Influence of Patient Age at Surgery on Long-Term Corneal Astigmatic Change Subsequent to Cataract Surgery KEN HAYASHI, SOICHIRO OGAWA, SHIN-ICHI MANABE, AND AKIRA HIRATA
PURPOSE:

To examine whether long-term corneal astigmatic change with age after cataract surgery depends on patient age at the time of surgery, and to evaluate whether this change is different from that in eyes that did not undergo surgery.
DESIGN: Retrospective cohort study.
METHODS: A total of 437 eyes that underwent phacoemulsification with a 4.1-mm horizontal corneoscleral incision more than 11 years ago and 600 control eyes without surgery were divided into 4 age groups: (1) 60 years or younger, (2) 61–65 years, (3) 66–70 years, and (4) 71 years or older. The corneal astigmatic change between baseline and 5 years after baseline, between 5 and 10 years, and between baseline and 10 years, as calculated using the polar (x-y) coordinate analysis, were compared among the age groups and between eyes with and without surgery.
RESULTS: Corneal astigmatic change, expressed as xand y-coordinates, showed an against-the-rule change of 0.2–0.4 diopter during the 10 years in all age groups of the surgery and nonsurgery groups. Using multivariate analysis of variance, the mean x- and y-coordinates did not differ significantly among the age groups in either the surgery or nonsurgery groups (P ‡ .4112). Furthermore, the mean x- and y-coordinates did not differ significantly between the surgery and nonsurgery groups in any age group (P ‡ .1359).
CONCLUSION: Long-term corneal astigmatic change with age after cataract surgery does not differ significantly depending on patient age at the time of surgery, and is comparable to that of eyes without surgery. (Am J Ophthalmol 2015;-:-–-. Ó 2015 by Elsevier Inc. All rights reserved.)

L

intraocular lens (IOL),1–4 a limbal relaxing incision,5,6 or an opposite clear corneal incision.7–9 Corneal astigmatism changes toward against-the-rule astigmatism, however, with advancing age throughout life.10–14 Accordingly, surgeons should understand how corneal astigmatism continues to change after stabilization of the induced astigmatic change following cataract surgery. Many studies with middle-term follow-up show that the surgically induced change in corneal astigmatism generally stabilizes within 1 year after sutureless cataract surgery.15–18 Long-term studies described by Rainer and associates19,20 and by Drews,21 however, report that corneal astigmatism continues to change toward the against-the-rule astigmatism for up to 5 years after superior incision cataract surgery, but it is possible that the later against-the-rule shift is attributable to aging. Indeed, our previous study revealed that corneal astigmatism shows an against-the-rule shift of approximately 0.2–0.4 diopter (D) within 10 years after stabilization of the induced astigmatism attributable to cataract surgery, and this change is comparable to that of eyes that did not undergo surgery.22 It remains unclear, however, whether this against-the-rule astigmatic change with age subsequent to the surgically induced change differed depending on the patient’s age at the time of cataract surgery. The purpose of the present study was to investigate whether long-term changes in corneal astigmatism with advancing age after cataract surgery differ depending on age at the time of surgery, and to evaluate whether the degree of this change differs from that in healthy eyes that did not undergo surgery. The results of the present study may provide surgeons clues to determine the amount of astigmatism that should remain according to the patient’s age at the time of cataract surgery.

ESS CORNEAL OR REFRACTIVE ASTIGMATISM IS

clearly associated with better uncorrected visual acuity (VA) after cataract surgery. To achieve sufficient uncorrected VA, recent advances in surgical techniques and devices are aimed at correcting preexisting astigmatism at the time of cataract surgery, including the toric Accepted for publication Apr 9, 2015. From the Hayashi Eye Hospital, Fukuoka, Japan. Inquiries to Ken Hayashi, Hayashi Eye Hospital, 4-23-35 Hakataekimae, Hakata-Ku, Fukuoka 812-0011, Japan; e-mail: [email protected] 0002-9394/$36.00 http://dx.doi.org/10.1016/j.ajo.2015.04.015

Ó

2015 BY

METHODS
PATIENTS: This was a retrospective cohort study. The medical records of all patients who had undergone sutureless phacoemulsification surgery with implantation of an IOL at the Hayashi Eye Hospital between May 2014 and August 2014 were consecutively reviewed. Only those eyes that underwent a follow-up of 11 years or longer from the time of cataract surgery were included (surgery

ELSEVIER INC. ALL

RIGHTS RESERVED.

1

group) in the study. Inclusion criteria for the surgery group were: (1) eyes that underwent phacoemulsification surgery with a 4.1-mm sutureless horizontal corneoscleral incision; (2) eyes that underwent at least 2 examinations by an autokeratometer at 1 year after surgery or later, and the difference between the 2 examinations was within 0.5 D in cylindrical power and within 615 degrees in the cylindrical axis (the latter examination was defined as baseline); (3) eyes that underwent examinations by the autokeratometer at approximately 5 and 10 years after baseline; (4) firstoperated eye if the patient had undergone bilateral cataract surgery; (5) eyes that had uneventful phacoemulsification surgery without sutures; (6) eyes with no comorbidity of the cornea, optic nerve, or macula; (7) eyes with no previous history of other surgery or inflammation; and (8) eyes without severe chronic eyelid disease during follow-up. Based on these criteria, a total of 437 eyes were identified, and divided into 4 age groups of (1) 60 years or younger, (2) 61–65 years, (3) 66–70 years, and (4) 71 years or older at the time of surgery. For controls for each age group, we recruited 150 eyes that did not undergo any ocular surgery during the 10 years or longer follow-up (nonsurgery group). Inclusion criteria for the nonsurgery group were (1) eyes that underwent examination by an autokeratometer at baseline, and at approximately 5 and 10 years after baseline; (2) eyes with no comorbidity of the cornea, optic nerve, or macula; (3) eyes with no history of other surgery or inflammation; and (4) eyes without severe chronic eyelid disease during follow-up. Eyes in the surgery group received a multi-piece hydrophobic acrylic IOL through a 4.1-mm straight horizontal corneoscleral incision. This research adhered to the tenets of the Declaration of Helsinki. The Institutional Review Board (IRB)/ethics committee of the Hayashi Eye Hospital, Fukuoka, Japan, at which the present study was conducted, approved the study protocol.
SURGICAL

PROCEDURES: A single surgeon (K.H.) performed all surgeries using essentially the same surgical procedure, as described previously.22,23 First, a continuous curvilinear capsulorrhexis measuring approximately 5.0 mm in diameter was accomplished using a 25 gauge bent needle through a side port. After continuous curvilinear capsulorrhexis, a corneoscleral incision was made horizontally at the meridian between 8 and 10 o’clock (temporally in the right eye and nasally in the left eye) for phacoemulsification. A 3.5-mm straight corneoscleral tunnel incision was made using a diamond knife (Huco, St-Blaise, Switzerland), a diamond crescent knife (Huco), and a 2.5mm stainless steel keratome (Inami, Tokyo, Japan). After hydrodissection, endocapsular phacoemulsification of the nucleus and aspiration of the residual cortex were conducted. The wound was enlarged to 4.1 mm using a stainless keratome (Alcon Laboratories, Fort Worth, Texas, USA) for implantation of an acrylic IOL using a diamond crescent knife. The lens capsule was inflated with 1% sodium hyaluronate (Healon; AMO, Santa Ana, California, USA), after which

2

an IOL was placed into the capsular bag using an IOL forceps (ASICO, Westmont, Illinois, USA). After the IOL was inserted, the viscoelastic material was thoroughly evacuated. No suture was placed in any case.
OUTCOME MEASURES:

Data on the eyes that underwent sutureless phacoemulsification surgery with a horizontal incision (surgery group) and on the control eyes that did not undergo surgery (nonsurgery group) were recorded. These data included corneal curvature at the steeper meridian and that at 90 degrees from the steeper meridian, as well as refractive spherical and cylindrical powers as measured using an autokeratometer (ARK-700A; NIDEK, Gamagori, Japan). The type of astigmatism (with-the-rule astigmatism, against-the-rule astigmatism, or oblique astigmatism), uncorrected or distance-corrected decimal VA, time interval between surgery and examination, length and type of incision, and type of IOL implanted were also recorded. Corneal astigmatism in which the steeper meridian was between 60 degrees and 120 degrees was defined as with-the-rule astigmatism, that in which the steeper meridian was between 0 degrees and 30 degrees or between 150 degrees and 180 degrees was defined as against-the-rule astigmatism, and that in which the steeper meridian was between 30 degrees and 60 degrees or between 120 degrees and 150 degrees was defined as oblique astigmatism. Decimal VA was converted to a logMAR scale for statistical analysis. The change in corneal astigmatism between baseline and 5 years after baseline, between 5 and 10 years after baseline, and between baseline and 10 years after baseline was analyzed using the polar (x-y) coordinate analysis, originally described by Naeser and Hjortdal.24 The surgically induced change in corneal astigmatism between the preoperative time point and baseline in the surgery group was also determined using the same method. The x-y coordinate analysis shows vertical (90 degrees) change in corneal astigmatism as the x-coordinate value (Rx) and torque (45 degrees) as the y-coordinate value (Ry). A positive Rx indicates a steepening of the vertical (90 degrees) corneal meridian—which is a with-the-rule change—while a negative Rx indicates a flattening of the vertical corneal meridian—which is an against-the-rule change. A positive Ry indicates a counterclockwise torque, while a negative Ry indicates a clockwise torque.


STATISTICAL ANALYSIS:

The normality of the data distribution was tested using the Kolmogorov-Smirnov test. Because Rx and Ry had normal distribution, the differences in Rx and Ry among the 4 age groups, between the surgery and nonsurgery groups, and between the left and right eyes were compared using multivariate analysis of variance (MANOVA). When a statistically significant difference was detected among the age groups, the difference between each group pair was compared using MANOVA for continuous variables and the x2 or Fisher exact test for categorical variables with Bonferroni adjustment for multiple

AMERICAN JOURNAL OF OPHTHALMOLOGY

--- 2015

TABLE 1. Patient Characteristics of Four Age Groups in Eyes That Underwent Cataract Surgery (Surgery Group) and Eyes That Did Not Undergo Cataract Surgery (Nonsurgery Group) Characteristic

60 years or younger Age (y) Sex (M/F) Left/right 61–65 years Age (y) Sex (M/F) Left/right 66–70 years Age (y) Sex (M/F) Left/right 71 years and older Age (y) Sex (M/F) Left/right

Surgery Group

Nonsurgery Group

57.2 6 2.3 47/66 55/58

57.0 6 2.1 61/89 73/77

P Value

.1580 .9800 >.9999

63.8 6 1.4 35/72 50/57

63.9 6 1.0 56/94 74/76

.9787 .5273 .7751

68.9 6 1.2 36/79 60/55

68.7 6 0.8 62/88 73/77

.0655 .1216 .6582

75.0 6 2.8 25/77 51/51

74.3 6 2.1 55/95 81/69

.0514 .0578 .6202

comparisons. Simple correlations between baseline age and the Rx or Ry were examined using Pearson correlation analysis. Because portions of the data regarding corneal astigmatism, and some of the other variables, were not normally distributed, corneal astigmatism, visual acuity, and the other continuous variables among the age groups were compared using the Kruskal-Wallis test, and between the surgery and nonsurgery groups using the MannWhitney U test. The number of eyes that had a with-therule, against-the-rule, or oblique corneal astigmatism and the other discrete variables were compared between the surgery and nonsurgery groups using the x2 or Fisher exact test, and among the 4 age groups using the x2 goodness-offit test. Differences with a P value of less than .05 were considered statistically significant.

RESULTS A TOTAL OF 437 EYES THAT UNDERWENT A 4.1-MM HORIZON-

tal corneoscleral incision were enrolled in the surgery group, while 600 eyes were enrolled in the nonsurgery group. Patient characteristics of the surgery group and the nonsurgery group in the 4 age groups are shown in Table 1. Age, sex, and the ratio of the left to right eyes did not differ significantly between the surgery and nonsurgery groups.
SURGICALLY INDUCED CORNEAL ASTIGMATISM IN THE SURGERY GROUP: The mean interval between surgery and

baseline was 13.4 6 2.3 months, ranging between 12 and 23 months. The length and type of incision were identical in all age groups. The surgically induced corneal astigmaVOL. -, NO. -

TABLE 2. Comparison of Induced Corneal Astigmatism After Cataract Surgery (X- and Y-Coordinate Value) Among the Four Age Groups

60 years or younger 61–65 years 66–70 years 71 years or older P value

X-Coordinate Value (D)

Y-Coordinate Value (D)

0.26 6 0.57 0.21 6 0.70 0.38 6 0.82 0.35 6 0.70

0.00 6 0.42 0.00 6 0.34 0.04 6 0.48 0.08 6 0.42 .4598a

D ¼ diopter. a No statistically significant difference using the multivariate analysis of variance.

tism expressed in Rx and Ry between preoperative astigmatism and that at baseline is shown in Table 2. The mean Rx between preoperative corneal astigmatism and that at baseline was 0.30 6 0.70 D, while the mean Ry was 0.03 6 0.42 D, which indicates that, on average, a with-the-rule astigmatic change and very small torque was induced by the cataract surgery. The mean Rx and Ry did not differ significantly among the 4 age groups (P ¼ .4598).
CORNEAL ASTIGMATISM AT BASELINE, 5 YEARS AFTER BASELINE, AND 10 YEARS AFTER BASELINE: In the surgery

group, the mean corneal astigmatism did not differ significantly among the 4 age groups preoperatively, at baseline, _ .3395). In the or at 5 and 10 years after baseline (P > nonsurgery group, the mean corneal astigmatism differed significantly among the age groups at baseline and at 5 _ .0465). The mean corneal and 10 years after baseline (P < astigmatism at baseline and at 5 years and 10 years after baseline was significantly greater in the surgery group than in the nonsurgery group in the 60 years or younger, _ .0493; 61–65 years, and 66–70 years age groups (P < Table 3), except in the 60 years or younger group at 5 years after baseline (P ¼ .1410), but did not differ significantly in _ .6369). the 71 years or older age group (P >
CHANGES IN CORNEAL ASTIGMATISM DURING 5 YEARS AND 10 YEARS AFTER BASELINE: In both the surgery and

nonsurgery groups, the mean Rx was a negative value of approximately 0.1 to 0.2 D between baseline and 5 years after baseline and between 5 and 10 years after baseline, and approximately 0.2 to 0.4 D between baseline and 10 years after baseline in the 4 age groups, which indicates an against-the-rule change in all age groups. The mean Ry was small in all age groups of the surgery and nonsurgery groups, which indicates a slight torque. In both the surgery (Figure 1) and nonsurgery groups (Figure 2), no significant differences were detected among the 4 age groups in the mean Rx and Ry between baseline and 5 years after baseline, between 5 and 10 _ .4112). years, and between baseline and 10 years (P >

AGE DIFFERENCE IN ASTIGMATIC CHANGES AFTER CATARACT SURGERY

3

TABLE 3. Comparison of Mean Corneal Astigmatism of Four Age Groups in Eyes That Underwent Cataract Surgery (Surgery Group) and Eyes That Did Not Undergo Surgery (Nonsurgery Group) Surgery Group

60 years and younger Baseline (D) 5 years after baseline (D) 10 years after baseline (D) 60–65 years Baseline (D) 5 years after baseline (D) 10 years after baseline (D) 66–70 years Baseline (D) 5 years after baseline (D) 10 years after baseline (D) 71 years or older Baseline (D) 5 years after baseline (D) 10 years after baseline (D)

Nonsurgery Group

P Value

1.04 6 0.64 0.84 6 0.60 1.03 6 0.77 0.87 6 0.60 1.01 6 0.73 0.81 6 0.58

.0461a .1410 .0116a

1.00 6 0.76 0.68 6 0.34 0.96 6 0.66 0.72 6 0.38 1.02 6 0.76 0.76 6 0.44

.0044a .0120a .0493a

1.03 6 0.73 0.72 6 0.50

FIGURE 4. Comparison of the number and percentage of eyes showing a with-the-rule (WTR), against-the-rule (ATR), or oblique astigmatism between baseline and 10 years after baseline in 4 age groups in eyes that did not undergo cataract surgery. In eyes that did not undergo surgery, the percentage of eyes with against-the-rule and oblique astigmatism increased during 10 years, while with-the-rule astigmatism decreased; the distribution of astigmatism between the baseline and 10 years after baseline differed significantly in all age groups. *Statistically significant difference.

group and was significantly greater in the nonsurgery group _ .0041). in the left eyes than in the right eyes (P <
VISUAL ACUITY:

In both the surgery and nonsurgery groups, mean distance-corrected visual acuity worsened with advancing age at baseline and at 5 and 10 years after baseline; the difference among the 4 age groups was _ .0269; Table 5). Mean statistically significant (P < distance-corrected visual acuity was significantly better in the surgery group than in the nonsurgery group in all age groups (P < .0001).

DISCUSSION THE FINDINGS OF THE PRESENT STUDY DEMONSTRATED


DIFFERENCE IN CORNEAL ASTIGMATIC CHANGE BETWEEN THE LEFT AND RIGHT EYES: The mean surgi-

cally induced corneal astigmatism between surgery and baseline was significantly greater in the left eyes than in the right eyes (P ¼ .0153). The mean Rx and Ry were significantly different between the left and right eyes in the time interval between baseline and 10 years after baseline in the surgery (P ¼ .0113) and nonsurgery groups (P < .0001, Figure 5). Based on univariate comparison, the mean Rx did not differ significantly between the left and right eyes in the time interval between baseline and 10 years _ .1195), in either the surgery or nonsurgery groups (P > while the mean Ry was significantly lower in the surgery VOL. -, NO. -

that long-term change in corneal astigmatism after stabilization of surgically induced corneal astigmatism showed an against-the-rule shift of approximately 0.2–0.4 D during 10 years in the 60 years or younger, 61–65 years, 66–70 years, and 71 years or older age groups. This against-the-rule change in corneal astigmatism during 10 years did not differ significantly among the 4 age groups. Furthermore, the actual age at baseline was not significantly correlated with the corneal astigmatic change during the 10-year follow-up. These findings suggest that age at the time of cataract surgery does not affect the long-term corneal astigmatic change over time subsequent to stabilization of a surgically induced astigmatism.

AGE DIFFERENCE IN ASTIGMATIC CHANGES AFTER CATARACT SURGERY

5

TABLE 5. Comparison of Distance-Corrected Visual Acuity Expressed in Logarithm of Minimal Angle of Resolution Scale Among Four Age Groups and Between Eyes That Underwent Cataract Surgery (Surgery Group) and Eyes That Did Not Undergo Surgery (Nonsurgery Group) Surgery Group Nonsurgery Group

FIGURE 5. Multivariate comparison of the mean x- and y-coordinate values between the left and right eyes. Mean x- (Rx) and y-coordinate (Ry) values differed significantly between the left and right eyes in the time interval between baseline and 10 years after baseline in the surgery and nonsurgery groups. *Statistically significant difference. D, diopter.

Eyes that did not undergo surgery also presented the against-the-rule shift during the 10 years after baseline in all 4 age groups; the degree of this against-the-rule shift during 10 years did not differ significantly among the 4 age groups. Furthermore, when comparing eyes with and without surgery, no significant difference was found in the corneal astigmatic change during the 10 years in all age groups. These findings suggest that the long-term corneal astigmatic change with age in eyes that underwent cataract surgery is comparable to that in eyes that did not undergo cataract surgery. The percentage of with-the-rule, against-the-rule, or oblique astigmatism changed significantly during the 10-year follow-up in both the surgery and nonsurgery groups among the 4 age classifications. In all age groups, eyes with the against-the-rule and oblique astigmatism increased during the 10 years, while eyes with the with-the-rule astigmatism decreased. The percentage of against-the-rule astigmatism did not increase markedly in the 66–70 years and 71 years and older age groups because eyes with the against-therule astigmatism are basically predominant at these ages. When comparing the eyes with and without surgery, however, the percentage of with-the-rule astigmatism was greater and that of the against-the-rule astigmatism was less in the surgery group than in the nonsurgery group in the 61–65 years, 66–70 years, and 71 years and older age groups, although there was no significant difference in the 60 years and younger age group. This result was attributed to the corneal astigmatic change toward with-the-rule astigmatism attributable to sutureless horizontal incision cataract surgery. Moreover, it is conceivable that the percentage of with-therule, against-the-rule, and oblique astigmatism did not differ significantly between eyes with and without surgery in the 60 6

Baseline 60 years and younger 61–65 years 66–70 years 71 years and older P value 5 years after baseline 60 years and younger 61–65 years 66–70 years 71 years and older P value 10 years after baseline 60 years and younger 61–65 years 66–70 years 71 years and older P value

P Value

0.03 6 0.13 0.04 6 0.12 0.02 6 0.10 0.07 6 0.12 0.02 6 0.08 0.10 6 0.13 0.03 6 0.08 0.14 6 0.11 .0269b