It is difficult to identify the exact cause of ocular motility disturbances in orbital wall fracture patients. By performing CT and ocular motility tests before and after surgery, this study analyzes the functions of the extraocular muscles and determines correlations between the results. Between February 2001 and January 2003, 45 eyes of 45 patients with orbital wall fractures, whose medical records could be traced back at least 6 months, underwent surgical repair in our hospital. All variables were analyzed using the independent t-test, paired t-test, and Chi-square test. There was no significant difference in the location and degree of fracture and the incarceration pattern of 6 patients who had moderate or severe diplopia, and of the remaining patients 6 months after surgery. However, in the case of diplopia, the sum of ocular motility limitation was 5.67 +/- 4.18, and the degree of extraocular motility disturbance was 3.67 +/- 2.42 before surgery. When there was no diplopia, the sum of ocular motility limitation was 1.13 +/- 1.38, and the degree of extraocular motility disturbance was 1.08 +/- 1.16 (p < 0.005, independent t-test). Ocular movement was successfully recovered by surgical reduction within 3 weeks from trauma. Postoperative ocular motility disturbance was more related to various ocular motility test results than CT findings. Ocular motility disturbances can remain after surgery if ocular motility limitation and extraocular motility disturbance are significant after trauma. Additional studies on the various tests to examine functions of extraocular muscles are required to identify and analyze the exact cause of ocular motility disturbance.
Adult ; Child ; Diagnostic Techniques, Ophthalmological ; Diplopia/*etiology/radiography ; Humans ; Middle Aged ; Ocular Motility Disorders/*etiology/radiography ; Orbital Fractures/*complications/radiography ; Tomography, X-Ray Computed

A 51-year old man presented with vertical and torsional diplopia after reduction of a blowout fracture at another hospital one year ago. He had no anormalies of head position and 14 prism diopters (PD) right hypertropia (RHT) in the primary position. In upgaze no vertical deviation was found, and hyperdeviation on downgaze was 35PD. Bielschowsky head tilt test showed a negative response. Distinct superior oblique (SO) and inferior rectus (IR) underaction of the right eye was noted but IO overaction was mild on the ocular version test. Double Maddox rod test (DMRT) revealed 10-degree extorsion, but fundus extorsion was minimal in the right eye.Thin-section coronal CT scan showed that there was no fracture line on the anterior orbital floor, but a fracture remained on the posterior orbital floor. Also, the anterior part of the right inferior oblique muscle was vertically reoriented and the medial portion of the inferior oblique muscle was not traced on the coronal CT scan. The patient underwent 14 mm right IO recession and 3 mm right IR resection. One month after the surgery, his vertical and torsional diplopia were eliminated in the primary position.
Constriction, Pathologic/complications/etiology/physiopathology/radiography ; Diplopia/etiology ; Humans ; Male ; Middle Aged ; Muscular Diseases/complications/etiology/*physiopathology/*radiography ; Oculomotor Muscles/*physiopathology/*radiography/surgery ; Orbital Fractures/*complications ; *Tomography, X-Ray Computed

Simulated Brown syndrome is a term applied to a myriad of disorders that cause a Brown syndrome-like motility. We encountered a case of acquired simulated Brown syndrome in a 41-year-old man following surgical repair of fractures of both medial orbital walls. He suffered from diplopia in primary gaze, associated with hypotropia of the affected eye. We performed an ipsilateral recession of the left inferior rectus muscle as a single-stage intraoperative adjustment procedure under topical anesthesia, rather than the direct approach to the superior oblique tendon. Postoperatively, the patient was asymptomatic in all diagnostic gaze positions.
Adult ; Anesthesia, Local ; Diplopia/*etiology/surgery ; Eye Movements ; Humans ; Male ; Ocular Motility Disorders/*etiology/radiography/surgery ; Oculomotor Muscles/surgery ; Ophthalmologic Surgical Procedures ; Orbital Fractures/radiography/*surgery ; *Postoperative Complications ; Strabismus/etiology/surgery ; Tomography, X-Ray Computed ; Vision, Binocular

Air-bags have received widespread support as an effective means of enhancing automotive safety, and they are becoming more common as standard automobile equipment on many cars. Although air-bag induced ocular injuries are rare, they present a serious concern because of the possibility of permanent damage or visual impairment. To date, most reports have investigated ocular injury from high velocity motor vehicle accidents and reports of ocular injury from low speed motor vehicle accidents have been rare. We describe a patient who sustained severe ocular injury, including periorbital fracture, hyphema, vitreous hemorrhage, and choroidal rupture of the macular area, due to an inflated air-bag in a low speed motor vehicle accident.
Accidents, Traffic ; Adult ; Air Bags/*adverse effects ; Choroid/*injuries ; Eye Injuries/*etiology ; Female ; Humans ; Hyphema/*etiology ; Orbital Fractures/*etiology/radiography ; Rupture ; Tomography, X-Ray Computed ; Vitreous Hemorrhage/*etiology/ultrasonography

Child ; Edema ; diagnostic imaging ; etiology ; Emphysema ; diagnostic imaging ; etiology ; Ethmoid Bone ; diagnostic imaging ; injuries ; Eyelid Diseases ; diagnostic imaging ; etiology ; Humans ; Male ; Orbit ; diagnostic imaging ; Orbital Diseases ; diagnosis ; diagnostic imaging ; pathology ; Radiography ; Skull ; diagnostic imaging ; pathology ; Skull Fractures ; complications ; diagnostic imaging

A case of acquired Brown syndrome caused by surgical repair of medial orbital wall fracture is reported in the present paper. A 23-year-old man presented at the hospital with right periorbital trauma. Although the patient did not complain of any diplopia, the imaging study revealed a blow-out fracture of the medial orbital wall. Surgical repair with a calvarial bone autograft was performed at the department of plastic surgery. The patient was referred to the ophthalmologic department due to diplopia that newly developed after surgery. The prism cover test at distant fixation showed hypotropia of the right eye, which was 4 prism diopters (PD) in primary gaze, 20 PD in left gaze, while orthophoric in right gaze. Eye movement of the right eye was markedly limited on elevation in adduction with normal elevation in abduction with intorsion in the right eye present. Forced duction test of the right eye showed restricted elevation in adduction. Computerized tomography scan of the orbits showed the right superior oblique muscle was entrapped between the autografted bone fragment and posterior margin of the fracture. When repairing medial orbital wall fracture that causes Brown syndrome, surgeons should always be careful of entrapment of the superior oblique muscle if the implant is inserted without identifying the superior and posterior margin of the orbital fracture site.
Bone Transplantation/*adverse effects ; Diplopia/etiology ; Humans ; Male ; Ocular Motility Disorders/*etiology/radiography ; Ophthalmologic Surgical Procedures/*adverse effects ; Orbital Fractures/*surgery ; Tomography, X-Ray Computed ; Transplantation, Autologous ; Young Adult

We report four unusual cases of upper eyelid retraction following periorbital trauma. Four previously healthy patients were evaluated for unilateral upper eyelid retraction following periorbital trauma. A 31-year-old man (Case 1) and a 24-year-old man (Case 2) presented with left upper eyelid retraction which developed after blow-out fractures, a 44-year-old woman (Case 3) presented with left upper eyelid retraction secondary to a periorbital contusion that occurred one week prior, and a 56-year-old man (Case 4) presented with left upper eyelid retraction that developed 1 month after a lower canalicular laceration was sustained during a traffic accident. The authors performed a thyroid function test and orbital computed tomography (CT) in all cases. Thyroid function was normal in all patients, CT showed an adhesion of the superior rectus muscle and superior oblique muscle in the first case and diffuse thickening of the superior rectus muscle and levator complex in the third case. CT showed no specific findings in the second or fourth cases. Upper eyelid retraction due to superior complex adhesion can be considered one of the complications of periorbital trauma.
Accidents, Traffic ; Adult ; Eye Injuries/*complications/surgery ; Eyelid Diseases/*etiology/radiography ; Female ; Humans ; Lacerations/complications/surgery ; Lacrimal Apparatus/*injuries ; Male ; Middle Aged ; Oculomotor Muscles ; Orbital Fractures/*complications/surgery ; Tomography, X-Ray Computed

OBJECTIVETo evaluate the application of digital surgical technology in reconstruction of orbital frame and assess the treatment outcomes.

METHODSSeven patients with post-traumatic orbital defect were included in this study. Images of the orbit were obtained for each individual through computed tomography (CT). Preoperative design was finished according to rapid prototyping, computer-aided design and computer-aided manufacturing (CAD-CAM) and other digital surgical techniques. Surgical fracture reductions with internal fixation and implant of Medpor were used in operation to reconstruct orbit as well as correct enophthalmos and diplopia.

RESULTSAccurate realignment of the displaced orbital rim was obtained in all the 7 patients, and enophthalmos and diplopia were corrected in 4 and 2 patients, respectively.

CONCLUSIONSDigital techniques provide a precise means for preoperative design and operation implementation during orbital reconstruction. As a result, complications can be reduced, and the patient's facial appearance can be maximally improved.

Adult ; Computer-Aided Design ; Diplopia ; etiology ; surgery ; Enophthalmos ; etiology ; surgery ; Female ; Fracture Fixation, Internal ; Humans ; Imaging, Three-Dimensional ; Male ; Middle Aged ; Orbit ; diagnostic imaging ; surgery ; Orbital Fractures ; complications ; diagnostic imaging ; surgery ; Radiography ; Reconstructive Surgical Procedures ; methods ; Surgery, Computer-Assisted ; Treatment Outcome ; Young Adult