Literature DB >> 35211592

Correlation of myopia onset and progression with corneal biomechanical parameters in children.

Li-Li Lu1, Xiao-Juan Hu2, Yan Yang2, Shen Xu2, Shi-Yong Yang2, Cui-Yu Zhang2, Qing-Ya Zhao2.   

Abstract

BACKGROUND: Recent epidemiological studies have shown that general eye measurement parameters and corneal biomechanical properties can predict the speed of myopic progression in children. AIM: To investigate the correlation between the onset and progression of myopia and corneal biomechanical parameters in children.
METHODS: The study included 102 cases in the emmetropia group, 207 cases in the myopic group, and 109 cases in the hyperopic group. The correlation between the change in corneal biomechanical indexes and the change in general ocular measurement parameters was analyzed. A one-way ANOVA test compared general ocular measurement and corneal biomechanical parameters. Pearson's correlation coefficient was analyzed to correlate corneal biomechanical and general ocular measurement parameters.
RESULTS: The general ophthalmometric parameters: Spherical equivalent (SE), intraocular pressure (IOP), and axial length (AL), differed significantly among subjects in myopia, emmetropia, and hyperopic groups. Children's SE positively correlated with corneal biomechanical parameters: Second velocity of applanation (A2V), peak distance (PD), and deformation amplitude (DA) (P < 0.05), and second applanation length (A2L) (P < 0.05). But it was negatively correlated with PD, DA and integral radius (IR) (P < 0.05). Also, IOP was negatively correlated with A2L and IR (P < 0.05). AL positively correlated with A2V and negatively correlated with second applanation time (A2T), highest concavity, and PD. Central corneal thickness positively correlated with first applanation length, first applanation time, first applanation deformation amplitude, A2V, A2L, A2T, second applanation deformation amplitude, central curvature radius at highest concavity (HCR), PD, DA, IR, ambrosia relational thickness-horizontal, first applanation stiffness parameter, corvis biomechanical index, topographic and biomechanics index and the first velocity of applanation. The general ocular Km in children positively correlated with corneal biomechanical parameters DA and IR and negatively correlated with A2L, HCR, and PD. There was a positive correlation between the general ocular measurement parameters ΔSE and corneal biomechanical parameters ΔA2V and ΔA2L, and a negative correlation with ΔIR. The increase in general ocular measurement parameter ΔKm positively correlated with changes in corneal biomechanical parameters, ΔDA and ΔIR, and negatively correlated with ΔHCR and ΔPD.
CONCLUSION: Myopia development in children was associated with multiple corneal biomechanical parameters. ©The Author(s) 2021. Published by Baishideng Publishing Group Inc. All rights reserved.

Entities:  

Keywords:  Children; Corneal biomechanical parameters; Correlation; Myopia

Year:  2022        PMID: 35211592      PMCID: PMC8855250          DOI: 10.12998/wjcc.v10.i5.1548

Source DB:  PubMed          Journal:  World J Clin Cases        ISSN: 2307-8960            Impact factor:   1.337


Core Tip: A total of 207 elementary school students aged 9-11 years, 142 males and 65 females, who presented to our hospital from November 2019 to April 2020, were enrolled for myopia study. We found a correlation between myopia development and various corneal biomechanical parameters in children. These findings may allow clinicians to take preventive measures to minimize a further increase in axial length.

INTRODUCTION

Refractive error is one of the leading causes of visual impairment in Chinese school-age children and is associated with a significant decrease in self-perceived visual function[1]. Patients with myopia, especially those with high myopia, could be much more likely to have serious complications, such as retinal detachment and open-angle glaucoma, than normal patients. Their reduced visual acuity and impaired visual function greatly affect their work, study, and daily activities. The progression of myopia is closely related to an increased eye axis. One possible reason for the accelerated growth of the eye axis is the weakening of the structure or function of the corneoscleral[2-5]. Therefore, the development of myopia may be related to corneoscleral stiffness, and the mechanical properties of the biological tissue play an important role in the increase of the ocular axis. Reducing scleral matrix metalloproteinase activity, decreasing the loss of extracellular matrix, and enhancing scleral biomechanical strength may slow down myopia progression. Therefore, it is crucial to learn about the correlation among children’s ocular parameters, including corneal biomechanical parameters, and their alterations in children’s myopia development. This study aimed to investigate the correlation between the occurrence and progression of myopia and corneal biomechanical parameters in children.

MATERIALS AND METHODS

General information

The study included elementary school students aged 9–11 years who visited our hospital from November 2019 to April 2020. Our hospital ethics committee approved the study, and all enrolled subjects provided informed consent. Inclusion criteria: (1) best-corrected vision acuity ≥ 0.5 (LogMAR); and (2) no history of wearing special glasses, such as keratoplasty lenses. Exclusion criteria: (1) other eye diseases, such as amblyopia, strabismus, cone cornea, and lid entropion; (2) history of previous ophthalmic surgery, such as retinal, congenital cataract, and ptosis surgery; and (3) systemic diseases affecting the eye, such as diabetes mellitus. We grouped the subjects according to their spherical equivalent lens degree: (1) myopic group: SE < -0.50 D; (2) emmetropia group: -0.50 D ≤ SE ≤ + 0.50 D; and (3) hyperopic group: SE > + 0.50 D. There were 207 cases in the myopic group, including 142 males and 65 females, with a mean age of 10.23 ± 0.58 years. There were 102 cases in the emmetropia group, including 61 males and 41 females, with a mean age of 10.04 ± 0.64 years. There were 109 cases in the hyperopia group, including 59 males and 50 females, with a mean age of 10.19 ± 0.84 years. We followed up on patients in the myopia group every 3 mo, recording the axial measurement, medical optometry, and corneal biomechanical parameters. After 1 year of follow-up, we compared changes in corneal biomechanical indexes and other clinical characteristics.

Methods

After enrollment, all subjects underwent routine ophthalmic examinations, including naked eye visual acuity, best-corrected visual acuity, anterior segment, fundus, medical optometry, and other ophthalmic examinations. Subjects’ intraocular pressure (IOP), anterior chamber depth, corneal curvature, spherical equivalent (SE), flat-axis corneal curvature, and steep-axis corneal curvature were recorded. IOLMaster measured axial length (AL). Corvis ST measured corneal biomechanical parameters and biological parameters, including the first velocity of applanation (A1V), first applanation length (A1L), first applanation time (A1T), first applanation deformation amplitude (A1DA), the second velocity of applanation (A2V), second applanation length (A2L), second applanation time (A2T), second applanation deformation amplitude (A2DA), time from the start until the highest concavity (HCT), central curvature radius at highest concavity (HCR), peak distance (PD), deformation amplitude (DA), central corneal thickness (CCT), integrated radius (IR), ambrosia relational thickness-horizontal (ARTh), first applanation stiffness parameter (SP-A1), corvis biomechanical index (CBI), and topographic and biomechanics index (TBI).

Statistical analysis

The Kolmogorov–Smirnov test analyzed the distribution of variables. Normally, distributed data were expressed as the mean ± SD. The one-ANOVA test compared the three groups’ general ocular measurement and corneal biomechanical parameters. Correlations between corneal biomechanical and general ocular measurement parameters were analyzed using a Pearson correlation coefficient. All statistical analyses were performed using the SPSS 23.0 software package and MedCalc 15.2.2 software. P < 0.05 was considered a statistically significant difference.

RESULTS

Comparison of general ocular measurement parameters among the three groups of subjects

There were statistically significant (P < 0.05) differences in the general ocular measurement parameters SE, IOP, and AL among subjects in three groups. However, there were no significant differences in the general ocular measurement parameters CCT and Km among subjects in three groups (P > 0.05), as shown in Table 1.
Table 1

Comparison of general ocular measurement parameters among the three groups of subjects

Number of cases
SE (D)
IOP (mmHg)
AL (mm)
CCT (μm)
Km
Myopia group207-2.543 ± 0.49317.04 ± 2.8825.61 ± 0.77560.31 ± 36.1343.15 ± 2.05
Emmetropia group102-0.104 ± 0.02515.40 ± 2.0923.35 ± 0.68559.23 ± 38.4343.05 ± 1.96
Hyperopia group1092.465 ± 1.02515.32 ± 2.9322.08 ± 0.79561.92 ± 40.5043.61 ± 2.34
F232119.94855.10.13642.279
P value< 0.0001< 0.0001< 0.00010.87250.1036

SE: Spherical equivalent; IOP: Intraocular pressure; AL: Axial length; CCT: Central corneal thickness.

Comparison of general ocular measurement parameters among the three groups of subjects SE: Spherical equivalent; IOP: Intraocular pressure; AL: Axial length; CCT: Central corneal thickness.

Comparison of corneal biomechanical parameters among the three groups of subjects

The corneal biomechanical parameters A1V, A1L, A1T, A1DA, A2V, A2DA, HCR, PD, IR, ARTh, SP-A1, CBI, and TBI were significantly different (P < 0.05) among subjects in three groups. However, the corneal biomechanical A2L, A2T, HCT, DA were not significantly different subjects in three groups (P > 0.05, Table 2).
Table 2

Comparison of corneal biomechanical parameters among the three groups of subjects

Number of cases
A1V (ms-1)
A1L (mm)
A1T (ms)
A1DA (mm)
A2V (ms-1)
A2L (mm)
A2T (ms)
A2D (mm)
HCT (ms)
HCR (mm)
PD (mm)
DA (mm)
IR
ARTh
SP-A1
CBI
TBI
Myopia group2070.13 ± 0.021.85 ± 0.297.63 ± 0.290.12 ± 0.010.29 ± 0.061.73 ± 0.3921.33 ± 0.930.37 ± 0.0816.70 ± 0.797.59 ± 0.733.42 ± 0.880.98 ± 0.099.23 ± 1.93472.03 ± 131.43102.01 ± 18.430.53 ± 0.350.56 ± 0.25
Emmetropia group1020.15 ± 0.051.93 ± 0.337.41 ± 0.220.13 ± 0.010.30 ± 0.021.70 ± 0.5521.57 ± 1.240.41 ± 0.0916.73 ± 0.496.42 ± 0.893.77 ± 0.920.99 ± 0.099.05 ± 2.61451.61 ± 111.43107.32 ± 14.620.23 ± 0.140.33 ± 0.23
Hyperopia group1090.14 ± 0.031.77 ± 0.397.39 ± 0.290.13 ± 0.020.31 ± 0.051.63 ± 0.5321.35 ± 1.290.47 ± 0.1316.59 ± 0.666.69 ± 1.023.02 ± 0.610.99 ± 0.1011.34 ± 1.34256.45 ± 46.34108.42 ± 14.450.02 ± 0.010.12 ± 0.07
F13.576.25836.8929.345.7801.6101.70637.521.26778.8521.670.607947.99145.76.681150.6158.2
P value< 0.00010.0021< 0.0001< 0.00010.00330.20110.1829< 0.00010.2829< 0.0001< 0.00010.5450< 0.0001< 0.00010.0014< 0.0001< 0.0001

A1V: First velocity of applanation; A1L: First applanation length; A1T: First applanation time; A1DA: First applanation deformation amplitude; A2V: Second velocity of applanation; A2L: Second applanation length; A2T: Second applanation time; A2D: Second applanation deformation; HCT: Time from the start until the highest concavity; HCR: Central curvature radius at highest concavity; PD: Peak distance; DA: Deformation amplitude; IR: Integrated radius; ARTh: ambrosia relational thickness-horizontal; SP-A1: First applanation stiffness parameter; CBI: Corvis biomechanical index; TBI: Topographic and biomechanics index.

Comparison of corneal biomechanical parameters among the three groups of subjects A1V: First velocity of applanation; A1L: First applanation length; A1T: First applanation time; A1DA: First applanation deformation amplitude; A2V: Second velocity of applanation; A2L: Second applanation length; A2T: Second applanation time; A2D: Second applanation deformation; HCT: Time from the start until the highest concavity; HCR: Central curvature radius at highest concavity; PD: Peak distance; DA: Deformation amplitude; IR: Integrated radius; ARTh: ambrosia relational thickness-horizontal; SP-A1: First applanation stiffness parameter; CBI: Corvis biomechanical index; TBI: Topographic and biomechanics index.

Correlation of general ocular measurement parameters with corneal biomechanical parameters in children

Children’s general ocular measurement parameter SE positively correlated with corneal biomechanical parameters A2V and A2L while negatively correlated with PD, DA, and IR. In children, the general ocular measurement parameter IOP was positively correlated with corneal biomechanical parameters PD and DA and negatively correlated with A2L and IR. The general ocular measurement parameter AL positively correlated with corneal biomechanical parameter A2V and negatively correlated with A2T, HCT, and PD. The general ocular measurement parameter CCT in children was positively correlated with corneal biomechanical parameters A1L, A1T, A2V, A2L, A2T, A2DA, HCR, PD, DA, IR, ARTh, SP-A1, CBI, and TBI and negatively correlated with A1V. Children’s general ocular measurement parameter Km positively correlated with corneal biomechanical parameters DA and IR but negatively correlated with A2L, HCR, and PD (all P < 0.05), as shown in Table 3.
Table 3

Correlation of corneal biomechanical parameters with general ocular measurement parameters

SE (D)
IOP (mmHg)
AL (mm)
CCT (μm)
Km
ρ
P value
ρ
P value
ρ
P value
ρ
P value
ρ
P value
A1V-0.0420.39170.0530.2797-0.0030.9512-0.583< 0.00010.1030.0353
A1L0.0330.5010-0.0610.2133-0.0770.11600.483< 0.0001-0.0890.692
A1T0.0240.6246-0.0910.0631-0.0820.09410.562< 0.00010.0080.8705
A1DA0.0380.4384-0.0730.13620.0530.27970.3580.23670.0480.3276
A2V0.235< 0.0001-0.1140.01970.302< 0.00010.542< 0.00010.0430.3805
A2L0.1240.0112-0.1390.0044-0.0940.05480.382< 0.0001-0.1170.0167
A2T0.0930.0575-0.0880.0723-0.1100.02450.421< 0.00010.0210.6686
A2DA0.0410.4031-0.0380.43830.0740.13090.345< 0.00010.0330.5010
HCT0.0040.9350-0.0080.8705-0.1090.02580.0490.31760.0630.1986
HCR0.0090.8705-0.0390.4265-0.0490.31760.482< 0.0001-0.285< 0.0001
PD-0.1300.00780.1170.01670.545< 0.00010.381< 0.0001-0.394< 0.0001
DA-0.1190.01490.1930.00010.0380.43840.295< 0.00010.234< 0.0001
IR-0.204< 0.00010.244< 0.00010.0250.61030.421< 0.00010.283< 0.0001
ARTh0.0620.2059-0.0720.14170.0170.72890.274< 0.0001-0.0850.0826
SP-A10.0320.5141-0.0240.6246-0.0590.22870.362< 0.00010.0080.8705
CBI0.0390.4265-0.0190.6985-0.060.22090.385< 0.00010.0870.0756
TBI0.0270.5820-0.0200.6835-0.0160.74430.0235< 0.00010.0640.1916

SE: Spherical equivalent; IOP: Intraocular pressure; AL: Axial length; CCT: Central corneal thickness; A1V: First velocity of applanation; A1L: First applanation length; A1T: First applanation time; A1DA: First applanation deformation amplitude; A2V: Second velocity of applanation; A2L: Second applanation length; A2T: Second applanation time; A2D: Second applanation deformation; HCT: Time from the start until the highest concavity; HCR: Central curvature radius at highest concavity; PD: Peak distance; DA: Deformation amplitude; IR: Integrated radius; ARTh: ambrosia relational thickness-horizontal; SP-A1: First applanation stiffness parameter; CBI: Corvis biomechanical index; TBI: Topographic and biomechanics index.

Correlation of corneal biomechanical parameters with general ocular measurement parameters SE: Spherical equivalent; IOP: Intraocular pressure; AL: Axial length; CCT: Central corneal thickness; A1V: First velocity of applanation; A1L: First applanation length; A1T: First applanation time; A1DA: First applanation deformation amplitude; A2V: Second velocity of applanation; A2L: Second applanation length; A2T: Second applanation time; A2D: Second applanation deformation; HCT: Time from the start until the highest concavity; HCR: Central curvature radius at highest concavity; PD: Peak distance; DA: Deformation amplitude; IR: Integrated radius; ARTh: ambrosia relational thickness-horizontal; SP-A1: First applanation stiffness parameter; CBI: Corvis biomechanical index; TBI: Topographic and biomechanics index. The general ocular measurement parameters ΔIOP was positively correlated with the corneal biomechanical parameters ΔDA, ΔIR, and negatively with ΔA2L, and increased ΔAL was positively correlated with corneal biomechanical parameters ΔA2V and ΔPD.

Correlation between myopia development and corneal biomechanical parameters in children

There was a positive correlation between the increase in general ocular measurement ΔSE and the change in corneal biomechanical parameters ΔA2V and ΔA2L and a negative correlation with ΔIR. There was a positive correlation between ΔIOP and ΔDA and a negative correlation between ΔA2L and ΔIR. There was a positive correlation between the increase in the general ocular measurement parameter ΔAL and the change in the corneal biomechanical parameters ΔA2V and ΔPD in children. There was a positive correlation between the general ocular measurement parameter ΔCCT and the corneal biomechanical parameters ΔA1L, ΔA1T, ΔA2V, ΔA2L, ΔA2T, ΔA2DA, ΔHCR, ΔPD, ΔDA, ΔIR, ΔARTh, ΔSP-A1, ΔCBI, and ΔTBI and a negative correlation with ΔA1V. There was a positive correlation between the increase in general ocular measurement parameter ΔKm and the change in corneal biomechanical parameters ΔDA and ΔIR and a negative correlation with ΔHCR and ΔPD in children (all P < 0.05), as shown in Table 4.
Table 4

Correlation between spherical equivalent, intraocular pressure, and axial length growth and the change in corneal biomechanical parameters in subjects in the myopic group

ΔSE (D)
ΔIOP (mmHg)
ΔAL (mm)
CCT (μm)
Km
ρ
P value
ρ
P value
ρ
P value
ρ
P value
ρ
P value
ΔA1V-0.03910.57580.04600.5107-0.00320.9631-0.5873< 0.00010.10100.1478
ΔA1L0.03700.5962-0.06730.3350-0.08180.24150.4236< 0.0001-0.07160.3053
ΔA1T0.02570.7133-0.09170.1889-0.09090.19260.4629< 0.00010.00800.9084
ΔA1DA0.03440.6230-0.05860.40130.04550.51470.3530< 0.00010.04750.4966
ΔA2V0.20270.0034-0.10750.12320.3121 < 0.00010.5029< 0.00010.04720.4994
ΔA2L0.13970.0446-0.14590.0360-0.09710.16400.4505< 0.0001-0.09720.1637
ΔA2T0.07720.2691-0.07180.3042-0.08970.19870.4920< 0.00010.02440.7268
ΔA2DA0.04620.5089-0.03210.64590.06770.33270.3561< 0.00010.03310.6357
ΔHCT0.00350.9601-0.00730.9171-0.11200.10820.04650.50610.07170.3047
ΔHCR0.00810.9073-0.03230.6446-0.05080.46690.5378< 0.0001-0.3190< 0.0001
ΔPD-0.13310.05590.13610.05050.4427< 0.00010.3246< 0.0001-0.3320< 0.0001
ΔDA-0.11300.10490.18140.00890.03910.57630.24740.00030.21250.0021
ΔIR-0.18410.00790.26740.00010.02280.74390.4886< 0.00010.26150.0001
ΔARTh0.05420.4378-0.06710.33650.01640.81500.3274< 0.0001-0.07260.2983
ΔSP-A10.03720.5951-0.02090.7655-0.06230.37270.4282< 0.00010.00740.9161
ΔCBI0.03210.6461-0.01600.8187-0.05340.44500.3329< 0.00010.10100.1474
ΔTBI0.02340.7378-0.01870.7888-0.01430.83810.02470.72380.05890.3988

SE: Spherical equivalent; IOP: Intraocular pressure; AL: Axial length; CCT: Central corneal thickness; A1V: First velocity of applanation; A1L: First applanation length; A1T: First applanation time; A1DA: First applanation deformation amplitude; A2V: Second velocity of applanation; A2L: Second applanation length; A2T: Second applanation time; A2D: Second applanation deformation; HCT: Time from the start until the highest concavity; HCR: Central curvature radius at highest concavity; PD: Peak distance; DA: Deformation amplitude; IR: Integrated radius; ARTh: ambrosia relational thickness-horizontal; SP-A1: First applanation stiffness parameter; CBI: Corvis biomechanical index; TBI: Topographic and biomechanics index.

Correlation between spherical equivalent, intraocular pressure, and axial length growth and the change in corneal biomechanical parameters in subjects in the myopic group SE: Spherical equivalent; IOP: Intraocular pressure; AL: Axial length; CCT: Central corneal thickness; A1V: First velocity of applanation; A1L: First applanation length; A1T: First applanation time; A1DA: First applanation deformation amplitude; A2V: Second velocity of applanation; A2L: Second applanation length; A2T: Second applanation time; A2D: Second applanation deformation; HCT: Time from the start until the highest concavity; HCR: Central curvature radius at highest concavity; PD: Peak distance; DA: Deformation amplitude; IR: Integrated radius; ARTh: ambrosia relational thickness-horizontal; SP-A1: First applanation stiffness parameter; CBI: Corvis biomechanical index; TBI: Topographic and biomechanics index. The corneal biomechanical parameters A1V, A1L, A1T, A1DA, A2V, A2DA, HCR, PD, IR, ARTh, SP-A, CBI, and TBI were statistically different in the myopic, emmetropia, and hyperopic groups (all P < 0.05).

DISCUSSION

The prevalence of myopia is rather high worldwide, reaching 80% in some Asian populations[6]. Well-documented changes in myopia include prolonged AL, deeper anterior chamber and vitreous depth, thinner retina, higher incidence of retinal detachment, and reduced scleral thickness and elasticity[6]. This study measured general ocular and corneal biomechanical parameters in myopic, emmetropic, and hyperopic children. The analysis revealed statistically significant (P < 0.05) differences in general ocular measurement parameters SE, IOP, and AL among subjects in three groups. Corneal biomechanical parameters A1V, A1L, A1T, A1DA, A2V, A2DA, HCR, PD, IR, ARTh, SP-A1, CBI, and TBI were significantly different (P < 0.05) in three groups. Despite the limited tracking time and the number of participants compared to the large scale of clinic studies, our data were effectively valid because of highly professional supervision and appropriate statistics. IOP is an important biometric parameter in myopic eyes. Previous studies have shown that thinner corneas may lead to underestimation errors in IOP measurements[7]. However, recent studies have found significantly higher mean IOP values in myopic children than in non-myopic children[8]. In this study, children’s general eye measurement parameter IOP was positively correlated with corneal biomechanical parameters PD and DA and negatively correlated with A2L and IR. The change in ΔIOP was positively correlated with the corneal biomechanical parameter ΔDA and negatively correlated with ΔA2L and ΔIR (all P < 0.05). Glaucoma is a blinding eye disease and the major ocular disease causing vision loss and blindness worldwide that shows characteristic damage to the optic nerve and loss of visual function[9]. Primary open-angle glaucoma is the most common form of glaucoma globally, where the degree of visual field damage is already severe, and the damage to visual acuity and visual field is irreversible[10]. Elevated IOP is considered the most important risk factor for developing and progression of primary open-angle glaucoma[11]. Therefore, alterations in DA in myopia development in children can be used as potential markers for glaucoma development. In the present study, the general ocular measurement parameter CCT in children positively correlated (P < 0.05) with the corneal biomechanical parameters A1L, A1T, A2V, A2L, A2T, A2DA, HCR, PD, DA, IR, ARTh, SP-A1, CBI, and TBI, while it was negatively correlated (P < 0.05) with A1V. The general ocular measurement parameter ΔCCT in children positively correlated with corneal biomechanical parameters ΔA1L, ΔA1T, ΔA2V, ΔA2L, ΔA2T, ΔA2DA, ΔHCR, ΔPD, ΔDA, ΔIR, ΔARTh, ΔSP-A1, ΔCBI, and ΔTBI (P < 0.05), while negatively correlated with ΔA1V (P < 0.05). Studies of CCT in children of different ages have shown that CCT increases with age so that the average CCT is thicker in older than in young children[12]. CCT and the change in CCT positively correlated with most corneal biomechanics except for A1V and ΔA1V, so these corneal biomechanical parameters may also increase with the child’s age. The refractive error results from a mismatch between various optical components of the eye, one of the most important parts of which is AL[13]. In the present study, there was a positive correlation between the general ocular measurement parameter AL and the corneal biomechanical parameter A2V (P < 0.05) and a negative correlation with A2T, HCT, and PD (P < 0.05) in children. There was a positive correlation between the increased general ocular measurement parameter ΔAL and the change in the corneal biomechanical parameter ΔA2V and ΔPD in children (P < 0.05). This usually corresponds to an AL ≥ 26 mm, which significantly increases the risk of serious complications later in life, including myopic macular degeneration, retinal detachment, and glaucoma[14,15]. The mean AL of the subjects in the myopic group included in this study was 25.61 ± 0.77 mm. Therefore, the corneal biomechanical parameters A2V, A2T, HCT, and PD may identify children at low risk. The application of corneal biomechanical parameters will allow clinicians to implement preventive measures to minimize the further increase in AL. These measures include pharmacological agents, such as atropine, and optical applications, such as multifocal contact lenses. There are still limitations in this study, including that this study is a prospective study and cannot determine the causal relationship between various variables. At the same time, this study only collected children from the same hospital, and the sample size is small. There may still be other influencing factors that have not been found. The age range of children included in this study is not large enough. In addition, due to time constraints, the children were not followed up for a longer time.

CONCLUSION

Myopia development in children was associated with multiple corneal biomechanical parameters. These findings may help clinics take preventive measures to minimize the further increase in myopic children’s axial length.

ARTICLE HIGHLIGHTS

Research background

Patients with myopia, especially those with high myopia, are much more likely to have serious complications such as retinal detachment and open-angle glaucoma than normal patients. High myopia may have a degenerative disorder, including cornea, sclera, choroid, optic disc, vitreous, macula, and peripheral retina.

Research motivation

The increasingly high incidents of myopia in children and the association with multiple corneal biomechanical parameters in local community and worldwide.

Research objectives

This study is to determine the change of corneal biomechanical parameters after onset and progression of myopia.

Research methods

A total of 207 myopic subjects were enrolled according to local clinic criteria and one-way ANOVA test was applied to determine whether there is statistical evidence between different general ocular measurement parameters.

Research results

There is a correlation between the development of myopia and various corneal biomechanical parameters in children.

Research conclusions

There are positive and negative correlations between myopia and general eye measurement parameters, corneal biomechanical parameters and other multiple parameters.

Research perspectives

Corneal ophthalmometric parameters and biomechanical properties including multiple baselines may be able to predict the development of myopia.
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Authors:  Shifei Wei; Shi-Ming Li; Wenzai An; Jialing Du; Xintong Liang; Yunyun Sun; Duoxing Zhang; Jiaxin Tian; Ningli Wang
Journal:  JAMA Ophthalmol       Date:  2020-11-01       Impact factor: 7.389

6.  The Associations between Near Visual Activity and Incident Myopia in Children: A Nationwide 4-Year Follow-up Study.

Authors:  Po-Wen Ku; Andrew Steptoe; Yun-Ju Lai; Hsiao-Yun Hu; Dachen Chu; Yung-Feng Yen; Yung Liao; Li-Jung Chen
Journal:  Ophthalmology       Date:  2018-06-20       Impact factor: 12.079

7.  Effect of High Add Power, Medium Add Power, or Single-Vision Contact Lenses on Myopia Progression in Children: The BLINK Randomized Clinical Trial.

Authors:  Jeffrey J Walline; Maria K Walker; Donald O Mutti; Lisa A Jones-Jordan; Loraine T Sinnott; Amber Gaume Giannoni; Katherine M Bickle; Krystal L Schulle; Alex Nixon; Gilbert E Pierce; David A Berntsen
Journal:  JAMA       Date:  2020-08-11       Impact factor: 56.272

Review 8.  A review on the epidemiology of myopia in school children worldwide.

Authors:  Andrzej Grzybowski; Piotr Kanclerz; Kazuo Tsubota; Carla Lanca; Seang-Mei Saw
Journal:  BMC Ophthalmol       Date:  2020-01-14       Impact factor: 2.209

9.  Progression of Myopia in School-Aged Children After COVID-19 Home Confinement.

Authors:  Jiaxing Wang; Ying Li; David C Musch; Nan Wei; Xiaoli Qi; Gang Ding; Xue Li; Jing Li; Linlin Song; Ying Zhang; Yuxian Ning; Xiaoyu Zeng; Ning Hua; Shuo Li; Xuehan Qian
Journal:  JAMA Ophthalmol       Date:  2021-03-01       Impact factor: 7.389

10.  Axial growth and refractive change in white European children and young adults: predictive factors for myopia.

Authors:  Sara McCullough; Gary Adamson; Karen M M Breslin; Julie F McClelland; Lesley Doyle; Kathryn J Saunders
Journal:  Sci Rep       Date:  2020-09-16       Impact factor: 4.379
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