HOME HELP FEEDBACK SUBSCRIPTIONS ARCHIVE SEARCH TABLE OF CONTENTS		QUICK SEARCH:   [advanced] Author: Keyword(s): Year:  Vol:  Page:

This Article Abstract Full Text (PDF) Submit a response Alert me when this article is cited Alert me when eLetters are posted Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in ISI Web of Science Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via ISI Web of Science (6) Citing Articles via Google Scholar Google Scholar Articles by Demer, J. L. Articles by Engle, E. C. Search for Related Content PubMed PubMed Citation Articles by Demer, J. L. Articles by Engle, E. C.

Magnetic Resonance Imaging Evidence for Widespread Orbital Dysinnervation in Dominant Duane’s Retraction Syndrome Linked to the DURS2 Locus

¹From the Departments of Ophthalmology and ²Neurology, Jules Stein Eye Institute, and the ³Bioengineering and ⁴Neuroscience Interdepartmental Programs, University of California, Los Angeles, California; the ⁵Department of Ophthalmology, College of Medicine, Ewha Womans University, Seoul, Korea; ⁶Programs in Genomics and ⁷Department of Neurology, Children’s Hospital, Boston, Massachusetts; and ⁸Department of Neurology and ⁹Program in Neuroscience, Harvard Medical School, Boston, Massachusetts.

	Abstract

Top Abstract Methods Results Discussion Conclusions References

 
PURPOSE. High-resolution, multipositional magnetic resonance imaging (MRI) was used to demonstrate extraocular muscles (EOMs) and associated motor nerves in Duane retraction syndrome (DRS) linked to the DURS2 locus on chromosome 2.

METHODS. Five male and three female affected members of two autosomal dominant DURS2 pedigrees were enrolled in the study. Coronal T₁-weighted MRI of the orbits was obtained in multiple gaze positions, as well as with heavy T₂ weighting in the plane of the cranial nerves. MRI findings were correlated with motility.

RESULTS. All subjects had unilateral or bilateral limitation of abduction, or of both abduction and adduction, with palpebral fissure narrowing and globe retraction in adduction. Orbital motor nerves were typically small, with the abducens nerve (cranial nerve [CN]6) often nondetectable. Lateral rectus (LR) muscles were structurally abnormal in seven subjects, with structural and motility evidence of oculomotor nerve (CN3) innervation from vertical rectus EOMs leading to A or V patterns of strabismus in three cases. Four cases had superior oblique, two cases superior rectus, and one case levator EOM hypoplasia. Only the medial and inferior rectus and inferior oblique EOMs were spared. Two cases had small CN3s.

CONCLUSIONS. DRS linked to the DURS2 locus is associated with bilateral abnormalities of many orbital motor nerves, and structural abnormalities of all EOMs except those innervated by the inferior division of CN3. The LR may be coinnervated by CN3 branches normally destined for any other rectus EOMs. Therefore, DURS2-linked DRS is a diffuse congenital cranial dysinnervation disorder involving but not limited to CN6.

Innervation of the LR by CN6 is deficient in both DRS and CN6 palsy, although unlike CN6 palsy, the eyes in central gaze are frequently aligned in DRS.¹⁰ This evidence for contractile tonus in the LR suggests that the involved LR is either solely, or coinnervated, by a branch of the oculomotor nerve (CN3) as supported by the autopsy studies.^{4 5} No direct anatomic evidence of LR innervation by CN3 in DRS has been available in living subjects. It is now possible to investigate such innervation in living subjects by high-resolution MRI, which affords the opportunity for detailed study of the functional anatomy of EOMs and nerves.^{11 12}

Although most cases of DRS are sporadic, approximately 10% are estimated to be familial.^{10 13} Only one genetic locus for isolated DRS has been established by linkage analysis—the DURS2 locus on 2q31. Two pedigrees have been reported in which the DRS phenotype segregated with the DURS2 locus as an autosomal dominant trait.^{13 14} The present study was performed to characterize the endophenotype, the internal phenotype of the structure and function of EOMs, as well as orbital innervation, in two additional families with autosomal dominant DRS that are demonstrated in the companion paper to map to the DURS2 locus.¹⁵

	Methods

Top Abstract Methods Results Discussion Conclusions References

 
Subjects and Clinical Examination
Two unrelated pedigrees, FY and JH, were identified that cosegregated the DRS phenotype with the DURS2 locus. The structure and mapping data for pedigrees FY and JH are presented in the companion paper.¹⁵ The living members of these pedigrees who had inherited all or a portion of the disease-associated DURS2 allele were invited to participate in an on-going clinical and MRI study of inherited congenital cranial dysinnervation disorders.¹⁵ Because of the need for prolonged visual fixation, however, only participants older than 10 years qualified for enrollment in the MRI portion of the study. Paid normal control subjects were recruited by advertising. To assess possible nonspecific effects of the strabismus surgeries that many subjects with DURS2 had undergone before entering this study, an additional control group comprised six strabismic adults without DRS who underwent MRI before and after conventional strabismus surgery. Clinical examinations were performed and MR images collected from volunteers who agreed to participate and gave written informed consent to a protocol conforming to the Declaration of Helsinki and approved by relevant institutional review boards. Control and affected subjects underwent examination of corrected visual acuity, ocular motility, eyelid structure and function, binocular alignment, anterior segment anatomy, and ophthalmoscopy. Ophthalmic histories were obtained, with corroboration of previous ocular surgeries from operative records, when possible.

Magnetic Resonance Imaging
MRI was performed with a 1.5-T scanner (Signa; General Electric, Milwaukee, WI). Orbital imaging was performed as described elsewhere in detail,^{16 17 18 19 20} using surface coils (Medical Advances, Milwaukee, WI) and fixation targets. Imaging posterior to the orbital apex in some subjects was performed with the standard head coil. When surface coils were used, images of 2 mm thickness in a matrix of 256 x 256 were obtained over a field of view of 6 to 8 cm for a resolution in plane of 234 to 312 µm. Imaging of subarachnoid cranial nerves was performed in 1-mm thickness image planes using the heavily T₂-weighted FIESTA sequence, which provides good contrast against the surrounding cerebrospinal fluid.^{11 21} In-plane resolution was 195 µm over a 10-cm field of view (matrix, 512 x 512) with 10 excitations. Magnetic resonance angiography was performed using the head coil in one subject with DURS2, and reconstructed in conventional fashion.

Digital MR images were quantified by using the programs NIH Image 1.59 and ImageJ 1.33µ (available by ftp at zippy.nimh.nih.gov/ or at http://rsb.info.nih.gov/nih-image; developed by Wayne Rasband, National Institutes of Health, Bethesda, MD). In coronal planes, the location of each rectus EOM was described by the "area centroid" using a published method.²² Cross section determinations were made in ImageJ, which, because of a difference in perimeter treatment, produces different area values than does NIH Image 1.59, which in turn produces different area values than some other versions of NIH Image. Centroid determinations do not differ between NIH Image and ImageJ. The globe center was determined as previously described.¹⁸ Rectus EOM positions were then translated to place the three dimensional (3-D) coordinate origin at globe center. Coronal plane rectus pulley locations were determined from the EOM centroids at published anteroposterior positions.¹⁸ Inferior oblique (IO) muscles were analyzed using outlined cross sections in quasisagittal images, as described elsewhere in detail.²³ Optic nerve (ON) cross sections were analyzed in the first image plane immediately posterior to the globe.²⁴

We computed rectus EOM volumes by summing the cross sections for each EOM in the image plane containing the junction of the globe and ON and the next five contiguous image planes posterior to this plane and then multiplying by the image plane thickness of 2 mm. Although this approach fails to account for EOM volume deep to the image planes collected, these data were available for every subject, and the technique was identical with that used for published data in control subjects and subjects with CFEOM1.¹¹ This technique avoids the confounding problem of defining the borders of highly dysplastic deep portions of EOMs, such as the LR, in several subjects with DRS.

	Results

Top Abstract Methods Results Discussion Conclusions References

 
Subjects
Eleven members of pedigrees FY and JH consented to participate. Of these, eight participants had DRS and harbored the DRS-associated allele (subjects 1–4 and 8–11). These eight subjects include five males and three females with an average age of 39 ± 6 (mean ± SE; range 2–76) years. The remaining three participating family members were clinically unaffected. Subject 5 was a 6-year-old boy who harbored the DRS-associated allele and was an obligate carrier of the DURS2 mutation. Subject 7 was a 50-year-old woman who harbored a portion of the DRS-associated allele, and it is unknown whether she carried the DURS2 mutation. Subject 6 was a 23-year-old woman who did not carry the DRS-associated allele but was enrolled in the clinical portion of the study because she traveled to UCLA with her family. All 11 participating family members underwent clinical examinations. General characteristics of these subjects are summarized in Table 1 .

Detailed orbital MRI was performed in subjects 1 to 4, and 9 to 11, and MRI of cranial nerves in the skull base was performed in subjects 4, 9, 10, and 11. Subject 7 consented to and attempted orbital MRI, but the study was limited due to claustrophobia, and images were inadequate to trace intraorbital innervation. Subjects 5 and 8 were too young to participate in the MRI portion of the study, which has a minimum age for participation of 10 years. Subject 6 did not undergo MRI, because she did not have DRS and did not harbor the disease-associated haplotype.

Thirteen normal volunteers underwent MRI of the cranial nerves in the skull base. Normal control subjects were of average age 22 ± 4 (mean ± SD, range 17–26) years. All control subjects had normal ocular and lid motility and visual acuity in each eye correctable to 0 logarithm of the minimum angle resolvable in arc minutes (logMAR, 20/20) or better.

Clinical Findings in DURS2
Mean corrected letter visual acuity in the group was identical in the left and right eyes of affected subjects (Table 1) , and averaged 0.04 logMAR (20/20^– Snellen). The maximum interocular acuity difference observed was 0.2 logMAR, found in subjects 2 and 4, indicating minimal to no amblyopia in affected subjects. Quantitative acuity could not be obtained in subject 8, age 1 year, who could not identify optotypes.

With the exception of subject 1, who exhibited unilateral motility abnormalities in the right eye only, affected subjects exhibited bilateral, albeit often asymmetrical, manifestations of DRS. Posterior displacement of the globe, termed retraction, was evident on attempted adduction of all affected eyes except for the right eye of subject 4. Although globe retraction was associated with narrowing of the palpebral fissure on attempted adduction, blepharoptosis in central gaze was present only in subject 4, in whom it was bilateral and had required surgical correction before the study. Five of the affected subjects had undergone two or three surgeries each for strabismus correction before the study. Affected subjects 2, 8, and 10 had not undergone prior ocular surgery.

The common clinical classification by Huber of DRS consists of three groups: type 1, with limitation of abduction only; type 2, with limitation of adduction only; and type 3, with limitation of both ab- and adduction.^{2 25} As noted in Table 1 , 1 right and 2 left eyes were classified as DRS type 1, and 10 eyes exhibited DRS type 3. Four affected participants had bilateral type 3, three had unilateral type 3 and unilateral type 1, and one was unilaterally affected with type 3. No eye exhibited the limitation of adduction only characteristic of type 2.

As indicated in Table 1 , three affected subjects exhibited esotropia in central gaze, and the other five exhibited exotropia. The strabismus was unaltered (concomitant) during vertical gaze changes in subjects 5 and 8 only, but varied with vertical gaze in the other subjects. Subjects 1, 2, 4, and 10 had incomitant horizontal strabismus evocative of the letter A or Greek letter because the eyes were in a more divergent position in down gaze than in up gaze. In subjects 1 and 10, esotropia was reduced in down gaze, whereas in subjects 2 and 4, exotropia was increased in down gaze. In several of these subjects, this A or pattern was highly suggestive of aberrant innervation of the lateral rectus (LR) muscle during infraduction, and LR inhibition during attempted supraduction (Fig. 1) . Subject 3 exhibited limited infraduction of the left eye and so could not be evaluated for vertical incomitance of his horizontal strabismus.

View larger version (72K): [in this window] [in a new window]   FIGURE 1. A-pattern in subject 4, showing esotropia in attempted upward gaze, and exotropia in central and downward gaze. Note limitation of vertical gaze, and left hypotropia. The upper eyelid configuration was created at surgery for blepharoptosis. There was prior strabismus surgery.

View larger version (142K): [in this window] [in a new window]   FIGURE 2. Quasicoronal MRI planes 2 mm thick of left orbit of subject 4 from pedigree SB, demonstrating a small, dysplastic SO, and dysplasia of the LPS, forming an abnormal slip extending toward the SO. The LR muscle was split into superior and inferior portions. The ON was small.

View larger version (112K): [in this window] [in a new window]   FIGURE 3. Quasicoronal MRI planes 2 mm thick of the right orbit of subject 4 from pedigree FY, demonstrating marked dysplasia of the LR, with continuity and apparent innervation of the LR by a branch of the inferior division of the oculomotor nerve (N3). The deep LR was also hypoplastic. The SO was of normal size. The LPS was mildly dysplastic. Note the small ON cross section in the most anterior image at lower right.

View larger version (136K): [in this window] [in a new window]   FIGURE 4. Quasisagittal, T1-weighted MRI of subject 4 showing longitudinal splitting of the left LR into superior and inferior portions, with intercalated bright signal consistent with orbital fat: 312-µm resolution in 2-mm image plane. LG, orbital lobe of the lacrimal gland.

Oblique EOM Size.
The size of the IO was not systematically determined because quasisagittal imaging was performed only in three EOMs of two subjects (subjects 2 and 4), in whom mean (± SEM) IO volume was significantly subnormal at 161 ± 2.2 microliters (P < 0.0001). Control IO volume averaged 301 ± 11 mL (n = 55).

For comparability to the published literature, SO size was assessed by maximum cross section in quasicoronal image planes. Averaging over both eyes of 10 normal subjects, mean maximum SO cross section was 18.8 ± 0.7 mm² (SEM). In DURS2, the mean maximum SO cross section was significantly smaller than normal at 14.2 ± 1.9 mm² (P < 0.025).

Rectus Muscle Paths.
Paths of the rectus EOMs were determined from area centroids in multiple contiguous image planes. The EOMs pass through their connective tissue pulleys, so that the anterior locations of these paths indicate the respective pulley locations in the coronal plane.²⁰ Because subjects with DURS2 were typically unable to achieve eccentric gaze positions, no inflections in rectus EOM paths were present to identify the anteroposterior coordinates of the rectus pulleys as is possible in normal subjects. It therefore was assumed that the anteroposterior coordinates of the rectus pulleys are the same as those known for normal subjects.²⁰ This was considered reasonable, since variations in anteroposterior coordinates would on geometric grounds be expected to have only a small effect on horizontal and vertical pulley coordinates in central gaze. After 3-D averaging of the paths of the IR, MR, and LR in subjects with DURS2, the horizontal coordinates were determined at the anteroposterior locations of normal rectus pulleys. This analysis indicated that the 3-D coordinates of all rectus pulleys in DURS2 do not differ significantly from normal.

Imaging of Intraorbital Motor Nerves.
Since the posterior orbit is less susceptible to motion artifacts from eye movement than is the anterior orbit, it was possible to examine in the deep orbit the motor nerves to the EOMs in image planes of 1.5- to 2-mm thickness, and field of view 6 to 8 cm. The superior division of CN3 was difficult to follow and was not analyzed systematically. The inferior division of CN3 and its individual branches are normally prominent in the orbit.^{11 12} Most posteriorly, it may be seen on MRI to divide into an inferior trunk, one branch of which bifurcates repeatedly as it travels anteriorly on the global surface of the IR that enters the EOM. The inferior trunk has a lateral branch that courses anteriorly along the lateral border of the IR and enters the IO at the point where it crosses the IR. The medial trunk of the inferior division on CN3 normally crosses inferior to the ON to make a prominent entry into the global surface of the MR. The normal CN6 is smaller than the branches of CN3, but typically may be seen on MRI to bifurcate repeatedly to form a manifold on the global surface of the LR as it courses anteriorly to innervate the LR. Since normal intraorbital motor nerves to individual EOMs are represented by one or at most a few pixels in the coronal image planes used in this study, the images were regarded as insufficiently precise for quantitative analysis of motor nerve size. However, qualitative impressions were consistently obtained and are illustrated herein Assessments were confirmed by evaluation of multiple contiguous MRI planes to trace the paths of presumed nerves to their target EOMs.

The CN6 was absent or below detection in the right orbits of subjects 1, 4, and 11, and appeared smaller than normal in subjects 9 and 10. All the foregoing exhibited DRS type 3 on the right. The CN6 was absent or below detection in the left orbit of subjects 10 and 11, both of whom had DRS type 1 in the affected orbit. In subject 1, who exhibited no clinical evidence of DRS on the left, the left CN6 was identified to be present in the orbit despite LR hypoplasia. All remaining subjects imaged had type 3 DRS on the left, and had identifiable CN6 in the orbit. When present, CN6 innervated the superior belly of the split LR. In the right orbit of subjects 3, 4, 6, 7, and 8 and in the left orbit of subjects 1, 4, 9, and 10, a branch of CN3 was in close contact with the inferior belly of the LR. As illustrated in Figure 3 , the intimate contact of the inferior division of CN3 with the LR suggested that the CN3 branch entered the EOM, although the limited resolution of MRI precludes confirmation of actual innervation at the level of the EOM fibers. The MR and IR were innervated normally by branches of CN3 in all orbits imaged.

Imaging of Intracranial Motor Nerves.
Heavily T₂-weighted imaging of the skull base region was conducted in 1-mm-thick slices at 390-µm resolution in the plane of the optic chiasm and major cranial nerves to the orbit. This technique has just sufficient resolution to demonstrate the normal CN6s coursing anteriorly from the pons (Fig. 5) , whereas it easily and consistently demonstrates the larger course of the CN3s of normal subjects (Fig. 6) .¹¹

View larger version (54K): [in this window] [in a new window]   FIGURE 5. Oblique, axial, heavily T2-weighted MR images showing at left the normal course of the abducens nerve (CN6 dark) from the pons highlighted against the bright signal of the surrounding cerebrospinal fluid. In contrast, the CN6s of subject 4 with DURS2 appeared absent and the left CN6 of subject 9 was shown to be absent by the identical technique. In each panel, CN6 was demonstrated in the optimal 1-mm-thick image plane in which it appeared or was expected to appear based on surrounding landmarks.

View larger version (91K): [in this window] [in a new window]   FIGURE 6. Heavily T2-weighted axial MR images of 1-mm thickness at the level of the midbrain obtained in the plane of the optic chiasm. In all normal subjects, the oculomotor nerve (CN3) was prominent in multiple contiguous image planes. In subject 6 with DURS2, the right CN3 was hypoplastic.

The heavily T₂-weighted imaging technique readily demonstrated the CN3 in multiple contiguous image planes in all 13 normal subjects (Fig. 6 , left). Imaging capable of demonstrating CN3 at the brain stem was performed in subjects 4, 9, 10, and 11. The right CN3 was unilaterally hypoplastic in affected subjects 9 and 10, and appeared qualitatively normal in subjects 4 and 11. Averaging bilaterally, mean ± SEM. CN3 width was 1.55 ± 0.18 mm in affected subjects, significantly smaller than the width of 2.10 ± 0.07 mm in normal subjects (P < 0.005).

Optic Nerve.
Despite the normal ophthalmoscopic appearance of the ON in all affected subjects, the coronal plane MRI was notable for the appearance of subnormal ON size in several subjects (Fig. 2) . Because the ON cross section normally decreases from anterior to posterior in the orbit due to the reduction of connective tissues surrounding the axon bundles,²⁴ ON cross sections were analyzed at the 2-mm-thick image plane thickness closest to the globe-ON junction. Mean (± SEM) cross section of the ON in 14 orbits with DURS2 was 6.85 ± 0.36 mm², significantly smaller than the mean cross section of 18 normal control orbits of 9.19 ± 0.46 mm² (P < 0.001).

Functional Evidence for Misinnervation.
Abnormal patterns of EOM contraction provided evidence of misinnervation in several illustrative cases. Subject 1 had the clinical phenotype of DRS type 3 on the right, with limited abduction, adduction, and supraduction, downshoot on adduction, and A-pattern esotropia (Table 1) . Coronal plane imaging was performed during target fixation by the left eye to control innervational effort, and was repeated in attempted abduction, central gaze, and attempted adduction (Fig. 7) . Although there was some abduction of the right eye, the right LR exhibited modest contractile thickening mainly in its more anterior portion, with little contractile change in the deep orbit (Fig. 7) . Although right MR exhibited robust contractile thickening in adduction (Fig. 7) , adduction was slightly limited. However, in adduction, the right eye exhibited a downshoot that was associated with an increase in IR cross section suggestive of active contraction (Fig. 7) . This inference of anomalous IR contraction on adduction is supported by the absence of an increase in SO cross section, the other EOM that would normally mediate infraduction. Anterior views near the level of the rectus pulleys showed no evidence of horizontal rectus EOM sideslip, indicating that the downshoot was not due to a "bridle effect" during horizontal rectus co-contraction.

View larger version (101K): [in this window] [in a new window]   FIGURE 7. Coronal MRI of the right orbit of subject 1 with the clinical phenotype of unilateral DRS type 3 on the right. Image planes 2-mm thick spaced by 2 mm, resolution 312 µm in planes arranged from posterior at top to anterior at bottom. Fixation was by the clinically normal left eye. Note the minimal increase in the deep LR cross section on abduction, with a moderate increase in the anterior LR cross section on abduction. Although the deep MR exhibited a marked contractile increase in cross section, the eye adducted little, and the elevated position of the globe–ON junction indicated a downshoot. Note the increase in IR cross section in adduction suggestive of IR contraction, without corresponding increase in SO cross section. Note the normal positions of the MR and LR muscles near the globe–ON junction (bottom row), indicating normal stability of the horizontal rectus pulleys and ruling out sideslip as the cause of the downshoot in adduction.

View larger version (71K): [in this window] [in a new window]   FIGURE 8. Coronal MRI of left orbit in planes 2-mm thick spaced by 2 mm, resolution 234 µm in plane. Top row: subject 1 with clinical phenotype of DRS unilateral type 3 on the right only. Note hypoplasia of the deep portion of the LR, without a recognizable abducens nerve (CN6). The LR is also fissured. Also evident is the motor nerve to the MR. Bottom row: normal control subject, showing a normal LR cross section.

	Discussion

Top Abstract Methods Results Discussion Conclusions References

In subject 1, MRI revealed an absent CN6 on the right, and abnormalities of the LR in both orbits, despite the absence of clinical manifestations of DRS in the left eye. This suggests that mutations in the DURS2 gene can result in orbital abnormalities consistent with DRS that are clinically silent (an endophenotype). Such an endophenotype may also occur in subject 5, who carried the DRS-associated allele but was clinically unaffected. Unfortunately, he was too young for participation in the MRI portion of this study.

Although most subjects with DURS2 had undergone strabismus surgery, six of the eight nevertheless exhibited A- or V-pattern strabismus. This prior surgery created no apparent change in rectus EOM volumes, as determined by the current technique, since volumes in DURS2 did not differ significantly from those in normal control subjects or in strabismic subjects without DRS, either before or after strabismus surgery. Three of the eight subjects with DURS2 exhibited limitation of vertical gaze in one or both eyes, similar to two of the 25 cases of hereditary DRS from the original DURS2 pedigree¹³ reported by Chung et al.²⁷ Unlike these original 25 cases, however, none of the eight patients in the current report exhibited dense amblyopia, and only subject 4 exhibited blepharoptosis. Of note, these additional symptoms were found in subsets of the 25 patients reported by Chung et al., and clustered within smaller family units, suggesting that they may represent the influence of modifying genes. Whereas one of the current 8 subjects had Klippel-Feil anomaly, seizures and deafness were each found in 1 of the 25 patients in Chung et al.; these may represent rare manifestations of the DURS2 gene or may be incidental findings.

The present MRI findings confirm limited autopsy^{4 5} and electromyographic^{2 3 28} reports of CN6 aplasia with peripheral misinnervation of the LR by CN3 and extend these findings to demonstrate a novel variety of patterns of mis- and coinnervation of the inferior portion of the LR belly by CN3 branches normally destined for the IR, MR, and SR muscles. Although the resolution of the current MRI technique was insufficient to demonstrate actual neuromuscular junctions and trace peripheral axons, it was possible to demonstrate contractile changes in the affected LR associated with innervational effort determined by target fixation by the fellow eye.

Paradoxical contraction of part or all the affected LR belly in upward or downward target fixation by the fellow eye strongly suggests innervation of the LR by CN3 branches normally destined for the SR and IR, respectively, causing a horizontal strabismus that varied with vertical gaze position. Similar to CFEOM1,¹¹ the most common pattern was A or pattern strabismus, with relative exodeviation in downward gaze. Consistent with a prior electrophysiologic report,²⁹ MRI indicated that pattern strabismus in DRS is due to LR contraction in downward gaze, presumably because the LR is innervated by a branch of CN3 that normal innervates the IR.

The present study also confirms prior reports of absence of the subarachnoid CN6 in some cases of DRS. Kim and Hwang^{9 30} have emphasized the frequent absence of CN6 ipsilateral to DRS type 1 and type 3,⁹ but the presence of CN3 ipsilateral to type 2.⁹ Three of four affected subjects imaged in the current study had bilateral absence of CN6, whereas CN6 was absent unilaterally in the fourth subject.

New Structural Findings in DURS2
The present study provides imaging evidence for LR innervation by a branch of CN3, including contractile thickening of the LR on attempted vertical gaze. Although MRI resolution is inadequate to confirm the presence of motor endplates in the LR, the inferior division of CN3 was consistently seen to run adjacent to the deep portion of the LR where CN6 normally enters and arborizes. We also found structural abnormality in the deep LR belly in DURS2. In DURS2, the deep LR was commonly split longitudinally into superior and inferior zones, or was even more structurally disorganized, similar to the structural abnormality in CFEOM1 resulting from mutations in KIF21A.¹¹ We propose that normal CN6 innervation is necessary for normal structure of the deep LR belly. Misrouting of CN3 in DURS2 is more likely the result of anatomic proximity than of inherent promiscuity of the nerve, and so it is the inferior zone of the LR that commonly receives aberrant innervation from CN3. It may be that CN3 is commonly misrouted to LR because CN3’s normal path takes it adjacent to the LR’s nerve entry site. No similar proximity of CN4 or CN6 occurs for other EOMs. However, other factors such as developmental timing may additionally or alternatively account for misinnervation of the LR.

In the present subjects with DURS2, the LR muscles demonstrated regional abnormalities, including hypoplasia and absent contractility in the deep portion of the EOM belly. Where present, CN6 entered the superior zone of the LR, whereas aberrant innervation from CN3 entered the inferior zone. This finding implies that the LR in DURS2 is a two-headed EOM, with each head separately innervated but joined to a common scleral insertion. This functional anatomic observation can explain the electromyographic observations of in DRS Scott and Wong,²⁹ who found evidence of two populations of LR motor units: the presumably normally innervated population activated during abduction, and an abnormally innervated population originally destined for the MR. These two populations presumably represent the two zones of the LR. More severe involvement of the deeper portions of EOMs is also seen in CFEOM1¹¹ and congenital oculomotor palsy,³¹ suggesting that innervation may be a general organizing and trophic factor in the deep bellies of EOMs.

Although in the present study we examined IO volume in only three EOMs affected by DURS2, reduced IO volume in these cases suggests involvement. The maximum SO cross section in DURS2 was also significantly reduced. Although oblique EOM hypoplasia is a novel finding in DURS2, SO palsy has been reported to be associated in a family subgroup with DURS2.²⁷ Hypoplasia of the SO muscle is a hallmark of acquired and congenital SO palsy.^{16 32} Oblique EOM palsy may represent neurogenic atrophy or hypoplasia.

Abnormalities were frequently found in the inferior division of CN3 as well as CN6 at its exit from the brain stem and in the orbit. Although hypoplasia and aplasia of CN6 were expected in at least some cases of DRS, hypoplasia of CN3 is novel. Hypoplasia of CN3 is characteristic of CFEOM1, which shares with DURS2 the findings of restricted vertical gaze and misrouting of CN3 branches to the LR to produce A- and V-pattern strabismus.¹¹ CFEOM1 is produced by missense mutations in the developmental kinesin KIF21A, whereas the cause of DURS2 is unknown. Endophenotypic similarity suggests that DURS2 and CFEOM1 share common pathogenetic mechanisms.

ON Involvement in DURS2
Quantitative MRI has emerged as a powerful technique for ON analysis.²⁴ subjects with CFEOM1 due to KIF21A mutations exhibit a subclinical 30% to 40% reduction in ON cross-sectional area.¹¹ ON cross-sectional area in the current subjects with DURS2 was reduced approximately 25% from normal. Our additional observation of ON hypoplasia suggests that the DURS2 gene also plays a role in the development or maintenance of the ON. Although the ON hypoplasia was statistically significant, it was not evident at ophthalmoscopy. None of the subjects with DURS2 had profound visual acuity loss, gross visual field deficits, or afferent pupillary defects. The current subjects with DRS exhibited little or no difference in best corrected visual acuity between eyes, indicating no or minimal amblyopia, and consistent with the reportedly low prevalence of amblyopia in DRS comparable to that in the normal population.³³

Absence of Widespread Pulley Abnormalities
Pulley disorders are now recognized as causes of strabismus.^{16 34} Abnormalities of rectus EOM paths due to misplaced pulleys are associated with craniosynostosis syndromes and are caused by mutations in FGFR³⁵ in which orbital nerves and EOM volumes are apparently normal. This contrasts with normal pulley positions in DURS2 and in CFEOM1.¹¹ Pulley positions can be normal despite abnormal innervation, supporting the idea that pulley abnormalities may be primary in cases of incomitant strabismus with which they are associated.^{19 36 37}

Cocontraction of antagonist EOMs producing LR sideslip has been documented as a cause of up- and downshoots in DRS,³⁸ but was not observed here in DURS2. Several lines of evidence support misinnervation of rectus EOMs as the mechanism of anomalous ocular versions here. The LR in subject 1 exhibited evidence of segmental contraction in its anterior portion during attempted abduction, without appreciable contractile change in the deep orbit where normal contractility is maximal. In adduction, the right IR of subject 1 increased in cross section in a manner suggestive of contraction, but the normal coinfraductor, the SO, did not change cross section. Imaging in multiple gaze positions did not indicate rectus EOM sideslip.

	Conclusions

Top Abstract Methods Results Discussion Conclusions References

 
Taken together, these findings indicate that DURS2 is a diffuse congenital cranial dysinnervation disorder affecting mainly CN6, but also producing misrouting of CN3 and ON hypoplasia. We speculate that structural abnormalities mainly of the LR belly in DURS2 are secondary to abnormal patterns of innervation.

	Footnotes

 
Supported by U.S. Public Health Service, National Eye Institute: Grants EY13583, EY08313, and EY00331. JLD is the recipient of an unrestricted award from Research to Prevent Blindness and is the Leonard Apt Professor of Ophthalmology.

Submitted for publication June 9, 2006; revised August 23, 2006; accepted November 15, 2006.

Disclosure: J.L. Demer, None; R.A. Clark, None; K.-H. Lim, None; E.C. Engle, None

The publication costs of this article were defrayed in part by page charge payment. This article must therefore be marked "advertisement" in accordance with 18 U.S.C. 1734 solely to indicate this fact.

Corresponding author: Joseph L. Demer, Jules Stein Eye Institute, 100 Stein Plaza, UCLA, Los Angeles, CA 90095-7002; jld{at}ucla.edu.

	References

Top Abstract Methods Results Discussion Conclusions References

 

1. Duane A. Congenital deficiency of abduction associated with impairment of adduction, retraction movements, contraction of the palpebral fissure and oblique movements of the eye. Arch Ophthalmol. 1905;34:133–159.
2. Huber A. Electrophysiology of the retraction syndromes. Br J Ophthalmol. 1974;58:293–300.[Free Full Text]
3. Strachan IM, Brown BH. Electromyography of extraocular muscles in Duane’s syndrome. Br J Ophthalmol. 1972;56:594–599.[Free Full Text]
4. Miller NR, Kiel SM, Green WR, Clark AW. Unilateral Duane’s retraction syndrome (type 1). Arch Ophthalmol. 1982;100:1468–1472.[Abstract]
5. Hotchkiss MG, Miller NR, Clark AW, Green WM. Bilateral Duane’s retraction syndrome: a clinical-pathologic case report. Arch Ophthalmol. 1980;98:870–874.[Abstract]
6. Parsa CF, Grant E, Dillon WP, du Lac S, Hoyt WF. Absence of the abducens nerve in Duane syndrome verified by magnetic resonance imaging. Am J Ophthalmol. 1998;125:399–401.[CrossRef][ISI][Medline][Order article via Infotrieve]
7. Ozkurt H, Basak M, Oral Y, Ozkurt Y. Magnetic resonance imaging in Duane’s retraction syndrome. J Pediatr Ophthalmol Strabismus. 2003;40:19–22.[ISI][Medline][Order article via Infotrieve]
8. Kim JH, Hwang J-M. Hypoplastic oculomotor nerve and absent abducens nerve in congenital fibrosis syndrome and synergistic divergence with magnetic resonance imaging. Ophthalmology. 2005;112:728–732.[CrossRef][ISI][Medline][Order article via Infotrieve]
9. Kim JH, Hwang JM. Presence of abducens nerve according to the type of Duane’s retraction syndrome. Ophthalmology. 2005;112:109–113.[CrossRef][ISI][Medline][Order article via Infotrieve]
10. DeRespinis PA, Caputo AR, Wagner RS, Guo S. Duane’s retraction syndrome. Surv Ophthalmol. 1993;38:257–288.[CrossRef][ISI][Medline][Order article via Infotrieve]
11. Demer JL, Clark RA, Engle EC. Magnetic resonance imaging evidence for widespread orbital dysinnervation in congenital fibrosis of extraocular muscles due to mutations in KIF21A. Invest Ophthalmol Vis Sci. 2005;46:530–539.[Abstract/Free Full Text]
12. Demer JL, Ortube MC, Engle EC, Thacker N. High resolution magnetic resonance imaging demonstrates abnormalities of motor nerves and extraocular muscles in neuropathic strabismus. J AAPOS. 2006;10:135–142.
13. Evans JC, Frayling TM, Ellard S, Gutowski NJ. Confirmation of linkage of Duane’s syndrome and refinement of the disease locus to an 8.8-cM interval on chromosome 2q31. Hum Genet. 2000;106:636–638.[CrossRef][ISI][Medline][Order article via Infotrieve]
14. Appukuttan B, Gillanders E, Juo SH, et al. Localization of a gene for Duane retraction syndrome to chromosome 2q31. Am J Hum Genet. 1999;65:1639–1646.[CrossRef][ISI][Medline][Order article via Infotrieve]
15. Engle EC, Andrews C, Law K, Demer JL. Two pedigrees segregating Duane’s retraction syndrome as a dominant trait linked to the DURS2 genetic locus. Invest Ophthalmol. Vis. Sci. 2007;48:189–193.[Abstract/Free Full Text]
16. Demer JL. A 12 year, prospective study of extraocular muscle imaging in complex strabismus. J AAPOS. 2003;6:337–347.
17. Demer JL, Miller JM. Orbital imaging in strabismus surgery. Rosenbaum AL Santiago AP eds. Clinical Strabismus Management: Principles and Techniques. 1999;84–98. WB Saunders Philadelphia.
18. Clark RA, Miller JM, Demer JL. Three-dimensional location of human rectus pulleys by path inflections in secondary gaze positions. Invest Ophthalmol Vis Sci. 2000;41:3787–3797.[Abstract/Free Full Text]
19. Clark RA, Miller JM, Demer JL. Displacement of the medial rectus pulley in superior oblique palsy. Invest Ophthalmol Vis Sci. 1998;39:207–212.[Abstract/Free Full Text]
20. Clark RA, Miller JM, Demer JL. Location and stability of rectus muscle pulleys inferred from muscle paths. Invest Ophthalmol Vis Sci. 1997;38:227–240.[Abstract/Free Full Text]
21. Seitz J, Held P, Strotzer M, et al. MR imaging of cranial nerve lesions using six different high-resolution T1 and T2(*)-weighted 3D and 2D sequences. Acta Radiologica. 2002;43:349–353.[CrossRef][ISI][Medline][Order article via Infotrieve]
22. Kono R, Clark RA, Demer JL. Active pulleys: magnetic resonance imaging of rectus muscle paths in tertiary gazes. Invest Ophthalmol Vis Sci. 2002;43:2179–2188.[Abstract/Free Full Text]
23. Demer JL, Oh SY, Clark RA, Poukens V. Evidence for a pulley of the inferior oblique muscle. Invest Ophthalmol Vis Sci. 2003;44:3856–3865.[Abstract/Free Full Text]
24. Karim S, Clark RA, Poukens V, Demer JL. Quantitative magnetic resonance imaging and histology demonstrates systematic variation in human intraorbital optic nerve size. Invest Ophthalmol Vis Sci. 2004;45:1047–1051.[Abstract/Free Full Text]
25. von Noorden GK. Binocular Vision and Ocular Motility: Theory and Management of Strabismus. 1996; Mosby St. Louis.
26. Al-Baradie R, Yamada K, St Hilaire C, et al. Duane radial ray syndrome (Okihiro syndrome) maps to 20q13 and results from mutations in SALL4, a new member of the SAL family. Am J Hum Genet. 2002;71:1195–1199.[CrossRef][ISI][Medline][Order article via Infotrieve]
27. Chung M, Stout T, Borchert MS. Clinical diversity of hereditary Duane’s retraction syndrome. Ophthalmology. 2000;107:500–503.[CrossRef][ISI][Medline][Order article via Infotrieve]
28. Sato S. Electromyographic study on retraction syndrome. Jpn J Ophthalmol. 1960;4:57–66.[Medline][Order article via Infotrieve]
29. Scott AB, Wong GY. Duane syndrome. Arch Ophthalmol. 1972;87:140–147.[ISI][Medline][Order article via Infotrieve]
30. Kim JH, Hwang J-M. Usefulness of MR imaging in children without characteristic clinical findings of Duane’s retraction syndrome. Am J Neuroradiol. 2005;26:702–705.[Abstract/Free Full Text]
31. Wu J, Isenberg SJ, Demer JL. Magnetic resonance imaging demonstrates neuropathology in congenital inferior division oculomotor palsy. J AAPOS. 2006;10:473–475.
32. Demer JL, Miller JM. Magnetic resonance imaging of the functional anatomy of the superior oblique muscle. Invest Ophthalmol Vis Sci. 1995;36:906–913.[Abstract/Free Full Text]
33. Tredici TD, von Noorden GK. Are anisometropia and amblyopia common in Duane’s syndrome?. J Pediatr Ophthalmol Strabismus. 1985;22:23–25.[Medline][Order article via Infotrieve]
34. Oh SY, Clark RA, Velez F, Rosenbaum AL, Demer JL. Incomitant strabismus associated with instability of rectus pulleys. Invest Ophthalmol Vis Sci. 2002;43:2169–2178.[Abstract/Free Full Text]
35. Muller U, Steinberger D, Kunze S. Molecular genetics of craniosynostotic syndromes. Graefes Arch Clin Exp Ophthalmol. 1997;235:545–550.[CrossRef][ISI][Medline][Order article via Infotrieve]
36. Clark RA, Miller JM, Rosenbaum AL, Demer JL. Heterotopic muscle pulleys or oblique muscle dysfunction?. J AAPOS. 1998;2:17–25.
37. Demer JL, Clark RA, Miller JM. Heterotopy of extraocular muscle pulleys causes incomitant strabismus. Lennerstrand G eds. Advances in Strabismology. 1999;91–94. Aeolus Press Burent, The Netherlands.
38. Miller JM, Demer JL, Rosenbaum AL. Two mechanisms of up-shoots and down-shoots in Duane’s syndrome revealed by a new magnetic resonance imaging (MRI) technique. Campos EC eds. Strabismus and Ocular Motility Disorders. 1990;229–234. Macmillian Press London.

This article has been cited by other articles:

				J. L. Demer, R. A. Clark, K. H. Lim, and E. C. Engle Magnetic Resonance Imaging of Innervational and Extraocular Muscle Abnormalities in Duane-Radial Ray Syndrome Invest. Ophthalmol. Vis. Sci., December 1, 2007; 48(12): 5505 - 5511. [Abstract] [Full Text] [PDF]

				T. M. Bosley, M. A. Salih, I. A. Alorainy, D. T. Oystreck, M. Nester, K. K. Abu-Amero, M. A. Tischfield, and E. C. Engle Clinical characterization of the HOXA1 syndrome BSAS variant Neurology, September 18, 2007; 69(12): 1245 - 1253. [Abstract] [Full Text] [PDF]

				K. H. Lim, E. C. Engle, and J. L. Demer Abnormalities of the Oculomotor Nerve in Congenital Fibrosis of the Extraocular Muscles and Congenital Oculomotor Palsy Invest. Ophthalmol. Vis. Sci., April 1, 2007; 48(4): 1601 - 1606. [Abstract] [Full Text] [PDF]

				E. C. Engle, C. Andrews, K. Law, and J. L. Demer Two Pedigrees Segregating Duane's Retraction Syndrome as a Dominant Trait Map to the DURS2 Genetic Locus Invest. Ophthalmol. Vis. Sci., January 1, 2007; 48(1): 189 - 193. [Abstract] [Full Text] [PDF]

This Article Abstract Full Text (PDF) Submit a response Alert me when this article is cited Alert me when eLetters are posted Alert me if a correction is posted Citation Map Services Email this article to a friend Similar articles in this journal Similar articles in ISI Web of Science Similar articles in PubMed Alert me to new issues of the journal Download to citation manager Citing Articles Citing Articles via HighWire Citing Articles via ISI Web of Science (6) Citing Articles via Google Scholar Google Scholar Articles by Demer, J. L. Articles by Engle, E. C. Search for Related Content PubMed PubMed Citation Articles by Demer, J. L. Articles by Engle, E. C.