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First published online March 28, 2008
Journal of Experimental Biology 211, 1336-1343 (2008)
Published by The Company of Biologists 2008
doi: 10.1242/jeb.011296
Estimating maximum performance: effects of intraindividual variation
Department of Biology, Harvey Mudd College, 301 Platt Boulevard, Claremont, CA 91711, USA
* Author for correspondence (e-mail: adolph{at}hmc.edu)
Accepted 4 February 2008
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Summary |
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 TOP Summary INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONCONCLUSIONSReferences |
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Key words: performance, correlation, intraindividual variation, repeatability, lizard, burst speed, bias, maximum
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INTRODUCTION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONCONCLUSIONSReferences |
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;
Arnold, 1983;
Arnold and Bennett, 1988;
Garland and Losos, 1995;
Norberg, 1995). Consequently,
hundreds of studies have measured burst speed, endurance, jumping distance and
other aspects of locomotor performance in the laboratory
(Garland, 1994; Wainwright and
Reilly, 1994; Garland and Losos,
1995; Alexander,
2002). Laboratory measurements of locomotor performance are used
for diverse purposes, ranging from identifying its mechanistic basis (e.g.
Garland, 1984;
Gleeson and Harrison, 1988;
Miles et al., 1995;
Bonine and Garland, 1999) to
examining the fitness consequences of among-individual variation in
performance (Arnold and Bennett,
1988; Jayne and Bennett,
1990; Watkins,
1996; Le Galliard et al.,
2004; Miles, 2004;
Husak et al., 2006;
Peterson and Husak, 2006;
Irschick and Meyers,
2007).
Whereas the goals of locomotion studies are diverse, laboratory procedures
often share a common feature: maximum performance [less commonly, mean
performance (Jayne and Bennett,
1990)] is estimated using a relatively small number of trials per
individual. Researchers have long recognized that the performance of
individual animals varies from one laboratory trial to the next. The presence
of intraindividual variation, coupled with relatively small sample sizes per
individual, guarantees that each individual's performance is estimated with
some error, whether individual maximum or mean values are used for statistical
analysis. In particular, maximum performance will always be underestimated, as
individuals will rarely achieve their true maximum in a small number of
laboratory trials. This problem was highlighted by Losos et al.
(Losos et al., 2002), who also
described the related problem of individual subjects who consistently perform
submaximally in the laboratory.
In this study we examined how intraindividual variation and per individual sample size affect the statistical estimation of performance. To obtain an example data set we measured burst speed performance in western fence lizards (Sceloporus occidentalis) 20 times per individual at 20°C and 35°C. We describe the intra- and interindividual statistical distributions of performance, and estimate overall repeatability and whether it varies over time. We then ran statistical sampling experiments that simulated laboratory studies in which speed was measured 1, 2, 3,... 20 times for each individual, to evaluate how the accuracy and precision of performance estimates vary with per individual sample size. This analysis addressed several goals.
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MATERIALS AND METHODS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONCONCLUSIONSReferences |
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). It is a
classic sit-and-wait predator with limited endurance capacity but can run
swiftly over short distances (Bennett and
Gleeson, 1976; Gleeson,
1979; Schall and Sarni,
1987). Locomotor performance of S. occidentalis has been
studied in diverse contexts (e.g. Bennett,
1980; Bennett and Gleeson,
1976; Garland et al.,
1990; Gleeson,
1979; Holem et al.,
2006; Marsh and Bennett,
1986; Schall et al.,
1982; Sinervo and Adolph,
1989; Sinervo and Huey,
1990; Sinervo et al.,
1991; Sinervo and Losos,
1991; Tsuji et al.,
1989; van Berkum,
1988; van Berkum and Tsuji,
1987; van Berkum et al.,
1989).
Collection and housing of subjects
We collected adult and subadult male lizards (N=21) from two sites
in Los Angeles County, California, in June 2004: Table Mountain (2 km
northwest of Wrightwood) and Joshua (8 km east of Valyermo). Adolph
(Adolph, 1990) and Sinervo and
Adolph (Sinervo and Adolph,
1994) provide further information on the ecology of S.
occidentalis at these sites. Lizard body mass averaged 10.1 g (range
5.6–15.2 g) and snout–vent length averaged 68.1 mm (range
60–79 mm). Lizards were held in the laboratory individually in 38 l
terraria with an incandescent light bulb (75 W) on 8 h per day. The air
temperature of the room averaged 20.5°C at night, and during the day the
light permitted the lizards to attain their preferred body temperature of
35°C. Lizards were fed crickets two to four times per week.
Measurement of sprint speed
We measured sprint speed following the procedures of Hertz et al.
(Hertz et al., 1983). Prior to
each run, lizards were held individually in 1 l plastic containers within a
constant-temperature chamber at either 35°C or 20°C for at least 1 h;
35°C is the optimal temperature for sprint locomotion in this species, and
is approximately the mean body temperature of field-active animals, whereas
20°C is at the lower end of the field body temperature distribution for
these populations (Bennett,
1980; Marsh and Bennett,
1986; van Berkum,
1988; Adolph,
1990). We removed each lizard from the chamber and chased it along
a horizontal racetrack (2.5 m longx28 cm wide) that had a rough particle
board surface. Photocells spaced every 0.25 m were connected to a computer
that recorded elapsed times (Huey et al.,
1981; Hertz et al.,
1983). We gave each lizard five training runs several days prior
to the experiment (Bennett,
1980). Trials were conducted between 10:00 h and 17:00 h. Each
lizard ran five trials per day, with at least 1 h rest in the environmental
chamber between trials. The fastest 0.75 m interval was used as the lizard's
speed for a given trial. Lizards were run in haphazard order for each trial on
a given day. We weighed and measured (snout–vent length) each lizard on
the first day of racing. Lizards were given 1–2 days of rest between
each set of five trials. All trials at 35°C were run first, followed by
the trials at 20°C. On one trial day at 35°C, three subjects were run
six times to replace data lost from previous runs.
Repeatability
We assessed the repeatability of sprint performance in several ways.
Overall repeatability of speed within each of the two temperatures was
examined by estimating intraclass correlation coefficients
(ri) following Haggard
(Haggard, 1958) (see also
Sokal and Rohlf, 1981;
Lessells and Boag, 1987).
Standard errors for intraclass correlation coefficients were calculated
following Becker (Becker,
1984). We also calculated pairwise Pearson product-moment
correlations between mean, median, maximum and minimum speed both within and
across temperatures as additional measures of individual consistency and
repeatability.
We tested for temporal dependence of repeatability within each temperature
by calculating all pairwise correlations rij between
speeds on trials i and j, where i
j and
both i and j range from 1 to 20. We tested the hypothesis
that the magnitude of rij should decrease with the
separation between trials (|i–j|); i.e.
trials that immediately follow one another should have more similar speeds
than widely spaced trials (T. Garland, Jr, personal communication). We used
Mantel tests (Mantel, 1967) to
assess the statistical significance of the relationship between pairwise
correlation of speeds and the spacing between trials because the number of
pairwise correlations (190) exceeded the number of independent trials (20). We
wrote a Matlab program using Manly's
(Manly, 1986) algorithm to
perform the Mantel tests.
Statistical sampling experiments
To determine the effects of sample size (number of trials per individual)
on estimates of performance parameters, we performed a sampling experiment in
which we randomly chose Ntrials speed measurements from
each individual (without replacement), where Ntrials
ranged from 1 to 20. We chose the maximum and mean speeds from the random
sample for each individual as performance estimates. This procedure was
repeated 1000 times for each value of Ntrials at each
temperature, using programs written in Matlab. This sampling experiment
allowed us to quantify the effect of Ntrials on the
precision and accuracy of estimating maximum speed, mean speed and the
correlation between speeds at the two temperatures.
We used the same procedure to evaluate how the magnitude of intraindividual
variation influences the sampling distribution of sprint speed statistics. To
do this, we modified the data set by multiplying each individual's sprint
speed residuals by a constant factor and adding these rescaled residuals back
to the individual's mean sprint speed, thereby changing the within-individual
variance but not the among-individual variance. We adjusted the data to
achieve repeatabilities (ri) of 0.25, 0.50 and 0.75 (for
examining correlations of mean speeds across temperatures) and to achieve mean
within-individual coefficients of variation (CV) of 10%, 20% and 30% (for
examining maximum speed). We then repeated the statistical sampling
experiments using these modified data sets. Mathieu et al.
(Mathieu et al., 1981)
performed a conceptually similar study involving the effects of measurement
error and sampling variation in stereological analysis of microscope
images.
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RESULTS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONCONCLUSIONSReferences |
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Lizards showed substantial interindividual and intraindividual variation in speed at both temperatures (Fig. 2). Maximum speed of individual subjects ranged from 1.34 to 2.27 m s–1 at 20°C and from 1.70 to 3.41 m s–1 at 35°C. Likewise, mean speed of individual subjects ranged from 0.56 to 1.91 m s–1 at 20°C and from 1.36 to 2.88 m s–1 at 35°C. Two individuals were unusually fast outliers at 35°C (Figs 2, 3). CV for speeds of individual lizards were similar at the two temperatures: the mean CV was 22.8% at 20°C (range 10.0–56.2%) and mean CV was 20.3% at 35°C (range 13.0–26.6%). The distribution of residual speeds around each subject's average speed did not differ significantly from normality (Ryan–Joiner tests). A randomization test (1000 trials; Matlab program) revealed no significant variation among individuals in the magnitude of residual speeds either at 20°C (P=0.815) or at 35°C (P=0.579). The symmetry of residual speeds is also reflected by the fact that median and mean speeds for each individual were nearly identical at each temperature (Fig. 3).
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The magnitude of the pairwise correlations between sprint speeds for two different trials decreased with increasing separation between the trials (Fig. 4). These declines were significant for both 20°C and 35°C (Mantel tests, P=0.010 and P=0.002, respectively). The regression equations for these relationships predicted a decrease in the pairwise correlation from 0.62 for successive trials to 0.50 for trial 1 vs trial 20 at 20°C, and from 0.60 for successive trials to 0.35 for trial 1 vs trial 20 at 35°C. Thus, repeatability of sprint speed declined with time over a 1–2 week time frame. However, separation between trials explained relatively little of the overall variation in pairwise correlations (r2=0.123 for 35°C and r2=0.058 for 20°C). Mean pairwise correlations (±s.d.) were 0.579 (±0.128) for 20°C and 0.516 (±0.176) for 35°C.
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Statistical sampling and the estimation of performance parameters
Statistical resampling of the data sets showed that estimates of maximum
sprint speed were biased when small samples were used: all values of
Ntrials<20 yielded underestimates on average
(Fig. 5). Both the magnitude of
the bias and variability of the estimate decreased as
Ntrials increased (Fig.
5), and the form of this relationship was virtually identical for
the 20°C and 35°C data. For example, choosing the fastest speed of two
trials per individual would underestimate maximum performance by 20% (on
average), whereas using five trials per individual would reduce this bias to
11%.
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The resampling experiment also showed that the correlation between individual mean speed at 20°C and individual mean speed at 35°C was underestimated; the magnitude of this bias was inversely related to Ntrials (Fig. 6). For example, the correlation between mean speeds at 20°C and 35°C averaged 0.47 for Ntrials=2 and increased to 0.59 for Ntrials=5. The sample variance of the estimated correlation coefficient was also much higher for lower values of Ntrials (Fig. 6). The correlation between maximum speeds at 20°C and 35°C likewise increased as a function of Ntrials (Fig. 6). The correlation between maximum speeds was lower than the correlation between mean speeds for all values of Ntrials except 1 (in which case the maximum and mean speed for an individual were the same).
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Magnitude of intraindividual variation and the estimation of performance parameters
The manipulated data sets illustrated how the amount of intraindividual
variation affects the bias in estimating performance parameters. Maximum
sprint performance was biased by the greatest amount (for a given value of
Ntrials) when the CV for each individual averaged 30%, and
least biased when average CV was adjusted to 10%
(Fig. 7A). Similarly, the bias
in the estimated correlation between mean speed at 20°C and mean speed at
35°C was greatest when repeatability was low
(ri=0.25), and bias decreased as repeatability increased
(Fig. 7B).
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DISCUSSION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONCONCLUSIONSReferences |
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;
Bennett, 1987;
Tolley et al., 1983;
Huey and Hertz, 1984;
Garland, 1985;
Huey and Dunham, 1987;
Jayne and Bennett, 1990;
Austin and Shaffer, 1992;
Reidy et al., 2000).
Repeatability is considered to set the upper bound for heritability of
quantitative traits, and therefore indicates the potential for traits to
respond to directional selection (Falconer
and Mackay, 1997) (but see
Dohm, 2002;
Nespolo and Franco, 2007).
Previous studies have documented both repeatability and broad-sense
heritability of sprint speed in S. occidentalis from Washington state
(van Berkum and Tsuji, 1987;
Tsuji et al., 1989;
van Berkum et al., 1989).
Bennett (Bennett, 1980) found
that individual differences in sprint speed in S. occidentalis from
southern California were consistent across temperatures. Our study confirms
these earlier findings for this species.
However, a trait can be significantly repeatable and still exhibit substantial intraindividual variation. Intraindividual variation comprises about 50% of the overall phenotypic variation in sprint performance of fence lizards at both 20°C and 35°C. In contrast to interindividual variation, intraindividual variation is not informative for researchers; it is functionally equivalent to measurement error. Nevertheless, it is important to quantify intraindividual variation because it leads to biased estimates of maximum performance and of the correlations between traits. These biases can be substantial for the sample sizes often used in locomotion studies.
Studies of sprint locomotion in lizards typically use from two to five trials per individual per condition (e.g. different temperatures, slopes, perch diameters). If the magnitude of intraindividual variation is similar for different species, our analysis indicates that published maximum performance values are underestimated by 10–20% on average. This bias may not be a problem in some contexts; for example, the estimated optimal temperature for sprint performance would probably not be affected much. However, comparisons of maximum performance between species or populations could be affected if either the number of trials per individual or the amount of intraindividual variation differed between the samples. Therefore, we recommend that researchers report average CV for individuals in addition to reporting Ntrials; future quantitative analyses may provide correction factors that rely on this information.
Few studies report information about the absolute amount of intraindividual
variation in speed in lizards or other animals. One noteworthy exception is
Bennett's (Bennett, 1980) study
of burst sprint speed in S. occidentalis and several other lizard
species [Aspidoscelis (Cnemidophorus) murinus,
Dipsosaurus dorsalis, Plestiodon (Eumeces) obsoletus,
Elgaria (Gerrhonotus) multicarinatus and Uma
inornata]. In each of these six species the maximum speed from three
trials was approximately 15% higher than the average speed. Our results for
S. occidentalis were very similar: the maximum speed from three
trials averaged 17.6% higher than the mean speed for 35°C and 17.9% higher
for 20°C. This suggests that the CV of speeds for each individual is
similar for these six lizard species, which represent six different families.
Consequently, the statistical properties of the estimated maximum sprint speed
(Fig. 5) might be similar for
diverse groups of lizards.
Fuiman and Cowan (Fuiman and Cowan,
2003) reported averages of individual CV for a variety of
anti-predator performance traits in larval fish (Sciaenops
ocellatus). Average CV varied widely among traits, ranging from 14.5% for
visual response latency score to 91.3% for acoustic response score. Their
results illustrate that CV of performance variables can be quite high,
underscoring the importance of using multiple trials for estimating maximum
values. Interestingly, routine swimming speed in S. ocellatus has a
high CV (38.7%) but also a high repeatability (ri=0.86),
reflecting a large among-individual variance.
Statistical remedies for bias in estimating performance parameters
The underestimation of correlation coefficients
(Fig. 6) due to intraindividual
variation (or measurement error) has long been known to statisticians
(Spearman, 1904;
Fuller, 1987), but is not well
known in organismal biology. There is a simple estimator that corrects for
this bias, as long as the repeatabilities for both traits are known
(Adolph and Hardin, 2007).
Using this estimator yields an estimate of r=0.686 for the
correlation between mean speeds at 20°C and 35°C, which is slightly
higher than the correlation between mean speeds obtained using all 20 samples
for each individual (0.657; Table
2). This indicates that even a large per individual sample will
underestimate the correlation coefficient on average.
Attenuation of correlation coefficients can affect our ability to detect
functional relationships between traits. For example, a number of studies have
investigated whether individual variation in muscle fiber morphology, enzyme
activity, and other lower-level physiological and biochemical traits is
correlated with individual variation in whole-organism locomotor performance
(Garland, 1984;
Gleeson and Harrison, 1988;
Bennett et al., 1989;
Husak et al., 2006).
Attenuation due to within-individual variation in either or both traits could
reduce the sample correlation coefficient to a non-significant value. The
degree of attenuation can be reduced by using the mean of multiple
measurements for each individual, which has dual benefits: it increases
statistical power and it permits an unbiased estimate of the correlation
(Adolph and Hardin, 2007).
Whereas bias in correlation coefficients involving individual mean values
is straightforward to correct, we do not know of a simple statistical remedy
for the underestimation of maximal performance per se, or of the
correlations involving maximum performance values. Statistical distributions
of maxima and minima are generally more complicated than are distributions of
mean values (Gumbel, 1958;
Gaines and Denny, 1993), and
are likely to differ among organisms and due to laboratory procedures.
Temporal changes in repeatability
While burst speed was significantly repeatable both within and between
temperatures, the magnitude of repeatability declined with the temporal
separation between trials (Fig.
4). Because we measured sprint speed over a relatively short time
span (several weeks), it is unlikely that the decline in repeatability was due
to changes in the physiological factors affecting speed, particularly given
the lack of a decline in speed during this study
(Fig. 1). Instead, it seems
more likely that temporal fluctuations in labile behavioral factors such as
motivation are responsible for the decline in repeatability over time. For
example, two successive races may be more likely to be run under similar
motivational levels, contributing to the greater similarity of sprint speeds
measured close together in time.
Other researchers have reported decreases in repeatability of locomotor
performance over time, particularly when measurements were separated by time
spans of several months to several years
(van Berkum et al., 1989;
Shaffer et al., 1991;
Watkins, 1997;
Elnitsky and Claussen, 2006).
For example, Jayne and Bennett (Jayne and
Bennett, 1990) found that the magnitude of correlations involving
speed and endurance in garter snakes decreased with increasing time separating
the measurements. Similarly, Austin and Shaffer
(Austin and Shaffer, 1992)
found that repeatability of speed in tiger salamanders was lower over a 15
month period than over shorter time intervals. However, long-term declines in
repeatability are not inevitable for locomotor performance or other
physiological traits, as several other studies illustrate
(Rønning et al., 2005;
Vézina and Williams,
2005; Elnitzsky and Claussen, 2006;
Nespolo and Franco, 2007).
Implications of intraindividual variability for performance in the field
Several recent studies have combined laboratory and field measurements of
locomotor performance by lizards (Irschick
and Garland, 2001;
Braña, 2003;
Irschick, 2003;
Irschick et al., 2005;
Husak, 2006;
Husak and Fox, 2006). These
studies have shown that individual lizards in the field often do not use their
maximum locomotor capacity during activities such as predator avoidance and
foraging. These findings highlight the importance of accurately estimating
maximum sprint performance in the laboratory, because realized performances in
the field are evaluated by direct comparison to laboratory values. Bias and
lack of precision in estimating laboratory performance values will result in
reduced statistical power for detecting interesting patterns that involve
individual field-to-laboratory comparisons.
Exceptional individual performances
Two individuals at 35°C were substantially faster than the rest of the
sample (Figs 2 and
3). The mean speeds of each of
these two individuals were 2.5 and 2.9 s.d. greater than the population mean
speed at 35°C. These two individuals were likewise among the fastest
individuals at 20°C, ranking 2nd and 6th out of 21 individuals. However,
we did not observe any unusually fast outliers at 20°C (Figs
2 and
3). Other studies have
sometimes identified unusually strong performances by a few individuals in a
sample (Bennett and Huey,
1990). For example, Huey et al.
(Huey et al., 1990) measured
endurance times in two Sceloporus merriami females that exceeded the
population mean by more than 6 s.d. The physiological or behavioral bases for
these exceptional performances by lizards are unknown. Intriguingly, Garland
et al. (Garland et al., 2002)
have discovered a discrete polymorphism in leg muscle structure and function
within artificially selected mouse populations. These two muscle types differ
in their biochemistry and contractile properties and exhibit a trade-off
between endurance and power. The discrete polymorphism evidently results from
variation at a single genetic locus
(Garland et al., 2002;
Houle-Leroy et al., 2003).
Single-locus effects on muscle structure and running performance have also
been described in whippets (Mosher et al.,
2007).
In lizards, muscle fiber-type composition varies substantially among
species, and is correlated interspecifically with locomotor performance
capability [burst speed vs endurance
(Bonine et al., 2001;
Bonine et al., 2005)].
Similarly, Gleeson and Harrison (Gleeson
and Harrison, 1988) found significant negative correlations
between some measurements of muscle fiber size and sprint speed among
individual desert iguanas, suggesting a possible causal relationship. Although
Gleeson and Harrison (Gleeson and
Harrison, 1988) did not mention exceptional individual
performances, they did report approximately twofold variation in speed among
individuals, which is typical for lizards in general. Populations that reveal
exceptional individual performances, such as we observed in two individuals at
35°C, might serve as promising candidates for exploring whether genetic
variants with discretely different locomotor capabilities exist in lizards,
and for detecting discrete differences in morphological or biochemical traits
associated with performance.
Whereas two individuals at 35°C were exceptionally fast runners, we did
not observe any unusually slow individuals that were clearly performing
submaximally. Instead, lizards had similar magnitudes of within-individual
variation in speed, and the distribution of mean speeds among individuals did
not show any discontinuities or outliers that would indicate submaximally
performing individuals (Losos et al.,
2002).
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CONCLUSIONS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONCONCLUSIONSReferences |
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Acknowledgments |
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Footnotes |
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Present address: Division of Biostatistics, Department of Preventive
Medicine, Keck School of Medicine, University of Southern California, 1540
Alcazar, Los Angeles, CA 90089-9010, USA 
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