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First published online October 7, 2008
Journal of Experimental Biology 211, 3258-3265 (2008)
Published by The Company of Biologists 2008
doi: 10.1242/jeb.017533
Scaling the duration of activity relative to body mass results in similar locomotor performance and metabolic costs in lizards
Department of Integrative Physiology, University of Colorado, Boulder, CO 80309, USA
* Author for correspondence at present address: Biology Department, MS 314, University of Nevada, Reno, NV 89557, USA (e-mail: edonovan{at}unr.edu)
Accepted 20 August 2008
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Summary |
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 TOP Summary INTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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O2. Following
activity, EPOC volume (ml O2) and the cost of activity per body
length traveled (ml O2 per body length) scaled linearly with body
mass. This study shows that the mass-specific costs of activity over an
equivalent number of body lengths are similar across a broad range of body
mass and does not show the typical patterns of allometric scaling seen when
cost of locomotion are expressed on a per meter basis. Under field conditions
larger animals are likely to travel greater absolute distances in a given bout
of activity than smaller animals but may travel a similar number of body
lengths. This study suggests that if locomotor costs are measured on a
relative scale (ml O2 per body length traveled), which reflects
these differences in daily movement distances, that locomotor efficiency is
similar across a wide range of body mass.
Key words: energetics, lactate, locomotion, scaling
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INTRODUCTION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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;
Van Damme and Van Dooren,
1999; Iriarte-Diaz, 2002). Comparing animals on the same absolute
scale by holding speed, duration of activity or total distance constant all
pose problems when asking questions relevant to the ecology and daily field
energetics of each species examined. Home ranges, daily movement distances and
maximum running distance have all been shown to increase with an animal's body
mass in a variety of species (Garland,
1983a; Garland,
1993; Lindstedt et al.,
1986; Perry and Garland,
2002) indicating that larger animals move greater distances to
accomplish the same daily activities as smaller animals. Because of this it
does not always make sense to compare the locomotor costs of traveling a fixed
distance between animals of different size. Similarly, running speed
(Garland, 1983b), endurance
(Garland, 1994) and the speed
at which the maximal rate of oxygen consumption
(O2,max) is
reached (Taylor et al., 1981)
have been shown to scale positively with body mass. Because of these
allometric relationships, holding the duration of activity or speed constant
would result in animals traveling at different multiples of their maximum
endurance time or maximum speed and at different multiples of their
O2,max.
An alternative is to adjust activity patterns such that each animal is
compared on the same relative scale. To accomplish this, locomotor performance
is often compared at a common gait
(Heglund and Taylor, 1988;
Drucker, 1996), relative to
the number of body lengths traveled
(Bainbridge, 1958;
Videler and Wardle, 1991), or
at the same percentage of each animal's maximum aerobic speed
(Weibel et al., 2004). These
methods allow for comparisons that can be thought of as behaviorally or
physiologically equivalent across a range of body masses. The importance of
examining activity scaled to animal size is supported by Van Damme and Van
Dooren (Van Damme and Van Dooren,
1999) who showed that relative speed (in body lengths per second)
may be more important to predator avoidance than absolute speed. This idea
also applies to studies of daily energetics and overall daily movement.
Garland (Garland, 1984) showed
that for Ctenosaura similis endurance scales in a similar fashion to
maximum running distance (0.270 and 0.265 power of body mass, respectively)
suggesting that, relative to how far lizards move, endurance is similar at
different body masses.
Measuring locomotor energetics relative to home range, daily movement
distance, or some other parameter that is relevant to each species' natural
behavior would be an effective way to compare locomotor costs and gain insight
into the actual energetic demands faced in the field. However, the
difficulties involved in doing detailed metabolic measurements with even a
moderate number of species makes collecting this kind of additional field
behavior data prohibitive. In this study we test the use of an easily measured
parameter, body mass, as a way to scale the duration of activity in order to
compare locomotor energetics in lizards. By scaling run times to the 1/4 power
of body mass this study attempted to establish a comparable activity pattern
across an 800-fold range in mass. Based on the scaling of stride frequency to
body mass and length (Heglund and Taylor,
1988; Marsh and Bennett,
1985; Irschick and Jayne,
1999) we predicted that scaling run times in this manner would
result in animals traveling a similar number of body lengths. Measurements of
the cost of activity (Cact), which is the total metabolic
cost incurred by activity during both the activity and recovery periods
(Baker and Gleeson, 1998), and
associated locomotor parameters were used to evaluate the effectiveness of
scaling locomotion in this fashion. Although other aspects of resting and
activity metabolism have been examined in relation to body mass, we are
unaware of any data on how Cact might vary with body mass.
This study presents data on this relationship in lizards.
We also used this approach to test the hypothesis that the metabolic
strategy for clearing post-activity lactate should depend on body mass in
lizards. Following exhaustive exercise, lactate is elevated to a similar
concentration across lizards of different mass. However, reptiles appear to
remove lactate at a slower rate as they get larger
(Moberly, 1968;
Bennett and Licht, 1972;
Coulson, 1980;
Gleeson, 1980;
Gleeson, 1982;
Gleeson and Bennett, 1982;
Hailey et al., 1987;
Gleeson and Dalessio, 1989).
In addition, activities of key glycolytic and oxidative enzymes in muscles
have been shown to vary with body mass, based on studies in both mammals and
fish (Emmett and Hochachka,
1981; Somero and Childress,
1990; Norton et al.,
2000; Davies and Moyes,
2007), further suggesting that rates of lactate metabolism might
be sensitive to body mass. Mass-specific resting rates of oxidative metabolism
decrease as body mass increases suggesting that less oxidative fuel would be
needed in larger animals per gram of body mass. Based on the patterns in
enzyme activities and oxidative metabolism we predicted that the fate of
lactate would be mass sensitive, with a smaller proportion of the
post-exercise lactate load being oxidized as body mass increased and a greater
proportion being converted to glycogen.
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MATERIALS AND METHODS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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Metabolic gas analysis
During all procedures involving gas analysis, exhaled breath was analyzed
for CO2 and O2 content using an Anarad AR-411
CO2 analyzer and an Applied Electrochemistry S3A O2
analyzer. All gases were passed through Drierite to remove water vapor before
analysis. Gas analysis was run in 20 min intervals with the first 2 min of
each interval used for calibration. Respiratory gases from smaller animals
(U. stansburiana, S. occidentalis) were sampled using an open-flow
chamber. Larger animals (D. dorsalis, C. similis, I. iguana) were
fitted with masks covering the mouth and nares. Air flow through the mask or
chamber was at a rate that ensured all exhaled gases were drawn through the
analyzers (flow rates: U. stansburiana, 0.15 l
min–1; S. occidentalis, 0.2 l
min–1; D. dorsalis, 0.4 l min–1;
C. similis, 2.5 l min–1; I. iguana, 4.0 l
min–1). To minimize washout and mixing effects the chambers
used for the smaller species were fitted to the animal's body size to reduce
movement and ensure that the head remained inside a close fitting cone
attached to the outgoing air tube. Larger animals were also placed inside
appropriately sized containers to similarly restrict movement during recovery.
For the larger lizards, masks were removed before running and replaced
immediately following activity.
Trial 1: recovery from scaled activity
All animals were fasted for 3 days prior to trials. On the day before the
trial, animals were weighed and their snout–vent length was measured
then placed in individual cages overnight. On the morning of the trial they
were moved to a temperature-controlled cabinet until they reached their
preferred body temperature (35°C for all animals except D.
dorsalis, which was at 40°C)
(Norris, 1953;
McGinnis, 1966;
Waldschmidt and Tracy, 1983;
Garland, 1984;
van Marken Lichtenbelt et al.,
1997). Cloacal body temperature was checked using a Yellow Springs
Instruments thermistor. Animals were kept at their preferred temperature for
the entire trial. After reaching a stable body temperature animals were fitted
with a mask or placed in an open-flow chamber and then placed back in the
temperature-controlled cabinet for 3 h to determine their resting metabolic
rate (RMR). The lowest 15 min average
O2 (ml
O2 h–1) over this span was used to determine
RMR.
Following measurements of RMR animals were placed on the treadmill surface
and immediately induced to run at their maximum speed for a duration
determined by the following equation:
 | (1) |
|
; Savage et al.,
2004), mass-specific resting metabolic rates in reptiles do appear
to scale to the 1/4 power of body mass
(White et al., 2006). This
scaling value was also chosen based on the frequency with which it has been
found to be associated with the allometric scaling of animal locomotion
(Lindstedt, and Calder, 1981;
Huey and Hertz, 1982;
Garland, 1983a;
Garland, 1984;
Heglund and Taylor, 1988). The
constant (4.94) was set so that the middle species in the body mass range,
D. dorsalis, would run for 15 s, the longest interval that D.
dorsalis has been observed to run in the field
(Hancock et al., 2001). The
run time of this species was chosen to determine the scaling constant as it
was the only one for which data on voluntary locomotory duration were
available. Animals were induced to run by tapping the base of the tail. Only
trials where an animal ran consistently for the entire time period were used.
The width of the treadmill surface was adjusted for each species so that each
animal was forced to run in a straight line with minimal side-to-side motion.
Treadmill speed was continuously adjusted to match running speed, and distance
was determined by integrating treadmill speed over the run.
At the end of the run, animals were masked or put back in respiratory
chambers, placed inside the temperature-controlled chamber and allowed to
recover undisturbed for 2 h. Following the run it took approximately 5 s to
mask an animal or place it into its respiratory chamber.
O2,peak (ml
O2 h–1) was calculated as the highest 10 s average
oxygen consumption rate immediately following activity. During recovery the
excess post-exercise oxygen consumption (EPOC)
(Gaesser and Brooks, 1984),
which is the total volume of oxygen consumed in excess of the animal's RMR,
was measured and used to determine the cost of activity
(Cact) (Baker and
Gleeson, 1998). Cact is defined here as the
total EPOC during recovery per unit distance traveled. We used oxygen
consumption during just the recovery period to represent
Cact because lizards breathe irregularly while running
(Wang et al., 1997) and oxygen
consumption during 15 s sprints in D. dorsalis accounts for only 2%
of the metabolic costs incurred by activity
(Donovan and Gleeson,
2006).
The duration of the EPOC period was determined by how long it took each
animal's O2 to
fall to 1.5x their RMR (Baker and
Gleeson, 1999; Hancock and
Gleeson, 2002). Each animal was run twice and the results were
averaged within each species. Trials for individual animals were separated by
at least 5 days.
Trial 2: profile of post-exercise lactate metabolism
A second round of trials was conducted to determine the metabolic fate of
lactate during recovery. The animal handling and exercise protocols were the
same as above except for the following changes. After reaching a resting
state, but prior to running, each animal was injected intra-peritoneally with
0.0125 µCi g–1 of U-14C-lactate (ICN
Biomedicals, Irvine, CA, USA). To account for the increase in circulation time
as body mass increases (Holt et al.,
1968; Prothero,
1980) each animal was allowed to rest following the injection for
a time scaled to its body mass:
 | (2) |
The constant in this equation was chosen to set the equilibration time for
D. dorsalis to 20 min, which has been shown to be sufficient time for
injected lactate to reach a steady state of oxidation
(Donovan and Gleeson, 2006).
At the end of the equilibration time each animal was run in the same fashion
as described above and then allowed to recover for a duration equal to twice
the EPOC period determined from the first trial.
During the recovery period exhaled CO2 was collected using 15 ml
CO2 traps consisting of ethanolamine and methycellusolve mixed in a
1:3 ratio (Brooks et al.,
1973). Traps were changed every 10 min and analyzed for
14CO2 content as described by Donovan and Gleeson
(Donovan and Gleeson, 2006).
At the end of the recovery period muscle samples were taken. For samples of
D. dorsalis, S. occidentalis and U. stansburiana, animals
were decapitated into liquid nitrogen and hind legs were clamped between
aluminum blocks cooled in liquid nitrogen, cut off and submerged in liquid
nitrogen. The gastrocnemius was then removed from the frozen legs. For I.
iguana and C. similis, because of the limited availability of
these larger species, biopsies from the gastrocnemius were taken to allow for
a second sample from the other leg, if needed. After cleaning the area of skin
over the gastrocnemius with iodine, Lidocaine (20 mg ml–1)
was injected to anaesthetize the area. A 1 cm incision was made and a strip of
muscle (approximately 200 mg) was cut away and frozen in liquid nitrogen. The
site of the incision was sutured and sealed with a liquid wound sealant
(Liquid Bandage, Johnson and Johnson). For one I. iguana a second
trial was needed because the animal refused to run during the first trial. The
second trial was conducted 1 month following the first to allow for complete
healing from the initial biopsy and for exhaled 14CO2 to
return to background levels (Donovan and
Gleeson, 2006). The second sample was taken from the other leg,
not from the same site as the first sample. All muscle samples were kept at
–70°C until analyzed for [14C]glycogen content to
determine conversion of lactate into glycogen, as described previously
(Donovan and Gleeson,
2006).
|
The mean trait values for each species, transformed when appropriate, were
used to generate phylogenetically independent contrasts (PIC) which correct
for the non-independence due to the phylogenetic relationships between species
(Felsenstein, 1985;
Harvey and Pagel, 1991). The
phylogeny for this analysis was produced from sequences for the highly
conserved mitochondrial cytochrome b gene
(Graybeal, 1993; Jonhs and
Avise, 1998; Bradley and Baker,
2001) obtained from GenBank
(Petren and Case, 1997;
Radtkey et al., 1997;
Paulo et al., 2001;
Whiting et al., 2003;
Hodges and Zamudio, 2004;
Kumazawa and Nishida, 1995)
and aligned using ClustalX v.1.81 software
(Thompson et al., 1997). PAUP
v.4.0b10 was used to construct a rooted phylogeny, using a minimum evolution
model, and to determine branch lengths in units of total character differences
between each species (Fig. 1).
In addition to the five species mentioned above, sequences for
Cnemidophorus tigris, Tiliqua gigas and Lacerta agilis were
also included as outgroups to root the tree. Physiological measurements were
not made for the three outgroup species. Mesquite v.1.06
(Maddison and Maddison, 2004)
and the PDTREE package v.1.07 (Midford et
al., 2005) were used to calculate the PIC values for each node in
Fig. 1
(Garland et al., 1999;
Garland and Ives, 2000).
The standardized independent contrasts for each variable were regressed on the standardized contrasts values for mass. Visual assessment of all plots following transformation indicated that a linear regression was appropriate to determine if a significant allometric trend was present in the data and all variables were analyzed using least squares regression. All of the statistical results (Table 1) are based on these phylogenetically independent contrasts (PIC). Figures show the variables in their original units (log transformed when appropriate), not those of the PIC values. Figures also show the trait values of individuals within each species to illustrate the within-species variance.
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RESULTS |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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; Wiens
and Hollingsworth, 2000; Townsend et al.,
2004) and the phylogeny generated for this study agrees with the
evolutionary relationships shown by these previous studies. However, we chose
to construct our own phylogeny in order to generate a consistent set of branch
length values for use in our analysis. The appropriateness of the branch
lengths of the phylogeny used in this analysis were checked by regressing the
absolute values of the standardized PIC values on their standard deviations
(Garland et al., 1992).
Results for this diagnostic showed no significant relationships for any of the
physiological variables (all P-values >0.37), suggesting that the
branch length assumptions are adequate.
Table 2 summarizes the size,
activity patterns and metabolic variables measured for each species. Although
the absolute distance in meters traveled by each species did increase with
body mass (Fig. 2A;
P=0.001) the relative distance in total body lengths did not vary
with body mass (Fig. 2B;
P=0.39). The scaling of run times to the 1/4 power of body mass
resulted in each species running an average of 168±11 body lengths. RMR
(ml O2 h–1) scaled significantly with body and
showed an allometric slope of 0.71. Both the total EPOC
(Fig. 3A; P=0.001) and
the Cact per body length traveled
(Fig. 3C; P=0.001)
scaled linearly with body mass.
O2,peak
(P=0.0001) and Cact per meter traveled
(Fig. 3D; P=0.002)
were both significantly dependent on body mass and showed a negative
allometric trend with slope significantly less than 1. The ratio of
O2,peak to RMR
was calculated to determine the factorial increase in
O2 following
activity (Fig. 3B). This ratio
had a mean of 8.94±0.56 and did not vary with body mass
(P=0.44).
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Data for the removal of lactate are presented as the percentage of the total injected 14C from lactate appearing in either the exhaled CO2 or the muscle glycogen pools during the recovery period (Table 2). Data are expressed per whole animal and per gram of muscle mass, respectively. Whole-body oxidation of lactate (Fig. 4A) during the recovery period was not significantly related to body mass (P=0.15). Glycogen synthesis per gram of muscle (Fig. 4B) showed a significant negative correlation with body mass (P=0.03).
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DISCUSSION |
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TOPSummaryINTRODUCTIONMATERIALS AND METHODSRESULTSDISCUSSIONReferences |
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). In addition, the total number of limb cycles and muscle
contractions would vary widely. Using estimates for the scaling of stride
length with body size (Heglund and Taylor,
1988; Marsh and Bennett,
1985; Irschick and Jayne,
1999) a U. stansburiana would need 69 strides to cover 10
meters whereas I. iguana would need only seven strides. In this study
each animal ran for an approximately equivalent number of body lengths
(Fig. 2B). In addition, from
the estimates of the scaling of stride length to body mass cited above, each
animal used roughly the same number of strides during activity. This supports
the use of our method of scaling run times to body mass as a way to compare
relatively equivalent behaviors between animals covering a wide mass range.
This method allows for comparisons of distances that probably correlate more
closely to the actual distances they might cover in their daily movements than
would runs of the same absolute distance.
Another consideration for studies of different body mass is how to evaluate
comparisons of the intensity of their metabolic effort. During steady-state
locomotion in mammals this comparison is frequently based on
O2,max, and
activities are often considered metabolically comparable if each animal
performs at the same percentage of this value. Reptiles are generally only
able to sustain low levels of steady-state activity and
O2,max is
achieved at speeds much lower than those reached during typical running
behavior (Bennett, 1978).
However, O2
dramatically increases soon after the end of vigorous activity
(Scholnick and Gleeson, 2000;
Hancock et al., 2001;
Donovan and Gleeson, 2006) and
the current study uses
O2,peak
following each run instead of
O2,max to
compare the relative intensity of metabolic expenditure by each animal. The
model of activity used here resulted in the same factorial-increase in
O2 across the
range of body mass measured (Fig.
3B) which indicates a similar amount of metabolic effort by each
species.
Cost of activity
In general, costs of locomotion increase with body mass but with a slope of
less than 1 when measured on a per meter or per hour basis
(Taylor et al., 1982;
Garland, 1983b;
Walton et al., 1990;
Rome, 1992) showing that on a
mass-specific scale, larger animals have lower costs of locomotion than
smaller animals. However, for reasons discussed previously, comparing activity
over a fixed time or distance is very different from comparisons among animals
that have traveled a similar number of body lengths. Comparisons of costs of
activity per meter or per hour may not be as relevant when trying to compare
the daily energetics of the animals of varying body mass.
Our data show that when traveling the same number of body lengths locomotor
costs scale isometrically and that larger lizards did not have a lower
mass-specific cost of activity, per body length traveled, than smaller lizards
(Fig. 3C). The fact that
Cact scales linearly with body mass under these conditions
suggests that mass-specific locomotor costs, relative to the actual distances
traveled by an animal during normal daily locomotion may be similar across a
wide range of body mass. These findings are similar to previous work showing
that when mammals are run at equivalent gaits, the cost of locomotion per
stride is independent of body mass
(Heglund and Taylor, 1988).
Heglund and Taylor (Heglund and Taylor,
1988) showed that the increase in mass-specific metabolic rate
seen as body mass decreases is due to the greater stride frequency in smaller
animals.
Post-activity lactate metabolism
Lizards generate large amounts of lactate during vigorous activity. In
D. dorsalis the conversion of lactate into glycogen is the major
metabolic cost during recovery while oxidation of lactate provides most of the
ATP required to fuel recovery costs
(Gleeson and Dalessio, 1989;
Donovan and Gleeson, 2006;
Hancock and Gleeson, 2008). We
hypothesized that the mass-specific metabolic fate of lactate between glycogen
synthesis and oxidation would shift with body mass. Use of lactate as an
oxidative substrate to pay recovery costs was predicted to occur to a greater
degree in smaller species because of the higher mass-specific metabolic rate,
and therefore greater rate of cellular ATP use. Conversely, we hypothesized
that the ATP-consuming process of converting lactate to glycogen would be
preferred in larger species. Although this strategy would increase the
short-term metabolic recovery costs for larger animals, the immediate
oxidation of lactate could provide more ATP than would be needed by larger
animals with lower mass specific metabolic rates. Converting the lactate back
to glycogen would preserve much of the chemical energy in the lactate pool for
later use.
Data presented here provide mixed support for this hypothesis. Across all species whole-animal lactate oxidation did not show a clear allometric trend and the data indicate that each species is oxidizing a similar percentage of its total lactate load during recovery. This suggests that mass-specific oxidation of lactate would scale with an exponent close to –1 and decrease to a greater degree with increasing body mass that does the conversion of lactate to glycogen (slope=–0.77). This trend supports our hypothesis of an increase in the relative mass-specific fate of lactate metabolism towards conversion to glycogen. However, the confidence intervals around these slopes and the variation in the percentage values (Table 1 and Table 2) make it difficult to draw precise conclusions on the allometric scaling of lactate metabolism and suggest that the metabolic fate of lactate may be only weakly linked to body mass.
Although the fate of lactate following activity may not be heavily
determined by body mass, clearing lactate may still influence an animal's
locomotor patterns. Following maximal activity, lactate levels rise to a
similar concentration in reptiles regardless of body mass and remain elevated
for a prolonged period (Moberly,
1968; Bennett and Licht,
1972; Coulson,
1980; Gleeson,
1980; Gleeson,
1982; Gleeson and Bennett,
1982; Hailey et al.,
1987; Gleeson and Dalessio,
1989). This results in a significant drop in plasma and tissue pH
(Bennett, 1973;
Gleeson and Bennett, 1982;
Wagner et al., 1999). Even
though the relative fate of lactate may be similar in large and small lizards,
the time to clear the accumulated lactate is much greater in larger animals.
As a result, larger lizards might be inclined to move less frequently, travel
shorter relative distances (i.e. fewer body lengths) or run at slower relative
speeds during daily activities to avoid this prolonged recovery and
acidosis.
The activity model presented here provides support for using body mass as a scaling parameter when comparing activity and metabolism between animals of different body mass. These results have important implications for the ecological energetics of naturally occurring field behaviors. When lizards across a wide range of body mass are compared over relatively equivalent distances, such as the same number of body lengths traveled, the metabolic consequences do not show the negative allometric scaling patterns seen when examining locomotion over the same absolute distances. This suggest that if animals are compared over distances typical of natural daily activities that locomotor efficiency is similar across a wide range of body mass.
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Acknowledgments |
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