Context Motor vehicle crash risk in older drivers is elevated in those with
cataract, a condition that impairs vision and is present in half of adults
aged 65 years or older.
Objective To determine the impact of cataract surgery on the crash risk for older
adults in the years following surgery, compared with that of older adults
who have cataract but who elect to not have surgery.
Design, Setting, and Patients Prospective cohort study of 277 patients with cataract, aged 55 to 84
years at enrollment, who were recruited from 12 eye clinics in Alabama from
October 1994 through March 1996, with 4 to 6 years of follow-up (to March
1999).
Main Outcome Measure Police-reported motor vehicle crash occurrence involving patients who
elected to have surgery compared with those who did not.
Results Comparing the cataract surgery group (n = 174) with the no surgery group
(n = 103), the rate ratio for crash involvement was 0.47 (95% confidence interval,
0.23-0.94), adjusting for race and baseline visual acuity and contrast sensitivity.
The absolute rate reduction associated with cataract surgery was 4.74 crashes
per million miles of travel.
Conclusions In our sample, patients with cataract who underwent cataract surgery
and intraocular lens implantation had half the rate of crash involvement during
the follow-up period compared with cataract patients who did not undergo surgery.
Cataract surgery thus may have a previously undocumented benefit for older
driver safety, reducing subsequent crash rate.
Cataract is the leading cause of vision impairment in older adults in
the United States.1 Population-based studies
indicate that approximately 50% of white adults aged 65 to 74 years have cataract,2,3 with a higher prevalence of about 60%
reported for African Americans.3 Cataract causes
deficits in acuity and contrast sensitivity and increased disability glare.4 Older drivers with cataract are more likely to have
a history of recent crash involvement compared with older drivers who are
cataract-free,5 which is mediated by severe
contrast sensitivity impairment secondary to increased lens opacity.6
Fortunately, cataract is highly treatable in the majority of cases through
surgical removal of the crystalline lens followed by intraocular lens (IOL)
insertion. Cataract surgery leads to improvements in visual acuity and contrast
sensitivity and a reduction in disability glare problems,4,7
and following surgery, older adults report decreased difficulty with visual
tasks.8-10 However,
nothing is known about the impact of cataract surgery on driver safety. Since
cataract and the visibility problem it engenders increase crash risk in older
drivers, a question is whether surgical removal of the cataract and IOL implantation
reduces the likelihood of crashing.
Drivers older than 60 years have the lowest crash rate when measured
on the basis of licensed drivers—approximately 40 crashes per 1000 licensed
drivers compared with approximately 140 crashes per 1000 licensed drivers
among those younger than 25 years.11 However,
when measured on a per-mile-driven basis, older adults have a crash rate nearly
equivalent to that of younger drivers whose crash rate is the highest among
all age groups (approximately 15 crashes per million miles of travel). Once
in a crash, older adults are more likely to incur a disabling injury or die
than are younger drivers.12,13
Older adults are the fastest growing group of drivers on the road today, both
in terms of the total number of drivers and the number of miles driven annually.14 Thus, there is a pressing need to identify ways to
lower the rate of crash involvement among older drivers.
We report the results of the Impact of Cataracts on Mobility (ICOM)
project that was designed to address the question, for those older drivers
who have cataract, what is the impact of cataract surgery on crash rate in
the 4 years following surgery compared with those who have cataract who do
not elect surgery? Strengths of this study design are the use of a comparison
group of patients with cataract who do not undergo surgery followed prospectively
over the same time period and the statistical adjustment for potential differences
in the surgery and no surgery groups at baseline that could serve as confounders
for the hypothesized effect. Using a randomized design would have been unethical
since cataract surgery with intraocular lens implantation is an accepted and
proven standard of care.
Two groups of older adults with cataract were recruited through 10 ophthalmology
and 2 optometry clinics in Birmingham, Ala. The surgeons affiliated with practices
used for recruitment had operating privileges at the Callahan Eye Foundation
Hospital, a university-affiliated eye hospital. Potential subjects were identified
through consecutive chart review for patients seen in these clinics in the
prior 6-month period. Surgeons had no role in the selection of patients during
recruitment.
One group consisted of older adults with cataract who met the following
inclusion criteria at enrollment: (1) cataract in one or both eyes with acuity
of 20/40 or worse (best-corrected, distance) as indicated by the medical record;
(2) no previous cataract surgery in either eye; (3) cataract surgery in at
least one eye had been previously recommended by an ophthalmologist as a treatment
for the patient's visual problems and the subject elected to have the surgery;
(4) health insurance, either Medicare and/or a private plan, (5) at least
55 years old, (6) living independently in the community, and (7) licensed
to drive in the state of Alabama and had not given up driving. A second group
of older adults with cataract were also recruited who met the criteria as
outlined above, except that the patients did not elect cataract surgery as
a treatment for their visual problems (even though they were made aware by
the ophthalmologist or optometrist that it was an option). In both groups
the primary cause of vision loss had to be cataract as judged by the ophthalmologist
or optometrist.
Exclusion criteria were amblyopia, use of a wheelchair for mobility,
and diagnoses of dementia, Parkinson disease, psychosis, or any illness that
would likely preclude annual clinic visits for the follow-up period. Candidates
for enrollment were contacted by a letter describing the study, followed by
a telephone call from the study coordinator. Those who agreed to participate
were scheduled for an appointment at the Clinical Research Unit in the Department
of Ophthalmology, University of Alabama at Birmingham. Target enrollment (130/group)
was based on sample size calculations using data from a previous cross-sectional
study15,16 with the goal of having
power of 80% to detect a 2-fold difference in crash rate between those who
do and do not elect cataract surgery.
Information on key variables was obtained by telephone from those who
declined to participate in the ICOM project in order to facilitate the generalizability
of findings. As described in the baseline report,5
"refusers" were on average 3 years older, had slightly worse visual acuity,
were more likely to have low driving exposure, and were less likely to have
been involved in a crash in the prior 5 years, compared with those who enrolled.
The Institutional Review Board for Human Use at the University of Alabama
at Birmingham approved the study protocol. After the purpose of the study
was explained, each subject was asked to sign a document of informed consent
before enrolling. For subjects who had elected cataract surgery, the initial
(baseline) visit for the protocol was before their surgery date. The baseline
protocol was as described below for all enrollees. Test examiners were masked
to the crash histories of all subjects. Demographic data and driving status
during the prior 5 years were obtained through interview.
Three types of visual function were assessed for each eye separately:
acuity, contrast sensitivity, and disability glare. Visual function measurements
were made while subjects wore the lens correction they typically used during
the performance of everyday distance activities, including driving. This lens
correction was the refractive correction prescribed at the most recent eye
examination (within 6 months prior to enrollment). Distance acuity was measured
using the Early Treatment Diabetic Retinopathy Study (ETDRS) letter chart
and its standard protocol (Lighthouse Products, Long Island City, NY).17 Contrast sensitivity was measured with the Pelli-Robson
Contrast Sensitivity chart and its standard protocol18
and was expressed as log contrast sensitivity. Disability glare was estimated
with the Brightness Acuity Tester (BAT) as the subject viewed the Pelli-Robson
Chart and was defined as the Pelli-Robson score without the BAT minus the
Pelli-Robson score with the BAT.19,20
Lens photographs were taken for both eyes and evaluated for the presence and
severity of nuclear sclerotic, cortical, and posterior subcapsular opacities
by a trained grader using the Lens Opacities Classification System III (LOCS
III) protocol.21 Retinal fundus photographs
were also taken for both eyes and assessed by a trained grader for the presence
and severity of age-related maculopathy using a macula grading scale based
on the international classification and grading system.22
The graders were masked with respect to demographic, functional, medical,
and crash characteristics of subjects and whether or not cataract surgery
had been elected.
Cognitive status, visual processing speed/attentional ability, depression,
and general health were assessed because they have been associated with crash
involvement in older drivers and thus are potential confounders.16,23,24
Cognitive function was evaluated by the Mattis Organic Mental Syndrome Screening
Examination (MOMSSE),25,26 a 20-minute
test for assessing cognitive function in elderly people. It provides a composite
score that reflects performance in 14 domains of cognitive functioning, with
scores ranging from 0 to 28 (best score). Visual processing and attention
were assessed by the useful field of view test (Visual Awareness, Inc, Chicago,
Ill) where scores represent the percentage reduction (0-90) in visual attention
capability under brief target durations.27
The presence of depressive symptoms was assessed by the Center for Epidemiological
Studies Depression Scale (CES-D),28 where participants
rated 20 items based on how often they felt the way described in each item
in the last week (responses on a 4-point scale from "none of the time" to
"all of the time"). Total scores ranged from 0 to 60 (higher number signifies
more depressive symptoms). An estimate of general health was provided through
a questionnaire5 that asked about the presence
vs absence of problems in 17 areas (eg, heart disease, cancer, diabetes).
Current prescription medication usage was obtained from subjects by requesting
that they bring all prescription medications to the visit. Medication names
were transcribed from medicine containers and then converted into American
Hospital Formulary Service codes. Six medication classes known to have an
association with crash involvement29 were selected
for analysis (benzodiazepines; anxiolytics, sedatives, and hypnotics; psychotherapeutics;
antihistamines; hypoglycemics; opioid analgesics). The above protocol, except
for the lens and fundus photography, was repeated at 2 subsequent follow-up
visits at annual intervals. For subjects who underwent cataract surgery, information
about the date of surgery and the existence of complications was obtained
from the medical record.
The Alabama Department of Public Safety, the state agency in charge
of compiling crash records, provided information on collisions incurred by
each study participant for a 5-year period prior to study enrollment. This
information was used in combination with driving exposure information (estimated
miles driven per week) obtained through the Driving Habits Questionnaire5 to calculate crash rates per million miles of travel
for the surgery and no surgery groups for the period prior to enrollment.
Earlier work has demonstrated that older adults can provide valid estimates
of driving exposure.30
The primary outcome of interest was involvement in a police-reported
motor vehicle collision between the date of study enrollment (between 1994
and 1996) and either date of driving cessation, date of death, or March 1,
1999, whichever came first. Information about the number of crashes was obtained
through reports made available by the Alabama Department of Public Safety.
A secondary outcome was self-reported driving difficulty, obtained through
the Driving Habits Questionnaire, an interviewer-administered instrument mentioned
above and described previously for which reliability and validity have been
established.5 Subjects rated the degree of
difficulty they experienced during the previous 3 months when driving in 8
challenging situations (eg, at night, in the rain, making left turns, in rush
hour) on a 5-point scale (from "no difficulty" to "so difficult that I no
longer drive in that situation"). A composite score of driving difficulty
was computed across items and scaled on a 100-point scale (lower scores indicating
greater difficulty). Driving difficulty was assessed at baseline and at the
2 annual follow-up visits.
Descriptive statistics were generated for demographic, medical, visual
function, and crash rate and compared between cataract patients who did and
did not undergo cataract surgery using t and χ2 tests for continuous and categorical variables, respectively. The
dependent variable to test the primary hypothesis of the study was crash rate
per person-miles of travel. The numerator of this variable is the number of
motor vehicle collisions, for which collection is described above. For the
denominator, person-miles of travel during the follow-up period was based
on driving exposure information (estimated miles driven per week) obtained
through the Driving Habits Questionnaire.5
Driving exposure was estimated at baseline and at the 2 annual follow-up visits.
Each subject's person-miles of travel was calculated by summing the estimated
miles driven per week from the time of enrollment until the date of driving
cessation, date of death, or March 1, 1999, whichever came first. Mileage
information from the baseline interview was used for the first year of person-mileage
calculations while information from the first and second annual follow-ups
was used for the second and third years of calculations, respectively, when
necessary (eg, patient died before second visit). For patients who failed
to return for the first and second annual visits for reasons other than death,
baseline mileage information was used for all years of calculation. For these
calculations, it is assumed that the estimated miles driven per week provided
as part of the Driving Habits Questionnaire is consistent throughout the year.
Poisson regression was used to calculate the crude and adjusted rate ratio
(RR) and 95% confidence interval (CI) for the association between crash rate
and cataract surgery.
Prior to the selection of potential confounding variables for the adjusted
analyses, it was necessary to evaluate the form of several candidate variables
(age, education, cognitive status, depression, chronic medical conditions,
useful field of view, visual acuity, contrast sensitivity, disability glare)
to determine if these variables performed better in their natural form or
as categorical measures. Using previously established cutpoints for the variables
in question,5 2 separate models were constructed
for each variable. One model contained the variable in its continuous form
while the other model contained the categorical variable. The 2 models were
then compared using the likelihood ratio test. In all instances, the results
indicated that the continuous forms of the variables provided no better model
fit than the categorical forms and thus the former were used in all subsequent
analyses.
For the adjusted analyses, candidate demographic, medical, and visual
function variables were evaluated as potential confounding variables for the
association between cataract surgery and crash involvement using the change-in-estimate
strategy.31 For a variable to be included in
the adjusted analysis, the RR for the association between surgery and crash
involvement had to change by at least 10% following adjustment for the candidate
variable. Each candidate variable was evaluated individually and then those
that met the 10% criteria were included in a single multivariable model. Those
variables that met this criterion included race, visual acuity (better and
worse eye), and contrast sensitivity (better and worse eye).
P values of ≤.05 were considered statistically
significant. All data analyses were conducted using SAS v8.0 (SAS Institute
Inc, Cary, NC).
Between October 1994 and March 1996, 277 subjects with cataract were
enrolled in the ICOM project. At enrollment there were 140 subjects who were
scheduled for surgery and 137 subjects who decided against surgery. However,
over the course of the study 34 patients with cataract who originally at enrollment
did not elect surgery subsequently changed their decision, and in fact underwent
cataract surgery. Person-miles accumulated by these 34 subjects from the date
of enrollment to the date of surgery were allocated to the no surgery group
whereas those accumulated post-surgery were allocated to the surgery group.
This subset of subjects experienced no collisions between the time of enrollment
and the date of surgery. Thus the final sample for the cataract surgery group
was 174, and for the no surgery group, 103.
Demographic, medical, and visual characteristics for patients who did
or did not elect surgery by the end of the study period are presented in Table 1. There were no differences between
the groups with respect to age, years of education, or annual mileage. The
surgery group was less likely to be male and more likely to be white compared
with the no surgery group. There were no differences between the groups with
respect to the mean number of medical conditions or CES-D scores. The surgery
group had lower MOMSSE scores compared with the no surgery group (5.0 vs 6.2, P = .001). Thirteen percent of subjects electing cataract
surgery and 25% of subjects deciding against surgery had secondary ocular
conditions (nonexudative age-related maculopathy [ARM], primary open glaucoma,
or nonproliferative diabetic retinopathy). With respect to the presence and
severity of ARM as determined by fundus photograph grading, there was no significant
difference between the groups. Useful field of view scores as well as the
frequencies of medication use were also similar.
Compared with the no surgery group, visual acuity and contrast sensitivity
were worse in both the better and worse eyes in the surgery group at baseline,
whereas disability glare was more accentuated in the no surgery group compared
with the surgery group. There was no difference between the groups in the
motor vehicle crash rate in the 5 years preceding study enrollment.
For the surgery group, slightly over half of subjects (55.7%) had surgery
in both eyes. On average, surgery on the first eye took place 2.2 months from
the time of enrollment; 50% of subjects had first eye surgery less than 2
weeks from enrollment. For those who had surgery in both eyes, the mean interval
of time between first and second eye surgery was 8.9 months (median, 4.7 months).
For both first and second eyes, the most common type of extraction procedure
was phacoemulsification (95%). The incidence of intraoperative and postoperative
complications was low (3.0%). For the majority of subjects (93.2%), the primary
reason for cataract surgery cited in the medical record was difficulty with
non–driving-related activities (eg, reading, work). By visit 2, the
surgery group averaged a 2-line (10 letters, 0.2 log10 minimum
angle resolvable [logMAR]) acuity improvement on the ETDRS chart for both
the right and left eyes (SD, 0.3 logMAR). For the no surgery group at visit
2, acuity declined on average by 2 letters in the right eye and 1 letter in
the left eye (SD, 0.13 logMAR for both right and left eyes).
Table 2 presents the LOCS
III grades for the surgery and no surgery groups for the worse and better
eyes (defined by visual acuity). Cortical opacities were of similar magnitude
in the 2 groups. For the worse eye, the surgery group had more severe nuclear
sclerotic and posterior subcapsular grades than did the no surgery group.
For the better eye, the surgery group had more severe posterior subcapsular
grades but not nuclear sclerotic grades. The data are also stratified by right
and left eyes. The results are similar to those just described. In the right
eye, the mean nuclear sclerotic and posterior subcapsular grades were significantly
higher in the surgery group compared with the no surgery group. For the left
eye, the only difference between groups was for the posterior subcapsular
grade.
Table 3 presents the postbaseline
crash rates for the surgery and no surgery groups and associated RRs and 95%
CIs. Despite the 2 groups accumulating a similar number of collisions in aggregate,
the surgery group had nearly twice as many subjects and person-miles of travel.
Thus, the unadjusted RR comparing the surgery with the no surgery group was
0.64 (95% CI, 0.37-1.13). Following adjustment for race, visual acuity, and
contrast sensitivity, the RR was 0.47 (95% CI, 0.23-0.94), indicating approximately
half the rate of subsequent crash involvement for those who had cataract surgery
compared with those who did not have surgery. This RR estimate translates
to an absolute rate reduction of 4.74 crashes per million miles of travel
from a base rate of 8.95 crashes per million miles of travel (ie, the crash
rate among the no surgery group).
In addition to evaluating crash rates during the follow-up period, analyses
were also conducted to compare crash rates during the 5 years prior to study
enrollment and during the study follow-up period within the no surgery and
surgery groups. For the no surgery group, there was a significant 72% increase
(95% CI, 1.00-3.10) in crash rate while the surgery group experienced a statistically
nonsignificant 27% increase (95% CI, 0.80-2.10).
Figure 1 presents visual and
driving characteristics for the 2 groups measured at each of the 3 annual
study visits. Visual acuity in the worse eye was worse for the surgery group
at baseline compared with the no surgery group, but then was notably improved
at visit 2, not unexpectedly due to the fact that 86% of surgery patients
had their first eye surgery prior to visit 2. A similar pattern was observed
for contrast sensitivity. Visual acuity and contrast sensitivity data for
the better eye for both groups showed similar trends over the 2 years of follow-up.
At baseline, the driving difficulty composite score was lower for the surgery
group compared with the no surgery group, ie, they reported more difficulty
driving. By the second study visit the 2 groups were highly similar and by
visit 3 the cataract surgery group reported less difficulty, ie, they had
a higher score, compared with the no surgery group. For the no surgery group,
the driving difficulty composite remained at a moderately high score (indicating
little difficulty) throughout the 2 years of follow-up. Self-reported annual
mileage declined over the course of the study for both groups in a similar
fashion. Some subjects did not return for visits 2 and 3 (Figure 1), thus introducing the potential for improvements being
the result of subjects in poorer health not being followed up. Among those
not returning for visit 2 (35 subjects), the most common reasons cited were
subject or spouse had a serious illness (30%), no longer wanted to participate
(22%), death (14%), or could not contact or moved away (8%). The visit 3 reasons
for the 2 groups were very similar. When analyses were limited to only those
subjects who completed all 3 visits, the pattern of results was the same as
displayed in Figure 1.
In the 5 years before study enrollment, older drivers with cataract
who elected surgery and those who declined surgery had similar rates of crash
involvement. Subsequent to enrollment, those who had cataract surgery had
half the crash rate over the 4- to 6-year period following surgery compared
with those who decided against surgery. During follow-up, crash rate for those
having surgery increased only 27%, whereas for those who decided against surgery,
crash rate increased nearly 75% during this period. There were small, but
significant, baseline differences between the surgery and no surgery groups
in race, comorbid eye conditions, visual function, mental status, and cataract
severity, and the no surgery group was more likely to be male, all of which
are known risk factors for crash involvement. However, only 3 variables—race,
visual acuity, and contrast sensitivity—proved to be potentially confounding
factors and were included in the adjusted analysis. It is worth noting that
crash rate increased for both the surgery and no surgery groups during the
prospective period compared with their pre-enrollment rate, reflecting the
well-documented trend of increasing crash rate in the later decades of life.11,14 However, the increase was not statistically
significant in the surgery group whereas the no surgery group did experience
a significant increase. Our result that the cataract surgery intervention
slowed the rate of increasing crash rate is reminiscent of other effects in
gerontology for which the positive impact of intervention in older adults
is a slowing of the rate of decline, rather than a dramatic reversal of dysfunction
or disease.32,33
Over 10 years of outcomes research on cataract surgery has clearly demonstrated
that the vast majority of older patients experience positive effects after
cataract surgery and IOL implantation, including improvements in visual acuity
and contrast sensitivity,4,7,34,35
decreased difficulty (by self-report) in the tasks of daily living,8-10 and improvements in
visual task performance such as reading.7 The
present study suggests that cataract surgery has a previously undocumented
benefit for everyday life, namely, preventing the increased crash rate that
would be expected in future years without cataract removal. This information
could be useful when ophthalmologists and patients discuss the benefits vs
risks of cataract surgery, and could be critical information for patients
contemplating surgery who want a lifestyle that heavily depends on driving.
The present study was not designed to determine whether cataract surgery in
one eye is sufficient to generate a protective effect from crashing or whether
cataract removal in the second eye provides further benefits for driver safety,
an issue for further study. Second-eye surgery may be a practically important
consideration for patients with bilateral cataract, since previous findings
indicate that crash risk in older adults with cataract is more strongly linked
to vision in the worse functioning eye than in the better eye.6
Those patients who elected surgery expressed serious difficulty with
driving, which may have contributed to their decision for surgery. Following
surgery, they reported that driving was less difficult, in agreement with
earlier work.8,9,36
Those with cataract who declined surgery reported little driving difficulty
at baseline, which remained relatively stable throughout 2 years of follow-up.
Their driving difficulty composite scores were similar to those previously
published for older drivers who were free of cataract.5
It is interesting that even though they believed that they had little difficulty
with driving they had double the crash rate during follow-up, compared with
those who had surgery. These findings suggest that insight into how vision
impairment impacts driving, and the decisions and behaviors that result from
this self-awareness, may play a key role in understanding crash risk in older
drivers. Previous studies have shown that older drivers who are keenly aware
of their visual processing impairments including acuity and contrast sensitivity
deficits are more likely to avoid challenging driving situations.26,37
However, differences in awareness of visual impairment could also partly
explain the results of the current study. The patients who elect surgery may
be more concerned about the impact their cataract is having on their life
and this may reflect broader attitudes or concerns toward safety that are
associated with driver performance. This study collected information that
may reflect such attitudes toward safety including seat belt use, speeding,
and avoidance of difficult driving situations. Adjustment for these characteristics
yielded an association (RR, 0.49) that was not appreciably different than
that reported in Table 3 (RR,
0.47; 95% CI, 0.23-0.94). Another issue that could partly explain our results
is the possibility that those in the no surgery group were more likely to
drive at night than were those who had surgery, and this may have increased
their crash risk. At baseline, more surgery participants reported not driving
at night because of their vision compared with no surgery participants (8%
of no surgery group vs 18% of surgery group). However, by the time of the
second visit (the postsurgery visit for surgery participants), these percentages
were equivalent in the 2 groups (9% in both groups). Because surgery took
place in the surgery group on average within 1 week of enrollment, and because
at the first postsurgery follow-up the percentage of participants who stopped
driving at night was equivalent, it is unlikely that night driving had an
influence on our findings. Finally, alcohol use plays a prominent role in
crash risk in younger adults, thus raising the question of its role in the
findings reported here. At baseline there were no differences between the
surgery and no surgery groups in the number of reported drinks per week of
beer, wine, or liquor, and adjusting for alcohol use had no impact on the
results reported in Table 3.
Driving exposure (eg, miles driven per week) did not increase following
cataract surgery, even though vision improved. Rather, for both those undergoing
surgery and those declining surgery, driving exposure declined in a highly
similar pattern during the first 2 years of follow-up. These downward trends
in driving exposure in these older adults mirror those from national surveys
of elderly drivers,38 and suggest that the
amount of driving an older person does may not rebound even when functional
impairments are partially reversed as was the case in this study.
It is interesting to consider whether the improvements in vision following
surgery underlie the lower crash rate in the cataract surgery group. Previous
research has shown that contrast sensitivity impairment due to cataract, but
not visual acuity deficit, mediates the association between cataract and a
recent history of crash involvement.6 The present
study design does not permit the direct examination of this question because
virtually all surgery patients experienced improvements in visual acuity and
contrast sensitivity following surgery while the converse was true for those
who did not elect surgery. Therefore, changes in visual function are collinear
with surgery status and identifying the independent effect of these measures
is statistically unfeasible.
The results of randomized clinical trials represent the highest level
of scientific evidence in clinical research. Employing a randomized design
to address the relationship between cataract surgery and crash involvement
was not possible because cataract surgery is an accepted standard of care.
Thus, the design of the present study represents the best available approach.
However, because the 2 patient groups were not randomized to receive surgery
or to have their surgery delayed, there remains the possibility that the observed
results are due to confounding by some unmeasured variable. The evaluation
of measured potential confounders revealed only 3 variables—race, visual
acuity, and contrast sensitivity—for inclusion in the multivariable
analysis, yet the association was still present (RR, 0.47; 95% CI, 0.23-0.94).
In further analyses, additional variables were added to the multivariable
model because the literature suggests some of these variables increase crash
risk in older drivers.14 These included age,
sex, education, chronic medical conditions, depression, cognitive status,
comorbid eye conditions, useful field of view, and use of specific medications;
however, their inclusion in the model did not appreciably change the association
between surgery and crash involvement (RR, 0.53). Finally, an analysis was
also conducted wherein the numerator of the crash rate (per mile traveled)
was the number of crash-involved subjects rather than the number of crashes,
and again, the adjusted RR was similar to that presented in Table 3 (RR, 0.49).
Despite the increased crash rate in older drivers compared with middle-aged
adults, there are no primary prevention interventions focused on the older
driver that have proven effectiveness in reducing their crash risk. Several
have been proposed, including educational programs37,39-41
and cognitive training42,43; however,
their effectiveness in enhancing driver safety has not yet been determined.
Another means of reducing crash risk among older drivers may be the treatment
of common chronic diseases and conditions in elderly drivers that cause functional
impairments. Improvement in vision through cataract surgery and IOL implantation
is an example of this approach. The results here suggest that it could have
widespread benefit to driver safety in our society given the increase in the
older driver population14 and the high prevalence
of cataract in the population older than 65 years.1-3
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