In congenital third nerve palsy, the function in four of the six extraocular muscles is compromised, and its treatment is the most difficult problem in paralytic strabismus. In general, either large recession and resection on horizontal rectus muscles or superior oblique muscle transposition is used for treatment. We compared the results of the two methods of surgical therapy. A Total of nine eyes in nine cases underwent surgical correction for ocular alignment in the primary position, In four eyes of four cases horizontal rectus muscle surgery was performed. In five eyes of five cases superior oblique muscle transposition was performed. Postoperatively, one of four cases who underwent horizontal rectus muscle surgery and four of five cases who underwent superior obique muscle transposition resulted in acceptable ocular alignment, in which the angle of deviation at the primary position was within 2 delta. Therefore, in the treatment of congenital third nerve palsy, superior oblique muscle transposition is more effective than horizontal rectus muscle surgery for the correction of ocular alignment.
Muscles ; Oculomotor Nerve Diseases ; Oculomotor Nerve* ; Strabismus*

PURPOSE: Blepharoptosis can result from either congenital or acquired causes. Blow out fracture or facial bone fracture including blow out fracture can be one of the causes. Authors experienced 3 cases of severe blepharoptosis after blow out fracture treated only with observation after reduction of associated fracture. METHODS: Reconstruction of orbital wall was conducted on all cases diagnosed as blow out fracture using 3 dimensional computed tomography, and conservative treatment was done on accompanying severe blepharoptosis. RESULTS: At the time of injury, all cases showed severe blepharoptosis requiring frontalis muscle transfer for correction. But blepharoptosis was recovered in an average of 18 weeks without any surgical procedure except reconstruction of orbital wall. CONCLUSION: Once Blepharoptosis occurred after blow out fracture, thorough evaluation must be done at first. If definitive cause of blepahroptisis cannot be found as authors' cases, injury of oculomotor nerve may result in blepharoptosis. So, as for blepharoptosis after blow out fracture, conservative treatment following reconstruction of fractured orbital wall can be one of good management.
Blepharoptosis ; Facial Bones ; Muscles ; Oculomotor Nerve ; Orbit

When the oculomotor nerve is completely paralyzed, the affected eye shows severe outward displacement and poor cosmetic appearance. Past results of many surgical procedures for oculomotor palsy have been generally unsatisfactory. We tried a new surgical approach experimentally, in which the disinserted lateral rectus muscle was used as an adductor by medial transposition of the muscle. Five adult cats underwent disinsertion of the medial rectus muscle of both eyes to induce iatrogenic medial rectus paralysis. The disinserted medial rectus was removed as far back as possible to prevent reattachment. Then, the right lateral rectus muscle was disinserted and passed beneath the superior rectus muscle and resutured to the sclera 4mm superoposterior to the medial rectus insertion site. After excision of the bilateral medial rectus, a large exotropia of an average 47.6 delta (42.0-55.5 delta) was induced. The medial transposition of the right lateral rectus produced an average 36.6 delta (24.8-45.8 delta) correction of the exotropia. A satisfactory cosmetic result was achieved by this procedure.
Animals ; Cats ; Exotropia/etiology ; Oculomotor Muscles/*surgery ; Oculomotor Nerve Diseases/physiopathology/*surgery ; Vision Disparity

In third nerve palsy, the functions in the four of the six extraocular muscles are compromised and its treatment is the most difficult problem in the paralytic strabismus. In surgical method, large recession and resection of horizontal rectus muscles, lateral rectus muscle transposition to medial rectus muscle and superior oblique muscle transposition are used for strabismus surgery on oculomotor nerve palsied eye. We compared the results of two methods of surgical correction. In three eyes, lateral muscle transpositions to medial rectus muscle were performed. On the last follow up examination (men; 6.7 months), two eyes resulted in severe hypertropia and unacceptable ocular alignment and no improvement of limited adduction. In six eyes of whom superior oblique muscle transpositions were performed, all resulted in acceptable ocular alignment, no hypertropia, and the limitations of adduction were improved markedly. Therefore, in the treatment of third nerve palsy, sperior oblique muscle transposition is more effective than lareral rectus muscle transposition to medial rectus muscle.
Exotropia* ; Follow-Up Studies ; Muscles ; Oculomotor Nerve Diseases* ; Oculomotor Nerve* ; Strabismus

Endoscopy ; Female ; Humans ; Middle Aged ; Nose ; surgery ; Oculomotor Muscles ; surgery

Objective To establish the normal measurements of diameter of extraocular muscles (EOMs) by multislice computed tomography (CT). Methods Orbits of 50 volunteers (25 male and 25 female) were scanned with a multislice CT scanner. For each subject, one axial image at the central level of the eyeball, one coronal image about 1 cm behind globe, and two oblique sagittal images respectively along the left and right optic nerve were used for measurements of the thickness and width of EOMs. The statistic significance of measurement value between male and female and between left and right eyes was evaluated. Results There were no significant differences in the thickness and width of superior muscle group, lateral rectus, medial rectus, lateral rectus, superior oblique, inferior oblique and the thickness of levator palpebrae superioris between the left and right eyes as well as between male and female groups (all P>0.05). The thickness of superior muscle group and inferior rectus had not significant difference (2.9±0.7 vs. 3.3±0.8 mm, P=0.162), while the thickness of medial rectus was significantly higher than that of lateral rectus (3.1±0.5 vs. 2.2±0.6 mm, P=0.000). Conclusions The CT measurement of extraocular musculature is simple and time-saving and can be applied in the clinical work. The normative data obtained may be useful in determining pathologic enlargement of the EOMs in both thyroid-associated orbitopathy patients and other various orbital conditions.
Humans ; Multidetector Computed Tomography ; Oculomotor Muscles ; Optic Nerve ; Orbit

Objectives: Refractive changes have been studied after muscle surgery in literature but most results are inconsistent. It has been postulated that changes in corneal tension after muscle surgery may cause a change in corneal curvature resulting in the change in refraction postoperatively. This study investigated changes in corneal topography and clinical refraction after horizontal rectus muscle surgery. Methods: Twenty-one eyes of 13 patients underwent horizontal rectus muscle surgery via limbal approach. Manifest refraction, cycloplegic refraction, and corneal topography were measured preoperatively, and postoperatively at day 1 and weeks 1, 2, 4 and 8. The proportion of subjects with at least 0.5 D change from preoperative measurements and the proportion of subjects that needed new prescription postoperative were also computed. Analysis of the results were done using the Friedman test to identify significant differences among measurements at different time periods with post-hoc analysis utilized to identify specific time periods with significant changes from preoperative measurements. Results: Mean corneal keratometry, horizontal, vertical, and oblique astigmatism, obtained topographically showed no significant difference from preoperative measurements. The statistically significant difference in corneal astigmatism in the recession group at day 1, week 4 and week 8 postoperatively was not confirmed when converted to power vectors in both vertical/horizontal (J0) and oblique (J45) astigmatism. Clinical refraction showed a transient myopic shift in spherical equivalent, statistically significant only on postoperative day 1 in the recession group. There was no statistically significant difference in clinical astigmatism. There was ≥ 0.5 D change in spherical equivalent in 60% in both study groups by the end of follow-up. The shift in J0 was more than 10% in the recession group. More than fifty percent (52.4%) needed new prescription for glasses. Conclusion No statistically significant change in corneal topography and clinical refraction following horizontal rectus muscle surgery were found. Patients should still be refracted at least 2 weeks postoperatively to check if there is a need for change in prescription glasses to improve alignment and/or improve vision.
Astigmatism ; Oculomotor Muscles ; Ophthalmologic Surgical Procedures ; Vision Tests ; Strabismus

PURPOSE: To investigate the effect of adjusted Kestenbaum surgery in patients with idiopathic infantile nystagmus who were affected by both strabismus and face turn. METHODS: This retrospective consecutive case series included 12 patients with infantile nystagmus who had face turn and strabismus. All patients underwent adjusted Kestenbaum surgery between 1996 and 2014, and primary outcome measures were the postoperative degree of face turn and strabismus. RESULTS: All patients had jerky nystagmus with compensatory face turn and strabismus. Of the 12 patients, eight patients were exotropes and four patients were esotropes. The mean age at surgery was 12.5 ± 10.7 years (range, 2–36 years). The mean postoperative follow-up was 17.8 ± 12.0 months (range, 7–43 months). Surgery was successful in eight (66.7%) out of 12 patients. Improvement of anomalous head posture was satisfactory in all patients, but an angle of deviation within 10 prism diopters was not achieved in four patients. CONCLUSIONS: Adjusted Kestenbaum surgery simultaneously improved both ocular misalignment and face turn with one-stage surgery. Two or three rectus muscles surgery can be considered in these patients because it is not only simpler than four muscles surgery but also can preserve one or two rectus muscles.
Follow-Up Studies ; Head ; Humans ; Muscles ; Oculomotor Muscles ; Outcome Assessment (Health Care) ; Posture ; Retrospective Studies ; Strabismus

Congenital ocular motor apraxia (COA), first described by Cogan in 1953, is a rare disorder which shows characteristic defects of the horizontal voluntary saccades, and compensatory head thrust. Until now, most cases have showed a presumably congenital origin, bilaterality, and a tendency to various stages of recovery with aging. But the cause and mechanism of COA are not completely known. Occasionally, it combines with other neurologic abnormalities and metabolic diseases such as Gaucher's disease exhibit similar clinical characteristics to COA. We recently experienced a case of a 3-year-old girl who showed the clinical features of unilateral congenital ocular motor apraxia.
*Apraxias ; Child, Preschool ; Female ; Humans ; Ocular Motility Disorders/*congenital ; Oculomotor Muscles

Eyelid anatomy, including thickness measurements, was examined in numerous age groups. The thickest part of the upper eyelid is just below the eyebrow (1.127+/-238 microm), and the thinnest near the ciliary margin (320+/-49 microm). The thickness of skin at 7 mm above the eyelashes was 860+/-305 microm. The results revealed no significant differences among the age groups. Fast fibers (87.8+/-3.7%) occupied a significantly larger portion of the orbicularis oculi muscle (OOM) than nonfast fibers (12.2+/-3.7%). The frontalis muscle passed through and was inserted into the bundles of the OOM on the superior border of the eyebrow at the middle and medial portions of the upper eyelid. Laterally, the frontalis muscle inserted about 0.5 cm below the superior border of the eyebrow. Fast fibers occupied a significantly larger portion of the OOM than did non-fast fibers. The oculomotor nerve ends that extend forward to the distal third of the levator muscle are exposed and vulnerable to local anesthetics and may be numbed during blepharoplasty. The orbital septum consists of 2 layers. The outer layer of loose connective tissue descends to interdigitate with the levator aponeurosis and disperses inferiorly. The inner layer follows the outer layer, then reflects and continues posteriorly with the levator sheath. Widths of the tarsal plate at its lower border, mid-height, and upper border were 21.8+/-1.8, 16.2+/-1.6, and 8.3+/-1.0 mm, respectively. The widths of the levator aponeurosis were 32.0+/-2.2, 29.2+/-3.5, and 27.2+/-3.9 mm, respectively. Below the levator, the "conjoint fascial sheath" (CFS) is attached to the conjunctival fornix. The CFS was 12.2+/-2.0 mm anteroposterior length and 1.1+/-0.1 mm thick. The shape was equilateral trapezoid with a longer base anteriorly. The superior palpebral muscle was trapezoidal. The lengths of its sides were 15.58+/-1.82 and 22.30+/-5.25 mm, and its height was 13.70+/-2.74 mm. The width of the levator aponeurosis was approximately 4 mm wider than the superior palpebral muscle.
Anesthetics, Local ; Blepharoplasty ; Blepharoptosis ; Connective Tissue ; Eyebrows ; Eyelashes ; Eyelids ; Humans ; Muscles ; Oculomotor Nerve ; Orbit ; Skin