Optic Coher for Accommo with Hypero
DOI: 1
I.L. Kulikova, MD, DSc, Deputy Director for Clinical Work1; Professor of the Ophthalmology Course2;
K.A. Aleksandrova, Ophthalmologist, Diagnostic and Treatment Department1 Cheboksary Branch of S. Fyodorov Eye Microsurgery Federal State Institution
f the Ministry of Health of Russia, 10 Traktorostroiteley St., Cheboksary, 428000, Chuvash Republic, Russia; 2Institute for Advanced Training of Doctors of the Ministry of Health of the Chuvash Republic, 27 Mikhail Sespel St., Cheboksary, 428018, Chuvash Republic, Russia
The aim is to evaluate the ocular accommodation system in hyperopic anisometropia and amblyopia in children after femtosecond laser-assisted in situ keratomileusis (FS-LASIK) and in children with spectacle correction using optical coherence tomography (OCT).
Materials and Methods. The present study included children with hyperopia and anisometropia of more than 3 D, high and medium degree of amblyopia. Patients were divided into two groups: group 1 consisted of 30 children after FS-LASIK, group 2 was comprised of 30 children with spectacle correction. The temporal part of the ciliary muscle was assessed using the CASIA2 optical coherence tomography system (Tomey, Japan). The study was carried out with a narrow pupil fixing the gaze on the target at a distance of 33 cm and under cycloplegic conditions. The ciliary muscle thickness (CMT) was analyzed at four different levels: the maximum thickness of the ciliary muscle (CMTmax), and at a distance of 1, 2, and 3 mm from the scleral spur (CMT1, CMT2, and CMT3, respectively). The fluctuation amplitude in the thickness of the ciliary muscle (ACMT), i.e. the ratio of indicators with a narrow and wide pupil, was also evaluated.
Results. The ciliary muscle thickness of the amblyopic eye in group 1 was 808±38 ^m for CMTmax, 724±54 ^m for CMT1, 446±44 ^m for CMT2, and 223±37 ^m for CMT3, these indicators in group 2 were 812±33, 735±33, 432±35, and 229±29 ^m, respectively.
Children of group 1 have been found to have an increase in ACMT of the amblyopic eye. The value of ACMTmax increased from 21±6 to 30±4 |im, ACMT1 from 19±6 to 29±5 |im, ACMT2 from 12±4 to 16±4 |im, ACMT3 from 11±4 to 16±4 ^m, which is associated with an increase in visual acuity and a decrease in the refractive component. All changes within the group were statistically significant (p<0.01).
Conclusion. OCT is a fairly informative method for studying the accommodative structures of the eye in children, providing the opportunity to objectively assess the amplitude of fluctuations in the thickness of the ciliary muscle during the treatment. It has been established that after refraction operation, the work of the ciliary muscle of the amblyopic eye was significantly improved, which is reflected in the increased values of ACMT, CMT2, and CMT3 and brings these parameters closer to those of the better paired leading eye.
Key words: optical coherence tomography; ciliary muscle; anisometropia; amblyopia; accommodation.
How to cite: Kulikova I.L., Aleksandrova K.A. Optic coherence tomography for accommodation control in children with hyperopic anisometropia and amblyopia. Sovremennye tehnologii v medicine 2023; 15(5): 24, https://doi.org/10.17691/stm2023.15.5.03
This is an open access article under the CC BY 4.0 license (https://creativecommons.org/licenses/by/4.0/).
Introduction
Exploration of the accommodative apparatus biomechanics is necessary for the development of new approaches to the restoration of the accommodative ability of the eye [1]. One of the challenging problems is ciliary muscle imaging and understanding its interaction with the lens during accommodation in vivo [2].
The first information about physiological functioning of the ciliary muscle in static conditions was obtained from the results of the postmortem histological examinations of the rhesus monkeys having the accommodative structure of the eyes similar to that of humans [3]. It
has been previously reported on the differences in the morphology of the ciliary muscle of the young and adult eyes [4-6] although the effect of these differences on the muscle functioning has not been shown. Images of the lens and/or ciliary muscle in static accommodation conditions were acquired using magnetic resonance imaging (MRI), ultrasound, Scheimpflug camera, ultrasound biomicroscopy (UBM), and time-domain optical coherence tomography (OCT) at the wavelengths of about 1300 nm [5, 6]. MRI produces distortion-free images, but a low velocity of image production limits its application for the study of dynamic accommodation. UBM application is also restricted due to the contact
Corresponding author: Kseniya A. Aleksandrova, e-mail: [email protected]
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of the probe with the ocular surface and usage of anesthetics during investigations. These manipulations may cause psychological discomfort and sometimes allergic reactions [7]. Besides, MRI and UBM are performed in prone position, which reduces the validity of the results obtained. To diagnose accommodation in children, it is preferable to use fast non-invasive procedures with maintaining the original position, therefore, the OCT technique seems to be the most optimal modality.
The ciliary muscle is known to participate in accommodation and possibly influence emmetropization, however, there are relatively scanty investigations of the ciliary muscle in vivo.
The aim is to study the state of the ocular accommodative apparatus in children with hyperopic anisometropia and amblyopia in dynamics.
Ta bl e 1
Description of the patients (n/%)
Children Children
Parameters after FS-LASIK wearing spectacles
(group 1) (group 2)
Gender:
female 13/43.3 14/46.7
male 17/56.7 16/53.3
Amblyopic eye:
right 9/30.0 10/33.3
left 21/70.0 20/66.7
Moderate hyperopia 5/16.7 16/53.3
High hyperopia 25/83.3 14/46.7
Moderate amblyopia 9/30.0 13/43.3
High amblyopia 21/70.0 17/56.7
Materials and Methods
The study included 60 patients at the age of 6 to 15 years with anisometropia over 3 D, high and moderate degree of amblyopia, and with a spherical equivalent refraction (SE) from +3.5 to +7.25 D on the amblyopic eye. The study was carried out in compliance with the Declaration of Helsinki developed by the World Medical Association (2013) and Federal Law of the Russian Federation No.323-FZ of November 21, 2011 "On the fundamentals of public health protection in the Russian Federation". The study was approved by the Ethical Committee of the Cheboksary Branch of S. Fyodorov Eye Microsurgery Federal State Institution of the Ministry of Health of Russia (Cheboksary, Russia). Written informed consent was obtained from the children's parents to the ophthalmologic examination, treatment, and usage of the data for scientific purposes.
Patients were divided into two groups (n=30 in each). Group 1 included children who were medically indicated to undergo femtosecond laser intrastromal in situ keratomileusis (FS-LASIK) [8, 9] on the amblyopic eye. Group 2 consisted of the children with a comparable initial status wearing spectacles. During 2 years, all patients received device-assisted treatment for amblyopia (laser-, magneto-, photo-, and electrostimulation) 2 times a year. A general description of patients is presented in Table 1. In our study, amblyopia occurred on the left eye more often, high degree hyperopia (83.3% in group 1 and 46.7% in group 2) and high degree amblyopia (70.0% in group 1 and 56.7% in group 2) prevailed.
A standard ophthalmological diagnostic procedure has been carried out: refractometry before and after cycloplegia, uncorrected vision acuity (UCVA) and best-corrected visual acuity (BCVA) tests in decimal units or using LogMAR units according to Holladay's formula [10] for 5 m and 50 cm.
The parameters of the eye accommodative structures were additionally evaluated on the optical coherence tomographic system CASIA2 (Tomey, Japan) under natural accommodation with a narrow pupil — with a preliminarily placed contact lens having an optical power equal to the best vision acuity and with medicamentally inhibited accommodation after the removal of the contact lens. The temporal part of the ciliary muscle was examined since it is more readily accessible for imaging and analysis. When capturing the images of the temporal part of the ciliary muscle, a black snowflake was used as a target on a white background having the size corresponding to the vision acuity of 0.1 at a 33-cm distance. The gaze was displaced towards the nose by 40°. This angle allows fixing the target at a minimum turn of the eye, when the optical axis of the scanner passes through the sclera rather than through the cornea, which reduces optical distortions. Ciliary muscle thickness (CMT) was analyzed at four levels relative to the scleral spur: maximum thickness of the ciliary muscle CMTmax, and CMT!, CMT2, CMT3 were taken from the scleral spur at a distance of 1, 2, and 3 mm, respectively (Figure 1).
Figure 1. Examination of the temporal side of the ciliary muscle on the optical coherence tomography system CASIA2
Figure 2. Examination of the anterior-posterior size of the crystalline lens and anterior chamber on the optical coherence tomography system CASIA2
Anterior-posterior size of the anterior chamber and the crystalline lens (Figure 2) was measured in a way similar to the examination of the ciliary muscle, first with a narrow pupil (the gaze was fixed directly on the target) and then under cycloplegia. Three measurements were done, and the average values were calculated.
Statistical data were processed using the following software: Statistica 10.0 (StatSoft, USA) and Microsoft Office Excel (Microsoft, USA). Variables
were checked for the normality of distribution using Kolmogorov-Smirnov test. Traditional indicators of descriptive statistics were used in the study: the number of observations (n), arithmetic mean (M), standard deviation (SD), and categorical data (%). The Student's t-test for dependent and independent samples was used to compare data before and after the operation. Differences between the sample values were considered significant at p<0.05. Equality of variances was tested using Fisher's F-criterion.
Results
Before the amblyopic eye treatment, SE measured with a wide eye was equal to +6.77±1.80 D, anisometropia was +4.25± 1.40 D in children of group 1. In group 2, these values were within the range of +5.9±2.5 and 4.4±1.9 D, respectively. Refraction of the better eye was close to emmetropia. BCVA values for 5 m were comparable between the groups prior to the treatment and amounted to 0.12±0.08 (LogMAR — +0.90±0.31) in group 1 and 0.19±0.17 (LogMAR — +0.72±0.42) in group 2.
After 2 years of treatment, an average BCVA value at a 5 m distance was equal to 0.40±0.09 (LogMAR — +0.40±0.16) in group 1 and 0.25±0.10 (LogMAR — +0.60±0.13) in group 2 (p=0.01) (Figure 3).
Spherical equivalent refraction of the operated amblyopic eye in group 1 at the end of the follow-up
Figure 3. The change in best-corrected visual acuity during the conducted treatment in the groups
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period decreased to +1.31±0.16 D (p<0.001 relative to the value before the treatment), while the degree of anisometropia decreased to +1.29±1.10 D (p<0.001). These values remained at the initial level in group 2. By the end of the follow-up period, the differences between the two groups were statistically significant (p<0.001).
The increase of the BCVA value at a 50-cm distance has been noted in both groups after the conducted
treatment. In group 1, BCVA increased by 0.21±0.09 and was equal to 0.32±0.12; in group 2, the increase was by 0.05±0.05 and made up 0.16±0.12; the data between the groups were statistically significant (p=0.02).
During the entire follow-up period, the gain in the ciliary muscle thickness was noted (Tables 2 and 3). In group 2, the thickness increase in the original parts of the ciliary muscle of the amblyopic eye was more prominent.
Table 2
The level of increase in the ciliary muscle thickness of the amblyopic eye according to the OCT data (Mm), M±SD
Parameters Before treatment After 6 months After 1 year After 1.5 years After 2 years p*
CMTmax:
group 1 808±38 813±38 821±34 824±33 829±33 0.07
group 2 812±33 818±38 830±38 836±37 840±36 0.02
p1-2 0.11 0.04
CMT-,:
group 1 724±54 729±54 733±53 740±53 744±52 0.05
group 2 735±33 746±34 752±33 759±24 761±29 0.03
p1-2 0.07 0.05
CMT2:
group 1 446±44 451±31 458±30 461±31 465±30 0.03
group 2 432±35 435±38 436±39 439±38 441±36 0.13
p1-2 0.06 0.04
CMT3:
group 1 223±37 229±33 234±31 237±32 241±17 0.05
group 2 229±29 231±26 233±28 234±29 236±25 0.25
p1-2 0.23 0.09
* the level of significance for the results compared before treatment and after 2 years.
Table 3
The level of increase in the ciliary muscle thickness of the leading eye according to OCT data (Mm), M±SD
Parameters Before treatment After 6 months After 1 year After 1.5 years After 2 years p*
CMTmax:
group 1 787±38 790±37 794±41 798±38 803±39 0.12
group 2 797±39 802±40 812±38 819±42 823±43 0.07
p1-2 0.16 0.04
CMT-,:
group 1 694±46 699±45 705±45 708±44 712±45 0.08
group 2 701±46 710±51 718±49 722±50 727±48 0.06
p1-2 0.25 0.06
CMT2:
group 1 459±30 462±31 465±29 469±30 472±31 0.07
group 2 453±31 456±30 460±29 462±28 463±26 0.10
p1-2 0.21 0.1
CMT3:
group 1 248±38 251±40 253±35 253±38 255±40 0.09
group 2 242±31 243±30 245±28 247±25 247±30 0.18
p1-2 0.33 0.12
* the level of significance for the results compared before treatment and after 2 years.
By the end of the treatment, the differences between the groups at the level of CMTmax and CMT1 were statistically significant (p=0.04 and p=0.05, respectively). In the posterior parts, vice versa, the greater gain was noted in group 1. After 2 years, the differences between the groups were statistically significant (p=0.04) at the CMT2 level. The differences between the groups
in the paired leading eye were statistically significant at the level of CMTmax (p=0.04) at the end of the follow-up.
Functional changes of accommodation were evaluated by the amplitude of thickness fluctuation of the ciliary muscle (ACMT), representing the ratio of ciliary muscle thickness, taken at the medicamentally inhibited accommodation, to the ciliary muscle
Figure 4. Changes in ACMT of the amblyopic eye during the conducted treatment in the group of children after FS-LASIK (M±SD)
Figure 5. Changes in ACMT of the amblyopic eye during the conducted treatment in the group of children with spectacle correction (M±SD)
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thickness, taken before dropping cycloplegics with 30±4 im, ACMT! — from 19±6 to 29±5 im, ACMT2 —
target fixation. from 12±4 to 16±4 im, ACMT3 — from 11±4 to 16±4 ^m
At the end of the follow-up period, the ACMTmax value (Figure 4). All intragroup changes were statistically
of the amblyopic eye increased in group 1 from 21±6 to significant (p<0.01).
Figure 6. Changes in ACMT of the leading eye during the conducted treatment in the group of children after FS-LASIK (M±SD)
Figure 7. Changes in ACMT of the leading eye during the conducted treatment in the group of children with spectacle correction (M±SD)
Increase of ACMT was also noted in group 2. The ACMTmax value before treatment was 23±5 Mm, ACMT! — 22±6 Mm, ACMT2 — 14±5 Mm, ACMT3 — 12±5 Mm. After 2 years, the value of ACMTmax was 27±4 Mm (p=0.005 relative to the value before the treatment), ACMT! — 25±5 Mm (p=0.003), ACMT2 — 15±4 Mm (p=0.13), ACMT3 — 14±5 Mm (p=0.02) (Figure 5). Changes within group 2 were statistically significant but less marked than in group 1.
In both groups, there was increase in ACMT at all levels in a paired leading eye and in amblyopic eye as well. In group 1, the ACMTmax value increased from 29±5 to 32±4 Mm (p=0.005), ACMT! from 27±4 to 31±4 Mm (p=0.001), ACMT2 from 16±4 to 18±3 Mm (p<0.001), ACMT3 from 16±3 to 17±3 Mm (p=0.05) (Figure 6). In group 2, the ACMTmax value increased from 27±5 to 31±5 Mm (p=0.01), ACMTi from 26±6 to 29±5 Mm (p<0.001), ACMT2 from 15±4 to 16±3 Mm (p=0.06), ACMT3 from 13±4 to 15±3 Mm (p=0.02) (Figure 7). Two years after the treatment, differences of ACMT1 values between the groups were statistically significant (p=0.05).
When investigating the lens thickness and the depth of the anterior chamber of the amblyopic eye with a narrow and wide pupil, no statistically significant changes before and after the treatment have been found. In group 1, the lens thickness with a narrow pupil before treatment was 3.40±0.25 mm, with a wide pupil 3.30±0.20 mm; in group 2 the values were 3.30±0.15 and 3.30±0.22, respectively. After 2 years, the indicators between the groups were also close. Thus, in group 1, the crystalline lens thickness with turned-on accommodation was 3.40±0.16, with turned-off accommodation it was equal to 3.20±0.18; in group 2 it was 3.40±0.19 mm (p=0.21 relative to group 1) and 3.30±0.15 (p=0.43), respectively. The depth of the anterior chamber in children after FS-LASIK with turned-on accommodation was 2.96±0.17 mm at the beginning of the study, with turned-off accommodation it was 3.10±0.20 mm; in the group of children with spectacle correction these values were 3.01 ±0.18 and 3.11 ±0.23 mm, respectively. After the treatment, these indicators were at the level of 3.09±0.20 and 3.14±0.16 mm in group 1; and 3.10±0.21 mm (p=0.18 relative to group 1) and 3.12±0.22 mm (p=0.34), respectively, in group 2. The values of the lens thickness and anterior chamber for the paired leading eye were similar to those for the amblyopic eye.
Discussion
Amblyopia is a cause of refraction disability. Anisometropia occurs in 35-45% of patients with hyperopia. In hyperopic amblyopia, anisometropia is encountered in 89.3-96.3% of cases [11]. A late diagnosis of this problem makes it difficult to restore visual functions. Analyzing amblyopia of various intensity degree in children with severe refraction disorders, it
has been established that accommodation is a leading function involved in the development of vision acuity [12]. Thus, the effectiveness of amblyopia treatment depends on the severity of accommodative disorders.
The comparison of mean values of the amblyopic and paired eye in both groups has demonstrated that before the treatment, the ciliary muscle of the leading eye was thinner by 19 Mm at the CMTmax level and by 32 Mm at the CMT1 level in the anterior parts, in the depth of the posterior parts it was thicker by 17 Mm at the CMT2 level and by 19 Mm at the CMT3 level. The increase in the posterior compartments was higher in children after FS-LASIK, i.e. by 19 Mm at the CMT2 level and by 18 Mm at the CMT3 level, in children with spectacle correction the values of these indicators increased by 9 and 7 Mm, respectively. On the contrary, a large increase in the thickness of the anterior part of the ciliary muscle was observed in children of group 2 by 28 Mm at the CMTmax level and by 26 Mm at the CMT1 level. In group 1, these values increased by 21 and 20 Mm, respectively.
The diagnostic examination of children with anisometropia using OCT was conducted by Lewis et al. [13]. According to the authors' data, the ciliary muscle thickness was 756.7 Mm at the CMTmax level, 730 Mm at the CMT1 level, 525 Mm at the CMT2 level, and 315 Mm at the level of CMT3. The data of the present study are close to these indicators, however, we registered higher parameters (806 and 724 Mm) in the anterior parts of the ciliary muscle, which is probably determined by the presence of amblyopia and a higher degree hyperopia in the examined children.
In our study, the increase in the fluctuation amplitude of the ciliary muscle thickness (ACMT) for the amblyopic eye has been revealed in children after FS-LASIK, which seems to be associated with the improvement of visual acuity and significant reduction of the refraction component.
The biometric data on the eye without cycloplegia and with it were studied by Tarutta et al. [14]. It has been shown by the OCT data that at a mean refraction component of +3.5±1.2 D, the depth of the anterior chamber without cycloplegia was 3.49±0.02 mm, with cycloplegia — 3.63±0.02 mm; the thickness of the crystalline lens without cycloplegia was 3.60±0.03 mm, with cycloplegia — 3.50±0.03 mm, which agrees with the results obtained by us.
Conclusion
Optical coherence tomography is a sufficiently informative method of investigation of ocular accommodative structures in children providing objective assessment of the amplitude of fluctuation of the ciliary muscle thickness during the conducted treatment. Monitoring of the accommodation structures has shown that after the refraction operation, in addition to the reduction of the refractive disorder and enhancement of visual functions, there was a significant improvement
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in the work of the ciliary muscle of the amblyopic eye, which is evidenced by the increase in the ACMT, CMT2, and CMT3 indicators, bringing these parameters closer to the better paired leading eye.
Study funding. The work was not supported by any financial sources.
Conflicts of interest. The authors have no conflicts of interest to declare.
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