Effectiveness of Cross-Linked Acellular Dermal Matrix to Correct Post-Traumatic Enophthalmos.

BACKGROUND: The use of an acellular dermal matrix is rarely reported in orbital wall fracture reconstruction. This study aimed to share the author's experience with the cross-linked acellular dermal matrix as an allograft material for enophthalmos correction. METHODS: In this retrospective study, the author evaluated the medical records and 3-dimensional facial computed tomography scans of patients with enophthalmos caused by neglected orbital fractures between May 2021 and June 2022. Facial computed tomography scans confirmed the clinical diagnosis of enophthalmos. A single surgeon performed all surgical operations. In all patients, the author accessed the orbital floor via subciliary incision while approaching the medial wall with a retrocaruncular incision. After fully exposing the lesion, the author used a 1.0-mm-thick cross-linked acellular dermal matrix (ADM) (MegaDerm; L&C Bio, South Korea). After trimming the cross-linked ADM to a proper size, the author implanted the ADM into the lesion. RESULTS: During May 2021 and June 2022, 3 cases of enophthalmos were successfully corrected with cross-linked ADM at the author's hospital. All patients were improved clinically and radiologically. CONCLUSION: This is the first study to show the effectiveness of cross-linked ADM for the correction of enophthalmos.

Virtual Surgical Planning and 3-Dimensional Printing for the Treatment of Zygomaticomaxillary Complex and/or Orbital Fracture.

BACKGROUND: Traditionally, in zygomaticomaxillary complex and orbital fractures, miniplates and titanium orbital mesh are used and adapted intraoperatively, which may cause fatigue of the metal and increase the surgical time. Recently, computer-assisted surgery and 3-dimensional printing enable the surgeon to employ 3-dimensional segmentation and mirroring tools, which mimic the pretraumatized anatomy on which the miniplates and titanium orbital mesh are preoperatively molded to precisely duplicate the orbital volume, enophthalmos, and zygomatic bone position. AIM: To evaluate the results of computer technology using 3-dimensional printing model to prebend miniplates and titanium orbital mesh in the restoration of orbital volume, enophthalmos, and zygomatic bone position in the initial management of patients with zygomaticomaxillary complex and/or orbital fractures. PATIENTS AND METHODS: This prospective clinical study included 10 Iraqi male patients who met the eligibility criteria and subjected to open reduction and internal fixation utilizing virtual surgical planning and a 3-dimensional model to prebend miniplates and titanium orbital mesh as a treatment modality for facial fractures. The data were analyzed according to the orbital volume, enophthalmos, zygomatic bone position, age, gender, etiology of the fracture, and complications. The patients were radiographically followed up with a computed tomography scan at 4 months postoperatively. The statistical analysis was performed using percentages, the mean±SD, Shapiro-Wilk test, Paired t test, One Way Anova, and Independent t test. RESULTS: The age of the patients ranged from 18 to 66 years, with an average of 28.6 years and a SD of±14.5 years. Regarding gender, all patients were males. By utilizing virtual surgical planning and 3-dimentional model to prebend miniplates and titanium orbital mesh and concerning the fracture types, which include the zygomaticomaxillary complex, orbital, and combined fractures, there was no significant difference between the measurement of intact side and 4 months postoperatively in orbital volume, enophthalmos, and zygomatic bone position ( P >0.05). CONCLUSION: This study demonstrated that computer-aided techniques, virtual planning, and the use of prebend miniplates and titanium orbital mesh enable anatomically precise reduction and fixation of the orbital, zygomaticomaxillary complex, and combined fractures regarding orbital volume, enophthalmos, and zygomatic bone position.

Prediction of Post-Traumatic Enophthalmos Based on Orbital Volume Measurements: A Systematic Review.

PURPOSE: Enophthalmos greater than 2 mm should be considered clinically relevant and can be responsible for esthetic and functional morbidity. The difficulty has always been the best method to use to accurately determine when the orbital wall displacement will lead to clinically relevant enophthalmos. None of the currently used techniques is able to accurately predict for post-traumatic enophthalmos (PE). The aim of the present study was to systematically review the use of orbital volumetric tools in the prediction of PE after orbital fracture. MATERIALS AND METHODS: The terms searched in each database were "(orbital volumetry) and enophthalmos," "volumetry and enophthalmos," "volume and enophthalmos," and "volumetric and enophthalmos." The relationship between PE and the orbital volume (OV) was assessed. RESULTS: The initial search yielded 346 results. Of the 346 studies, 14 were included and analyzed. Every study reported a different numerical relationship between the OV and PE, with a mean enophthalmos of 0.80 mm after a 1-cm3 increase in the OV. CONCLUSIONS: The present review found that most studies concluded that a direct relationship exists between the OV and PE and defined the degree of PE in relation to the OV expansion. Enophthalmos assessment using radiologic evaluation provides increased accuracy and reproducibility compared with clinical measurement using an exophthalmometer. It has been notoriously difficult to determine when orbital wall displacement will lead to clinically relevant enophthalmos. Measurement of the OV could have a role in the decision for surgical or conservative treatment.

Post-traumatic enophthalmos secondary to orbital fat atrophy: a volumetric analysis.

PURPOSE: To investigate via volumetric analysis whether orbital fat atrophy occurs in late post-traumatic enophthalmos. METHODS: An IRB-approved retrospective cohort study identified patients with diagnoses of both orbital fracture and enophthalmos with a CT orbits >3 months after injury. Exclusion criteria were surgical repair, other orbital disease or surgery, adjacent sinus disease, and an abnormal contralateral orbit. Images were analyzed using OsiriX imaging software (v.9.0.2, Pixmeo, Switzerland). Total orbital volume and orbital fat volume for the fractured and normal contralateral orbits were measured via three-dimensional volume rendering assisted region-of-interest computation. Enophthalmos was measured radiographically. Paired samples t-tests were used to compare orbital fat and total orbital volumes between the fractured and normal contralateral orbits. RESULTS: Thirteen patients met the inclusion criteria. The numbers of patients with each fracture pattern were floor (4), medial wall (4), floor/medial wall (3), zygomaticomaxillary complex (floor+lateral wall) (1), zygomaticomaxillary complex+medial (inferior/medial/lateral walls) (1). Mean time from injury to CT scan was 21.8 ± 16.3 months. Comparing the fractured and normal contralateral orbits, there was a statistically significant decrease in orbital fat volume (mean difference 0.9 ml (14.2%), p = .0002) and increase in total orbital volume (mean difference 2.0 ml (7.0%), p = .0001). One ml orbital volume change was responsible for 0.83 mm enophthalmos. CONCLUSIONS: In addition to an increase in total orbital volume, orbital fat loss occurs with late post-traumatic enophthalmos due to unrepaired fractures. This suggests correction of bony change alone may be insufficient in some cases, and the use of custom implants may compensate for fat atrophy.

Does Orbital Volume Change Using the Mirror Technique Have a Correlation With Posttraumatic Enophthalmos?

An increase in orbital volume (OV) is an important factor in posttraumatic enophthalmos. The aim of this study was to evaluate the correlation of OV change using the mirror technique with posttraumatic enophthalmos.In this cross-sectional study, a 3-dimensional (3D) semi-automated volumetric method, using a 3D volume rendering tool, was applied to measure OV. The total orbital volume difference (TOVD), posterior orbital volume difference (POVD), and anterior orbital volume difference (AOVD) were measured as predictive factors in traumatic and intact orbits. Enophthalmos was also examined as the outcome, using a Hertel exophthalmometer.A total of 27 patients were examined in this study. The mean TOVD was 4.48 ±â€Š1.82 mm, the mean POVD was 1.91 ±â€Š0.31 mm, and the mean AOVD was 2.57 ±â€Š1.71 mm; also, the mean enophthalmos was 2.89 ±â€Š1.12 mm. Pearson's correlation test demonstrated a positive correlation between enophthalmos and TOVD, POVD, and AOVD (P <0.05). Based on the linear regression model, TOVD had a predictive power of 61.7% for enophthalmos. For every 1-mm volume change, a 0.38-mm enophthalmos was expected (R, 0.617; B, 0.38; P = 0.001).TOVD, POVD, and AOVD showed strong correlations with enophthalmos. However, it seems that POVD has the greatest effects on the occurrence of posttraumatic enophthalmos.

Orbital Fat Injection: Technique and 5-Year Follow-Up.

BACKGROUND: Orbital volume loss, early or late, is common after placement of an orbital implant or dermis fat graft, and there is currently no satisfactory long-lasting solution. Hyaluronic fillers are relatively easy to administer but are prone to migration and are temporary. Cannula-based orbital fat grafting has not gained the status of standard of care because of perceived low likelihood of success in the near term. This paper describes a technique for fat volume augmentation, its rationale, long-term follow-up, and a description of a complication unique to fat grafting in the orbit. METHODS: Ten consecutive subjects with acquired anophthalmic enophthalmos were enrolled in two IRB (institutional review board)-approved protocols (10.27 and 12.01) undergoing a single session of autologous fat grafting to the orbit using a closed blunt cannula technique. Preoperative photography and non-contrast MRIs (magnetic resonance imaging) were obtained prior, immediately after, and at 1 year after injection. Yearly postoperative photography was performed on subjects with successful results. RESULTS: Three of five subjects in IRB 10.27 clearly showed a clinically apparent increase in orbital volume at 1 year. One subject who failed to show improvement also sustained inadvertent injection into three extraocular muscles; she subsequently volunteered to enter IRB 12.01. Three of five subjects in IRB 12.01 did benefit, showing volume increase at 1 year, including the subject who had experienced intramuscular injection in 10.27. One subject in IRB 12.01 was lost to follow-up. Of the total of ten subjects enrolled, three showed no improvement and one was lost to follow-up; six subjects showed volume improvement at 1 year with two retaining the correction at 5 years and four showing variable diminution over 2-5 years. With the exception of the subject who sustained injection into extraocular muscles, none experienced complications. CONCLUSION: A modified technique is recommended for orbital fat injection distinct from methods used elsewhere in the body. Theoretical limits of volumetric enhancement temper expectations in orbital fat grafting and should inform surgical planning. Cannula-based orbital fat grafting can be done safely and result in a gain of orbital fat volume at 1 year and in some cases up to 5 years. LEVEL OF EVIDENCE IV: This journal requires that authors assign a level of evidence to each article. For a full description of these Evidence-Based Medicine ratings, please refer to the Table of Contents or the online Instructions to Authors www.springer.com/00266 .

Correction of Delayed Traumatic Enophthalmos Using Customized Orbital Implants.

PURPOSE: To determine the relation between overcorrection of orbital volume and ocular projection in patients with orbital trauma. MATERIALS AND METHODS: A prospective cohort study was performed of patients with enophthalmos as a side effect of orbital trauma. The sample included patients older than 18 years who required reconstruction using customized implants to treat enophthalmos with or without diplopia. The exclusion criteria were patients who had multiple or extended fractures and patients with amaurosis or a prosthetic eye. Orbital volumes were calculated and the position of the eyeball in the healthy and traumatized sockets was determined before and after installing the implant and the ratio between these variables was calculated. Two variables were identified: 1) orbital volume and 2) enophthalmos. Analysis of the estimator variables was performed, defining 3 groups: 1) healthy eye socket, 2) traumatized eye socket without implant, and 3) traumatized eye socket with implant. The Shapiro-Wilk test, paired t test, and linear regression analysis were performed. A P value less than .05 (95% confidence interval) indicated significant differences. RESULTS: Of 294 patients who underwent orbital zygomatic complex reconstruction surgery, 13 required customized implants and only 5 met the inclusion criteria. The average volumetric variation in the groups of traumatized eye sockets with and without implants was statistically significant (P < .05), overcorrecting by an average of 4.2 cm3. The average enophthalmos variation in the groups of traumatized eye sockets with and without implants was statistically significant (P < .05), projecting the eyeball by an average 1.80 mm. The ratio between the average orbital volume and projection of the eyeball was determined to be 1:0.721 (correlation, 45.6%). CONCLUSION: This study concluded that the eyeball is projected 0.7 mm for every 1 cm3 of volume added in customized orbital implants. However, additional clinical studies with larger samples should be conducted.

Orbital Reconstruction by Patient-Specific Implant Printed in Porous Titanium: A Retrospective Case Series of 12 Patients.

PURPOSE: The purpose of this study was to evaluate the orbital patient-specific implant (PSI) directly printed in porous titanium for the reconstruction of complex orbital bone defects in a series of 12 patients. PATIENTS AND METHODS: The authors designed and implemented a case series. The sample consisted of patients with unilateral complex orbital bone loss. All patients received a porous titanium PSI designed from the healthy contralateral side (mirroring). The criteria analyzed were the functional results: correction of enophthalmos, correction of ocular motility, operative time, complications, and operative revisions. The study was performed from 2015 through 2017. RESULTS: The sample was composed of 12 patients (mean age, 47 yr; age range, 13 to 70 yr). Patients were followed for a mean of 36 weeks postoperatively (range, 4 to 100 weeks). Twelve of the 12 patients presented preoperative enophthalmia, and 8 of the 12 patients presented preoperative diplopia. The mean operating time was 71 minutes (range, 60 to 200 minutes). For 8 patients, the follow-up was simple. In contrast, 2 patients required surgical revision with repositioning of the implant because of intraoperative implant malpositioning with esthetic or functional disturbance and malpositioning was confirmed on the postoperative computed tomogram, 1 patient required explantation of his implant 7 months after the surgery because of spheno-orbital meningioma recurrence (the implant was well positioned), and 1 patient operated on by a subciliary approach presented a postoperative ectropion. In this series of porous titanium orbital PSIs without positioning guides, 17% had malpositioning (2 patients who required a new intervention for repositioning). CONCLUSION: The results of this study suggest that porous titanium PSI could be a surgical option for patients with complex orbital bone defects. In this series 17% of the sample needed a second operation. There are several ways to improve these results, such as intraoperative navigation or integrated positioning guides.

Orbital fat regeneration following hormonal treatment of metastatic breast carcinoma.

Enophthalmos in the setting of breast cancer metastatic to the orbit results primarily from the disease pathogenesis, or secondary to treatment effects. Orbital volume restoration and fat regeneration following endocrine treatment monotherapy has not been previously reported. A 76- year-old previously healthy female presented with progressive right enophthalmos secondary to metastatic lobular breast carcinoma. Treatment with an aromatase inhibitor (letrozole) resulted in tumor regression and orbital fat restoration with a corresponding improvement in orbital volume and enophthalmos on clinical exam. The patient is alive on continued letrozole with no progressive disease ten years after diagnosis. This case illustrates the resilience of orbital soft tissues and ability of orbital fat to regenerate in face of breast cancer metastasis. We hypothesize that endocrine monotherapy, and avoidance of radiation therapy, allowed for differentiation of remaining orbital stem cells, and facilitated the fat regenerative process.

[Exophthalmometry with computed tomography]. / Metod ékzoftal'mometrii s ispol'zovaniem komp'iuternoi tomografii.

Bone abnormalities of orbit seen in patients with trauma or radiolesion are accompanied by enophthalmos or exophthalmos. Conventional measurements of eyeball protrusion with Hertel's exophthalmometer or with computed tomography do not provide accurate and reliable data, especially in patients with asymmetry of lateral orbital rims. PURPOSE: To develop a method of computed exophthalmometry that provides accurate and reliable measurements in patients with various orbital conditions. MATERIAL AND METHODS: Medical records and computerized axial tomography scans of 25 patients' orbits without false enophthalmos or exophthalmos were analyzed posthoc. First group included 13 patients with trauma or radiolesion of the orbit at the different stages of plastic-reconstructive treatment. Second group consisted of 12 patients with lacrimal duct obstruction and without any orbital bone abnormalities. Eyeball protrusion was measured from a line joining styloid processes of temporal bones according to the developed method. RESULTS: Comparison of the results of three independent measurements showed that in group 1 mean value varied from 0.40 mm to 10.13 mm and in group 2 - from 0.10 mm to 0.87 mm. Standard deviation (0.00-0.29 mm) and standard error in mean (0.00-0.17 mm) was the same in both groups. CONCLUSION: The newly developed method of exophthalmometry with the use of computed tomography provides accurate and reliable data in patients with various orbital conditions including asymmetry of lateral orbital rims. Eyeball protrusion with asymmetry not exceeding 0.9 mm does not lead to functional and esthetical abnormalities and may be considered normal. The developed method is easy to setup and use, it can be applied in medical practice for diagnostics, surgery planning and evaluation of postoperative results in patients with various orbital conditions.

Chronic maxillary atelectasis and silent sinus syndrome: two faces of the same clinical entity.

Chronic maxillary atelectasis (CMA) and silent sinus syndrome (SSS) are rare clinical entities characterized by an implosion of the maxillary sinus that may or may not be associated with sinonasal symptoms, and are complicated by ipsilateral enophthalmos. The objective of this article is to discuss the definitions, physiopathology, clinical and radiographic characteristics, and surgical management of these entities. We retrospectively reviewed 18 patients (7 women, 11 men, aged 12-70 years) diagnosed and treated in the ear, nose, and throat departments of four Belgian teaching hospitals between 2000 and 2015. Nine patients had a history of sinus disease. In all cases, a computed tomography scan showed downward displacement of the orbital floor, increased orbital volume, and maxillary sinus contraction. Five patients met the criteria for grade II CMA and 13 for grade III CMA. Four patients met the criteria for SSS. All patients underwent wide endoscopic middle maxillary antrostomy. There were no orbital complications and all patients experienced resolution or a dramatic reduction of their symptomatology. Only one patient asked for an orbital floor reconstruction to correct a persisting cosmetic deformity. Although CMA and SSS are usually regarded as different entities in the literature, we believe that they lie on the same clinical spectrum. Treatment for both conditions is similar, i.e., middle meatal antrostomy to halt or even reverse the pathological evolution and reconstruction of the orbital floor in the event of persistent cosmetic deformity.

Silent sinus syndrome an acquired condition and the essential role of otorhinolaryngologist consultation: a retrospective study.

The silent sinus syndrome (SSS) is a rare clinical entity characterized by painless spontaneous enophthalmos, hypoglobus, and facial deformities secondary to chronic maxillary sinus atelectasis. The aim of this study was to present an SSS diagnostic feature and evaluate the relationship between nasal septum deviation and maxillary sinus volume. A retrospective chart review of the clinical characteristics of 20 patients diagnosed with SSS between January 2013 and July 2014 were analyzed by the Department of Otorhinolaryngology of University Hospital Complex of Santiago de Compostela. 14 patients were females and six males. The mean age was 43 years (range 28-67 years). The right maxillary sinus was involved in 12 patients and the left maxillary sinus in eight patients. There was no statistical difference between gender and the presence of SSS. Maxillary sinus sizes were significantly smaller on the same side as the deviation (p < 0.01). 14 patients were treated with functional endoscopic sinus surgery (FESS) with maxillary antrostomy. We concluded that patients with SSS usually present with facial asymmetry, and the best approach to document and show all facial asymmetries for these patients are the frontal and craneo-caudal photographs. The present study demonstrates that, in adult patients, SSS generally presents a septal deviation to the affected maxillary sinus. We recommend performing a paranasal sinus CT scan when the patient has a deviated nasal septum, retraction of the malar eminence (evidenced from the viewpoint cranio-caudal facial) and hypoglobus. FESS performing postero-anterior uncinectomy and enlargement of the maxillary ostium is recommended to restore sinus pressure and prevent progression of the enophthalmos, hypoglobus and facial deformities.

Reconstruction of Inferior Orbital Wall Fractures Using Bone Fragments.

INTRODUCTION: Various materials have been used as implants in orbital floor fractures. The fractured bone fragments, however, are not usually used because of their small size and delicate characteristics. To overcome this limitation, the authors used autologous bone fragments combined with fibrin glue and an absorbable plate to repair inferior orbital wall fractures. METHODS: Thirty-four patients with orbital floor fractures treated in a single center from January 2013 to September 2014 were prospectively evaluated. Patients' demographic characteristics, clinical signs and symptoms, physical examination findings, postoperative complications, and preoperative and postoperative computed tomography findings were assessed. Fracture repair by a transconjunctival approach in which bone fragments were merged with fibrin glue and an absorbable plate was performed in all the patients. RESULTS: Postoperative computed tomography showed good orbital fracture reduction and soft tissue restoration in all the patients. Five patients developed postoperative diplopia; however, this symptom resolved spontaneously. Exophthalmometry showed that the degree of enophthalmos had improved significantly. CONCLUSION: Based on the results of this study, the combination of autologous bone fragments and absorbable mesh appears to be a safe and feasible option for the reconstruction of orbital floor fractures.

Hyaluronic Acid Gel Re-Injection for Enophthalmos Correction in Silent Sinus Syndrome.

A 43-year-old female with residual enophthalmos following functional endoscopic surgery (FESS) due to silent sinus syndrome (SSS) was initially successfully treated with a 2-ml intraorbital injection of hyaluronic acid gel (HAG). The enophthalmos partially recurred 22 months after the injection. HAG was re-injected with good functional and cosmetic results. Functional (kinetic) computed tomography was performed to visualize HAG distribution in the orbit.

Maxillary sinus posterior wall remodeling following surgery for silent sinus syndrome.

Silent SINUS SYNDROME is a clinical syndrome defined by unilateral maxillary sinus opacification with atelectasis of the uncinate process. Clinically, this disorder is characterized by enophthalmos and hypoglobus. The current case report illustrates dramatic bony remodeling of the maxillary sinus following maxillary antrostomy. Although the remodeling is noted in the posterior wall of the maxillary sinus, this demonstrates the dynamic nature of bone remodeling in silent sinus syndrome, which may obviate the need for surgical correction of enophthalmos and hypoglobus. Following maxillary antrostomy, observation with staged orbital surgery, if required, is recommended.

Clinical and radiographic assessment of patient-specific transantral reconstruction of orbital floor fractures: A case series.

To clinically and radiographically evaluate patient-specific titanium meshes via a trans-antral approach for correction of enophthalmos and orbital volume in patients with recent unilateral orbital floor fracture. Seven patients with unilateral orbital floor fractures received patient-specific titanium meshes that were designed based on a mirror-image of the contralateral intact orbit. The patient-specific implants (PSIs) were inserted via a trans-antral approach without endoscopic assistance. The patients were evaluated clinically for signs of diplopia and restricted gaze as well as radiographically for enophthalmos and orbital volume correction. Diplopia was totally resolved in two of the three patients who reported diplopia in the upward gaze. Whereas enophthalmos significantly improved in all but two patients, with a mean value of 0.2229 mm postoperatively compared to 0.9914 mm preoperatively. CT scans showed excellent adaptation of the PSIs to the orbital floor with a mean reduction of the orbital volume from 29.59 cc to 27.21 cc, a mean of 0.6% smaller than the intact orbit. It can be concluded that the proposed PSI can offer good reconstruction of the orbital floor through an isolated intraoral transantral approach with minimal complications. It could of special benefit in extensive orbital floor fractures.

Change of the orbital volume ratio in pure blow-out fractures depending on fracture location.

The purposes of this study were to observe bony orbital volume (OV) changes in pure blow-out fractures according to fracture location using a facial computed tomographic scan and to investigate whether the OV measurements can be used as a quantitative value for the evaluation of the surgical results of the acute blow-out fracture.Forty-five patients with unilateral pure blow-out fracture were divided into 3 groups: inferior (group I), inferior medial (group IM), and medial (group M) orbital wall fracture. The OV and the orbital volume ratio (OVR) were prospectively measured before and 6 months after surgery with the use of 3-dimensional computed tomographic scans, and the Hertel scale was measured with a Hertel exothalmometer.The preoperative OVR increased to the greatest extent in group IM, and the mean preoperative OVR was 121.46. The mean preoperative OVR in group I was significantly higher than that of group M (P = 0.005). The OV and OVR revealed a statistically significant decrease after the surgery (P = 0.000). The Hertel scale improved from -1.04 mm before the surgery to -0.78 mm after the surgery, but no significant difference was observed (P = 0.051).The OVR was useful as a quantitative value to evaluate pure blow-out fractures, compared with that of the Hertel scale. Fracture location-associated OVR studies are needed to make volume guidelines of blow-out fracture surgery.