect if combined with intravenous steroids. Although data on safety seem to be reassuring, further studies are needed to assess the real long-term effectiveness and safety, because of controversial for the theoretical concerns about carcinogenesis, especially for younger patients, and other side effects such as retinopathy and cataract [15-17].

Antiproliferative agents

Mycophenolate mofetil (MMF) inhibits the proliferative responses of T and B lymphocytes and has a mechanism of a direct effect on orbital fibroblasts [18]; Cyclosporin, inhibits calcineurin pathway reducing IL-2, that is highly produced by T-cells activated in GO. Both MMF and Cyclosporin showed benefit in ocular symptoms and quality of life [19]. Methotrexate and Azathioprine have also been evaluated for utility in GO management as steroid-sparring agents, but more data are needed [20].

Targeted therapy

Several monoclonal antibodies have been tested as novel therapeutic options in second-line treatment for Active GO. Tocilizumab, a humanized monoclonal antibody directed against the IL-6 receptor, showed efficacy in terms of activity reduction [21]. A multicentre, randomized, trial versus placebo, showed that the use of tocilizumab in glucocorticoid-resistant GO showed a reduction in Clinical Activity Score (CAS) of at least 2 points, improvement in EUGOGO ophthalmic score and a bigger reduction of exophthalmos [22]. Most adverse effects tend to be mild and transient; however, a consistent risk of developing opportunistic infections has been noted during treatment for rheumatoid arthritis and need to be monitored [23]. Rituximab is a chimeric mouse-human monoclonal antibody, which targets the B-lymphocyte antigen CD20. Two clinical trials reported contradictory outcomes: no benefit in one trial, when compared with placebo; a significant improvement in CAS, when compared with intravenous steroids, in the other [24,25].

Indications for surgery

Generally speaking, it is recommended to avoid surgery in Active TED, because it is evident that surgical procedures during this phase may increase orbital inflammation [26].

Urgent indications: surgical indication for orbital decompression can be considered in patients with active GO who are nonresponsive or intolerant to glucocorticoids, if waiting for spontaneous inactivation could be a risk for vision loss [27], in case of CON (estimated incidence 3-9% of TED patients) [28]. In fact, extraocular muscle enlargement could restrict the vascular supply to the optic nerve: this is the most well-accepted mechanism of DON. The diagnosis of DON remains still challenging and controversial, and possible clinical findings are represented by decreased visual acuity, a relative afferent pupillary defect, altered colour vision, optic disc abnormalities and visual field defects. In this case, the amount of orbital wall removal is particularly critical and should be achieved as complete as possible along the intraorbital portion of the optical nerve [29].

Extreme eye proptosis can also determine vision loss: persistent eyelid retraction caused by persistent inflammation and scarring of the eyelid retractors increasing corneal exposure, predisposing patients to ulceration and subsequent vision compromise.

Nonurgent indications: orbital decompression for disfiguring exophthalmos could be deferred until the orbitopathy has been inactive for at least 6 months [27]. Other nonurgent indications are represented by chronic retrobulbar pain or discomfort, congestion, ocular hypertension and diplopia (Fig. 2).

Figure 2.

65-years old, male patient affected by severe TED with proptosis and strabismus. (A-C) Pre-operative CT-scan images and appearance. (D-F) CT-scan images and appearance after bilateral endoscopic orbital decompression.

The majority of patients presents a good response to conservative treatments, only in 5% of cases an orbital decompression surgery is demanded in the 1st year after diagnosis, but in the ten years after diagnosis this rate rise up to 20% [28].

In relation to the staging of the surgical ophthalmic procedures for the rehabilitation of the patients affected by the TED, the decompression should be the first procedure performed, as it can affect ocular motility [30]. This is followed by eyelid surgery, which can be affected by both decompression and strabismus surgery [31]. Some have challenged this paradigm, suggesting that there is minimal change in upper eyelid position with decompression or strabismus surgery and that simultaneous upper eyelid and decompression surgery may be performed in order to shorten rehabilitation intervals [32] (Tab. III).

Table III.

Timing and the order for surgery in Graves’ Orbitopathy (from EUGOGO [10]).

Timing and the order for surgery	Level of evidence
Surgical management should proceed in the sequence: orbital decompression, squint surgery, lid lengthening with blepharoplasty	III, B
Rehabilitative surgery should be performed in patients with inactive GO for at least 6 months	III, B

GO: Graves’ Orbitopathy.

There are no absolute surgical contraindications to orbital decompression surgery; patients under anticoagulant treatment should discontinue the assumption preoperatively because of the major risk of bleeding intraoperatively that could impact negatively on surgery and the risk of postoperative haemorrhage. When a concomitant paranasal sinuses disease is present (sphenoidal and/or frontal rhinosinusitis), a parallel surgical opening of the involved sinuses could be addressed even if not needed for decompression surgery. Most of the studies show the efficacy and relative safety of orbital decompression [33]; however, the available studies do not allow any meaningful comparison of the available approaches [27]. Orbital decompression can be achieved with different surgical techniques: fat decompression, orbital floor or medial or inferior-medial wall decompression, orbital lateral wall decompression isolated or associated with the other wall decompression [31].

Multidisciplinary surgical approaches in orbital decompression

Transantral

Before the endoscopic era, the Walsh-Ogura transantral approach was the gold standard for treatment of exophthalmos in patients with Graves’disease [34].

This approach started with a sublabial incision in the oral vestibule mucosa, taking care to not injure the infra-orbital nerve during the exposition of the anterior wall of the maxillary sinus. Then an osteoplastic anterior maxillotomy is performed, by the temporary removal of a bony gusset that is replaced with microplates at the end of the procedure. The orbital floor and the lamina papyracea are then exposed and resected, resulting in orbital decompression and subsequent immediate reduction in proptosis.

It is important to preserve a bony bridge together with the infra-orbital canal, avoiding downward displacement of the eyeball and subsequent diplopia.

hypoesthesia of the cheek, the lateral nasal ala, and the anterior teeth, due to lesion or temporary stretching of infra-orbital nerve in the bony canal inside the orbital floor or after its exit from the infraorbital foramen;

paresis of extraocular muscles (inferior rectus, inferior oblique, possibly medial and lateral rectus muscles) and subsequent diplopia, due to lesions to nerve fibres that enter the muscles;

haemorrhage due to injury to the infraorbital artery or infra-orbital branches of the ophthalmic artery;

enophthalmos, if the entire orbital floor is resected.

Transnasal (Figures 3 and 4)

The endoscopic transnasal technique starts performing an uncinectomy and a maxillary antrostomy in order to obtain a good exposure of the posterior maxillary wall and orbital floor, and also to avoid obstruction due to inferior dislocation of orbital fat. Then a complete sphenoid-ethmoidectomy exposes the medial orbital wall from the sphenoid sinus down to the crista ethmoidalis and superiorly to the skull base. In some cases, it is possible to realize the resection of the middle turbinate for better visualization with subsequent cauterization of its postero-lateral remnant to avoid postoperative bleeding. The second step of the procedure is the removal of the bone from the inferior and medial orbital wall.

The lamina papyracea is then fractured with a blind dissector and elevated away from periorbita. Bone is thicker in the region of the orbital apex in the proximity of the annulus of Zinn, through which the optic nerve passes and where four extraocular muscles originate. Then, the periorbita can be elevated off the bony floor of the medial orbit. Only the portion of the floor that is medial to the infraorbital nerve is removed, preserving its canal as the lateral limit of dissection. Moreover, the preservation of a bony inferior-medial strut may reduce postoperative diplopia and help in improving proptosis [35]. The next step is the incision of the periorbita to enable extraconal orbital fat herniation into the ethmoid and maxillary cavities, avoiding lesions to the orbital contents, in particular of the medial rectus muscle. In order to decrease the risk of postoperative diplopia, it could be preserved the periorbital sling that covers the medial rectus muscle, as described by Metson and Samaha [6].

Complications

The more common complications of this kind of surgery include epistaxis, nasal adhesions, sinusitis, worsening of pre-existing diplopia or new-onset diplopia; pre-operative diplopia frequently does not resolve with surgery. Rare complications are represented by injury to the optic nerve and ophthalmic artery; otherwise, cerebrospinal fluid leaks rarely occur [36].

Bony removal, periosteum opening and fat resection

The techniques and extent of bony removal widely differ in the literature. Currently, for the floor the lateral extent removal has been limited to the space medial of the infraorbital nerve [2]. Anteriorly, some suggest leaving 10mm of bone under the globe to prevent hypoglobus [37]. The limits of medial wall removal differ depending on the surgeon and the clinical features. Anteriorly, the maximal extent is classically thought to be the posterior lacrimal crest [2]. Posteriorly, most descriptions involve dissection to the anterior wall of the sphenoid sinus; however, dissection can extend as far as the optic canal [2]. Many endonasal approaches describe canal decompression as part of the management for DON [38].

Superiorly, most authors describe dissection to the frontoethmoidal suture. At this level, it is critical to be aware of the skull base anatomy, as inadvertent entry into the cranial cavity through the fovea ethmoidalis has been reported [39]. Inferiorly, the inferior-medial orbital strut separates the medial and inferior walls and provides structure to the bony orbital cone. Authors have argued that removing this strut is important to allow for complete prolapse of the orbital tissue and maximal decompression. Others have suggested that leaving the strut (or part of it) intact is vital to avoid hypoglobus and important strabismus postoperatively [31,35].

The orbital periostium is unelastic and will minimize prolapse of orbital fat in periorbital spaces. For this reason, some suggest opening periostium completely after the bony decompression.

Other authors have suggested cross-hatching or linear incisions [31].

Extensive opening of the periosteum has been associated with greater rates of postoperative strabismus [37].

Medially, endoscopic surgeons have described the importance of leaving a strip of periosteum overlying the medial rectus and the inferior rectus to reduce the rate of eye inferior prolapse and strabismus [6].

The infraorbital nerve should be spared to avoid permanent anaesthesia dissecting the orbital floor only medial to the nerve or leaving a bony canal and dissecting on either side [31].

Lateral wall decompression

Lateral orbitotomy is an external approach first described by Krönlein in 1888 and since then has undergone some modifications. The original approach involved a curvilinear incision running towards the lateral canthus from the hairline [31]. Stallard and Wright modified the incision with a more acceptable postoperative scar running through the eyebrow [40]. Berke in 1953 proposed a canthal splitting lateral incision [41], while the first coronal flap to access lateral orbit was described in 1982 by Bonavolonta. Today, the most used approach is the lateral eyelid creased incision that provides excellent access and hides well in the eyelid crease [42].

The skin incision could be performed in the area of the lateral orbital rim, with possibility of injury to the ramus frontalis and ramus ocularis of the facial nerve, or in alternative, a pterional incision into the hairline could be realized without a cosmetic problem.

With a pterional incision, a scalp flap is formed and prepared until the lateral orbital rim is exposed, preserving the lateral palpebral ligament; temporalis muscle that overlies the lateral orbital wall is incised and bluntly pushed away. Microplates are needed for the reconstruction of the lateral orbital rim. With a saw, the bone at the lateral orbital rim is now separated. This is followed by the resection of the lateral orbital wall including parts of the zygomatic bone up to the greater wing of the sphenoid bone in the region of the inferior orbital fissure.

For the reconstruction of the lateral orbital wall, the temporarily separated bone is repositioned and fixed in place by microplates and the temporalis muscle is moved back and fixed. It could be necessary to insert drainage before closure layer by layer of the scalp.

blunt shape of the lateral canthus due to detachment of the lateral palpebral ligament from the orbital rim;

impairment of eye globe motility and diplopia because of injury to the lateral rectus and the inferior rectus muscles;

anisocoria due to injury of the ciliary ganglion (laterally to optic nerve), during very extensive medial preparation;

disorder of the mimetic musculature due to injury to the ramus frontalis or the ramus orbitalis of the facial nerve;

sinking of soft tissue above the zygomatic arch because of incomplete repositioning of the temporalis muscle.

Optic nerve decompression

Many studies have reported the efficacy of medial wall decompression in optic compressive neuropathy. Transcaruncular, transorbital, transantral and endonasal approaches seem similar in the rate of DON improvement reported, range 75-90% [31]. The periosteum was described not incised, incised in the anteroposterior direction, radially incised. Despite the clinical efficacy of the medial wall optic nerve decompression, a few studies focus on pressure orbital changes [43].

Discussion

Most of the literature about orbital decompression consists of retrospective, cohort or case series studies. These papers provide useful descriptive information, but clarification is required to show the effectiveness of each operation related to different indications.

Orbital decompression is achieved by removing bony walls, orbital fat or both. It is an established procedure to correct exophthalmos for visual improvement in patients with optic neuropathy, corneal involvement and for the rehabilitation of patients with marked anterior positioning of the eyes. Several approaches are described with contradicting results, and the comparison of different surgical techniques was biased by inclusion of patients at a different stage of disease (active or inactive), different surgical indications (dysthyroid neuropathy or disfiguring proptosis) and assessment of outcomes (such as a different system for ocular motility evaluation).

The few Randomized Control Trials (RCTs) do not provide robust evidence to support recommendations for clinical practice. There is evidence only from available uncontrolled studies that the removal of the medial and lateral wall (so-called balanced decompression) with or without fat removal could be the most effective surgical technique, related to few complications [44].

The removal of the inferior wall through the antrum and transnasal removal of the medial wall had similar effects in reducing exophthalmos, but the second approach had a lower rate of complications, such as diplopia and infraorbital nerve damage [45].

The timing of surgical decompression is another debated issue and must be related to the failure of medical therapy. One of the few RCTs showed how intravenous corticosteroids achieve better visual recovery than surgical orbital decompression (56 vs 17%) [46]. Adverse outcomes were reported more frequently in the steroids group, i.e. weight gain and a Cushing-like syndrome, hypertension and transient diabetes; while side effects of surgery consisted of transient numbness of the facial skin in 4/14 participants or decrease in extraocular muscle motility. The beneficial effect of I.V. steroids on visual rehabilitation would appear to overcome the increased number of transient side effects in active TED with optic neuropathy.

In case of urgent orbital decompression, the main outcome is obviously represented by visual acuity: different studies have demonstrated high success rates with improvements in more than 82% of patients [28,33].

Medial and inferior-medial wall decompression is advisable in patients with severe posterior optic neuropathy, caused by apical crowding of the enlarged muscles, in particular of medial rectus.

For nonurgent orbital decompression, proptosis is the main outcome, orbital fat removal alone has been shown to reduce proptosis up to 4.7 mm, while decompression of the medial, inferior, and/or lateral walls could reduce proptosis up to 7.4 mm [28,33].

Lateral decompression allows for exophthalmos reduction causing less strabismus, especially with the incision of fascia temporalis. The literature suggests that three-wall decompression is chosen for high degrees of proptosis while two-wall for patients with less exophthalmos; fat removal in addition to bone removal could increase the effectiveness of the procedures [44].

The aim of orbital decompression surgery is not to create the biggest space with disruption of periorbital structures for maximal decompression, but to realize adequate decompression for relief of optic neuropathy or keratopathy caused by severe proptosis [47]. Moreover, cosmesis, was one of the most common indications for surgery and represented an important quality of life issue for patients [48].

Several studies suggest that three-wall decompression achieves the greatest reduction in proptosis but that complications are more frequent; for this reason, more conservative approach, such as balanced medial and lateral wall or endoscopic inferior-medial decompression may be preferable choices. The accuracy of measuring proptosis was also questioned. Although postoperative Hertel measurements were widely reported, they were inaccurate in particular when lateral canthotomy is performed, as these were made with a Hertel exophthalmometer using altered reference points, which may result in overestimation of improvement in proptosis [47].

Interestingly, diplopia can be considered both an outcome and a complication. In every kind of approach, new-onset diplopia could be present at different rates [33].

Many theories have been proposed to understand this phenomenon, for example, removal of the posterior medial wall, removal of the inferomedial strut, and the displacement of the extraocular muscle paths, but no one of these theories has been commonly accepted [49]. It has been suggested that preservation of inferomedial strut and a balanced orbital decompression causes less diplopia and some studies show new onset or worsening of diplopia ranges from 10 to 20% [50-52].

Although, some endoscopic surgeons described lower rates of strabismus with modifications to the periosteal opening medially. Additionally, higher rates of over 30% have been reported for balanced decompression. These rates could be technique dependant, both on the side of balanced decompression and medial decompression alone [31].

Finally, the comparison of induced diplopia rates after different orbital approaches is difficult to perform because of many factors: type of surgical indications, different measurements, the timing of outcome assessment, different criteria to define the condition.

In the study of Mourits et al. [49], authors used two tools to assess diplopia: ophthalmologist and orthoptist and determined clinically whether or not there was diplopia in any direction of gaze, while patients self-assessed their diplopia using the Gorman score. Using these criteria seemed to be a tendency for the swinging eyelid approaches to be associated with less induced diplopia. In the group of three-wall swinging eyelid decompression, the incidence of diplopia decreased, and the Gorman score improved. In some studies, the subjective response to treatment was measured using Terwee’s GO-QOL, a validated disease-specific questionnaire to assess changes in visual function and changes in appearance [53].

Various attempts have been made in the literature to study radiographic-based and QOL-based outcomes after orbital decompression, in addition to the evaluation of clinical features.

An objective evaluation could be performed by the imaging measurements of radiographic-based outcomes; recent research has been focused on establishing the validity of an algorithm to determine various parameters, such as the measurement of the angle of the orbital apex, diameter of the extraocular muscles, exophthalmos and orbital volume [54-56].

Unfortunately, the use of radiographic-based outcomes is not assessed, and its specific role in outcome evaluation needs to be determined by further studies aimed to standardize analyzed parameters.

Probably, in the last years, the most important concept about outcome evaluation is the patient’s point of view. For this reason, recently, many questionnaires about quality of life have been developed and validated. One of these is represented by Graves Ophthalmopathy Quality of Life (GO-QOL) scale that provides vision-related and appearance-related scores, which were assessed before, 6 weeks and 6 months after surgery [57].

Improvements in eyelid retraction and congested orbit did not predict the change in the appearance-related quality of life. As reported in previous studies, the correlation between clinical changes and quality of life outcomes is weak, also supporting the notion that subjective appraisals of appearance will predict psychological well-being better than clinical measures of severity. For example, patients with strabismus evaluated appearance as more important than other clinical factors [57].

A recent study has examined the impact of orbital decompression surgery on sinonasal-specific QOL evaluated by SNOT-22 administered preoperatively and one year after surgery, that showed a statistically significant improvement in sinonasal-specific QOL, in particular, improvements have been observed in the psychological domains of the test, confirming a preserved sino-nasal function even after fat prolapse into nasal cavities [58].

Conclusions and key notes

TED is the most common indication for orbital decompression in case of failure of medical therapies. The urgent surgical indications are represented by optic neuropathy and severe corneal exposure, while non-urgent surgical indications include diplopia, proptosis, orbital and retrobulbar pain, and ocular hypertension. In the case of optic neuropathy, bony removal in the region of the orbital apex is mandatory, reducing pressure on the optic nerve and leading to improvement in vision in patients with visual loss.

The main clinical outcomes include visual acuity, proptosis, and new-onset diplopia.

Recent studies focused on the development of imaging assessment in order to objectively evaluate the surgical results. QoL questionnaires are gaining increasing importance, based on patients’ point of view.

The goal of orbital decompression is the reduction of proptosis, but additional ophthalmological procedures are needed to normal eye function and cosmesis. Strabismus surgery to address diplopia and lowering the position of the upper eyelid represent some of the additional steps for the final rehabilitation of GO.

A balanced decompression (combined external and endoscopic or only external approach) or pure endoscopic approach with the preservation of the anterior inferomedial orbital strut represents the gold standard to reduce the incidence of new-onset diplopia, but RCTs are required to confirm these data. Moreover, the orbital sling technique, obtained by the preservation of a strip of the periorbita overlying the medial rectus muscle is an additional technical trick to reduce diplopia.

Anatomic dissection showing the periorbit (PO) after complete spheno-ethmoidectomy with the exposure of the Skull base from the I fovea ethmoidalis, anterior ethmoidal artery (AEA), Posterior ethmoidal artery (PEA); to the sphenoid sinus and the following structures: Optic nerve (ON), Interoptic carotid recess and sellar floor Sphenoid Sinus (SS).

(A-D) Intraoperative view of left orbital decompression with the exposure of the sphenoid sinus (SS), Posterior maxillary wall (PMW), infraorbital nerve (ION), with incision of the inferior periorbit and the final fat ernjation.