Pakistan Journal of Ophthalmology Vol. 30, No. 3, Jul – Sep, 2014      156 

Original Article 

 

Comparison of Pre and Postoperative 
Astigmatism after Cataract Extraction by 
Phacoemulsification through a 3.2 MM 
Clear Corneal Superotemporal Incision 
 
M. Shakaib Anwar 

 
Pak J Ophthalmol 2014, Vol. 30 No. 3 

 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .. . .. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .  . .  
See end of article for 
authors affiliations 
 
…..……………………….. 
 
Correspondence to: 
M. Shakaib Anwar 
Ophthalmology. Department 
Rawal Institute of Health 
Sciences 
Khana Dak Lehtrar Road. 
Islamabad. 
E mail: 
shakaib_2001@yahoo.co.uk 
 
 
 
 
 
 
 
 
 
 
 

…..……………………….. 

Purpose: To evaluate the difference between pre and postoperative astigmatism 
in patients undergoing cataract extraction by phacoemulsification with intraocular 
lens implantation through 3.2 mm superotemporal clear corneal incision. 

Material and Methods: A prospective study was performed on 144 eyes of 132 
patients. They were operated upon for cataract between 12/01/2007 and 
31/12/2012 by a single eye surgeon at a private set up. Follow up period was 
from 6 month to five years (mean 33 months). The patients included in this 
study, underwent cataract surgery by phacoemulsification through 3.2 mm 
superotemporal clear corneal incision. Their mean age at the time of surgery  
was 50.5 years (range: 25  to 76 years). They were divided into two groups 
depending upon, “With the Rule” (Group A) or “Against the Rule”(Group B),  pre 
operative astigmatism. 

Results: Before surgery, mean astigmatism in group A patients was -0.83 D 
(Diopter) and in those of group B was -0.76 D. After the surgery, mean 
astigmatism in group A patients was -1.10 D and in those of group B was -1.10 
D. The mean increase in astigmatism post operatively in the two groups was 
0.27 D and 0.34 D respectively. 

Conclusion: Superotemporal clear corneal incision of 3.2 mm size is favourable 
in terms of wound stability and the final optical outcome. When followed up over 
a long time, the post operative astigmatism approaches almost the preoperative 
value although there may be a negligible increase in it. 

Key words: Astigmatism, Phacoemulsification, Intraocular lens. 

 
hacoemulsification, and foldable IOLs, have 
made cataract surgery through a small incision 
possible1-3. Rapid and stable optical recovery is 

achieved by preventing significant changes in corneal 
curvature. The smaller incision size induces less 
postoperative astigmatism.1,4,5 The clear corneal 
incision technique was introduced by Fine. This has 
lead to increased safety, decreased pain, inflammation 
and surgically induced astigmatism (SIA).6 

A positive SIA (horizontal positive cylinder) 
means “against the rule” change while a negative SIA 

(horizontal negative cylinder) signifies a “with the 
rule” change.14 

Visual outcome after cataract surgery is 
significantly affected by the preexisting astigmatism 
and the one induced by the surgery itself. Usually, in 
young people cornea is steepest in its vertical 
meridian, i.e. AWR (horizontal negative cylinder). 
With the advancing age there is a shift to ATR 
astigmatism (horizontal positive cylinder). In cataract 
age group we mostly find ATR astigmatism. 

P 



M. SHAKAIB ANWAR 

157      Vol. 30, No. 3, Jul – Sep, 2014 Pakistan Journal of Ophthalmology 

Modern techniques in cataract surgery aim to 
achieve optimum uncorrected visual acuity (UCVA). 
Different sites and sizes of incisions have been tried to 
reduce pre-existing astigmatism which adds to the 
total post operative astigmatism. A small incision 
leads to less astigmatism postoperatively.2,7-11 Mostly 
superior or temporal approaches are preferred by the 
surgeons. When the preoperative corneal astigmatism 
is significant, incision can be placed on the steeper 
corneal meridian (parallel to negative cylinder or on 
the positive cylinder axis) to reduce overall 
postoperative astigmatism. Surgically induced astig-
matism with small incision surgery is significantly 
lower if incision is placed posteriorly nearer to the 
limbus12. The size, shape, and place of the incision 
influence surgically induced astigmatism. It has an 
important bearing on the corneal stability13. 

A medium sized (3.2 mm) superotemporal clear 
corneal incision has the advantage of its size and site. 
This size does not allow the wound lips to undergo 
unnecessary stretching, while injecting the IOL, 
avoiding increase and change in axis of the 
preoperative astigmatism14. The superotemporal site 
of the incision in the oblique meridian, in fact, has a 
positive effect on both types of astigmatisms as the 
steepest meridians are not usually exactly at 180 or 90 
degrees15, rather these lie in between and have a 
relative vertical or relative horizontal positions as we 
have considered in our study. 

Generally, a clear corneal incision placed 
superotemporally leads to smaller postoperative 
astigmatism by flattening the horizontal corneal axis. 
This has an advantage as ATR astigmatism is common 
in older age group16. 

Another factor, which can influence the expected 
out come is axis in which the IOL haptics are placed. If 
the IOL haptics are placed at 180°, pre-existing WTR 
astigmatism can be reduced and vice versa17. These 
days toric intraocular lenses can reduce preexisting 
astigmatism quite effectively18. Femtosecond laser 
assisted cataract surgery further promises better 
incision  morphology and stability thereby reducing 
chances of post operative astigmatism19. 

 
MATERIAL AND METHODS 

A retrospective study was performed on 144 eyes of 
132 patients. They were operated upon for cataract 
with intraocular lens implantation from 12 Jan 2007 to 
31 Dec 2012 with a follow up period of 6 month to five 
years (mean 33 months). The patients underwent 

cataract surgery by phacoemulsification through 3.2 
mm superotemporal clear corneal incision (approx. 
0.5mm central to the limbus). At the time of surgery 
their mean age was 50.5 years (range: 25 to 76 years). 
They were divided into two groups depending upon, 
“With the Rule” (Group A) or “Against the Rule” 
(Group B). In group A, mean astigmatism before 
surgery was - 0.83 D while it was -0.76 D in group B. 

WTR astigmatism (negative cylinder in the 
horizontal axis) was considered to be the one in the 
meridian between 60 and 120 degrees and ATR 
(negative cylinder in the vertical axis) in the meridian 
between 1 and 30 degrees and 150 and 180 degrees. 
Astigmatism other than these was classified as 
oblique. 

The patients with oblique or irregular astigmatism 
were not included in the study. Similarly the patient 
who had undergone filtration, refractive or pterygium 
excision surgery or had corneal scaring and opacities, 
very high or irregular preoperative astigmatism, were 
also not included in this study. 

Intraocular lens calculations were performed 
using A-scan ultrasonography (Quantel Medical 11 M 
Hz) for axial length measurements and keratometry 
using Topcon KR 8800 digital autokerato-
refractometer. After administering peribulbar local 
anaesthesia with 2% lignocane with 1:200,000 
adrenaline, in all the cases a clear corneal supero-
temporal (10-11 clock) incision (approx 0.50 mm 
central to the limbus) was made using a 3.2 mm true 
cut keratome. A continuous curvilinear capsulorhexis 
was performed with cystitome. Phacoemulsifation was 
performed using system (Ammerican Optics Inc.) 
machine with 19 Ga 30 degree tip. All patients 
implanted with single piece, foldable acrylic IOL with 
an optical diameter of 6.0 mm (total diameter of 
13.0mm), placed in the capsular bag. 

All patients were treated postoperatively with a 
combination of dexamethasone 0.1 % and tobramycin 
0.3%, three hourly for the first week and then six and 
eight hourly over the three subsequent weeks. Topical 
ofloxacin was given 6 hourly for 1 week 
postoperatively. 

Follow up for evaluation of astigmatism was 
performed on Topcon KR 8800 autokerato-refracto-
meter from three months onwards after surgery. 

 
RESULTS 

Mean preoperative astigmatism in group A (45 
patients) was - 0.83 and in group B (99 patients) was - 



COMPARISON OF PRE AND POSTOPERATIVE ASTIGMATISM AFTER CATARACT EXTRACTION BY PHACOEMULSIFICATION 

Pakistan Journal of Ophthalmology Vol. 30, No. 3, Jul – Sep, 2014      158 

0.76 (Table 1). In group A and and B, the mean and 
median postoperative astigmatism were -1.10 and 0.75 
diopters respectively. The mean increase in 
astigmatism post operatively in the two groups was 
0.27 and 0.34 and the median increase was 0.50 and 
0.25 diopters respectively over 6 months to 5 years 
follow up (Table 1-3). This showed a slight shift 
toward WTR astigmatism post operatively. In group 
A, 15 (33.33%) cases showed an increase in 
astigmatism while 9 (20%) remained unchanged, 9 
(20%) converted to ATR astigmatism, 6 (13.33%) 

neutralized and 6 (13.33%) experienced a decrease in 
WTR astigmatism. In group B, 60 (62.50%) cases 
showed an increase in astigmatism while 9 (9.37%) 
remained unchanged, 12 (12.50%) converted to WTR 
astigmatism, 3 (3.12%) neutralized and 12 (12.50%) 
experienced a decrease in ATR astigmatism (Table 4). 
In group A 24 (53.33%) eyes showed a clockwise shift 
in the axis (median 11 degrees) and 9 (20%) eyes 
showed an anti-clockwise shift (median 20 degrees). In 
group B 27 (28.12%) eyes showed a clockwise shift in 
the axis (median 14 degrees) and 51(53.12%) eyes

 

 



M. SHAKAIB ANWAR 

159      Vol. 30, No. 3, Jul – Sep, 2014 Pakistan Journal of Ophthalmology 

 

 
showed an anti-clockwise shift (median 7 degrees) 
(Table 5). The rest did not show any shift. 

 
DISCUSSION 

In our study we have found that a superotemporal 
(10-11 O’ clock) 3.2 mm incision hardly causes any 
astigmatism or induces any significant change in the 
existing preoperative astigmatism, i.e. less than 0.50 
diopters generally, when followed over a longer 
period of time. This correlates with a similar study 
carried out by S C Moon et al14. However the median 
value showed a slightly more shift on the WTR side 
(Table 2&3). 

Regarding the toric shift, most of the cases in 
group A showed a clockwise shift (median 7 degrees) 
while in group A the trend was opposite (median shift 
8 degrees) in most of the cases (Table 5). This shift is 
not very significant during refraction and prescription 
of glasses. Less number of cases in both the groups 
showed wider shift (14-20 degrees). This concluded a 
minor overall change in the keratometric readings 
although the incision was made through the clear 
cornea. 

Our patients showed a slight shift towards higher 
median WTR astigmatism with the passage of time. 
Different studies have demonstrated flattening of the 
cornea along the incisional meridian14. This leads to 
WTR astigmatic changes with a temporal incision20,21, 
comparable with the results of our study. 

In a similar study where keratometric analysis of 
corneal astigmatism was done after surgery and a 
comparison was done between two groups 
undergoing phacoemulsification through supero-
temporal corneal incision and superior scleral incision. 
The former did not increase keratometric corneal 
astigmatism more than the one by superior scleral 
incision after three months of operation22. 

The incision length and location have a bearing on 
the changes in the horizontal and vertical meridians of 
the cornea after cataract surgery. This study was also 

affected by these two factors. This fact is also 
supported by two other similar studies; small 
temporal incisions induced less change than superior 
incisions14,23. 

 
CONCLUSION 

Superotemporal, 3.2 mm clear corneal incision is quite 
stable and does not significantly increase post 
operative astigmatism when followed up over a long 
(several months to years) period of time. This size and 
site of the incision have also proved to be superior to 
smaller or larger and superior or scleral incisions 
respectively. 

One limitation of this study was that 27 patients 
did not return for follow up at their designated times. 

 
Author’s Affiliation 

Dr. M. Shakaib Anwar 
Associate Professor of Ophthalmology 
Rawal Institute of Health Sciences 
Khana Dak Lehtrar Road 
Islamabad 
E mail: shakaib_2001@yahoo.co.uk 

 
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