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Anterior and posterior segment structural features of acute primary angle-closure eyes: date based on AS-OCT and SS-OCT

Anterior and posterior segment structural features of acute primary angle-closure eyes: date based on AS-OCT and SS-OCT

来源期刊: Annals of Eye Science | 2020年12月 第5卷 第4期 - 发布时间: 15 December 2020.阅读量:1057
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关键词:
Acute primary angle-closure anterior segment optical coherence tomography (AS-OCT) swept source optical coherence tomography (SS-OCT) ocular biometry
Acute primary angle-closure anterior segment optical coherence tomography (AS-OCT) swept source optical coherence tomography (SS-OCT) ocular biometry
DOI:
10.21037/aes-20-87

Background: To measure the anterior and posterior segment structural features of acute primary angle-closure (APAC) eyes.

Methods: A total of 36 subjects with unilateral APAC were recruited in this study. The ocular biometric characteristics were measured by anterior segment optical coherence tomography (AS-OCT) and swept source optical coherence tomography (SS-OCT), respectively at baseline, 2 weeks, and 1 month after surgical intervention.

Results: At baseline, when compared with the fellow eyes, APAC-affected eyes showed significantly greater corneal thickness (P=0.004), shallower anterior chamber depth (ACD) (P<0.001), smaller anterior chamber area (ACA) (P=0.013), angle opening distance at 750 μm from the scleral spur (AOD750) (P=0.002), trabecular–iris space area at 750 μm from the scleral spur (TISA750) (P=0.033), angle recess area (ARA) (P=0.014), and iris area (IARE) (P=0.003), less iris curvature (ICURVE) (P=0.003), and larger lens vault (LV) (P=0.030). After intervention, the corneal thickness was significantly decreased at 1 month (P<0.001), while ACD, ACA, and AOD750 were significantly increased at 2 weeks and 1 month (all P<0.017). Changes in ACD were correlated with decreasing LV (P<0.05). The posterior segment parameters did not change over the 4-week period.

Conclusions: When compared with the fellow eyes, APAC-affected eyes had greater corneal thickness, shallower anterior chamber, narrower angle, less ICURVE, and larger LV. After intervention, the corneal thickness was decreased, while the shallower anterior chamber was relieved to some extent.

Background: To measure the anterior and posterior segment structural features of acute primary angle-closure (APAC) eyes.

Methods: A total of 36 subjects with unilateral APAC were recruited in this study. The ocular biometric characteristics were measured by anterior segment optical coherence tomography (AS-OCT) and swept source optical coherence tomography (SS-OCT), respectively at baseline, 2 weeks, and 1 month after surgical intervention.

Results: At baseline, when compared with the fellow eyes, APAC-affected eyes showed significantly greater corneal thickness (P=0.004), shallower anterior chamber depth (ACD) (P<0.001), smaller anterior chamber area (ACA) (P=0.013), angle opening distance at 750 μm from the scleral spur (AOD750) (P=0.002), trabecular–iris space area at 750 μm from the scleral spur (TISA750) (P=0.033), angle recess area (ARA) (P=0.014), and iris area (IARE) (P=0.003), less iris curvature (ICURVE) (P=0.003), and larger lens vault (LV) (P=0.030). After intervention, the corneal thickness was significantly decreased at 1 month (P<0.001), while ACD, ACA, and AOD750 were significantly increased at 2 weeks and 1 month (all P<0.017). Changes in ACD were correlated with decreasing LV (P<0.05). The posterior segment parameters did not change over the 4-week period.

Conclusions: When compared with the fellow eyes, APAC-affected eyes had greater corneal thickness, shallower anterior chamber, narrower angle, less ICURVE, and larger LV. After intervention, the corneal thickness was decreased, while the shallower anterior chamber was relieved to some extent.

Introduction

Acute primary angle-closure (APAC) is a notable ophthalmic crisis described by sudden and excessive increases in intraocular pressure (IOP) (1). Severe episodes of APAC can prompt the advancement of visual field damage, chronic glaucoma, and visual deficiency (2,3).

APAC has a higher incidence in parts of Asia; for example, its revealed occurrence is 12.2/100,000 per year in Singapore Chinese and 10.4/100,000 per year in Hong Kong Chinese (4). Early biometric research (5,6) has demonstrated that the APAC eyes often have a shallower anterior chamber, a smaller corneal diameter, a thicker lens, and a shorter axial length than is seen in normal eyes. However, the development of imaging diagnostic techniques continues to uncovering extra physiological components that are equally significant, particularly concerning the triggering of an acute attack.

Recent studies using anterior segment optical coherence tomography (AS-OCT) have recognized novel anatomic elements related with APAC, including shallower anterior chamber depth (ACD), smaller anterior chamber area (ACA) and volume (ACV), and increased lens vault (LV) (7-9). Our previous series of studies (10,11), which utilized enhanced depth imaging optical coherence tomography (EDI-OCT) to research posterior ocular biometry, revealed a correlation between increased subfoveal choroidal thickness (SFCT) and the pathogenesis of APAC. We hypothesized that the choroidal expansion described by Quigley et al. (12,13) could be a physiological trigger accounting for APAC. However, to date, few studies have attempted to investigate the anterior and posterior biometric characteristics together in APAC eyes.

The aim of this study was to investigate the structural features of the anterior and posterior segments of APAC-affected eyes by comparing the APAC-affected eyes with their fellow eyes, together with longitudinal follow-up observation of the structural features after iridectomy. We present the following article in accordance with the STROBE guideline checklist (available at http://dx.doi.org/10.21037/aes-20-87).


Methods

Subjects and enrolment criteria

This is an observation study. The study was approved by the Ethical Review Committee of the Zhongshan Ophthalmic Center (ID: 2012KYNL037), and was performed in compliance with the Declaration of Helsinki (as revised in 2013). All participants received a detailed explanation of the study and signed an informed consent form. This study was conducted from April 2014 to April 2017.

Patients suffering unilateral APAC attacks [the fellow eyes were diagnosed with primary angle closure suspect (PACS)] were recruited to participate in the study. APAC was characterized dependent on the following criteria (4): (I) presence of at least two of the following manifestations: nausea and/or vomiting, ocular or periocular pain, and a precursor history of intermittent blurring of vision with halos; (II) presenting an IOP ≥22 mmHg (as estimated by Goldmann applanation tonometry); (III) the presence of at least three of the following manifestations: corneal epithelial edema, a shallow anterior chamber, and mid-dilated unreactive pupil; and (IV) the presence of an occluded angle in the attacked eye, confirmed by gonioscopy. PACS was characterized as a pigmented trabecular meshwork in the eye not visible for ≥180 degrees under static gonioscopy, without peripheral anterior synechiae or glaucomatous neuropathy, and with an IOP <21 mmHg. All eyes experienced an ultrasound biomicroscopy (UBM) assessment to affirm the presence of a narrow-angle pupillary block segment.

Patients with any of the following criteria were rejected: a secondary acute attack due to tumor; trauma; iris neovascularization; lens subluxation; uveitis; any conspicuous cataract cause an intumescent lens; a pre-existing ocular disease (such as age-related macular degeneration, retinal vein occlusion, retinal artery occlusion, and diabetic retinopathy, etc.); a history of previous ocular surgery; opacities of the optical media; or difficulty in fundus examination and OCT imaging.

The APAC eyes were treated with standard medical treatment. This comprised topical pilocarpine, timolol, Azopt, Alphagan, and topical steroids. Intravenous mannitol and oral acetazolamide were added in cases where the IOP was not decreased by 20%. After the initial medical treatment, all APAC eyes underwent surgical iridectomy, which was performed by same surgeon (X.Z.). Although laser iridotomy has become the first-line treatment of APAC in recent years, surgical iridectomy was chosen in the present study because it is covered by hospitalization insurance in China.

Examination protocol and study measurements

Patients underwent three scheduled examinations: the first occurred when the cornea became clear (usually IOP <30 mmHg after intensive medical therapy) and before iridectomy, which was defined as the baseline measurement. The second and third visits occurred 2 weeks and 1 month after the surgery, respectively. At each study visit, the patients underwent complete ophthalmic evaluations, which included a visual acuity measurement, gonioscopy, IOP measurement (Goldmann applanation tonometry), fundus examination, visual field text (24-2 test pattern; Carl Zeiss Meditec, Germany), a refractive error examination using an autorefractometer (Topcon, Japan), AL measurements using the IOL Master (Carl Zeiss Meditec, Germany), AS-OCT measurements (Visante OCT; Carl Zeiss Meditec, Germany), and SS-OCT measurements (DRI OCT-1; Topcon, Japan).

AS-OCT and SS-OCT measurements

Anterior chamber parameters were measured by AS-OCT in a darkened room (0 lux) by a single operator. The protocol for AS-OCT measurement was described in our previous study (14). The AS-OCT images were estimated by Zhongshan Angle Assessment Program (ZAAP, Guangzhou, China) (15). The only operation was to decide the location of the scleral spur. Then, the ZAAP software automatically calculated the anterior chamber parameters. The following parameters were measured: cornea thickness, ACD, anterior chamber width (ACW), ACA, ACV, pupil diameter (PD), angle opening distance at 750 μm from the scleral spur (AOD750), trabecular–iris space area at 750 μm from the scleral spur (TISA750), angle recess area (ARA), iris thickness at 750 μm from the scleral spur (IT750), iris curvature (ICURV), iris area (IAREA), and lens vault (LV).

The SS-OCT measurements immediately followed the AS-OCT measurements. Details of the SS-OCT measurement protocol of the macular region are available in our previous report (14). A 3D imaging scan pattern was used, and the images were analyzed using built-in manufacturer’s software (9.12.003.04). A 6×6 mm2 thickness map of five layers [retinal nerve fiber layer (RNFL), ganglion cell layer plus (GCL+), ganglion cell complex (GCC), retina, and choroid] was automated segmentation by the manufacturer’s software. A 6×6 mm2 scan grid was used for the thickness map, and the mean regional thicknesses were calculated for the 36 sectors of the grid.

Statistical analysis

By using the difference test, a significance level below 0.05 was set and a power of 0.80 to detect an average ACD difference of 0.2 mm with a 0.3 mm standard error, it was estimated that a minimum of 20 eyes were needed. All statistical analyses were calculated using SPSS (Version 13.0; SPSS, Chicago, IL) statistical software. Statistical significance was accepted at P<0.05. First, the anterior and posterior segment parameters were compared between APAC-affected eyes (baseline) and fellow eyes using a paired t-test. Second, a paired t-test was used again to compare the variables at different time points (baseline, 2 weeks, and 1 month after surgery). In this model, to adjust for multiple comparisons, P values of 0.017 for paired t-tests were regarded as statistically significant, with significance levels of 0.05 dependent on Bonferroni's strategies. Third, the Pearson correlation was used to determine the factors affecting the changes in the ACD. Lastly, the theory of choroidal expansion, proposed by Quigley et al. (12), was verified using uni- and multivariate linear regression to identify the relationship between choroidal thickness and anterior segment parameters in the baseline of APAC-affected eyes.


Results

Demographic and clinical characteristics

The study included 36 subjects with unilateral APAC that met the inclusion and exclusion criteria. The recruitment and follow-up of subjects are illustrated in Figure 1. All fellow eyes had a diagnosis of PACS. The mean age of the patients was 60.0±8.4 years, with 29 females and 7 males. The mean IOP at presentation was 46.2±10.3 mmHg. The median duration of experienced attack was 3.5 days (range, 1 to 7 d). The demographic and baseline characteristics of the patients are shown in Table 1. Most patients had an IOP that remained at less than 21 mmHg for the duration of the study after peripheral iridectomy, except for three patients who required IOP-lowering medications after surgery.

figure1

figure1

table1

Table 1

Clinical characteristics of the study subjects

Characteristic Values
Age, y 60.0 (8.4)
Gender (female/male) 29/7
Laterality of affected eye (right/left) 17/19
Presenting IOP (mmHg) 46.2 (10.3)
IOP at baseline imaging (mmHg) 21.2 (11.9)
No. of glaucoma medications (SD) 4.80 (0.81)

Values are expressed as the mean (SD). IOP, intraocular pressure; SD, standard deviation.

APAC-affected eyes vs. fellow eyes

The results of a comparison of ocular biometric parameters between APAC-affected eyes and fellow eyes are summarized in Table 2. As expected, the IOP was higher in the APAC-affected eyes than in the fellow eyes (P=0.009). No differences were detected in SE and AL. The AS-OCT measurement parameters revealed significantly greater corneal thickness (P=0.004); shallower ACD (P<0.001); and smaller ACA (P=0.013), AOD750 (P=0.002), TISA750 (P=0.033), ARA (P=0.014), and IARE (P=0.003); less ICURVE (P=0.003), and larger LV (P=0.030) in the affected eyes than in the fellow eyes. No significant differences were evident in the posterior segment parameters (including RNFL, GCL+, GCC, retina, and choroidal thickness) of the affected and fellow eyes.

table2

Table 2

Comparison of ocular biometric parameters between APAC-affected eyes and the fellow eyes

Characteristic APAC-affected eyes Fellow eyes P value*
IOP at imaging, mmHg 21.2 (11.9) 13.4 (3.4) 0.009
Al, mm 22.21 (0.78) 22.21 (0.85) 0.963
SE, D 1.49 (2.00) 1.74 (1.61) 0.279
ASOCT-anterior segment parameters
   CCT, μm 586.3 (48.5) 557.1 (30.7) 0.004
   ACD, mm 1.77 (0.22) 1.88 (0.19) <0.001
   ACW, mm 11.02 (0.41) 11.11 (0.38) 0.091
   ACA, mm2 11.57 (2.05) 12.43 (1.82) 0.013
   ACV, mm3 64.7 (16.9) 72.4 (13.6) 0.057
   PD, mm 4.26 (1.55) 4.05 (1.47) 0.635
ASOCT-mean anterior chamber angle parameters
   AOD750, mm 0.09 (0.07) 0.17 (0.09) 0.002
   TISA750, mm2 0.04 (0.04) 0.07 (0.04) 0.033
   ARA, mm2 0.06 (0.06) 0.09 (0.06) 0.014
ASOCT-iris and lens parameters
   IT750, mm 0.47 (0.08) 0.51 (0.08) 0.077
   IAREA, mm2 1.42 (0.25) 1.69 (0.30) 0.003
   ICURV, mm 0.23 (0.11) 0.37 (0.15) 0.003
   LV, mm 0.95 (0.18) 0.89 (0.13) 0.030
SSOCT parameters
   RNFL, μm 30.2 (7.35) 33.6 (13.5) 0.288
   GCL+, μm 69.4 (8.42) 71.4 (6.56) 0.242
   GCC, μm 100.3 (13.6) 102.5 (10.6) 0.482
   Retina, μm 272.1 (22.2) 267.8 (11.0) 0.291
   CT, μm 224.8 (91.5) 209.5 (71.8) 0.330

*, based on paired t test. Data are expressed as the mean (SD). APAC, acute primary angle-closure; IOP, intraocular pressure; SE, Spherical equivalent; AL, axial length; D, diopter; CCT, corneal thickness; ACD, anterior chamber depth; ACW, anterior chamber width; ACV, anterior chamber volume; ACA, anterior chamber area; PD, pupil diameter; AOD750, angle opening distance at 750 ìm from the scleral spur; TISA750, trabecular–iris space area at 750 ìm from the scleral spur; IT750, anterior chamber volume; ARA, angle access area; IAREA, iris area; ICURV, iris curvature; LV, lens vault; RNFL, retinal nerve fiber layer; GCL+, ganglion cell layer plus; GCC, ganglion cell complex; CT, choroidal thickness.

APAC-affected eyes at baseline, 2 weeks, and 1 month after intervention

Table 3 shows the ocular biometric parameters in APAC-affected eyes measured at baseline, 2 weeks, and then 1 month after the intervention. The baseline IOP was 21.2±11.9 mmHg and decreased to 16.9±5.0 at 2 weeks (P=0.016), and to 15.9±5.0 at 1 month after surgery (P=0.010). No significant difference was noted in IOP at 2 weeks and at 1 month (P=0.569). The AS-OCT measurement parameters after surgery showed a significant decrease in cornea thickness at 1 month (P<0.001), while ACD, ACA, and AOD750 were significantly increased at 2 weeks and 1 month (all P<0.017). Changes in ACD at 2 weeks and 1 month were correlated with decreasing LV (P=0.001, and P=0.028, respectively). No significant association was evident between changes in ACD and any other analyzed factors (age, baseline AL, and changes in corneal thickness and choroidal thickness) (Table 4). No significant difference was noted in anterior segment parameters between 2 weeks and 1 month. No significant changes occurred in posterior segment parameters (including RNFL, GCL+, GCC, retina, and choroidal thickness) over the 4-week period (all P>0.05) (Table 3).

table3

Table 3

Comparison of ocular biometric parameters in APAC-affected eyes between baseline, 2 weeks, and 1 month after intervention

Characteristic Baseline 2 weeks 1 month P value*, Baseline vs. 2 weeks P value*, Baseline vs. 1 month P value*, 2 weeks vs. 1 month
IOP at imaging, mmHg 21.2 (11.9) 16.9 (5.0) 15.9 (5.0) 0.016 0.010 0.569
Al, mm 22.21 (0.78) 22.15 (0.81) 22.17 (0.84) 0.027 0.133 0.168
SE, D 1.49 (2.00) 1.59 (1.66) 1.40 (1.96) 0.751 0.123 0.324
ASOCT-anterior segment parameters
   CCT, μm 586.3 (48.5) 554.8 (39.6) 550.8 (38.2) 0.035 <0.001 0.314
   ACD, mm 1.77 (0.22) 1.95 (0.35) 1.91 (0.34) 0.010 0.015 0.023
   ACW, mm 11.02 (0.41) 11.06 (0.41) 11.08 (0.46) 0.292 0.202 0.373
   ACA, mm2 11.57 (2.05) 13.69 (3.93) 12.73 (2.21) 0.002 0.006 0.102
   ACV, mm3 64.7 (16.9) 87.2 (26.2) 82.0 (21.3) 0.004 0.036 0.052
   PD, mm 4.26 (1.55) 4.36 (0.99) 4.24 (0.98) 0.070 0.220 0.127
ASOCT-mean anterior chamber angle parameters
   AOD750, mm 0.09 (0.07) 0.19 (0.11) 0.16 (0.10) 0.001 0.016 0.436
   TISA750, mm2 0.04 (0.04) 0.07 (0.05) 0.07 (0.05) 0.043 0.106 0.081
   ARA, mm2 0.06 (0.06) 0.08 (0.06) 0.07 (0.04) 0.194 0.313 0.083
ASOCT-iris and lens parameters
   IT750, mm 0.47 (0.08) 0.52 (0.08) 0.51 (0.08) 0.065 0.099 0.138
   IAREA, mm2 1.42 (0.25) 1.28 (0.39) 1.37 (0.30) 0.013 0.252 0.704
   ICURV, mm 0.23 (0.11) 0.14 (0.13) 0.15 (0.12) 0.027 0.026 0.147
   LV, mm 0.95 (0.183) 0.87 (0.30) 0.91 (0.24) 0.042 0.057 0.145
SSOCT parameters
   RNFL, μm 30.2 (7.35) 30.1 (8.82) 30.8 (13.4) 0.993 0.789 0.310
   GCL+, μm 69.4 (8.42) 68.2 (13.7) 66.9 (9.43) 0.628 0.214 0.604
   GCC, μm 100.3 (13.6) 99.1 (20.3) 99.21 (19.2) 0.693 0.782 0.283
   Retina, μm 272.1 (22.2) 274.2 (29.0) 272.1 (24.1) 0.465 0.998 0.635
   CT, μm 224.8 (91.5) 235.9 (105.9) 219.0 (102.9) 0.529 0.768 0.354

*, based on paired t test. P value <0.017 was considered to be significant, by Bonferroni correction for multiple comparisons. APAC, acute primary angle-closure; IOP, intraocular pressure; SE, Spherical equivalent; AL, axial length; D, diopter; CCT, corneal thickness; ACD, anterior chamber depth; ACW, anterior chamber width; ACV, anterior chamber volume; ACA, anterior chamber area; PD, pupil diameter; AOD750, angle opening distance at 750 μm from the scleral spur; TISA750, trabecular–iris space area at 750 μm from the scleral spur; IT750, anterior chamber volume; ARA, angle access area; IAREA, iris area; ICURV, iris curvature; LV, lens vault; RNFL, retinal nerve fiber layer; GCL+, ganglion cell layer plus; GCC, ganglion cell complex; CT, choroidal thickness.

table4

Table 4

Pearson correlation of various factors affecting the changes in the ACD

Factors ?ACD (baseline-2 weeks) ?ACD (baseline-1 month)
r P value r P value
Age, year 0.219 0.367 ?0.002 0.993
Baseline AL, mm 0.170 0.486 ?0.116 0.647
?CCT, μm ?0.191 0.479 ?0.066 0.794
?LV, mm ?0.947 0.001 ?0.547 0.028
?CT, μm 0.095 0.716 ?0.052 0.859

ACD, anterior chamber depth; LV, lens vault; CCT, corneal thickness; LV, lens vault; CT, choroidal thickness.

Association between choroidal thickness and anterior segment parameters

Uni- and multivariate linear regression analyses were performed (Table 5) to discover the relationship between choroidal thickness and anterior segment parameters in APAC-affected eyes. However, no association was found between choroidal thickness and ACD, ACA, AOD750, and LV in either the unadjusted or adjusted models (all P>0.05).

table5

Table 5

Association between choroidal thickness and anterior segment parameters in APAC-affected eyes

Unadjusted Adjusted*
β [95% CI] P value β [95% CI] P value
ACD, mm 132.4 [?52.3, 317.1] 0.151 76.7 [?101.1, 254.6] 0.377
ACA, mm2 17.8 [?11.0, 46.6] 0.205 18.9 [?16.0, 54.0] 0.252
AOD750, mm 449.0 [?261.1, 1159.2] 0.201 418.1 [?262.9, 1099.2] 0.210
LV, mm ?87.0 [?275.8, 101.7] 0.349 ?97.9 [?277.7, 81.7] 0.267

*, adjusted for age, gender, AL, IOP. APAC, acute primary angle-closure; ACD, anterior chamber depth; ACA, anterior chamber area; AOD750, angle opening distance at 750 μm from the scleral spur; LV, lens vault.


Discussion

In the present study, our aim was to achieve a better understanding of the anatomical characteristics of APAC eyes by incorporating concurrent AS-OCT and SS-OCT measurements. The present study findings confirmed that APAC-affected eyes had greater corneal thickness, shallower ACD, narrower angle, smaller ACA and IARE, less ICURVE, and larger LV than the fellow eyes. This is consistent with the results of recent AS-OCT study in Korean patients (7). The longitudinal follow-up observation of the structural features after iridectomy revealed that cornea thickness was significantly decreased at 1 month, while ACD, ACA, and AOD750 were significantly increased at 2 weeks and 1 month. These observations are similar to those of preliminary investigations that proposed an association between laser iridotomy and increases in central ACD [Gazzard, personal communication, quoted in Quigley et al. (12)]. However, no significant changes in posterior segment parameters (including RNFL, GCL+, GCC, retina, and choroidal thickness) were found over the 4-week period.

Previous studies have recommended that a shallower ACD has a higher risk for an acute attack (16,17). A shallower ACD has been considered as one of the main biometric parameters related with APAC during the attack (18). Our study showed that the ACD was smaller in the acute eyes than in the fellow eyes and that ACD was increased after iridectomy. This further accentuates the importance of a shallow ACD in terms of susceptibility to an acute attack, and suggests that APAC progression may be associated with changes in ACD. The ACD value is affected by the LV and posterior corneal surface height. In the present study, changes in ACD showed a correlation with decreasing LV. The importance of the LV in angle closure has been well established (16). Similar to our findings, Sng et al. demonstrated that the LV was a significant determinant of ACD, contributing 58% of its variability (17).

The reason for the shallower ACD and larger LV in affected eyes is still unclear. Positive correlation between LV with increasing age has been reported previously (19). Aging can increase lens thickness, which cause LV increases (20,21), yet this brings up another issue in regards to other different reasons for larger LV in the affected eye compared to the fellow eye within the same patient. Quigley et al. (12) have hypothesized choroidal expansion as a potential component for anterior lens movement. They theorized that choroidal expansion incidental with increase of intraocular volume could cause an immediate IOP increase.

In the present study, we used uni- and multivariate linear regression analyses to try to demonstrate the association between the choroidal thickness and anterior segment parameters in APAC-affected eyes. But no association between the choroidal thickness and the ACD and LV was found. In addition, the longitudinal follow-up observation revealed no significant association between changes in the ACD and choroidal thickness. The proposed mechanism of choroidal expansion as a possible physiological trigger accounting for APAC is biologically conceivable. However, this study did not give enough proof to support this mechanism.

Some potential limitations in our study should be mentioned. First, measurements were done after interventions for the acute attack, so potential trigger factors may already have resolved. The effect of glaucoma drugs may also have had a substantial effect on ocular biometry. Hence, the baseline measurements may only approximate the true baseline at the onset of the attack. This points out the difficulty in recognizing subtle physiological changes in such a dynamic situation. Second, surgical iridectomy is a significant confounder since this is an intraocular procedure that in itself may affect the ocular biometric characteristics. The iridectomies in the present study were performed by the same specialist to minimize potential surgical effects. Finally, all of these studies were conducted on Chinese individuals, so evaluation of this phenomenon in other populations would be interesting. Besides these limitations, valuable information still can be gained from this study. We believe that the results of this study will be useful in future studies about this topic.


Conclusions

In this study, we used AS-OCT and SS-OCT for concurrent measurements of anterior and posterior segment structural features of APAC. We found greater cornea thickness, shallower anterior chamber, narrower angle, less ICURVE, and larger LV in APAC-affected eyes than in fellow eyes. Iridectomy decreased the cornea thickness, while ACD, ACA, and AOD750 were significantly increased. An association analysis between choroidal thickness and anterior segment parameters revealed no any evidence to support the mechanism of choroidal expansion as a possible physiological trigger accounting for APAC.


1、Kasthurirangan S, Markwell EL, Atchison DA, Pope JM. MRI study of the changes in crystalline lens shape with accommodation and aging in humans. J Vis 2011;11:34. Kasthurirangan S, Markwell EL, Atchison DA, Pope JM. MRI study of the changes in crystalline lens shape with accommodation and aging in humans. J Vis 2011;11:34.
2、Praveen MR, Vasavada AR, Shah SK, et al. Lens thickness of Indian eyes: impact of isolated lens opacity, age, axial length, and influence on anterior chamber depth. Eye (Lond) 2009;23:1542-8. Praveen MR, Vasavada AR, Shah SK, et al. Lens thickness of Indian eyes: impact of isolated lens opacity, age, axial length, and influence on anterior chamber depth. Eye (Lond) 2009;23:1542-8.
3、Sun JH, Sung KR, Yun SC, et al. Factors associated with anterior chamber narrowing with age: an optical coherence tomography study. Invest Ophthalmol Vis Sci 2012;53:2607-10. Sun JH, Sung KR, Yun SC, et al. Factors associated with anterior chamber narrowing with age: an optical coherence tomography study. Invest Ophthalmol Vis Sci 2012;53:2607-10.
4、Sng CC, Aquino MC, Liao J, et al. Pretreatment anterior segment imaging during acute primary angle closure: insights into angle closure mechanisms in the acute phase. Ophthalmology 2014;121:119-25. Sng CC, Aquino MC, Liao J, et al. Pretreatment anterior segment imaging during acute primary angle closure: insights into angle closure mechanisms in the acute phase. Ophthalmology 2014;121:119-25.
5、Sng CC, Foo LL, Cheng CY, et al. Determinants of anterior chamber depth: the Singapore Chinese Eye Study. Ophthalmology 2012;119:1143-50. Sng CC, Foo LL, Cheng CY, et al. Determinants of anterior chamber depth: the Singapore Chinese Eye Study. Ophthalmology 2012;119:1143-50.
6、Moghimi S, Vahedian Z, Fakhraie G, et al. Ocular biometry in the subtypes of angle closure: an anterior segment optical coherence tomography study. Am J Ophthalmol 2013;155:664-73. Moghimi S, Vahedian Z, Fakhraie G, et al. Ocular biometry in the subtypes of angle closure: an anterior segment optical coherence tomography study. Am J Ophthalmol 2013;155:664-73.
7、Nongpiur ME, He M, Amerasinghe N, Friedman DS, Tay WT, Baskaran M, et al. Lens vault, thickness, and position in Chinese subjects with angle closure. Ophthalmology 2011;118:474-9. Nongpiur ME, He M, Amerasinghe N, Friedman DS, Tay WT, Baskaran M, et al. Lens vault, thickness, and position in Chinese subjects with angle closure. Ophthalmology 2011;118:474-9.
8、Huang W, Gao X, Li X, et al. Anterior and posterior ocular biometry in healthy Chinese subjects: data based on AS-OCT and SS-OCT. Plos One 2015;10:e0121740 Huang W, Gao X, Li X, et al. Anterior and posterior ocular biometry in healthy Chinese subjects: data based on AS-OCT and SS-OCT. Plos One 2015;10:e0121740
9、Quigley HA. Angle-closure glaucoma-simpler answers to complex mechanisms: LXVI Edward Jackson Memorial Lecture. Am J Ophthalmol 2009;148:657-69.e1. Quigley HA. Angle-closure glaucoma-simpler answers to complex mechanisms: LXVI Edward Jackson Memorial Lecture. Am J Ophthalmol 2009;148:657-69.e1.
10、Quigley HA, Friedman DS, Congdon NG. Possible mechanisms of primary angle-closure and malignant glaucoma. J GLAUCOMA 2003;12:167-80. Quigley HA, Friedman DS, Congdon NG. Possible mechanisms of primary angle-closure and malignant glaucoma. J GLAUCOMA 2003;12:167-80.
11、Wang W, Zhou M, Huang W, et al. Does acute primary angle-closure cause an increased choroidal thickness? Invest Ophthalmol Vis Sci 2013;54:3538-45. Wang W, Zhou M, Huang W, et al. Does acute primary angle-closure cause an increased choroidal thickness? Invest Ophthalmol Vis Sci 2013;54:3538-45.
12、Huang W, Wang W, Gao X, et al. Choroidal thickness in the subtypes of angle closure: an EDI-OCT study. Invest Ophthalmol Vis Sci 2013;54:7849-53. Huang W, Wang W, Gao X, et al. Choroidal thickness in the subtypes of angle closure: an EDI-OCT study. Invest Ophthalmol Vis Sci 2013;54:7849-53.
13、Shan J, DeBoer C, Xu BY. Anterior Segment Optical Coherence Tomography: Applications for Clinical Care and Scientific Research. Asia Pac J Ophthalmol (Phila) 2019;8:146-57. Shan J, DeBoer C, Xu BY. Anterior Segment Optical Coherence Tomography: Applications for Clinical Care and Scientific Research. Asia Pac J Ophthalmol (Phila) 2019;8:146-57.
14、Guzman CP, Gong T, Nongpiur ME, et al. Anterior segment optical coherence tomography parameters in subtypes of primary angle closure. Invest Ophthalmol Vis Sci 2013;54:5281-6. Guzman CP, Gong T, Nongpiur ME, et al. Anterior segment optical coherence tomography parameters in subtypes of primary angle closure. Invest Ophthalmol Vis Sci 2013;54:5281-6.
15、Lee JR, Sung KR, Han S. Comparison of anterior segment parameters between the acute primary angle closure eye and the fellow eye. Invest Ophthalmol Vis Sci 2014;55:3646-50. Lee JR, Sung KR, Han S. Comparison of anterior segment parameters between the acute primary angle closure eye and the fellow eye. Invest Ophthalmol Vis Sci 2014;55:3646-50.
16、Lowe RF. Aetiology of the anatomical basis for primary angle-closure glaucoma. Biometrical comparisons between normal eyes and eyes with primary angle-closure glaucoma. Br J Ophthalmol 1970;54:161-9. Lowe RF. Aetiology of the anatomical basis for primary angle-closure glaucoma. Biometrical comparisons between normal eyes and eyes with primary angle-closure glaucoma. Br J Ophthalmol 1970;54:161-9.
17、Alsbirk PH. Primary angle-closure glaucoma. Oculometry, epidemiology, and genetics in a high risk population. Acta Ophthalmol Suppl 1976;5-31. Alsbirk PH. Primary angle-closure glaucoma. Oculometry, epidemiology, and genetics in a high risk population. Acta Ophthalmol Suppl 1976;5-31.
18、Ang LP, Aung T, Chew PT. Acute primary angle closure in an Asian population: long-term outcome of the fellow eye after prophylactic laser peripheral iridotomy. Ophthalmology 2000;107:2092-6. Ang LP, Aung T, Chew PT. Acute primary angle closure in an Asian population: long-term outcome of the fellow eye after prophylactic laser peripheral iridotomy. Ophthalmology 2000;107:2092-6.
19、Aung T, Ang LP, Chan SP, Chew PT. Acute primary angle-closure: long-term intraocular pressure outcome in Asian eyes. Am J Ophthalmol 2001;131:7-12. Aung T, Ang LP, Chan SP, Chew PT. Acute primary angle-closure: long-term intraocular pressure outcome in Asian eyes. Am J Ophthalmol 2001;131:7-12.
20、Douglas GR, Drance SM, Schulzer M. The visual field and nerve head in angle-closure glaucoma. A comparison of the effects of acute and chronic angle closure. Arch Ophthalmol 1975;93:409-11. Douglas GR, Drance SM, Schulzer M. The visual field and nerve head in angle-closure glaucoma. A comparison of the effects of acute and chronic angle closure. Arch Ophthalmol 1975;93:409-11.
21、Pokhrel PK, Loftus SA. Ocular emergencies. Am Fam Physician 2007;76:829-36. Pokhrel PK, Loftus SA. Ocular emergencies. Am Fam Physician 2007;76:829-36.
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