BioMed Central
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BJB��'o� BMC Ophthalmology
PZ�
AyHXY Research article Open Access
qI5_@[�S*� Comparison of age-specific cataract prevalence in two
'>�@�e�vrG population-based surveys 6 years apart
Z��Z�X|MA! Ava Grace Tan†, Jie Jin Wang*†, Elena Rochtchina† and Paul Mitchell†
l]uF!']��f Address: Centre for Vision Research, Westmead Millennium Institute, Department of Ophthalmology, University of Sydney, Westmead Hospital,
wH�Et;�rc( Westmead, NSW, Australia
�O�LX�G0@� Email: Ava Grace Tan -
ava_tan@wmi.usyd.edu.au; Jie Jin Wang* -
jiejin_wang@wmi.usyd.edu.au;
9V�9K3x�Wn Elena Rochtchina -
elena_rochtchina@wmi.usyd.edu.au; Paul Mitchell -
paul_mitchell@wmi.usyd.edu.au hDSt6O4�za * Corresponding author †Equal contributors
R]/3`X9!d> Abstract
J)"2^?�!&B Background: In this study, we aimed to compare age-specific cortical, nuclear and posterior
�sV�%<U-�X subcapsular (PSC) cataract prevalence in two surveys 6 years apart.
B#�O�nooJI Methods: The Blue Mountains Eye Study examined 3654 participants (82.4% of those eligible) in
�
�|'aG�j cross-section I (1992–4) and 3509 participants (75.1% of survivors and 85.2% of newly eligible) in
�Uz�} #.�� cross-section II (1997–2000, 66.5% overlap with cross-section I). Cataract was assessed from lens
�Wj(
O_�2
photographs following the Wisconsin Cataract Grading System. Cortical cataract was defined if
)R(kX�z=M� cortical opacity comprised ≥ 5% of lens area. Nuclear cataract was defined if nuclear opacity ≥
gp`$�/�c�i Wisconsin standard 4. PSC was defined if any present. Any cataract was defined to include persons
K�7 -A�VMY who had previous cataract surgery. Weighted kappa for inter-grader reliability was 0.82, 0.55 and
�H�QCx�O?� 0.82 for cortical, nuclear and PSC cataract, respectively. We assessed age-specific prevalence using
�!D!��~4h) an interval of 5 years, so that participants within each age group were independent between the
a`
� s2 z two surveys.
nm`[�\3��R Results: Age and gender distributions were similar between the two populations. The age-specific
#^|y0��:�
prevalence of cortical (23.8% in 1st, 23.7% in 2nd) and PSC cataract (6.3%, 6.0%) was similar. The
,.A@�U*�j� prevalence of nuclear cataract increased slightly from 18.7% to 23.9%. After age standardization,
/�Nt#|�C>� the similar prevalence of cortical (23.8%, 23.5%) and PSC cataract (6.3%, 5.9%), and the increased
�MxQhk�Y-= prevalence of nuclear cataract (18.7%, 24.2%) remained.
WY��Sqnm�i Conclusion: In two surveys of two population-based samples with similar age and gender
Ti��$G2dBO distributions, we found a relatively stable cortical and PSC cataract prevalence over a 6-year period.
%UT5KYd!=N The increased prevalence of nuclear cataract deserves further study.
-K� eo���q Background
� :tB�Io�7 Age-related cataract is the leading cause of reversible visual
#�.L9/b(�
impairment in older persons [1-6]. In Australia, it is
b"H�
c==` estimated that by the year 2021, the number of people
f>!)y�-��7 affected by cataract will increase by 63%, due to population
kw{dv�E\K aging [7]. Surgical intervention is an effective treatment
x�vw���@'| for cataract and normal vision (> 20/40) can usually
n_QSuh/W�n be restored with intraocular lens (IOL) implantation.
_N)/X|=~s� Cataract surgery with IOL implantation is currently the
m�#1��>y�} most commonly performed, and is, arguably, the most
'5V}�Z3zJ/ cost effective surgical procedure worldwide. Performance
\kWL:�u��U Published: 20 April 2006
Pt5"q3ec{T BMC Ophthalmology 2006, 6:17 doi:10.1186/1471-2415-6-17
��]8@s+��N Received: 14 December 2005
����fE`�p Accepted: 20 April 2006
E+z)�,"�QA This article is available from:
http://www.biomedcentral.com/1471-2415/6/17 ��Q�\Wh]=} © 2006 Tan et al; licensee BioMed Central Ltd.
C��2t�] � This is an Open Access article distributed under the terms of the Creative Commons Attribution License (
http://creativecommons.org/licenses/by/2.0),
n�cTPFv
H5 which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
f euAT�
L] BMC Ophthalmology 2006, 6:17
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43wm_4C�!H of this surgical procedure has been continuously increasing
$40�G$w��� in the last two decades. Data from the Australian
^�AhV1rBB� Health Insurance Commission has shown a steady
5�PY4PT=�G increase in Medicare claims for cataract surgery [8]. A 2.6-
6-E>-9�]'E fold increase in the total number of cataract procedures
��@��TJx�U from 1985 to 1994 has been documented in Australia [9].
�5
w-Pq&�q The rate of cataract surgery per thousand persons aged 65
�J.;!��l � years or older has doubled in the last 20 years [8,9]. In the
='A VI-go5 Blue Mountains Eye Study population, we observed a onethird
Es�<�&�� 6 increase in cataract surgery prevalence over a mean
b~$�8��<\ 6-year interval, from 6% to nearly 8% in two cross-sectional
�e5AZU7%�. population-based samples with a similar age range
h"0)g��:\� [10]. Further increases in cataract surgery performance
��[K�Q�#�b would be expected as a result of improved surgical skills
!;3h�N$5�� and technique, together with extending cataract surgical
A"tE~�m;"7 benefits to a greater number of older people and an
�6Y`rQ/��F increased number of persons with surgery performed on
E�3��hXs6P both eyes.
LZtO Q__B) Both the prevalence and incidence of age-related cataract
C�'~�E�q�3 link directly to the demand for, and the outcome of, cataract
lvAK�L�>qX surgery and eye health care provision. This report
;n��q"��jm aimed to assess temporal changes in the prevalence of cortical
���R ;k1(p and nuclear cataract and posterior subcapsular cataract
�%i�6/=
'u (PSC) in two cross-sectional population-based
\@[�Y���~: surveys 6 years apart.
!�'eh@B�U; Methods
d>gQgQ;��g The Blue Mountains Eye Study (BMES) is a populationbased
}}�qY,@eeX cohort study of common eye diseases and other
�.],:pL9�d health outcomes. The study involved eligible permanent
HV&i! M@T� residents aged 49 years and older, living in two postcode
;il+C!6zpf areas in the Blue Mountains, west of Sydney, Australia.
k4��d;4D�? Participants were identified through a census and were
�p;qFMzyS9 invited to participate. The study was approved at each
(A� )f
r4� stage of the data collection by the Human Ethics Committees
XXw>�h�4hl of the University of Sydney and the Western Sydney
7{��tU'`P> Area Health Service and adhered to the recommendations
���e�Z]>;5 of the Declaration of Helsinki. Written informed consent
�<(t{C8>g% was obtained from each participant.
:�q��>)c]� Details of the methods used in this study have been
u9{SG�^��� described previously [11]. The baseline examinations
`PZ\3SC'i (BMES cross-section I) were conducted during 1992–
Sd�F+�b+P] 1994 and included 3654 (82.4%) of 4433 eligible residents.
�cA+T�-�A] Follow-up examinations (BMES IIA) were conducted
p�//mV�H�% during 1997–1999, with 2335 (75.0% of BMES
|!81�M|��H cross section I survivors) participating. A repeat census of
Gkx�Q�E�L� the same area was performed in 1999 and identified 1378
d/�3bE*gr
newly eligible residents who moved into the area or the
6i;�q=N$'� eligible age group. During 1999–2000, 1174 (85.2%) of
�Py?e+�[cN this group participated in an extension study (BMES IIB).
ay
�=B<|�! BMES cross-section II thus includes BMES IIA (66.5%)
L�=<$^�m�� and BMES IIB (33.5%) participants (n = 3509).
R��, #szTu Similar procedures were used for all stages of data collection
B�8u�nF�=u at both surveys. A questionnaire was administered
m70A�WG��� including demographic, family and medical history. A
'�py�IMB?x detailed eye examination included subjective refraction,
��� f��,kV slit-lamp (Topcon SL-7e camera, Topcon Optical Co,
<00nu'Ex1v Tokyo, Japan) and retroillumination (Neitz CT-R camera,
�-'��}�#j\ Neitz Instrument Co, Tokyo, Japan) photography of the
\PD�%=���~ lens. Grading of lens photographs in the BMES has been
2I3H?Lrx!m previously described [12]. Briefly, masked grading was
)6B�
��ySk performed on the lens photographs using the Wisconsin
h�@]�{j_$u Cataract Grading System [13]. Cortical cataract and PSC
L8f_^
�*,� were assessed from the retroillumination photographs by
W0;�Qu�f�V estimating the percentage of the circular grid involved.
]N,'3`&::� Cortical cataract was defined when cortical opacity
u�P$�i2�Cy involved at least 5% of the total lens area. PSC was defined
x[fp7*�TiG when opacity comprised at least 1% of the total lens area.
<Qr*!�-Kc6 Slit-lamp photographs were used to assess nuclear cataract
M�?��Fv'YE using the Wisconsin standard set of four lens photographs
A�
k~|r#@� [13]. Nuclear cataract was defined when nuclear opacity
C��8��do8$ was at least as great as the standard 4 photograph. Any cataract
4`'Rm/�)�� was defined to include persons who had previous
mKE'�l'9A_ cataract surgery as well as those with any of three cataract
EiP N�44(� types. Inter-grader reliability was high, with weighted
lYS���� �" kappa 0.82 for cortical cataract, 0.55 (simple kappa 0.75)
�n�ET�<u;� for nuclear cataract and 0.82 for PSC grading. The intragrader
S|;�}��]6p reliability for nuclear cataract was assessed with
oiM�['iDK� simple kappa 0.83 for the senior grader who graded
F&#I�[]#
� nuclear cataract at both surveys. All PSC cases were confirmed
J*z�Q8\f=} by an ophthalmologist (PM).
�S�;/pm$?/ In cross-section I, 219 persons (6.0%) had missing or
s0�CDp"uJY ungradable Neitz photographs, leaving 3435 with photographs
"r8N-
h/P� available for cortical cataract and PSC assessment,
_,v>�P2)� while 1153 (31.6%) had randomly missing or ungradable
3g56[;Up?� Topcon photographs due to a camera malfunction, leaving
I��~E&�::, 2501 with photographs available for nuclear cataract
T�!�p�A$eE assessment. Comparison of characteristics between participants
+;*4�.}�� with and without Neitz or Topcon photographs in
J�9f�]=�1` cross-section I showed no statistically significant differences
!�[�eY%2;< between the two groups, as reported previously
L^�PBcf��g [12]. In cross-section II, 441 persons (12.5%) had missing
>6W�#��v�[ or ungradable Neitz photographs, leaving 3068 for cortical
���EY.m,@{ cataract and PSC assessment, and 648 (18.5%) had
{%�RwZ��'
missing or ungradable Topcon photographs, leaving 2860
��b��\��kA for nuclear cataract assessment.
�&O�kPO�|� Data analysis was performed using the Statistical Analysis
�}���7K~-� System (SAS, SAS Institute, Cary, NC, USA). Age-adjusted
]3���Ibl^J prevalence was calculated using direct standardization of
C[�l5[�DpH the cross-section II population to the cross-section I population.
kY9$� M8�b We assessed age-specific prevalence using an
3hE��bM'�L interval of 5 years, so that participants within each age
hBifn\dF�r group were independent between the two cross-sectional
dB QCr{7�� surveys.
yMmUOIxk�\ BMC Ophthalmology 2006, 6:17
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�5�{IbKj�| Results
�r�%>7n,+o Characteristics of the two survey populations have been
�7�{k?"�NF previously compared [14] and showed that age and sex
f�P8�bWZ�{ distributions were similar. Table 1 compares participant
Po.�by�~|� characteristics between the two cross-sections. Cross-section
1zCgPiAe�m II participants generally had higher rates of diabetes,
dQ��AF;�L� hypertension, myopia and more users of inhaled steroids.
QF22_D<.}J Cataract prevalence rates in cross-sections I and II are
^X"x,�8}&V shown in Figure 1. The overall prevalence of cortical cataract
�5`i�+a�H( was 23.8% and 23.7% in cross-sections I and II,
'�z=���d&K respectively (age-sex adjusted P = 0.81). Corresponding
*Uf�>�X�r& prevalence of PSC was 6.3% and 6.0% for the two crosssections
������YM
. (age-sex adjusted P = 0.60). There was an
�mg�od��vX increased prevalence of nuclear cataract, from 18.7% in
6T�XTJ�]er cross-section I to 23.9% in cross-section II over the 6-year
��^ ]+vt�k period (age-sex adjusted P < 0.001). Prevalence of any cataract
���[9F���� (including persons who had cataract surgery), however,
tbf�w��gK� was relatively stable (46.9% and 46.8% in crosssections
I�=
c�ayR I and II, respectively).
^V]��IPGV� After age-standardization, these prevalence rates remained
LW9�F%?e!> stable for cortical cataract (23.8% and 23.5% in the two
b�?,�=�|�H surveys) and PSC (6.3% and 5.9%). The slightly increased
K�*p3�#iB� prevalence of nuclear cataract (from 18.7% to 24.2%) was
4��AF.K�X7 not altered.
k�%a�J�%�( Table 2 shows the age-specific prevalence rates for cortical
e�5'U[�bQm cataract, PSC and nuclear cataract in cross-sections I and
X/���m�
~^ II. A similar trend of increasing cataract prevalence with
f��9)0�OHa increasing age was evident for all three types of cataract in
_?eT[!o�O8 both surveys. Comparing the age-specific prevalence
M�~�+DxnJ= between the two surveys, a reduction in PSC prevalence in
CW���.T�`F cross-section II was observed in the older age groups (≥ 75
#3A|Z=,�5� years). In contrast, increased nuclear cataract prevalence
$e{}S�Q;fW in cross-section II was observed in the older age groups (≥
j�x
?"`;�a 70 years). Age-specific cortical cataract prevalence was relatively
~��)6EH`- consistent between the two surveys, except for a
�MN:�LL
�< reduction in prevalence observed in the 80–84 age group
(Ap?ixrR�_ and an increasing prevalence in the older age groups (≥ 85
,K|UUosS-# years).
/a�6�i`��� Similar gender differences in cataract prevalence were
\e�R�ct�_� observed in both surveys (Table 3). Higher prevalence of
1�y,/|
Y�� cortical and nuclear cataract in women than men was evident
���k)W&ZY� but the difference was only significant for cortical
}X��qC�'z cataract (age-adjusted odds ratio, OR, for women 1.3,
of��Pv?_�@ 95% confidence intervals, CI, 1.1–1.5 in cross-section I
�i)$<�j!�L and OR 1.4, 95% CI 1.1–1.6 in cross-section II). In con-
W! J�@�30 Table 1: Participant characteristics.
z�*�9� �ke Characteristics Cross-section I Cross-section II
S�6fbwZZMG n % n %
5du�� xW>D Age (mean) (66.2) (66.7)
�6�qWWfm/6 50–54 485 13.3 350 10.0
j�dx T662q 55–59 534 14.6 580 16.5
M�I�h\z7gW 60–64 638 17.5 600 17.1
Jb-�.x�_Bf 65–69 671 18.4 639 18.2
Pw5[X5�.DX 70–74 538 14.7 572 16.3
Ch:EL-���L 75–79 422 11.6 407 11.6
*d�PbV.HCl 80–84 230 6.3 226 6.4
;V?��d;O4u 85–89 100 2.7 110 3.1
�2.
v<p�qn 90+ 36 1.0 24 0.7
{Byh:�-e<� Female 2072 56.7 1998 57.0
{w�7/M]m�- Ever Smokers 1784 51.2 1789 51.2
II�Amx[ �b Use of inhaled steroids 370 10.94 478 13.8^
�4�yj�IR�? History of:
�a�PQ�xpK? Diabetes 284 7.8 347 9.9^
�%Y�>��E
� Hypertension 1669 46.0 1825 52.2^
!�SIk�9~rJ Emmetropia* 1558 42.9 1478 42.2
W!Fc60>p@f Myopia* 442 12.2 495 14.1^
[�AA}P/i�W Hyperopia* 1633 45.0 1532 43.7
5L_`��Fw\l n = number of persons affected
Yy6$q\@r�V * best spherical equivalent refraction correction
II�!~"-W�H ^ P < 0.01
MH�9vg5QKp BMC Ophthalmology 2006, 6:17
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�l�5�\�V4 t
�EdkIT|c{� rast, men had slightly higher PSC prevalence than women
G=�SMz+z�� in both cross-sections but the difference was not significant
�b&dv("e
4 (OR 1.1, 95% CI 0.8–1.4 for men in cross-section I
�iRbe$�v&N and OR 1.2, 95% 0.9–1.6 in cross-section II).
'�t5�`N��i Discussion
"Mhn?PT�q Findings from two surveys of BMES cross-sectional populations
U4�<c![Pp. with similar age and gender distribution showed
�6�U.|0mG[ that the prevalence of cortical cataract and PSC remained
z?( b�|v�� stable, while the prevalence of nuclear cataract appeared
�I~&9�c/&� to have increased. Comparison of age-specific prevalence,
�qZ&~&f|>e with totally independent samples within each age group,
�i^V(L�GQF confirmed the robustness of our findings from the two
D W^Zuu/) survey samples. Although lens photographs taken from
M�.r�7^9�P the two surveys were graded for nuclear cataract by the
Z�fK[o�{9> same graders, who documented a high inter- and intragrader
,?k1i�f(0[ reliability, we cannot exclude the possibility that
{]Hv*{ ��] variations in photography, performed by different photographers,
OZ�nK��J�< may have contributed to the observed difference
&�i.sSqSI5 in nuclear cataract prevalence. However, the overall
Cx�Zh^V8LP Table 2: Age-specific prevalence of cataract types in cross sections I and II.
G\T�O���]c Cataract type Age (years) Cross-section I Cross-section II
^��gZ�,A]
n % (95% CL)* n % (95% CL)*
nSC2�wTH!1 Cortical 50–54 473 4.4 (2.6–6.3) 338 7.4 (4.6–10.2)
?Ve I��lD� 55–59 522 9.2 (6.7–11.7) 542 9.0 (6.6–11.5)
K +3=gBU*w 60–64 615 16.4 (13.5–19.4) 556 16.7 (13.6–19.8)
�3RT\G0?8f 65–69 653 26.2 (22.8–29.6) 581 23.6 (20.1–27.0)
1�3`�Mt�1R 70–74 516 31.2 (27.2–35.2) 514 35.4 (31.3–39.6)
v��{f�cQb� 75–79 366 40.2 (35.1–45.2) 332 39.8 (34.5–45.1)
;}�"Eqq��: 80–84 194 58.8 (51.8–65.8) 163 42.9 (35.3–50.6)
m�<�#1�2#D 85–89 74 52.7 (41.1–64.4) 73 54.8 (43.1–66.5)
]|�+M0:�2? 90+ 22 68.2 (47.0–89.3) 14 78.6 (54.0–103.2)
kuV7nsXi�Q PSC 50–54 474 2.7 (1.3–4.2) 338 2.4 (0.7–4.0)
F!wz{i6\h� 55–59 522 2.9 (1.4–4.3) 541 2.6 (1.3–3.9)
n�=vD�EX:' 60–64 616 4.6 (2.9–6.2) 548 5.7 (3.7–7.6)
f�
zQR�0
65–69 655 6.3 (4.4–8.1) 573 4.5 (2.8–6.3)
~��~Ezt*lH 70–74 517 6.8 (4.6–8.9) 505 9.7 (7.1–12.3)
\�/o$io,kV 75–79 367 11.4 (8.2–14.7) 327 9.5 (6.3–12.7)
5$D�"uAp<V 80–84 196 12.2 (7.6–16.9) 155 10.3 (5.5–15.2)
5�;U�Iz@BJ 85–89 74 18.9 (9.8–28.1) 69 11.6 (3.9–19.4)
*_�o(~5w-K 90+ 23 21.7 (3.5–40.0) 11 0.0
�H��dJ�� g Nuclear 50–54 323 1.6 (0.2–2.9) 331 0.9 (–0.2–1.9)
��,_I
rE�� 55–59 386 2.3 (0.8–3.8) 507 3.6 (1.9–5.2)
U`m�X
f�#D 60–64 453 5.3 (3.2–7.4) 501 11.6 (8.8–14.4)
P<�<+�;'�] 65–69 478 17.2 (13.8–20.1) 534 18.5 (15.2–21.9)
�"J��1�A9| 70–74 392 27.6 (23.1–32.0) 453 36.0 (31.6–40.4)
89�g�
a+#7 75–79 255 45.1 (39.0–51.3) 302 55.6 (50.0–61.3)
VTM* 1uXS> 80–84 146 54.1 (45.9–62.3) 147 73.5 (66.3–80.7)
|�JxVfX�8^ 85–89 50 64.0 (50.2–77.8) 70 80.0 (70.4–89.6)
!i^"3!.l,] 90+ 18 72.2 (49.3–95.1) 15 73.3 (48.0–98.7)
�pO�
�c2V n = number of persons
4a+�gM._+O * 95% Confidence Limits
f
+{=�##'0 Cataract FMioguunrtea i1n ps rEeyvea lSetnucdey in cross-sections I and II of the Blue
alaL�/p{�O Cataract prevalence in cross-sections I and II of the Blue
�$Es\��ld� Mountains Eye Study.
/I=�|;�FGq 0
5��@w�6pda 10
w={�q@.
g% 20
c\{��N:S�> 30
s�F��TAE1| 40
�Z8��#�nu� 50
\yr��9��j$ cortical PSC nuclear any
��XB7A�a�) cataract
0Z1ksfLU�� Cataract type
""0�Y^M2�I %
|V��x���[� Cross-section I
"GO!^Z�G] Cross-section II
4v\Ha�O�k� BMC Ophthalmology 2006, 6:17
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_O`��p��(6 (page number not for citation purposes)
P���R�
%)3 prevalence of any cataract (including cataract surgery) was
xs�Z��G(Tz relatively stable over the 6-year period.
:?��6HG_9X Although different population-based studies used different
,8@<sF�B'� grading systems to assess cataract [15], the overall
J:@gmo`M;V prevalence of the three cataract types were similar across
k�pgA2�u7 different study populations [12,16-23]. Most studies have
L 4j#0I]lq suggested that nuclear cataract is the most prevalent type
��E�>�bkEm of cataract, followed by cortical cataract [16-20]. Ours and
�r�1L�@p[> other studies reported that cortical cataract was the most
7�;�E�D�U� prevalent type [12,21-23].
:#YC�_
i�d Our age-specific prevalence data show a reduction of
Q,KNZxT,
q 15.9% in cortical cataract prevalence for the 80–84 year
w2
Y%y�jCV age group, concordant with an increase in cataract surgery
46>rvy.r�� prevalence by 9% in those aged 80+ years observed in the
M�sqqjhoy� same study population [10]. Although cortical cataract is
�*9�\�j1Nd thought to be the least likely cataract type leading to a cataract
xt^1,V4Ei~ surgery, this may not be the case in all older persons.
ZmsYRk~@- A relatively stable cortical cataract and PSC prevalence
IuXg�xR%�� over the 6-year period is expected. We cannot offer a
QX=�T
�uyO definitive explanation for the increase in nuclear cataract
�%1i:*~g�� prevalence. A possible explanation could be that a moderate
^~~Rto)Y�� level of nuclear cataract causes less visual disturbance
f�d'��kv�� than the other two types of cataract, thus for the oldest age
<��=.6Z*x+ groups, persons with nuclear cataract could have been less
rf�wJLl/�
likely to have surgery unless it is very dense or co-existing
�Y_%:%�J� with cortical cataract or PSC. Previous studies have shown
�<��XLae'R that functional vision and reading performance were high
x��S|9�Gk� in patients undergoing cataract surgery who had nuclear
^Q8yb*�MN� cataract only compared to those with mixed type of cataract
u@_|�4Bp," (nuclear and cortical) or PSC [24,25]. In addition, the
Ey=2�zo^F� overall prevalence of any cataract (including cataract surgery)
c(Dp`f�,�� was similar in the two cross-sections, which appears
wk�p2A18n� to support our speculation that in the oldest age group,
~�@'wqGTp nuclear cataract may have been less likely to be operated
/|v4��]t-
than the other two types of cataract. This could have
�</�25J((� resulted in an increased nuclear cataract prevalence (due
D6��Vd�gU| to less being operated), compensated by the decreased
p�"0#��G&- prevalence of cortical cataract and PSC (due to these being
w9|
�x{B� more likely to be operated), leading to stable overall prevalence
.n�7�@$k�q of any cataract.
V(`�]hH0;T Possible selection bias arising from selective survival
�T_*i�n�Pf among persons without cataract could have led to underestimation
[�<XYU�,{R of cataract prevalence in both surveys. We
V�lx.C~WYn assume that such an underestimation occurred equally in
6��_�`Bo�% both surveys, and thus should not have influenced our
R'gd�/.[e� assessment of temporal changes.
��_[[0r�n$ Measurement error could also have partially contributed
�V?�EX`�2S to the observed difference in nuclear cataract prevalence.
`�4�K�|L6� Assessment of nuclear cataract from photographs is a
U�`6�|�K$@ potentially subjective process that can be influenced by
6Q�:Wo)^�! variations in photography (light exposure, focus and the
sK�#)�k\w> slit-lamp angle when the photograph was taken) and
a�_Xwi:e<� grading. Although we used the same Topcon slit-lamp
1]/;q�NEv� camera and the same two graders who graded photos
�$���NR[U+ from both surveys, we are still not able to exclude the possibility
JMB#Kz�vN[ of a partial influence from photographic variation
�HGYTh"�R� on this result.
1{N+B#*<[X A similar gender difference (women having a higher rate
0`�E G-H�w than men) in cortical cataract prevalence was observed in
f�&CQn.�K" both surveys. Our findings are in keeping with observations
��ec��;��� from the Beaver Dam Eye Study [18], the Barbados
3@
"����:& Eye Study [22] and the Lens Opacities Case-Control
�M�0$�MK>� Group [26]. It has been suggested that the difference
[RX��LR��# could be related to hormonal factors [18,22]. A previous
�T+�L=GnYl study on biochemical factors and cataract showed that a
#e��@N�V4q lower level of iron was associated with an increased risk of
E
3 % ~!ZC cortical cataract [27]. No interaction between sex and biochemical
t"�B3?�<?] factors were detected and no gender difference
~�Eg]Auk7� was assessed in this study [27]. The gender difference seen
vb[
0H{TT2 in cortical cataract could be related to relatively low iron
j�Spj6:@�B levels and low hemoglobin concentration usually seen in
w�1I07� �( women [28]. Diabetes is a known risk factor for cortical
�Z5xQ
-T`� Table 3: Gender distribution of cataract types in cross-sections I and II.
"SN*hzs"]` Cataract type Gender Cross-section I Cross-section II
�+.~K=.O)� n % (95% CL)* n % (95% CL)*
8�1�E��EYf Cortical Male 1496 21.1 (19.0–23.1) 1328 20.4 (18.2–22.6)
v7����p�u� Female 1939 25.9 (23.9–27.8) 1785 26.2 (24.2–28.3)
Z7b�J<�TpZ PSC Male 1500 6.5 (5.2–7.7) 1314 6.4 (5.1–7.7)
(�d#&m+
g] Female 1944 6.2 (5.1–7.2) 1753 5.7 (4.6–6.7)
x1Gx�9��z9 Nuclear Male 1106 17.6 (15.4–19.9) 1225 22.5 (20.1–24.8)
o�JD]h/fQs Female 1395 19.5 (17.4–21.6) 1635 25.0 (22.9–27.1)
x�_~_/�&X5 n = number of persons
,Vq�$>T@z� * 95% Confidence Limits
oz=�V�|7
, BMC Ophthalmology 2006, 6:17
http://www.biomedcentral.com/1471-2415/6/17 ��se��.HA� Page 6 of 7
\i+AMduAo� (page number not for citation purposes)
_FO�IMjh%N cataract but in this particular population diabetes is more
�6�/� 5c|� prevalent in men than women in all age groups [29]. Differential
(W#CDw<�ja exposures to cataract risk factors or different dietary
u�D(C jHM> or lifestyle patterns between men and women may
q�R�aPh:Q' also be related to these observations and warrant further
e�GT&&���Y study.
Ye]K 74�M. Conclusion
.�u\$wJ9Ai In summary, in two population-based surveys 6 years
{�X<��g9�3 apart, we have documented a relatively stable prevalence
G�>"n6v'^d of cortical cataract and PSC over the period. The observed
5/�Q��u5/� overall increased nuclear cataract prevalence by 5% over a
�0S��:&�wb 6-year period needs confirmation by future studies, and
2OpA1�$n6 reasons for such an increase deserve further study.
�x��"sbm�� Competing interests
O�[�= L#wi The author(s) declare that they have no competing interests.
lv?`+tU�2_ Authors' contributions
4L:O0Gg�z} AGT graded the photographs, performed literature search
?{aC�-3VAT and wrote the first draft of the manuscript. JJW graded the
��&�[{sA�; photographs, critically reviewed and modified the manuscript.
OIj.�K@Kr� ER performed the statistical analysis and critically
�Z�$IN�mo6 reviewed the manuscript. PM designed and directed the
�Q9�AvNj>X study, adjudicated cataract cases and critically reviewed
�sN8pwRj�b and modified the manuscript. All authors read and
bvJ@H
Z$
� approved the final manuscript.
,mx\
-lWFy Acknowledgements
�e�YP^.�U) This study was supported by the Australian National Health & Medical
=�r/8~��~= Research Council, Canberra, Australia (Grant Nos 974159, 991407). The
�2]�?=\_�T abstract was presented at the Association for Research in Vision and Ophthalmology
�5�9{�X;�� (ARVO) meeting in Fort Lauderdale, Florida, USA, May 2005.
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