Original Article

Comparing Two Inferior Oblique Weakening
Procedures: Disinsertion versus Myectomy

Kaveh Abri Aghdam, MD, PhD; Reza Asadi, MD; Mostafa Soltan Sanjari, MD; Ali Sadeghi, MD
Meshkat Razavi, MD

Eye Research Center, The Five Senses Institute, Rassoul Akram Hospital, Iran University of Medical Sciences, Tehran, Iran

ORCID:
Kaveh Abri Aghdam: https://orcid.org/0000-0001-7568-6455

Ali Sadeghi: https://orcid.org/0000-0001-5009-5771

Abstract

Purpose: To compare two methods for treating inferior oblique overaction (IOOA):
disinsertion versus myectomy of the muscle.
Methods: In this prospective interventional case series, patients were randomly
assigned to undergo either IO myectomy or disinsertion. The changes in vertical and
horizontal deviations following these two surgical procedures were evaluated. The
postoperative IO function of grade 0 or +1 and the fundus extorsion of grade 0 or +1
was considered as the successful outcome.
Results: Thirty-six patients (50 eyes) with a mean age of 12.67 ± 4.05 years were
included. In the myectomy group, the mean preoperative hyperdeviation in adduction
was 29.5 ± 9.32 prism diopter (PD), which decreased to 9.15 ± 7.86 PD after surgery (P
= 0.001). In the disinsertion group, these measurements were 32.73 ± 12.42 and 12.65 ±
9.34 PD before and after the surgery, respectively (P = 0.001). The success rate of surgery
based on the IOOA grading was 87.4% and 92.3% in the myectomy and disinsertion
groups, respectively (P = 0.780). The successful correction rate of abnormal fundus
torsion was 91.6% in the myectomy and 88.4% in the disinsertion group (P = 0.821). In
comparison, 48% of the cases in the myectomy group and 50% in the disinsertion group
were within the normal range of torsional position postoperatively (P = 0.786). There
was no statistically significant difference in terms of changes in the horizontal or vertical
deviations, V-pattern, and dissociated vertical deviation between the two groups.
Conclusion: Both surgical techniques seem to be effective for treatment of inferior
oblique muscle overaction.

Keywords: Disinsertion of Inferior Oblique Muscle; Inferior Oblique Muscle Overaction; Strabismus

J Ophthalmic Vis Res 2021; 16 (2): 212–218

Correspondence to:

Ali Sadeghi, MD. Department of Ophthalmology, Eye
Research Center, The Five Senses Institute, Rassoul
Akram Hospital, Sattarkhan-Niayesh St., Tehran 14456-
13131, Iran.
E-mail: alisadeghi40@yahoo.com
Received: 16-08-2019 Accepted: 23-10-2020

Access this article online

Website: https://knepublishing.com/index.php/JOVR

DOI: 10.18502/jovr.v16i2.9085

INTRODUCTION

Of the esotropic and the exotropic patients,
70% and 30% have inferior oblique overaction

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How to cite this article: Abri Aghdam K, Asadi R, Sanjari MS, Sadeghi
A, Razavi M. Comparing Two Inferior Oblique Weakening Procedures:
Disinsertion versus Myectomy. J Ophthalmic Vis Res 2021;16:212–218.

212 © 2021 ABRI AGHDAM ET AL. THIS IS AN OPEN ACCESS ARTICLE DISTRIBUTED UNDER THE CREATIVE COMMONS ATTRIBUTION LICENSE |
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IO Disinsertion versus Myectomy; Abri Aghdam et al

(IOOA) respectively. Oblique muscle dysfunction
is the primary cause of pattern strabismus. The
most common type of pattern strabismus is V
pattern esotropia with IOOA.[1] Inferior oblique (IO)
weakening procedures are self-adjusting; different
amounts of deviation can be corrected surgically
with the same method.[2]

Surgical procedures, including myectomy,
myotomy, recession, total extirpation, disinsertion,
denervation, and IO muscle fixation, can
successfully weaken the IO muscle. Seemingly,
none of them is superior to the other methods.
Surgeon’s preference and skill are the main factors
in decision-making about the type of procedure. IO
disinsertion is a safe and straightforward procedure
without a need for suturing. However, the IO
recession is preferred to disinsertion, myectomy,
and myotomy by many surgeons because of
the ability to achieve a graded response[3] and
the lower risk of unpredictable reattachment of
IO muscle to the sclera.[4] Some studies have
supported IO disinsertion because of its simplicity,
decreased risk of hemorrhage, and a similar
success rate to other methods.[5–8] In contrast,
some authors believe that IO myectomy is more
effective, despite the increased risk of bleeding
using this surgical technique. [9]

Considering the controversial opinions on the
effectiveness of these surgical procedures, we
conducted this study to evaluate the outcomes of
IO disinsertion versus myectomy.

METHODS

This prospective interventional case series was
conducted on 50 eyes of 36 patients from
August 2016 to September 2017 at Rassoul Akram
Hospital, Tehran, Iran. The Ethics Committee of
Iran University of Medical Sciences approved the
study design, and the study was conducted in
compliance with the Declaration of Helsinki; written
informed consent was obtained from all patients or
their parents before the start of the protocol.

For grading of IOOA, if the abducting eye
was the fixing eye and was fixating straight in
abduction, minimal upshoot of the adducting
eye was considered as grade +1 of IOOA. The
adducting eye’s obvious upshoot when the
abducting eye looks straight across at the lateral
canthus was rated as grade +2 of IOOA. The severe
upshoot of the adducting eye was recognized as

+3 of IOOA. A very severe upshoot of the adducting
eye was considered as +4 of IOOA.[10] Figure 1
shows the IOOA grading schematically.

All patients with IOOA ≥ +2 requiring IO muscle-
weakening operation were included in this study.
All participants underwent a comprehensive
ophthalmologic examination, and those with prior
strabismus surgery, restrictive strabismus, a history
of neurologic, genetic, or craniofacial disorders,
and simultaneous dissociated vertical deviation
(DVD) were excluded. Fundus photography
and indirect ophthalmoscopy were used for the
assessment of ocular torsion before and after the
surgery. The amount of abnormal torsion was
determined using a grading system from “trace”
to “+4,” as described by Guyton.[10] Normally, the
fovea is within the upper third of the optic disc
in the indirect ophthalmoscope view. For each
one-eighth of the disc diameter that fovea lies
upper than this border, +1 fundus extorsion is
estimated.[11]

The prism and alternate cover test were used
to measure the vertical and horizontal deviations
before the surgery compared to final values. The
deviation in the primary position at both near and
far fixation and lateral gaze at distance fixation was
recorded. V pattern existed when the difference
between the horizontal deviation at the upper 30
degrees and lower 30 degrees was ≥15 prism
diopters (PDs). IOOA in a patient with a positive
head tilt test was classified as secondary IOOA.

Each patient was randomly assigned to the
myectomy or disinsertion groups. In bilateral
cases, both eyes underwent the same surgical
procedure, and the operations were performed by
one surgeon (MSS). The successful outcome was
defined as the final IO function of grade +1 or 0 and
the fundus extorsion of grade 0 or +1.

Surgical Technique

All operations were performed under general
anesthesia. In both groups, a small fornix-based
incision was developed inferotemporally, and
Tenon’s capsule incision was made to reach the
bare sclera. The lateral rectus muscle was secured
on a muscle hook. IO muscle was dissected,
isolated from surrounding tissues, and then the
hook holding the lateral rectus was removed. In the
disinsertion group, the muscle was disinserted and
released to retract into the Tenon’s sleeve. In the

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IO Disinsertion versus Myectomy; Abri Aghdam et al

Figure 1. Schematic picture for classification of inferior oblique overaction (IOOA): (A) Grade +1: minimal upshoot of the adducting
eye. (B) Grade +2: obvious upshoot of the adducting eye when the abducting eye looks straight across at the lateral canthus. (C)
Grade +3: severe upshoot of the adducting eye is seen with the abducting eye in straight abduction. (D) Grade 4: very severe
upshoot is considered as grade +4 of IOOA.

myectomy group, two muscle clamps 5-mm apart
from each other were used to hold the muscle,
and the muscle located between two clamps was
excised and removed. Then the cut ends were
cauterized. The muscle was released, and the
proximal portion was allowed to be pulled back into
the Tenon’s sleeve. To ensure that no residual fiber
remained, Guyton’s exaggerated forced duction
test was performed in both groups.[12] Horizontal
eye muscle surgery was performed based on the
type of horizontal deviation after IO weakening.

Patients were evaluated one day, one week,
one month, and six months following the surgery
to determine the grade of IOOA, fundus torsion,
horizontal or vertical deviation, V pattern, and DVD.
An experienced orthoptist who was unaware of the
type of surgery performed the measurements in all
patients.

Statistical Analysis

Statistical data analysis was performed with the
SPSS 16.0 statistical software package (SPSS Inc.,
Chicago, IL, USA). Each eye was considered
a single case to compare the IO muscles’
function following myectomy and disinsertion. For
evaluating the horizontal and vertical deviations, V
pattern, or DVD, each patient was considered as

one case for statistical evaluation. For describing
data, mean ± standard deviation, frequency, and
percentage were used. For evaluation of the
difference between groups, the Mann–Whitney
U-test, the Wilcoxon signed-rank test, Chi-square,
and Fisher exact tests were conducted. P-values <
0.05 were considered statistically significant.

RESULTS

Overall, 36 patients (50 eyes) were enrolled in
this study. The patients’ mean age was 12.67
± 4.05 years (range, 6 to 22 years), and 52%
of them were male. The mean follow-up time
was 6.45 ± 4.3 and 7.03 ± 4.8 months in the
myectomy and disinsertion groups, respectively (P
= 0.359). Fourteen patients had bilateral IOOA (six
patients in the myectomy and eight patients in
the disinsertion groups); the same technique was
used in bilateral cases. Secondary IOOA (ipsilateral
superior oblique underaction) was found in 16
eyes, including 29.1% of the eyes in the myectomy
group and 34.6% in the disinsertion group. Table 1
represents the baseline demographic and clinical
characteristics of the patients. They were matched
in terms of age, sex, amount of vertical deviation,
and the differences between groups were not
statistically significant.

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IO Disinsertion versus Myectomy; Abri Aghdam et al

Table 1. Baseline demographic and clinical characteristics of the patients.

Variable Myectomy group Disinsertion group P-value

Patient number (18 patients, 24 eyes) (18 patients, 26 eyes)

Age (yr) 13.47 ± 4.62 11.96 ± 3.39 0.938
Sex (male/female) 10 (55.5%)/8 (44.4%) 9 (50%)/9 (50%) 0.605

Mean follow-up (month) 6.45 ± 4.3 7.03 ± 4.8 0.359
Unilateral/Bilateral 12 (66.6%)/6 (33.38%) 10 (55.5%)/8 (44.4%) 0.781

BCVA (LogMAR) 0.22 ± 0.14 0.23 ± 0.17 0.838
Spherical equivalent +2.6 ± 3.01 +3 ± 3.24 0.515
Primary/Secondary IOOA 17 (70.8%)/7 (29.2%) 17 (65.3%)/9 (34.7%) 0.573

BCVA, best-corrected visual acuity; LogMAR, logarithm of the minimum angle of resolution; IOOA, inferior oblique muscle
overaction

Table 2. Distribution of eyes with various grades of IOOA and fundus torsion in each group pre- and postoperatively

Preoperative Postoperative

Myectomy (24 eyes) Disinsertion (26 eyes) Myectomy (24 eyes) Disinsertion (26 eyes)

Grade of IOOA

+4 5 (20.8%) 6 (21.13%) 0 0

+3 10 (41.6%) 13 (50%) 0 0

+2 9 (37.5%) 7 (26.9%) 3 (12.5%) 2 (7.6%)

+1 0 0 10 (41.6%) 5 (19.2%)

0 or trace 0 0 11 (45.8%) 19 (73%)

Grade of fundus torsion

+4 7 (29.1%) 6 (23.07%) 0 0

+3 11 (45.8%) 10 (38.4%) 0 0

+2 6 (25%) 10 (38.4%) 2 3 (11.5%)

+1 0 0 11 (45.8%) 10 (38.4%)

0 or trace 0 0 11 (45.8) 13 (50%)

IOOA, inferior oblique overaction

Twenty-seven patients had concurrent
horizontal deviations in the primary position
(esotropia in 15 patients and exotropia in 12
cases) and received simultaneous surgery on the
horizontal muscles during IO weakening surgery.
Nine patients underwent IO weakening alone. No
V pattern was observed postoperatively. Table
2 demonstrates the grades of IOOA and fundus
torsion in both groups before and after the surgery.
The distribution of IOOA was similar between the
groups preoperatively (P = 0.867). At baseline,
62.5% of the eyes in the myectomy group and
73.1% in the disinsertion group had +3 or +4
IOOA. The successful outcome was defined as the
final IO function of grade +1 or 0 and the fundus

extorsion of grade 0 or +1. The success rate of
surgery based on IOOA grading was 87.4% and
92.3% in the myectomy and disinsertion groups,
respectively (P = 0.780). The successful correction
rate of abnormal fundus torsion was 91.6% in the
myectomy group and 88.4% in the disinsertion
group (P = 0.821). The median preoperative grade
of IOOA was +3 (with an interquartile range of +1) in
both groups (P = 0.084). The median postoperative
grade of IOOA was +1 (with an interquartile range
of +1) in both groups (P = 0.097). The median
preoperative grade of fundus torsion was +3 (with
an interquartile range of +2) in the myectomy
group and +3 (with an interquartile range of +1)
in the disinsertion group (P = 0.642). The median

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IO Disinsertion versus Myectomy; Abri Aghdam et al

Table 3. Amount of hypertropia in the primary position and adduction before and after the surgery in the unilateral cases

Myectomy Disinsertion

Before After P-value Before After P-value

HT in PP (PD) 12.7 ± 3.9 3.8 ± 2.6 0.001 13.42 ± 2.8 4.06 ± 2.7 0.001
HT in Add (PD) 29.5 ± 9.32 9.15 ± 7.86 0.001 32.73 ± 12.42 12.65 ± 9.34 0.001

Add, adduction; HT, hypertropia; PD, prism diopters; PP, primary position

Table 4. Comparison of myectomy and disinsertion in the subgroups of primary and secondary IOOA

Myectomy Disinsertion P-value

Primary IOOA 17 17 0.999

Secondary IOOA 7 9 0.742

Mean reduction in HT in Add (primary IOOA) (PD) 20.86 ± 11.45 21.46 ± 12.76 0.864
Mean reduction in HT in Add (secondary IOOA) (PD) 21.43 ± 11.38 22.42 ± 12.19 0.832
Success rate based on IOOA grading (primary IOOA) 88.2% 88.2% 0.999

Success rate based on grading of fundus torsion (primary IOOA) 85.7% 100% 0.853

Success rate based on the IOOA grading (secondary IOOA) 88.2% 88.2% 0.999

Success rate based on the grading of fundus torsion (secondary IOOA) 100% 85.7% 0.853

Add, adduction; HT, hypertropia; IOOA, inferior oblique overaction; PD, prism diopters; PP, primary position

postoperative grade of fundus torsion was +1 (with
an interquartile range of +1) in both groups (P =
0.960).

Table 3 shows the amount of hypertropia in
the primary position and adduction before and
after the surgery in both groups. The amount of
hypertropia in the primary position and adduction
significantly decreased in both groups (P = 0.001).
There was no statistically significant difference
between the two groups in terms of the mean
reduction in hypertropia in the primary position
(P = 0.086) and adduction (P = 0.187). Table
4 demonstrates the comparison between the
myectomy and disinsertion within two subgroups
of primary and secondary IOOA. No significant
difference was found between the two subgroups
regarding the mean reduction in hypertropia in the
primary position, adduction, success rate based on
IOOA, and fundus torsion (all P-values > 0.05).

Postoperative IO underaction was observed only
in one case in the myectomy group. In one single
case in the disinsertion group, IOOA developed
in the opposite eye. No new DVD was developed
postoperatively. Significant complications such as
scleral perforation, retrobulbar hemorrhage, or fat
adherence syndrome did not occur during the
study period.

DISCUSSION

According to our results, both myectomy and
IO disinsertion techniques can improve IOOA
and achieve gratifying results. Disinsertion of IO
muscle is a safe and effective treatment for
most cases with IOOA. Jones et al performed IO
disinsertion on 337 patients and found a successful
result in 88% of primary IO disinsertion.[5] For
secondary IOOA, a successful result was reported
in 72% of patients. Similarly, Duranglu[2] reported
a success rate of 73.6% in the disinsertion group
of patients with infantile esotropia and primary
IOOA.[13] Our findings are also in line with previous
findings of Sanjari et al, who compared three
surgical procedures for the treatment of IOOA,
including disinsertion, myectomy, and anterior
transposition.[14] They concluded that all these
procedures were useful for treating primary and
secondary IOOA with minimal side effects.

One of the most common phenomena following
unilateral IO weakening procedures is the
occurrence of IOOA in the contralateral eye. The
reported average time from the first disinsertion to
the contralateral second disinsertion was about 23
months.[5] In our study, IOOA in the opposite eye
occurred only in only one eye in the disinsertion

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IO Disinsertion versus Myectomy; Abri Aghdam et al

group. However, the length of follow-up is not
enough to conclude. De Angelis et al have
observed multiple insertions and duplications of
IO muscles during surgery in 17% and 8% of cases,
respectively.[12] They concluded that the recurrence
of IOOA following the weakening surgery might be
due to incomplete muscle capture in the surgical
procedure; however, we performed Guyton’s
exaggerated forced duction test for the IO muscles
at the end of surgery for all patients.[15]

Parks compared IO muscle recession with
disinsertion and myectomy.[16] He found a
recession to be superior due to the occurrence
of an adherence syndrome following some
cases of disinsertion and myectomy. However,
recession and myectomy are more complicated
than disinsertion, and there is no logical reason
for the development of adherent syndrome. We
observed fat adherence syndrome neither in the
myectomy nor in the disinsertion groups.

In our study, the amount of preoperative
hypertropia in the primary position and adduction
was similar in both groups; therefore, the similar
corrective effect of both surgical methods could
be due to the same effect on the function of the
inferior rectus muscle. Wertz et al[2] studied the
muscle length shortening following IO myectomy
and disinsertion surgery in Rhesus monkeys. They
observed a wide variation in the IO reattachment
site. Therefore, the same weakening procedure for
different amounts of IOOA could result in similar
outcomes, which might be related to the self-
adjusting nature of IO myectomy and disinsertion.
They also found that the average muscle length
was equal in both procedures after 6 to 20
weeks. IO muscle shortened to two-thirds of its
normal length. This similar effect on muscle length
could also be the reason for a similar effect on
muscle function and comparable postoperative
outcomes.

Awadein and Gawdat reported that symmetric
IO myectomy might have a symmetrizing effect in
cases of asymmetric IOOA.[17] They measured the
degree of IOOA and the degree of fundus torsion
by Guyton’s method and reported that the degree
of fundus torsion in their cases did not always
correlate with the degree of IOOA; this finding may
also relate to the self-adjusting nature of IO muscle,
which allows muscle retraction to find a proximal
site of insertion. The degree of IO tightness partially
determines the new insertion site. The tightness of
IO muscle on the side with more overaction would

cause more retraction and gain more proximal new
insertion.

Akbari et al showed that IO disinsertion
effectively corrected primary position vertical
deviation of unilateral congenital superior
oblique palsy patients as IO myectomy when
preoperative vertical deviation was ≤15D.[18]
However, when preoperative hypertropia was
>15D, IO myectomy had a more prominent effect
in reducing primary position vertical deviation.
However, the nonrandomized design of their study
may confound these results.

Finally, Chang et al reviewed four different
IO muscle-weakening surgeries for vertical
strabismus in superior oblique palsy:
myectomy, recession, anterior transposition,
and disinsertion.[19] They could not find high-
quality evidence to support recommendations for
surgical treatment choice in patients with vertical
strabismus due to superior oblique palsy.

Nevertheless, this study showed that both IO
myectomy and IO disinsertion are effective and
safe treatments for IOOA, and both techniques
have similar successful results. Disinsertion is a
safe procedure eliminating clinically significant V
pattern and high-grade extorsion, and it is not
associated with any clinically significant under or
overaction according to our results. Disinsertion is
also technically easier than myectomy with less
bleeding, and IO muscle is preserved for potential
future surgeries if needed.

The present study has several limitations,
including a small sample size in each group, short
follow-up time, and subjective measurement of
fundus torsion. A randomized controlled trial with a
large sample size and longer follow-up could lead
to more accurate results.

In conclusion, both disinsertion and myectomy
can effectively reduce the degree of IOOA, and
the success rate is comparable in the two surgical
methods.

Financial Support and Sponsorship

Nil.

Conflicts of Interest

The authors do not have any conflicts of interest.

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IO Disinsertion versus Myectomy; Abri Aghdam et al

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