BioMed Central
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�oK1[_k�o| BMC Ophthalmology
p. ��~�j�o Research article Open Access
!eoe�c2h#5 Comparison of age-specific cataract prevalence in two
�q9(}�wvtr population-based surveys 6 years apart
B�w7:r��y Ava Grace Tan†, Jie Jin Wang*†, Elena Rochtchina† and Paul Mitchell†
��y#0Z[[I0 Address: Centre for Vision Research, Westmead Millennium Institute, Department of Ophthalmology, University of Sydney, Westmead Hospital,
>f05+%^[�� Westmead, NSW, Australia
M<m6�4{�m1 Email: Ava Grace Tan -
ava_tan@wmi.usyd.edu.au; Jie Jin Wang* -
jiejin_wang@wmi.usyd.edu.au;
�)Nd:��PnA Elena Rochtchina -
elena_rochtchina@wmi.usyd.edu.au; Paul Mitchell -
paul_mitchell@wmi.usyd.edu.au u�tS M�x�( * Corresponding author †Equal contributors
Kd�1\D!#!6 Abstract
=�w?c�p}HW Background: In this study, we aimed to compare age-specific cortical, nuclear and posterior
� o�%�4+I> subcapsular (PSC) cataract prevalence in two surveys 6 years apart.
zO]�dQ$r\Z Methods: The Blue Mountains Eye Study examined 3654 participants (82.4% of those eligible) in
eh(]'%![/ cross-section I (1992–4) and 3509 participants (75.1% of survivors and 85.2% of newly eligible) in
:L��zj'I�j cross-section II (1997–2000, 66.5% overlap with cross-section I). Cataract was assessed from lens
qr;" K?�NX photographs following the Wisconsin Cataract Grading System. Cortical cataract was defined if
r�z7b�%�WY cortical opacity comprised ≥ 5% of lens area. Nuclear cataract was defined if nuclear opacity ≥
�:6i�q{XV^ Wisconsin standard 4. PSC was defined if any present. Any cataract was defined to include persons
/�V�ZU3p<~ who had previous cataract surgery. Weighted kappa for inter-grader reliability was 0.82, 0.55 and
X�0=-�{
<W 0.82 for cortical, nuclear and PSC cataract, respectively. We assessed age-specific prevalence using
En_�8H[<�% an interval of 5 years, so that participants within each age group were independent between the
�=�#fv�dj� two surveys.
;�B�vWU\!� Results: Age and gender distributions were similar between the two populations. The age-specific
b#^D�8_9�h prevalence of cortical (23.8% in 1st, 23.7% in 2nd) and PSC cataract (6.3%, 6.0%) was similar. The
�.�8~ x;P6 prevalence of nuclear cataract increased slightly from 18.7% to 23.9%. After age standardization,
��h���lEvL the similar prevalence of cortical (23.8%, 23.5%) and PSC cataract (6.3%, 5.9%), and the increased
86Vu���PV- prevalence of nuclear cataract (18.7%, 24.2%) remained.
50`��r}�s} Conclusion: In two surveys of two population-based samples with similar age and gender
�Y�"�� |U$ distributions, we found a relatively stable cortical and PSC cataract prevalence over a 6-year period.
v1�r�
Gq�� The increased prevalence of nuclear cataract deserves further study.
,%<��
77LE Background
�K)K���a"H Age-related cataract is the leading cause of reversible visual
AkC\�CdmA impairment in older persons [1-6]. In Australia, it is
z0�5pVe/5� estimated that by the year 2021, the number of people
]�7@Dqd-/S affected by cataract will increase by 63%, due to population
Wc[)mYOSuO aging [7]. Surgical intervention is an effective treatment
v4^VYi,�.- for cataract and normal vision (> 20/40) can usually
`R�;X��N�- be restored with intraocular lens (IOL) implantation.
�;pq�4El_� Cataract surgery with IOL implantation is currently the
07&S^ �X^/ most commonly performed, and is, arguably, the most
[r��em,i�+ cost effective surgical procedure worldwide. Performance
��<#i'3TUR Published: 20 April 2006
��p};<��l@ BMC Ophthalmology 2006, 6:17 doi:10.1186/1471-2415-6-17
S5M t?v|K� Received: 14 December 2005
Q�G
i���a( Accepted: 20 April 2006
elQ44)TrQ� This article is available from:
http://www.biomedcentral.com/1471-2415/6/17 �Ns{4BM6�j © 2006 Tan et al; licensee BioMed Central Ltd.
�aQuE�NsB� This is an Open Access article distributed under the terms of the Creative Commons Attribution License (
http://creativecommons.org/licenses/by/2.0),
�6iO��AYA= which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
:mL.Y em*' BMC Ophthalmology 2006, 6:17
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DzM�k���eX (page number not for citation purposes)
4l:�+>U@KU of this surgical procedure has been continuously increasing
W%x#p�s5%� in the last two decades. Data from the Australian
5N�K:94&JE Health Insurance Commission has shown a steady
~j_H�2+�! increase in Medicare claims for cataract surgery [8]. A 2.6-
� ��[i�z�� fold increase in the total number of cataract procedures
l1msX��B�C from 1985 to 1994 has been documented in Australia [9].
wlJ_,�wA�� The rate of cataract surgery per thousand persons aged 65
��AkF�3F�^ years or older has doubled in the last 20 years [8,9]. In the
�5 �,�HNb� Blue Mountains Eye Study population, we observed a onethird
j"]%6Rw�M] increase in cataract surgery prevalence over a mean
49yN|�h;c! 6-year interval, from 6% to nearly 8% in two cross-sectional
ZWv$K0�agu population-based samples with a similar age range
�gNJ\*]S�Y [10]. Further increases in cataract surgery performance
6�_7d1.wv9 would be expected as a result of improved surgical skills
��dbR4%�;< and technique, together with extending cataract surgical
am=56J$ig� benefits to a greater number of older people and an
4)?c�[aC4P increased number of persons with surgery performed on
| �e+m!G1G both eyes.
Z��D*>i=S� Both the prevalence and incidence of age-related cataract
V&G_�B�u�~ link directly to the demand for, and the outcome of, cataract
=����1D*K% surgery and eye health care provision. This report
MF�VFr �"� aimed to assess temporal changes in the prevalence of cortical
�i
):�el= and nuclear cataract and posterior subcapsular cataract
qsLsyi�|zG (PSC) in two cross-sectional population-based
�]l4\/E�W6 surveys 6 years apart.
O�fn:<d��� Methods
Z@>>ZS�1Do The Blue Mountains Eye Study (BMES) is a populationbased
IBR;q[Dj}� cohort study of common eye diseases and other
l�{���k��� health outcomes. The study involved eligible permanent
]uP���{Sj� residents aged 49 years and older, living in two postcode
iS�{)Tll}& areas in the Blue Mountains, west of Sydney, Australia.
L\"$R":3{d Participants were identified through a census and were
Z"P{/~H�G� invited to participate. The study was approved at each
��>�k�:)'* stage of the data collection by the Human Ethics Committees
y
j��b
.�6 of the University of Sydney and the Western Sydney
0FXM4YcrJO Area Health Service and adhered to the recommendations
�-Z:al\e<g of the Declaration of Helsinki. Written informed consent
|�^F�DsJUN was obtained from each participant.
Wv���R}c�� Details of the methods used in this study have been
thOC�zG�J$ described previously [11]. The baseline examinations
9[:nW��p�^ (BMES cross-section I) were conducted during 1992–
�\HR�QSfGt 1994 and included 3654 (82.4%) of 4433 eligible residents.
��L%fWa2P' Follow-up examinations (BMES IIA) were conducted
7FWf,IjcGY during 1997–1999, with 2335 (75.0% of BMES
UF}f��mDi� cross section I survivors) participating. A repeat census of
F
M`�pP��x the same area was performed in 1999 and identified 1378
|�e�k*�w�o newly eligible residents who moved into the area or the
h�1,J��<B@ eligible age group. During 1999–2000, 1174 (85.2%) of
E#T�'=f[r~ this group participated in an extension study (BMES IIB).
LV`- ���eW BMES cross-section II thus includes BMES IIA (66.5%)
7m�8L�!t9� and BMES IIB (33.5%) participants (n = 3509).
^c�+�6?��� Similar procedures were used for all stages of data collection
i3YAK$w;& at both surveys. A questionnaire was administered
rsrv1A=t?
including demographic, family and medical history. A
<�&:3|2��p detailed eye examination included subjective refraction,
�$U�!�w#|& slit-lamp (Topcon SL-7e camera, Topcon Optical Co,
7��GK�eq�v Tokyo, Japan) and retroillumination (Neitz CT-R camera,
Rb#?c+�&�# Neitz Instrument Co, Tokyo, Japan) photography of the
d@`yRueWiV lens. Grading of lens photographs in the BMES has been
0�\u_��\%[ previously described [12]. Briefly, masked grading was
|Y:T3hra61 performed on the lens photographs using the Wisconsin
yl��|�+D]� Cataract Grading System [13]. Cortical cataract and PSC
�
�c,x�2�� were assessed from the retroillumination photographs by
^
��.>)*P� estimating the percentage of the circular grid involved.
g=a-zg9LX� Cortical cataract was defined when cortical opacity
h%�#@X�d>. involved at least 5% of the total lens area. PSC was defined
�{�d=y9Jb^ when opacity comprised at least 1% of the total lens area.
D4_D{\xh�O Slit-lamp photographs were used to assess nuclear cataract
��
�]�5c|� using the Wisconsin standard set of four lens photographs
0p!�[�&O�� [13]. Nuclear cataract was defined when nuclear opacity
Ne�Upl./�b was at least as great as the standard 4 photograph. Any cataract
,�X+0�71.( was defined to include persons who had previous
U.d*E/O�R5 cataract surgery as well as those with any of three cataract
cND2(<�jx: types. Inter-grader reliability was high, with weighted
r0?�`t!%�V kappa 0.82 for cortical cataract, 0.55 (simple kappa 0.75)
k��f�^Wz�p for nuclear cataract and 0.82 for PSC grading. The intragrader
\U p<m>3�\ reliability for nuclear cataract was assessed with
">NBP��anJ simple kappa 0.83 for the senior grader who graded
p}�N'>+@=� nuclear cataract at both surveys. All PSC cases were confirmed
DH�@*O��z- by an ophthalmologist (PM).
luAhyEp�� In cross-section I, 219 persons (6.0%) had missing or
�*COr^7Kf5 ungradable Neitz photographs, leaving 3435 with photographs
5��h1�FvJg available for cortical cataract and PSC assessment,
�=OT��w��P while 1153 (31.6%) had randomly missing or ungradable
X�=_N7��!� Topcon photographs due to a camera malfunction, leaving
mL�Kw�k6I� 2501 with photographs available for nuclear cataract
�^�hTq~��" assessment. Comparison of characteristics between participants
'N0d==a�I� with and without Neitz or Topcon photographs in
ExV�>�s*�y cross-section I showed no statistically significant differences
%q(n'^#Z.y between the two groups, as reported previously
zLC\R�c4� [12]. In cross-section II, 441 persons (12.5%) had missing
xs+Mv�XT�C or ungradable Neitz photographs, leaving 3068 for cortical
��`[/B
G)4 cataract and PSC assessment, and 648 (18.5%) had
hZ5h(CQ?"# missing or ungradable Topcon photographs, leaving 2860
?�ZE1�>L7e for nuclear cataract assessment.
$�Ug�M�7V$ Data analysis was performed using the Statistical Analysis
[P,1�UO|$B System (SAS, SAS Institute, Cary, NC, USA). Age-adjusted
Q_qc_IcM y prevalence was calculated using direct standardization of
zEpc�JHI%� the cross-section II population to the cross-section I population.
��,`)!K}2� We assessed age-specific prevalence using an
�OT\�[qa�K interval of 5 years, so that participants within each age
ci6j"nKci� group were independent between the two cross-sectional
�
q/�<�.^X surveys.
r68'DJ&�m3 BMC Ophthalmology 2006, 6:17
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�a�Z@Ke$jD Results
N:Q}���Lil Characteristics of the two survey populations have been
pk�M�_� @K previously compared [14] and showed that age and sex
m�d�tq-v
distributions were similar. Table 1 compares participant
�gBf�%��9F characteristics between the two cross-sections. Cross-section
^t?
P�32GJ II participants generally had higher rates of diabetes,
I�H�'DCY: hypertension, myopia and more users of inhaled steroids.
$�@7�S+'Q3 Cataract prevalence rates in cross-sections I and II are
h��d8:�|�_ shown in Figure 1. The overall prevalence of cortical cataract
|*�e
�>�hk was 23.8% and 23.7% in cross-sections I and II,
=VH,� i/�@ respectively (age-sex adjusted P = 0.81). Corresponding
3�Q�L'uk� prevalence of PSC was 6.3% and 6.0% for the two crosssections
�)CS�b�\�� (age-sex adjusted P = 0.60). There was an
Z�H~��T'Bg increased prevalence of nuclear cataract, from 18.7% in
�=ugx��Pgn cross-section I to 23.9% in cross-section II over the 6-year
`/Zi=.rr� period (age-sex adjusted P < 0.001). Prevalence of any cataract
u�F+if�`�? (including persons who had cataract surgery), however,
I�r_K8�3VM was relatively stable (46.9% and 46.8% in crosssections
�3<AZ,gF1 I and II, respectively).
o>'�;�-} E After age-standardization, these prevalence rates remained
w� �q% 4'( stable for cortical cataract (23.8% and 23.5% in the two
k�z@@/DD/9 surveys) and PSC (6.3% and 5.9%). The slightly increased
E���dh�T;! prevalence of nuclear cataract (from 18.7% to 24.2%) was
�H� B�_�si not altered.
�.��|NF8Fj Table 2 shows the age-specific prevalence rates for cortical
,q]��W�i�# cataract, PSC and nuclear cataract in cross-sections I and
&s�>H�iL>f II. A similar trend of increasing cataract prevalence with
�.:�B]
a7b increasing age was evident for all three types of cataract in
S��>Z �V8� both surveys. Comparing the age-specific prevalence
P%]li`56-c between the two surveys, a reduction in PSC prevalence in
R
f+o�gLa= cross-section II was observed in the older age groups (≥ 75
KDhr.P.~�� years). In contrast, increased nuclear cataract prevalence
�#(�mm6�dj in cross-section II was observed in the older age groups (≥
�;\�DXRKR� 70 years). Age-specific cortical cataract prevalence was relatively
� (�f,D$mX consistent between the two surveys, except for a
=��t�oqEm~ reduction in prevalence observed in the 80–84 age group
�,a9�<\bd) and an increasing prevalence in the older age groups (≥ 85
N�� 3�i�,_ years).
+�/�*�g?Vt Similar gender differences in cataract prevalence were
*�Em �9R�� observed in both surveys (Table 3). Higher prevalence of
�#/�Y t�4n cortical and nuclear cataract in women than men was evident
~�@�S5*(&8 but the difference was only significant for cortical
-x�=a�b�yD cataract (age-adjusted odds ratio, OR, for women 1.3,
6�UXa
5�t
95% confidence intervals, CI, 1.1–1.5 in cross-section I
8zS't2
u� and OR 1.4, 95% CI 1.1–1.6 in cross-section II). In con-
�
�O�;h��] Table 1: Participant characteristics.
<�i``#"��/ Characteristics Cross-section I Cross-section II
lG;�RfDI-� n % n %
D *��R�F._ Age (mean) (66.2) (66.7)
jbc�J��\2� 50–54 485 13.3 350 10.0
3�/+��
9#� 55–59 534 14.6 580 16.5
�
+ulB�y�� 60–64 638 17.5 600 17.1
cob�q+Iyu� 65–69 671 18.4 639 18.2
M)C.�b�o{p 70–74 538 14.7 572 16.3
-Q��gu�6Ty 75–79 422 11.6 407 11.6
�&2C�6q04b 80–84 230 6.3 226 6.4
.<}�(J#v�C 85–89 100 2.7 110 3.1
#��m{�K��� 90+ 36 1.0 24 0.7
p��8o
�~�� Female 2072 56.7 1998 57.0
�%B5.zs]Of Ever Smokers 1784 51.2 1789 51.2
�%p�6"Sg�* Use of inhaled steroids 370 10.94 478 13.8^
,rVm81-��2 History of:
Sr� ��Z\]� Diabetes 284 7.8 347 9.9^
c-.t8X,5(~ Hypertension 1669 46.0 1825 52.2^
2�j&-3W$^� Emmetropia* 1558 42.9 1478 42.2
FZ'|�z�8Dm Myopia* 442 12.2 495 14.1^
t"k�6wv;Tq Hyperopia* 1633 45.0 1532 43.7
W�W82=2rJ9 n = number of persons affected
�m,NUNd#)\ * best spherical equivalent refraction correction
-L>xVF-|:1 ^ P < 0.01
�pv*u[ffi BMC Ophthalmology 2006, 6:17
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N
v}�'"V>� t
+��U_�> Bo rast, men had slightly higher PSC prevalence than women
H�TiqErD2_ in both cross-sections but the difference was not significant
�~&B�{"�d� (OR 1.1, 95% CI 0.8–1.4 for men in cross-section I
VcK�u�f�V' and OR 1.2, 95% 0.9–1.6 in cross-section II).
F`�K�A^ZI� Discussion
�(]7&][��� Findings from two surveys of BMES cross-sectional populations
,{
P*ZK�3u with similar age and gender distribution showed
Wh6j�r=�>G that the prevalence of cortical cataract and PSC remained
�fWie�fv[& stable, while the prevalence of nuclear cataract appeared
Sn=�|Q�4ZN to have increased. Comparison of age-specific prevalence,
KL�D)��h,] with totally independent samples within each age group,
Q�`k=VSUk� confirmed the robustness of our findings from the two
S^0�Po%��d survey samples. Although lens photographs taken from
�q8%�T)$�! the two surveys were graded for nuclear cataract by the
�$�Gh�d�H) same graders, who documented a high inter- and intragrader
e�p��M;�u� reliability, we cannot exclude the possibility that
.�U|irD��O variations in photography, performed by different photographers,
(#x��<qi,T may have contributed to the observed difference
p��J��35�M in nuclear cataract prevalence. However, the overall
�"�]h�4L�� Table 2: Age-specific prevalence of cataract types in cross sections I and II.
�|@���#�37 Cataract type Age (years) Cross-section I Cross-section II
�>xQg�COi� n % (95% CL)* n % (95% CL)*
K��P�{|xQ> Cortical 50–54 473 4.4 (2.6–6.3) 338 7.4 (4.6–10.2)
L1=+x^�W�Q 55–59 522 9.2 (6.7–11.7) 542 9.0 (6.6–11.5)
BUT{�}2+�K 60–64 615 16.4 (13.5–19.4) 556 16.7 (13.6–19.8)
�� eX7�dyM 65–69 653 26.2 (22.8–29.6) 581 23.6 (20.1–27.0)
\�H��X'^t` 70–74 516 31.2 (27.2–35.2) 514 35.4 (31.3–39.6)
�x�Vk|6vA7 75–79 366 40.2 (35.1–45.2) 332 39.8 (34.5–45.1)
h�u�}`,�2� 80–84 194 58.8 (51.8–65.8) 163 42.9 (35.3–50.6)
N~�7xj��?� 85–89 74 52.7 (41.1–64.4) 73 54.8 (43.1–66.5)
,#&\�1Vx�f 90+ 22 68.2 (47.0–89.3) 14 78.6 (54.0–103.2)
gB/��4ro8� PSC 50–54 474 2.7 (1.3–4.2) 338 2.4 (0.7–4.0)
ZC}�'! $r7 55–59 522 2.9 (1.4–4.3) 541 2.6 (1.3–3.9)
S�o>P)d$8+ 60–64 616 4.6 (2.9–6.2) 548 5.7 (3.7–7.6)
n�y# �?^.1 65–69 655 6.3 (4.4–8.1) 573 4.5 (2.8–6.3)
~ [L�4,��q 70–74 517 6.8 (4.6–8.9) 505 9.7 (7.1–12.3)
�Zz�y!��D� 75–79 367 11.4 (8.2–14.7) 327 9.5 (6.3–12.7)
-*�xm<R],� 80–84 196 12.2 (7.6–16.9) 155 10.3 (5.5–15.2)
{�No*�Z'�X 85–89 74 18.9 (9.8–28.1) 69 11.6 (3.9–19.4)
{
FVLH:{U^ 90+ 23 21.7 (3.5–40.0) 11 0.0
n8W�+q~sW% Nuclear 50–54 323 1.6 (0.2–2.9) 331 0.9 (–0.2–1.9)
l��Aj�P�'( 55–59 386 2.3 (0.8–3.8) 507 3.6 (1.9–5.2)
v4M1
uJ�8� 60–64 453 5.3 (3.2–7.4) 501 11.6 (8.8–14.4)
9G� njJ� 65–69 478 17.2 (13.8–20.1) 534 18.5 (15.2–21.9)
�8!��8 �yA 70–74 392 27.6 (23.1–32.0) 453 36.0 (31.6–40.4)
��4�n6EkTa 75–79 255 45.1 (39.0–51.3) 302 55.6 (50.0–61.3)
�(-k`|��X" 80–84 146 54.1 (45.9–62.3) 147 73.5 (66.3–80.7)
tQ!p<Q=
$) 85–89 50 64.0 (50.2–77.8) 70 80.0 (70.4–89.6)
OZ{YQ}t{^1 90+ 18 72.2 (49.3–95.1) 15 73.3 (48.0–98.7)
SN
w3xO!;& n = number of persons
n~~�0iU��) * 95% Confidence Limits
.Up\ ��0|b Cataract FMioguunrtea i1n ps rEeyvea lSetnucdey in cross-sections I and II of the Blue
�]O%wZIp\P Cataract prevalence in cross-sections I and II of the Blue
$P<�T`3J�g Mountains Eye Study.
J<K-�Y�eph 0
5/U|�oZ�M" 10
�<cC�0l-=� 20
i�WCR�5c=� 30
��S
b0�p?� 40
"ecG\}R=�� 50
bbG�Sh|u+P cortical PSC nuclear any
D���eqT�r: cataract
o�W0A8_|�9 Cataract type
NB�LiwL37{ %
sZ~q|}�D�- Cross-section I
a�4�'KiA2r Cross-section II
�7�Jm�&z/� BMC Ophthalmology 2006, 6:17
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Page 5 of 7
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T�6T3:DG_B prevalence of any cataract (including cataract surgery) was
P�KDzIA~�T relatively stable over the 6-year period.
*�t_"]�v-w Although different population-based studies used different
X5s.�F%Np! grading systems to assess cataract [15], the overall
�kzMul<>sl prevalence of the three cataract types were similar across
Y}d�b<Cz
X different study populations [12,16-23]. Most studies have
96L-bB�tyY suggested that nuclear cataract is the most prevalent type
�.9":Ljs(L of cataract, followed by cortical cataract [16-20]. Ours and
_�G$SA�-W( other studies reported that cortical cataract was the most
��<K^{3�6h prevalent type [12,21-23].
�hxwo<wEg� Our age-specific prevalence data show a reduction of
J[�C�k�z�] 15.9% in cortical cataract prevalence for the 80–84 year
[w0@7p"7�� age group, concordant with an increase in cataract surgery
�U8f�!yXF' prevalence by 9% in those aged 80+ years observed in the
��4*j��6~� same study population [10]. Although cortical cataract is
l�|,��
Hj
thought to be the least likely cataract type leading to a cataract
�1z����. surgery, this may not be the case in all older persons.
FU{$oCh/5� A relatively stable cortical cataract and PSC prevalence
&U_YDU�Q'L over the 6-year period is expected. We cannot offer a
{6_�M$"e�. definitive explanation for the increase in nuclear cataract
pUGFQ.�"�\ prevalence. A possible explanation could be that a moderate
D�d:�T�FZo level of nuclear cataract causes less visual disturbance
J$a�E�:g6' than the other two types of cataract, thus for the oldest age
Q9i�&]V[�` groups, persons with nuclear cataract could have been less
E{Kc�$,y�� likely to have surgery unless it is very dense or co-existing
:\!D 6�\o6 with cortical cataract or PSC. Previous studies have shown
a#hu�K~$~� that functional vision and reading performance were high
a���U�y!(Y in patients undergoing cataract surgery who had nuclear
?%|w?Fdx- cataract only compared to those with mixed type of cataract
1g{�-DIOmn (nuclear and cortical) or PSC [24,25]. In addition, the
[~aRA'qJ{V overall prevalence of any cataract (including cataract surgery)
�I�pp#{'Do was similar in the two cross-sections, which appears
��+�:Iw�P� to support our speculation that in the oldest age group,
6UAn�#��d9 nuclear cataract may have been less likely to be operated
VW$a(G�_�h than the other two types of cataract. This could have
q��G6?k}\\ resulted in an increased nuclear cataract prevalence (due
7J[DD5
��� to less being operated), compensated by the decreased
Cr7T��=&L prevalence of cortical cataract and PSC (due to these being
OV"uIY[%8V more likely to be operated), leading to stable overall prevalence
�'%H�\�k5^ of any cataract.
�/wR�,P��� Possible selection bias arising from selective survival
wHT]�&�f�Z among persons without cataract could have led to underestimation
�5LF��&C0v of cataract prevalence in both surveys. We
5LX%S��.CW assume that such an underestimation occurred equally in
�f}���!�Eu both surveys, and thus should not have influenced our
f`�g��s/�R assessment of temporal changes.
L0Ycf|[s,
Measurement error could also have partially contributed
%w3�Y!�7+� to the observed difference in nuclear cataract prevalence.
5r)]o'?�s� Assessment of nuclear cataract from photographs is a
{f
(RY��j� potentially subjective process that can be influenced by
(
kKQ�s"�) variations in photography (light exposure, focus and the
+_T�`tmQ�� slit-lamp angle when the photograph was taken) and
*U� mWcFoF grading. Although we used the same Topcon slit-lamp
q��`�0�wG3 camera and the same two graders who graded photos
�F�K+��`K< from both surveys, we are still not able to exclude the possibility
ubQbEv�{(, of a partial influence from photographic variation
Xl %ax!�/
on this result.
�f��P KF�U A similar gender difference (women having a higher rate
7�C>5Xyy
J than men) in cortical cataract prevalence was observed in
u�85���dG7 both surveys. Our findings are in keeping with observations
6ec�#3~ Y] from the Beaver Dam Eye Study [18], the Barbados
mUdj2vB$+' Eye Study [22] and the Lens Opacities Case-Control
N���\t( rp Group [26]. It has been suggested that the difference
IZs ��NMY could be related to hormonal factors [18,22]. A previous
=#>�F��' A study on biochemical factors and cataract showed that a
)
gHfb�UYS lower level of iron was associated with an increased risk of
NiSH$�MJ_� cortical cataract [27]. No interaction between sex and biochemical
��~wFiq)v( factors were detected and no gender difference
a�sZ(Hz%� was assessed in this study [27]. The gender difference seen
4d�e:h�E � in cortical cataract could be related to relatively low iron
<<Q}�|$Wu� levels and low hemoglobin concentration usually seen in
})y��B2Q0� women [28]. Diabetes is a known risk factor for cortical
?J��,�K[.z Table 3: Gender distribution of cataract types in cross-sections I and II.
045�_0+r"@ Cataract type Gender Cross-section I Cross-section II
�E;,����__ n % (95% CL)* n % (95% CL)*
Q5A�,9ovNZ Cortical Male 1496 21.1 (19.0–23.1) 1328 20.4 (18.2–22.6)
?���d�XAHY Female 1939 25.9 (23.9–27.8) 1785 26.2 (24.2–28.3)
H^dw=k�S� PSC Male 1500 6.5 (5.2–7.7) 1314 6.4 (5.1–7.7)
V�K!HuO9l� Female 1944 6.2 (5.1–7.2) 1753 5.7 (4.6–6.7)
\�58b�z<u" Nuclear Male 1106 17.6 (15.4–19.9) 1225 22.5 (20.1–24.8)
i(��;.��Y� Female 1395 19.5 (17.4–21.6) 1635 25.0 (22.9–27.1)
6&QOC9JW+7 n = number of persons
o�F� a,IA� * 95% Confidence Limits
abv���*X�1 BMC Ophthalmology 2006, 6:17
http://www.biomedcentral.com/1471-2415/6/17 s>�W �:vV@ Page 6 of 7
{|<yZ,�,p� (page number not for citation purposes)
�7��w]�3D� cataract but in this particular population diabetes is more
jT/P+2�hMW prevalent in men than women in all age groups [29]. Differential
VLVDi��>0i exposures to cataract risk factors or different dietary
$�xK\$k�w\ or lifestyle patterns between men and women may
0FLC�N!i�1 also be related to these observations and warrant further
Jd?qvE>P�p study.
vz|(��K�N[ Conclusion
7y�XJ\(6R_ In summary, in two population-based surveys 6 years
1GI�Bqs~-� apart, we have documented a relatively stable prevalence
vexF|'!}0# of cortical cataract and PSC over the period. The observed
�Onh��
R�` overall increased nuclear cataract prevalence by 5% over a
Z���"qJil} 6-year period needs confirmation by future studies, and
+�FA�xqCkA reasons for such an increase deserve further study.
�R*�D5n>~� Competing interests
sCP|�d�`�' The author(s) declare that they have no competing interests.
`.d�w�G�3R Authors' contributions
�Jt�#HbAY� AGT graded the photographs, performed literature search
Zy.A9��Bh~ and wrote the first draft of the manuscript. JJW graded the
�_n�!�>*A! photographs, critically reviewed and modified the manuscript.
Lb?��q��5_ ER performed the statistical analysis and critically
23Dl��d+E& reviewed the manuscript. PM designed and directed the
OCJt5#�e~A study, adjudicated cataract cases and critically reviewed
p~C�z��6�n and modified the manuscript. All authors read and
Z��{:;��LC approved the final manuscript.
�^*+M9�e9Z Acknowledgements
;M�K|l,aIQ This study was supported by the Australian National Health & Medical
`p1B�58deC Research Council, Canberra, Australia (Grant Nos 974159, 991407). The
tN_=&|{WE4 abstract was presented at the Association for Research in Vision and Ophthalmology
)siW�c_Z�4 (ARVO) meeting in Fort Lauderdale, Florida, USA, May 2005.
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�P;l�D��ri Pre-publication history
4�ew���#�@ The pre-publication history for this paper can be accessed
Q�U^�?a~r here:
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