Толщина латеральной стенки орбиты как определяющий фактор на этапе выполнения доступа при латеральной костной декомпрессии орбиты

Lateral orbital wall decompression is one of many well established techniques available to surgeons in management of patients with clinically significant thyroid eye disease (TED). Several different surgical approaches have been described in the literature and are reviewed herein. Lateral orbital wall decompression remains a popular technique for surgical management of TED, with a recent American Society of Ophthalmic Plastic and Reconstructive Surgery survey showing that 22.6% of respondents preferred a single-wall procedure, with 36.8% of that subset preferring lateral wall decompression alone. Surgical techniques for lateral orbital wall decompression differ based on several steps, such as the incisional approach, whether to take an ab-interno versus ab-externo approach, and whether to remove orbital fat to achieve further decompression. In addition, technological advances have produced an array of tools available to the orbital surgeon to achieve efficient and accurate bone removal. Lateral orbital wall decompression for TED, despite being an older technique, remains a popular and well established procedure for orbital decompression. Though no randomized controlled clinical trial supports one decompression technique over another for TED, lateral orbital wall decompression offers many benefits such as its ease of access and visualization of the orbital space.

Stereotactic navigation systems have been used in neurosurgery and otolaryngology with great success. The current investigation illustrates the novel use of a microdebrider with built-in stereotactic guidance in a series of thyroid orbitopathy patients who underwent deep lateral orbital wall decompression surgery. A noncomparative, interventional, retrospective case series of patients who underwent deep lateral deep orbital wall decompression from 2006 to 2013 was conducted in accordance with Institutional Review Board policy and the Declaration of Helsinki. Patient demographics, indications for surgery, pre-, intra-, and postoperative findings along with complications were recorded. One hundred eight deep lateral orbital decompression surgeries were performed in 69 patients using the Straightshot M4 Microdebrider with built-in stereotactic guidance (Medtronics). Seventy-eight cases were in women and 30 cases were in men. The average age was 50.4 years (SD = 11.9 years). Indications for surgery included proptosis, exposure keratopathy, or compressive optic neuropathy. No patient experienced intraoperative complications. Specifically, cerebrospinal fluid leak, visual loss, infection, or unanticipated inflammation were not encountered. The average postoperative follow-up time was 5.35 months. Mean reduction in proptosis was 3.72 mm (SD = 2.1). Visual acuity improved in 32.4% (35/108) of cases. This surgical instrument combines a single handpiece locator, microdebrider, irrigator, retractor, and suction device into one. It enhances anatomical localization during orbital decompression and, with an integrated tissue guard, may decrease the risk of injury to orbital soft tissues. Stereotactic navigation enhances the surgeon's ability to determine the maximal limits of decompression in real time by confirming depth of bone removal and may potentially increase surgeons' confidence in orbital decompression surgery.

A patients with Grave Ophthalmopathy who underwent orbital decompression surgery involving two walls, medial and lateral. The surgery was performed in collaboration with an ENT specialist. This case report described a patient who presented with Thyroid Eye Disease NOSPEC V. It has been reported that a 35-year-old male had complained of bilateral proptosis, decreased visual acuity, and eye pain. The patient had been diagnosed with hyperthyroid 1 year before coming to the eye clinic. The patient was given a peribulbar steroid injection, but no improvement was observed. Visual acuity of the right eye was 3/60 and the left eye was 1/60. Lagophthalmos were seen on both eyes, 6mm in the right and 4mm in the left. The cornea of the right eye had infiltrated due to exposure keratitis. Proper eye movement was restricted to superonasal. The patient underwent medial and lateral orbital wall decompression of the left eye. Left eye visual acuity was improved to 20/150. Lagophthalmos was improved up to 3 mm. Medial and lateral orbital wall decompression are minimally invasive procedures involving removing a small portion of the bone from either the medial or lateral wall of the orbit. This allows more space for the eye to move backward, reducing pressure on the optic nerve and improving vision. This procedure also improves the cosmetic appearance of the eye. The ophthalmologic specialist performed the lateral wall decompression, and the ENT specialist performed the medial wall decompression. Medial and lateral orbital wall decompression has proven to be effective in treating patients with proptosis. The procedures have a low complication rate, and patients typically experience a significant improvement in their symptoms within a few weeks of the surgery. Keywords:  orbital decompression, trans endoscopic decompression, thyroid eye disease

To evaluate the changes in eye position and orbital content expansion following medial and lateral orbital wall decompression for thyroid-associated orbitopathy. The authors used a computer software program (syngo InSpace4D, syngo 3D, syngo fusion, and syngo Volume Evaluation; Siemens AG, Forchheim, Germany) to measure the orbital expansion gained by medial and lateral orbital wall decompression and the change in eye position between the digitized preoperative and postoperative orbital CT scans. Twenty patients (16 women and 4 men) with a mean age of 45 years (range, 18-64 years) were enrolled in this study. Of the 20 patients who underwent balanced decompression for thyroid-associated orbitopathy, 18 patients had bilateral medial and lateral orbital wall decompression, and 2 patients had unilateral medial and lateral decompression. The average orbital volume expansion was 3.21 mL (13.51%) of the preoperative orbital volume (2.1 mL [8.98%] gained by medial wall decompression and 1.03 mL [4.53%] by lateral wall decompression). Postoperatively, proptosis decreased by 2.53 mm on average (p < 0.0001). The eyes became closer to each other postoperatively in the horizontal plane by 2.6 mm on average (p < 0.0001). No change in the vertical eye position was detected postoperatively. A significant nasal shift in the eye position was noticed following balanced orbital decompression. Computerized assessment of preoperative and postoperative digitized orbital CT scans helps evaluate the orbital changes in response to different orbital decompression techniques and improve the surgical outcomes in thyroid-associated orbitopathy.

PurposeTo evaluate the clinical outcomes of balanced deep lateral and medial orbital wall decompression and to estimate surgical effects using computed tomography (CT) images in Korean patients with thyroid-associated ophthalmopathy (TAO).MethodsRetrospective chart review was conducted in TAO patients with exophthalmos who underwent balanced deep lateral and medial orbital wall decompression. Exophthalmos was measured preoperatively and postoperatively at 1 and 3 months. Postoperative complications were evaluated in all study periods. In addition, decompressed bone volume was estimated using CT images. Thereafter, decompression volume in each decompressed orbital wall was analyzed to evaluate the surgical effect and predictability.ResultsTwenty-four patients (48 orbits) with an average age of 34.08 ± 7.03 years were evaluated. The mean preoperative and postoperative exophthalmos at 1 and 3 months was 18.91 ± 1.43, 15.10 ± 1.53, and 14.91 ± 1.49 mm, respectively. Bony decompression volume was 0.80 ± 0.29 cm3 at the medial wall and 0.68 ± 0.23 cm3 at the deep lateral wall. Postoperative complications included strabismus (one patient, 2.08%), upper eyelid fold change (four patients, 8.33%), and dysesthesia (four patients, 8.33%). Postsurgical exophthalmos reduction was more highly correlated with the deep lateral wall than the medial wall.ConclusionsIn TAO patients with exophthalmos, balanced deep lateral and medial orbital wall decompression is a good surgical method with a low-risk of complications. In addition, deep lateral wall decompression has higher surgical predictability than medial wall decompression, as seen with CT analysis.

To describe the use of a lateral wall implant as an adjunct in lateral orbital wall decompression in severe thyroid eye disease. This study is a retrospective review of 6 patients who underwent prior orbital decompression but had persistent proptosis. These patients underwent lateral wall decompression with adjunct lateral wall implant placement with a manually vaulted 0.6-mm polyethylene-coated titanium mesh implant. Data collection included: visual acuity, intraocular pressure, exophthalmometry, ocular motility, eyelid position, and complication rates. Eight orbits in 6 patients underwent maximal lateral wall decompression and reconstruction using the polyethylene-coated titanium implant. Four males and 2 females were included with ages ranging from 25 to 73 years. Visual acuity improved an average of 2.4 lines (range 0-5 lines). Intraocular pressure improved an average of 7.5 mm Hg (2-13 mm Hg). There was reduction of proptosis by 3.4 mm on average (1-7 mm). Upper eyelid retraction improved on average by 1.8 mm (0-5 mm). Horizontal eye movements improved by 11% on average (-3.1% to +25%). Excellent cosmesis was achieved with no visible temple deformity, trismus, conjunctival scarring, orbital hemorrhage, or vision loss. The amount of volume created in lateral wall decompression is limited by the amount of native bone present and the temporalis muscle. In severe or recalcitrant cases, the authors propose the placement of a lateral wall implant as an adjunct to laterally displace the temporalis muscle and create additional volume. This technique accomplishes further reduction of proptosis in patients who have undergone prior orbital decompression.

Graves' orbitopathy is the most common extrathyroidal manifestation of Graves' disease. In the burnt out fibrotic phase exophthalmos, diplopia and lid retraction may remain, which can require multiple rehabilitative surgical interventions. Orbital decompression is an established surgical procedure for the treatment of exophthalmos in Graves' orbitopathy. The aim of the study was to evaluate the efficacy and side effects of the deep lateral orbital wall decompression including the orbital rim. In this retrospective, non-comparative case series, all patients with Graves' orbitopathy, who underwent lateral orbital wall decompression at the Eye Clinic of the University of Göttingen between 2008 and 2015, were analysed in terms of exophthalmos reduction, diplopia (Gorman score) and complications. The surgical technique involved the removal of the lateral orbital wall including the orbital rim combined with additional orbital fat resection via swinging eyelid approach. 127 patients who underwent 195 orbital decompressions were included. Mean exophthalmos reduction was 4.0 ± 1.2 mm (range 1.5 - 7.5 mm). Preoperatively, 47 patients/77 orbits (37.0/39.5%) presented without diplopia. Postoperatively, 3 patients/3 orbits (6.4/3.9%) showed new-onset diplopia (2.4% of all patients, 1.5% of all orbits). Diplopia in primary gaze was noted in one of the 3 patients (0.8% of all patients, 2.1% of patients without preoperative diplopia), and inconstant diplopia was seen in the other 2 patients. Postoperative improvement of diplopia was noted in 19 patients/19 orbits (15.0% of all patients, 23.8% of patients with preoperative diplopia/9.7% of all 195 interventions), and 16.1% of cases with preexisting diplopia. No severe complications were seen, except for one case of postoperative bleeding, which was successfully managed surgically without any functional deficits. A visible scar formation was noted in 6 cases (3.1%), temporal hollowing in 3 cases (1.5%), oscillopsia when chewing in 3 cases (1.5%) and a de-insertion of the lateral canthal region in 2 cases (1%). Deep lateral orbital wall decompression, including the orbital rim, is an effective surgical technique to reduce exophthalmos in patients with Graves' orbitopathy with a low risk of functional and aesthetic complications.

ObjectiveTo compare horizontal eye positions between proptotic thyroid eye disease patients and normal individuals, and to examine positional changes after orbital decompression surgery in thyroid eye disease patients.MethodsThe present case-controlled and retrospective comparative study included 78 proptotic thyroid eye disease patients who underwent bilateral orbital decompression surgery [lateral orbital wall decompression (Group L), 47 patients; medial orbital wall decompression (Group M), 9 patients; and balanced orbital decompression (Group B), 22 patients] and 143 age-matched healthy volunteers as controls. The interpupillary distance was measured to determine horizontal eye positions before and 3 months after surgery in thyroid eye disease patients and was also examined in control eyes. Horizontal eye shifts were calculated by subtracting postoperative from preoperative interpupillary distances.ResultsPreoperative interpupillary distances in thyroid eye disease patients were significantly larger than in controls. The interpupillary distances were significantly decreased postoperatively in Groups M and B, but were significantly increased in Group L. The order of the magnitude of the horizontal shifts was Groups M>B>L.ConclusionsProptotic thyroid eye disease patients preoperatively showed laterally displaced eyes in comparison with controls. However, the eyes shifted medially after the medial orbital wall decompression and the balanced orbital decompression, although the former showed more shift. Medial orbital wall or balanced orbital decompression can be used to correct both lateral and anterior displacement of the eyes.

ABSTRACTPurpose: To share our experience on deep lateral wall rim-sparing orbital decompression for the prevention of further spontaneous globe subluxation, in patients with shallow orbits and eyelid laxity.Methods: This is a retrospective, interventional case series review. We report the results of deep lateral wall rim-sparing orbital decompression in 7 patients with recurrent spontaneous globe subluxation, operated in our department between 2010 and 2016. The orbital morphology was established by computed tomography scan images, and all patients with shallow orbit configuration and who in addition had eyelid laxity were included. Patients with thyroid eye disease were excluded.Results: No significant intraoperative and postoperative complications were encountered. In all cases, the patients were satisfied with the aesthetic result and none reported further episodes of globe subluxation.Conclusions: Deep lateral wall rim-sparing orbital decompression is a safe and effective decompressive procedure associated with minimal complications, which can be performed successfully in patients with spontaneous globe subluxation associated with shallow orbits with enough eyelid laxity.

To evaluate the outcome and late postoperative complications after lateral orbital wall decompression in a series of patients with thyroid eye disease (TED). One hundred and three patients operated in the period 1999-2013 were invited to participate in the study, and 84 were included after a median (range) follow-up time of 124 (13-188)months. The patients were interviewed, and preoperative and postoperative data were collected from hospital records. Photographs ('selfies') were obtained from 64 patients. Wilcoxon signed-rank test was used to evaluate the change in pre- and postoperative data. On average, visual acuity was unchanged with a median value (range) of 1.0 (0.4-1.25) before to 1.0 (0-1.25) after surgery (p=0.5). Intraocular pressure (IOP) was reduced from a median value (range) of 17 (9-26) to 15 (8-23)mmHg (p<0.001). Median (range) Hertel values were 23 (15-30)mm preoperatively and 20 (12-26)mm postoperatively (p<0.001) respectively. Mean (SD) reduction in proptosis was 3.6 (±2.1)mm. Oscillopsia was reported in 24 patients (29%), 42 (50%) experienced a change in temporal sensation, and four (5%) had new-onset diplopia. In 47 patients (56%), some degree of temporal hollowing was reported. Among 64 photographed patients, 38 (59%) had noticeable hollowing on examination of postoperative pictures. There was agreement of the patient's perception of temporal hollowing and the appearance in photographs in 26 of 37 patients (70%). Lateral orbital wall decompression has been considered a safe and effective procedure for treatment of TED. Serious side-effects are infrequent, but in rare circumstances, even blindness may occur. Less serious side-effects are relatively common. Among others, a significant number of the patients developed temporal hollowing after the procedure. The patients must be informed about the possible complications before surgery.

Hyaluronic acid is superior to autologous fat for treatment of temporal hollowing after lateral orbital wall decompression: A prospective interventional trial

To investigate the outcome of a customized approach with targeted zygomatic basin bone removal orbital decompression in lower eyelid retraction and contour of patients with thyroid eye disease. In a comparative case series, clinical charts and photos of a consecutive sample of 92 patients with thyroid eye disease submitted to different types orbital decompression were studied. Exophthalmos, midpupil to lower eyelid margin distances (MRD2) at 11 meridians, and globe position were measured and compared according to the types of decompression. Each eyelid was also labeled as within or outside normal limits regarding both contour pattern analysis and MRD2 compared with a control normal range. Eyelid contour and globe position from patients with orbital decompression with zygomatic basin removal were compared with those without basin removal. A total of 105 orbits from 57 patients met the study inclusion criteria. Ninety-eight orbits had lateral orbital wall decompression and in 53% of these cases, bone in the zygomatic basin was removed. Removal of the zygomatic basin did not significantly enhance decrease in proptosis, but significantly induced vertical globe descent and improved MRD2 (p < 0.05). Preoperatively, 37% of the eyelids were in the normal MRD2 range and 18% within the normal contour range. Preoperatively, 77% had normal MRD2 and 55% normal contour range. Our study findings support the practical utility of incorporating a customized approach to orbital decompression, and suggest that an individualized approach with targeted bone removal may obviate the need for additional surgeries such as lower eyelid retraction repair.

Purpose: To describe a new technique for deep lateral (single) wall orbital decompression surgery, developed by Mr. Geoffrey Rose, for proptosis in patients with thyroid-associated orbitopathy and to analyse the results achieved in our series.Methods: The study is an interventional, retrospective, non-comparative case series. Twenty-one eyes of seventeen patients underwent the described technique of deep lateral wall orbital decompression for thyroid-associated orbitopathy. All patients had controlled thyroid functions and underwent surgery for cosmetic rehabilitation, with analysis of the reduction in proptosis, changes in visual acuity and post-operative complications. The surgery involved removing the lateral orbital wall whilst preserving the lateral rim, the lateral wall being approached through a horizontal skin incision placed lateral to the lateral canthus. After reflecting the periosteum, most of the bone (deep lateral wall) between the skull base and inferior orbital fissure is removed.Results: A mean reduction in proptosis of 4.81 mm ±1.23 (SD) (p < 0.0001) with a median of 5.0 mm (range 3–7 mm) was achieved and the best-corrected visual acuity was maintained in all patients. There were no complications during surgery, and post-operative complications included worsening of pre-existing diplopia in one patient (6%) and transient cheek/temple numbness seen in three patients (18%).Conclusions: This technique of deep lateral wall orbital decompression developed by Mr. Rose is a safe and effective procedure for patients with mild to moderate proptosis. It carries a low risk of morbidity and avoids complications associated with decompressing the floor and medial wall, including new onset of motility disorders.

This study presents a comparative analysis of outcomes of lateral orbital wall decompression performed using ultrasonic bone removal with standard and modified techniques. The study included 78 patients (109 orbits) with exophthalmos without visual impairment (subgroups 1A and 1B) and with optic neuropathy (ON) due to thyroid eye disease (TED) (subgroups 2A and 2B). Lateral wall decompression (LWD) was performed using ultrasonic bone removal with a modified (n=58, patient subgroups 1A and 2A) or standard (n=51, subgroups 1B and 2B) technique. Postoperative evaluation included visual function, degree of exophthalmos, and palpebral fissure parameters. In subgroup 1A, exophthalmos regression averaged 3.8±0.9 mm, while in subgroup 1B it amounted to 2.9±0.8 mm. Comparable improvement in visual acuity was observed in subgroups 2A and 2B, with a median gain of 0.4, along with positive changes in perimetry and color vision. The modified LWD technique using ultrasonic bone removal achieved a mean exophthalmos reduction of approximately 4 mm. In cases complicated by ON, improvement in visual function was observed for up to 4 years.

Background: Isolated deep lateral and combined medial orbital wall decompressions (balanced decompression) are well accepted for treatment of disfiguring proptosis and compressive optic neuropathy in patients with Graves’ orbitopathy. However, cerebrospinal fluid leakage and/or optic nerve injury occasionally occur during these operations.Purpose: To describe the anatomy of the deep lateral and medial orbital walls and its surgical implications in orbital decompression.Methods: We reviewed literature on the anatomy of the deep lateral and medical orbital walls. In addition, we performed cadaver dissection and computed tomographics studies to illustrate the anatomy.Results: We provided an anatomical overview and elucidated the detailed surgical anatomy of the posterior and superior borders of the deep lateral orbital wall, the posterior and accessory ethmoidal foramina, and the frontoethmoidal suture.Conclusions: The anatomy of the deep lateral and medical orbital walls presented here will warrant safe and confident performance of orbital decompression surgery.