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First published online September 19, 2006
Journal of Experimental Biology 209, 3812-3827 (2006)
Published by The Company of Biologists 2006
doi: 10.1242/jeb.02443
The locomotor kinematics of Asian and African elephants: changes with speed and size
1 Structure and Motion Laboratory, Department of Veterinary Basic Sciences,
The Royal Veterinary College, University of London, Hatfield, Hertfordshire,
AL9 7TA, UK
2 Institut fuer Spezielle Zoologie und Evolutionsbiologie, mit Phyletischem
Museum, Jena, 07743, Germany
3 Department of Integrative Biology, University of California, Berkeley, CA
94720-3140, USA
4 Department of Psychology, Butler University, Indianapolis, IN 46208,
USA
5 Department of Integrative Physiology, University of Colorado, Boulder, CO
80309-0354, USA
* Author for correspondence (e-mail: jrhutch{at}rvc.ac.uk)
Accepted 13 July 2006
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Summary |
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Key words: elephant, Proboscidea, locomotion, biomechanics, speed, gait, scaling
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Introduction |
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TOPSummaryIntroductionMaterials and methodsResultsDiscussionReferences |
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;
Gregory, 1912)], elephants
provide insight into the biomechanical and physiological constraints that
extremely large body size imposes. However, our understanding of elephant
locomotion is impaired by a lack of data and analyses. Anecdotes, qualitative
descriptions, lack of rigorous methods and vague data plague this subject.
Hence broader inferences based on elephant locomotor data are generally
tenuous. For example, this lack of understanding of `normal' elephant
locomotion limits the determination of whether individual elephants are moving
abnormally. This hinders early diagnosis of common musculoskeletal pathologies
in captive elephants, some of which result in euthanasia
(Csuti et al., 2001). Here we
describe the kinematics of African bush/savanna (Loxodonta africana
Blumenbach 1797) and Asian (Elephas maximus Linnaeus 1758) elephants
using a range of individual sizes and speeds from a large data set. For
brevity here, in referring to `African elephants' we mean only the African
bush/savanna elephant (Loxodonta africana), not the smaller, possible
second African species, the forest elephant (L. cyclotis Matschie
1900). We ask five principal questions.
First, how do the kinematics of elephants change with speed and body size?
It is not even agreed what footfall patterns elephants use, let alone how they
change with speed or size. Marey and Pagès
(Marey and Pagès, 1887)
and Muybridge (Muybridge,
1899) were the first to quantitatively describe elephant
locomotion, during the dawn of cinematography
(Sacks, 2003). Muybridge
called the faster walk of an Asian elephant an amble, whereas subsequent
authors used a wide variety of terms including rack
(Gambaryan, 1974), pace
(Webb, 1972), running walk
(Howell, 1944), trot
(Hildebrand, 1965;
Hildebrand, 1966;
Hildebrand, 1976) and run
(Alexander et al., 1979a;
Gambaryan, 1974) for slow- or
fast-moving elephants. Hildebrand's useful gait formula for footfall patterns
has become favored, so we adopt his terminology here
(Hildebrand, 1962;
Hildebrand, 1965;
Hildebrand, 1966;
Hildebrand, 1980;
Hildebrand, 1985).
In a previous study we determined that Asian elephants maintain a lateral
sequence footfall pattern at all speeds
(Hutchinson et al., 2003).
There are no comparable kinematic data for African elephants, so it is unclear
whether this larger species moves any differently. Here we examine how the
footfall pattern changes in elephants of different sizes moving at different
speeds, focusing on stride parameters including lengths, times and
frequencies. This will provide basic data for more complex studies of elephant
locomotor mechanics and comparisons with other species. Furthermore, we
examine the kinematics of smaller, younger elephants to resolve whether they
truly trot, gallop and/or have an aerial phase.
Second, what is the range of elephant locomotor performance, such as
maximal speed, minimal duty factor, and other kinematic parameters? This is
not trivial, because elephants are crucial endpoint taxa for understanding the
scaling of maximal locomotor performance in animals (e.g.
Bakker, 1975;
Blanco et al., 2003;
Christiansen, 2002;
Coombs, 1978;
Garland, 1983;
Iriarte-Díaz, 2002).
Most literature has focused on maximal speeds and is rife with confusion and
misinformation. Asian elephants are often claimed to have slower maximal
speeds than African elephants (Alexander,
2000; Iriarte-Díaz,
2002; Spinage,
1994). For Asian elephants, Baker
(Baker, 1890) was cited by
Muybridge (Muybridge, 1899) as
observing a maximal speed of 6.7 m s-1 (15 mph) and others often
quoted this speed or similar values
[(Gale, 1974), Sanderson (in
Alexander, 2000); 7.0 m
s-1 (Iriarte-Díaz,
2002); 5.6 m s-1
(Paul, 1998)], although the
fastest speed claimed was 8.9 m s-1
(Spinage, 1994). Baker's
anecdotal speed estimate (Baker,
1890) was confirmed by video analysis of elephants on `racetracks'
(Hutchinson et al., 2003),
documenting the fastest verifiable near-maximal speed of Asian elephants at
6.8 m s-1 (15 mph). Alexander et al. approximated an Asian
elephant's speed in Muybridge (Muybridge,
1899) as 3.8 m s-1 but also measured an African
elephant's speed as 4-4.5 m s-1
(Alexander et al., 1979a).
African elephants have been stated to move anywhere from this 
4 m
s-1 [9 mph (Muybridge,
1899; Alexander and Maloiy,
1989)] to a dubious 13 m s-1 [30 mph
(Alexander, 2000)]. A speed of
11 m s-1 `charging, across 120 yards' [25 mph
(Andrews, 1937) (cited by
Garland, 1983;
Howell, 1944); similar
speedometer estimate claimed (Le Rue, III, 1994)] is often cited, although
other studies have used somewhat lower speeds [10 m s-1
(Bakker, 1975;
Hildebrand and Hurley, 1985);
9.7 m s-1 revised estimate
(Garland, 1983); 9.5 m
s-1 (Iriarte-Díaz,
2002)]. We consider African elephant near-maximal speeds to be
undocumented, and present new data that point toward a solution of this
mystery. In addition, we identify what peak values other stride parameters
reach at such speeds, for comparison with other animals.
Third, do detailed kinematic data illuminate whether elephants change gait
at any speed (Hutchinson et al.,
2003)? What gait(s) elephants use is an important question that
bears on the basic principles of why animals use different footfall patterns
at different speeds (e.g. Cartmill et al.,
2002; Hildebrand,
1976; Hildebrand,
1980; Hildebrand,
1985; Marey and Pagès,
1887; Muybridge,
1899), how much these gaits relate to underlying kinematics and
kinetics (e.g. Cavagna et al.,
1977; Alexander,
1980; Alexander,
1989; Heglund et al.,
1982a; Heglund et al.,
1982b; McGeer,
1992; McMahon et al.,
1987; Parchman et al.,
2003; Raibert,
1990; Riskin et al.,
2006) (J. J. Robilliard, T. Pfau and A. Wilson, manuscript
submitted for publication), and how size influences locomotor dynamics (e.g.
Bertram and Biewener, 1990;
Biewener, 1989;
Biewener, 1990;
Blanco et al., 2003;
Farley et al., 1993;
Heglund and Taylor, 1988).
Fourth, are there differences in locomotor kinematics between Asian and
African elephants? The two lineages of elephants have been separate for at
least 6 million years (Thomas et al.,
2000) and differ in size, anatomy and habitat, so locomotor
differences might exist.
Fifth, how do elephant kinematics compare with those of other animals based
on scaling predictions? Even moderately large animals such as horses and
rhinos use trotting and galloping footfall patterns in addition to normal
walking, yet elephants do not. Perhaps elephants simply follow scaling trends
observed in such species but restrict their range of locomotion to just
walking, or perhaps their faster locomotion bear more similarity to these
faster locomotor modes. Additionally, some horses [as well as primates and
other quadrupeds (Cartmill et al.,
2002; Schmitt et al.,
2006)] such as Icelandic ponies use a footfall pattern (the toelt,
or tölt) identical to the lateral sequence footfall pattern of elephants
(Biknevicius et al., 2004;
Nicodemus and Clayton, 2003;
Zips et al., 2001) (J. J.
Robilliard, T. Pfau and A. Wilson, manuscript submitted for publication). We
investigated whether the stride parameters of these locomotor modes in horses
and elephants differ in any fundamental ways.
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Materials and methods |
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), body
masses (Mb) had to be estimated for the Thai elephants.
All other elephants had known weights from having all four limbs on a truck
scale (±2 kg). The lateral surfaces of the right limb joints (shoulder,
elbow, hip and knee in particular) of the elephants were first marked with
white tempera paint (surrounded with black paint for added contrast) or (for
the four elephants in Europe) with infrared-reflective motion capture markers
(Fig. 1). Joint center
locations were estimated by palpation and by having elephants flex and extend
their joints while multiple observers visually tracked the approximate
rotational centers. Additional reference to museum-mounted specimens was made
to aid locating skeletal landmarks from surface features. All experiments with
elephants in the UK were done with the approval of The Royal Veterinary
College's Ethics and Welfare Committee.
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Trials
Similar procedures were used for all trials for all elephants (see
Hutchinson et al., 2003;
Schwerda, 2003). However, we
varied the method of motivation in order to elicit different speeds. Most were
led by trainers, but some were either ridden by their mahouts or allowed to
move on their own and even chase friendly elephants. For trials at faster
speeds, elephants were motivated by a variety of techniques, none inflicting
pain or suffering on the elephants, including playful chasing, presence of
friendly elephants near the end of the track, food rewards, noisemaking and
cheering, and mahout's or trainer's instructions. No behavioral artifacts were
observed in how the elephants moved at any particular speed. The elephants
moved across level trackways about 30 m in total length. This allowed the
animals to accelerate to and decelerate from various speeds as encouraged by
the trainers. The total number of trials was 602: 299 for Asian elephants (235
in Thailand) and 303 for African elephants (197 in Germany, 62 in California,
24 in Indiana, and 20 in England). In total about 2400 strides were measured
for the 602 trials; these strides were averaged within each trial.
Video acquisition and processing
Similar methods were used for all experiments in the USA, England, Germany
and Thailand. The central 10 m of a 30 m track had the field of view of one
camera oriented perpendicular to it. Camera image acquisition rates varied: 60
Hz for African elephants in the USA and Thailand, 200 Hz for Asian elephants
in California, 120 Hz for African elephants in England, and 50 Hz for African
elephants in Germany. The video recordings were encoded with field numbers and
manually analyzed to obtain foot touch-down and lift-off events (see below),
then digitized in Peak Motus (Peak Performance, Centennial, CO, USA) or
SiliconCOACH (Dunedin, New Zealand) software to obtain the positions and
displacements of the joint markers. Digitized data were post-processed with
Butterworth filtering (fourth order, low pass 6 Hz cut-off frequency). We
scaled the video linear dimensions from pixels to meters using the thigh
segment length (=hip-to-knee distance) as a scaling factor, when the
elephant's right hindlimb was at mid-stance near the center of the 10 m track
section. These data allowed us to calculate forward velocities throughout a
stride. Additionally, we tracked the vertical motions (in the sagittal plane)
of the hip and shoulder joints following Hutchinson et al.
(Hutchinson et al., 2003) to
examine whether there was a shift in the motion of these joints at any speed
that might help discriminate between inverted pendulum-like and spring-like
limb function. Hip height (h) from the hip joint to the ground during
standing was assumed to equal limb length for related calculations (see
below).
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; Hildebrand,
1980)], stance and swing durations (tst,
tsw; i.e. stance and swing times or periods), duty factor
(ß=tst[tst+tsw]-1;
averaged for all limbs or for respective fore/hindlimb pairs), duty factor
fore-hind difference (ßdiff=forelimb mean ß-hindlimb mean
ß); stride frequencies (F=no. strides s-1, or Hz) and
lengths (L=uF-1), Froude number
(Fr=u2[gh]-1,
where g=9.81 m s-2)
(Alexander and Jayes, 1983;
Alexander, 1989); also
non-dimensionalized speed û or Fr0.5 (e.g.
Gatesy and Biewener, 1991) and
the vertical displacements of the hip and shoulder joints (see
Hutchinson et al., 2003). We
normalized our compiled data for body size to obtain relative stride
frequencies
(F=F[h·g-1]0.5)
and lengths (L=Lh-1)
(Alexander and Jayes, 1983;
Gatesy and Biewener, 1991;
Hof, 1996).
Christian et al. (Christian et al.,
1999) used very similar methods (50 Hz digital video, 30 m track)
to obtain footfall patterns for two Asian elephants (their
table 1: 19 trials;
h=1.5 m; u=0.59-3.86 m s-1;
Fr=0.024-1.0; ß=0.57-0.77; Mb not reported
but assumed equal to our Asian female elephant of identical h: 1300
kg), so we included these data in our analysis for a total of 62 elephants (48
Asian) and 621 trials.
The maximal error of time-related factors for the fastest, smallest
elephants (tst 0.196 s) at 60 Hz video sampling was 2
fields or 0.033 s (16.8%); at 200 Hz it was 5.04%. This maximal error is
presumably an overestimate by a factor of two or more (see
Gatesy and Biewener, 1991),
especially for larger or slower elephants (tst<3 s).
Repeated measures of digitized coordinates by experienced users gave errors of
±0.1 m s-1 for velocities. Horizontal
accelerations/decelerations (calculated by double-integrating hip/shoulder
position) were typically low across the 10 m track area, <0.2 m
s-2 (Hutchinson et al.,
2003); here we do not use trials with substantial between-stride
speed variation.
Assessing when the elephants' feet were on the ground was sometimes difficult as elephants often brought their feet down at very low angles of attack, although there were still discrete heel-strike and toe-off events (Fig. 2), as in other large mammals. We scored video fields as having a foot-on event when the foot had ceased translating forward, and foot-off as when the foot began translating forward and/or upward. This approach is supported by preliminary foot-mounted accelerometer data (J. R. Hutchinson and L. Ren, unpublished data).
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Statistical analysis
To check for differences between the relationships of stride parameters
with dimensionless speed (û) between the African and Asian
elephants, we analyzed our data using a general linear model (GLM) in
STATISTICA software (StatSoft, Inc., Tulsa, OK, USA), with speed as the
independent variable, species as the categorical factor, and stride parameters
(normalized for size where necessary, so Plf,
Prh, Prf, tsw,
tst, ß, ßdiff, F and
L) as the dependent variables. P<0.05 was considered
statistically significant. To illustrate the relationships of these normalized
stride parameters with speed in our graphs and for comparison with published
data for other animals, we applied the best curve fit (based on highest
R2 value). For Reduced Major Axis (RMA or Model II)
regressions, we used custom code RMA for Java 1.19
(Bohonak and van der Linde,
2004).
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The relative phasing of elephant forelimb footfalls (P) increased
linearly with speed across the measured ranges
(Fig. 3), becoming more evenly
spaced in time - i.e. from having lateral couplets
(Hildebrand, 1976;
Hildebrand, 1980) at slower
speeds toward a true singlefoot (25% phase offset between all limbs) in
lateral sequence at faster speeds. The relative phasing of the right hind
footfall (Prh) showed a nearly significant increase with
speed (P=0.055). In summary, the left front foot hit the ground
20-25% of a stride after the left hind, and was followed 25-30% of a stride
later by the right hind, which the right front foot followed by 20-25% of a
stride. We observed very few deviations from this pattern (ranges of phases
were ±0.1 from modal values) in our sample of 621 trials; all elephants
remained within the boundaries of a lateral sequence footfall pattern, without
ever switching to diagonal sequence, trotting, pacing or asymmetrical footfall
patterns.
The average all-limb duty factors (ß) decreased curvilinearly with
speed for all elephants, at Fr around 1 reaching ß0.5,
below which would require aerial phases of some contralateral limbs
(Fig. 4A). This decrease of
ß showed signs of reaching a plateau at û>1.5. We never
observed anything close to a whole-body aerial phase; elephants had at least
one limb firmly contacting the ground at all points during a stride. At least
two limbs supported the body at speeds less than Fr=1, then there
were increasingly long periods of single-leg support at speeds greater than
Fr=1. At our lowest ß of 0.37, a young elephant spent 26% of
each stride supported on single limbs.
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) who reported roughly equal duty factors for elephant
fore/hindlimbs, average forelimb ß values were almost always slightly
greater than hindlimb ß (respectively, for 93% of African and 91% of
Asian elephant trials). ßdiff was randomly distributed about a
mean difference of 0.03 for both species
(Fig. 4B) and did not change
significantly with dimensionless speed (P>0.05). Hence the
hindquarters gained its aerial phase at a lower û than did the
forequarters.
Stance and swing phase durations (tst,
tsw) dropped precipitously with increasing speed
(Fig. 5A), with strong slopes
(especially for tst) at Fr<1, then leveled out
toward asymptotic values. The decrease of tst with speed
was generally three times steeper than tsw
(Table 3). The lowest
tst values of 0.20 s were reached at
û>1.5, whereas the lowest tsw values of
0.28 s were reached at slower speeds: û1.0. Thus minimal
stance times were about 71% of minimal swing times.
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Near-maximal locomotor performance
The Asian elephants from Thailand were the fastest of all of the elephants
we measured, in absolute and relative terms. The maximal u, L, F, L
and F we observed were: 1.8 (Fr=3.4), 4.5 m, 1.93 Hz, 3.0
and 0.66, respectively. The minimal ß value was 0.37. A large bull Asian
elephant (2790 kg) with the fastest absolute speed (6.8 m s-1;
Fr=2.8) and largest absolute L also had the most extreme
F, F and L values for an elephant over 1500 kg: 1.6 Hz, 0.64
and 2.6, respectively. Near-maximal speed did not show an obvious change with
size (Fig. 6A), although we
lack sufficient data for elephants >4000 kg to see whether the largest
elephants cannot reach the same absolute speeds as smaller ones. Even at young
ages (2 years), elephants can move as quickly as adults.
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Elephant hip heights increased near-isometrically with body mass (Fig. 6D; slope=0.26); the 95% confidence intervals include the slope expected for a geometric similarity model of scaling (slope=0.33).
Stride parameters: size-dependent factors
Elephants, large and small alike, move in generally similar ways (limb
phase, etc). They differ mainly in parameters that would be expected to change
with body size: at a given absolute speed smaller elephants use smaller
absolute stride lengths and greater absolute stride frequencies
(Fig. 7), corresponding to
absolutely lower tst and tsw.
Likewise, ß was lower at any particular absolute speed for smaller
elephants. Even the smallest elephants did not use a whole-body aerial phase
or change their footfall pattern to a trot, gallop or other pattern dissimilar
from adults.
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) we find that, in both species of elephant, at slow
speeds the hip and shoulder joints first rise, then fall during their
respective stance phases (Fig.
8A), reaching their maximal vertical position at mid-stance.
Christian et al. [(Christian et al.,
1999) their fig. 2]
report similar data (roughly convex arc of hip motion during stance) for an
Asian elephant moving at 1.6 m s-1 (Fr=0.18; ß=0.66).
However, in elephants moving at fast speeds the hips fall, then rise during
the stance phase (i.e. are at their minimum vertical position at mid-stance),
whereas the shoulders maintain the same rise-fall motion during stance
(Fig. 8B). Our larger data
sample supports the inference that this change occurs at around a Fr
of 1, although with some variation, and is common to both species. Some
elephants showed intermediate patterns (especially with the hip moving down
throughout stance) at Fr>0.5; of these some even maintained this
motion up to Fr3. In all cases, however, maximal vertical
displacement of the hip and shoulder joints during the stance phase (from heel
strike to maximum) remained relatively small: e.g. in
Fig. 8A a mean increase of 0.12
m for the shoulders and 0.068 m for the hips, or in
Fig. 8B an increase of 0.069 m
for the shoulders and a decrease of 0.063 m for the hips. These
values are only around 4-9% of hip height, which is expected for large animals
(e.g. Farley et al., 1993;
Schmitt et al., 2006).
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The individual shown in Fig. 8 (same one shown in Fig. 1C,D) is fairly typical in that the shift in vertical displacement of the hip (from Fig. 8A to 8B) correlates with a disappearance of the upward movement of the hip that is observed in slower walking during the last half of stance phase. This peak occurs in the swing phase instead (note two peaks in swing phase in Fig. 8B vs one in Fig. 8A). Increased limb flexion during stance (Fig. 1) at fast speeds seems related to this change in hindlimb motion.
Species differences
African and Asian elephants were statistically different in how ß,
tst, tsw, L and F
changed with dimensionless speed (P<0.05). However, most of these
differences were very slight (compare mean values and 95% confidence intervals
in Table 4). At any
dimensionless speed, African elephants tended to have larger duty factors with
shorter stance and swing times, using slightly greater stride frequencies and
smaller stride lengths. The most striking difference was among swing times,
which have a mean difference of 0.08 s (20%) at identical
û values. However, our analysis strongly indicates that
relative limb phases did not change with û differently in
African and Asian elephants (P>>0.05), nor did mean forelimb and
hindlimb duty factors have statistically significant differences (i.e.
ßdiff) between Asian and African elephants, although
there was a trend (P=0.067) (Table
4).
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). However
we find it implausible that the Thai elephants in particular were only
reaching 50-75% of an alleged 11 m s-1 maximal speed. These animals
were healthy, active and wide-ranging in their daily movements (tourist rides,
hauling heavy equipment, etc.). Furthermore, they were ridden/guided by
mahouts whom they were trained to obey, and many were `elephant hunters'
previously used to chase wild elephants for capture and subsequent
domesticity, or were used in elephant races and polo matches. Hence the Thai
elephants were trained for speed, unlike zoo-captive elephants that are
necessarily selected for passivity, for purposes of space and safety.
Considering the relative sizes (<60 kg mahouts, 1000-3000 kg elephants that
were ridden) it is doubtful that the riding mahouts affected elephant
performance. Additionally, the fastest speeds we recorded are slightly faster
than the 6 m s-1 average speeds for elephant races (J. R.
Hutchinson, unpublished). For these reasons, we refer to the fast speeds
(>5-6 m s-1) of many elephants as `near-maximal.'
Three of our 14 African elephant subjects reached Fr>1 and
u>4 m s-1. One individual that was being chased by
another reached a speed of 5.9 m s-1 (Fr=2.1), which is
around the near-maximal speed of many Asian elephant individuals. As African
and Asian elephants move very similarly, we doubt reports that African
elephants can reach speeds as fast as 11 m s-1
(Andrews, 1937; Le Rue, III,
1994) or even 9.5-9.7 m s-1
(Garland, 1983;
Iriarte-Díaz, 2002).
Estimating speeds from automobile speedometers or intuition can be
extraordinarily inaccurate, particularly because of parallax effects (see
Alexander and Maloiy, 1989). We
consider 9.5-11 m s-1 speed reports to be exaggerations based upon
these errors and the excitement of witnessing a charging wild elephant. Our
data (Table 3) allow us to
predict that an African bull elephant moving at 11 m s-1 (assuming
h=2 m; Fr=6.3) would have a duty factor of 0.40 (hence still
lacking a complete aerial phase), tst and
tsw of 0.17 and 0.26 s, respectively (lower than any
observed here for juvenile elephants), L=3.5, F=0.89, and
would be taking 2+ strides of 5+ m length every second. Considering the
maximal values we have measured for elephants (above), this is not
inconceivable, but stretches credulity. The most reasonable conclusion at
present, considering the strong similarities between Asian and African
elephant kinematics demonstrated in this study, is that the near maximal speed
of African elephants is essentially the same as Asian elephants: <7 m
s-1.
The minimal ß we observed (0.37) is substantially less than those
previously attributed to elephants [0.49+
(Alexander et al., 1979a;
Christian et al., 1999;
Gambaryan, 1974;
Hildebrand, 1980;
Hildebrand, 1985)]. Limb bone
stresses were estimated during locomotion in an African elephant moving at
4.5 m s-1 (ß=0.49)
(Alexander et al., 1979a).
Thus maximal bone stresses have probably been underestimated by a factor of
76% (duty factor 0.37/0.49) or more, especially for smaller elephants that
would be experiencing greater relative peak forces. Accurate estimation of
such stresses under peak loads depends directly on obtaining near-maximal
locomotor performance, particularly as the results have major influence on
comparative analyses of scaling, bone strength and speed (e.g.
Biewener, 1990;
Blanco et al., 2003;
Christiansen, 2002).
As minimal ß decreases with size, our data hint that very large elephants (>4000 kg) may no longer reach ß<0.5 and hence would lose any aerial phases for the fore- and hindlimb pairs. If elephants change gait (see below), then very large elephants might lose this capacity. Such a phenomenon would be remarkable for terrestrial animals, few of which are known to lose a gait during adulthood because of body size increase. This identifies a need for more locomotor studies of the largest elephants to test this speculation.
Our data (Fig. 6) show that
even small elephants can move as quickly as large elephants; related
parameters such as total leg length (Fig.
6D) do not exhibit strong allometry. Near-maximal speed may peak
early in life, as would be expected for animals that are especially vulnerable
to predation at young ages (Pennycuick,
1975), whereas larger adult elephants presumably have little need
for high speed capacity.
Kinematic changes with speed: is there a gait change?
There is no reason to doubt that slow-moving elephants are walking in any
sense of the word, but fast-moving elephants pose a challenge for applying
many gait definitions. Hutchinson et al. doubted whether fast-moving elephants
were merely walking (Hutchinson et al.,
2003), but the speed at which any potential gait transition
occurred was left open. As they intimated, this issue depends on how one
defines or diagnoses a gait: by footfall pattern
(Hildebrand, 1966;
Hildebrand, 1976;
Hildebrand, 1980), presence of
an aerial phase or a duty factor <0.5
(Gambaryan, 1974;
Hildebrand, 1962;
Hildebrand, 1966;
Hildebrand, 1976;
Hildebrand, 1980;
Muybridge, 1899), Froude
number (Alexander and Jayes,
1983), pendular/bouncing body or limb dynamics
(Cavagna et al., 1977;
Farley et al., 1993;
Heglund et al., 1982a;
Heglund et al., 1982b;
McGeer, 1992;
Parchman et al., 2003), or
discontinuities in locomotor parameters
(Alexander, 1989;
Gatesy, 1999;
Gatesy and Biewener, 1991). We
favor a biomechanical definition, but here explore how these definitions agree
and disagree in identifying a potential gait transition in elephants
(Table 5).
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The elephants only used lateral sequence (with lateral couplets or
singlefoot) footfall patterns; no change of footfall pattern to another mode
such as pacing or trotting was observed. Hildebrand stated that elephants use
a `slow trot' at lower speeds (Hildebrand,
1965; Hildebrand,
1966; Hildebrand,
1976) but we did not observe this in 62 elephants; it is
conceivable that this pattern might be used under unusual conditions. Hence a
strict footfall sequence-based definition would not classify elephants as
having any gait transition. Regardless, it is not only young elephants that
use these lateral sequence footfall patterns
(Hildebrand, 1985). We
observed similar locomotion in elephants as large as 4632 kg.
As speed increased, elephants moved away from having forefoot contacts
15% of a stride after the ipsilateral hindfoot contacts toward 25%
phasing. According to the quadrupedal walking model
(Griffin et al., 2004), the
phasing at slow walking (present in dogs) keeps pendulum-like energy recovery
high when combined with higher forelimb impulses [expected for elephants that
support 60% of their body weight on their forelimbs, like most mammals
(e.g. Alexander et al.,
1979a); J.R.H., unpublished observations]. The shift toward evenly
offset footfalls in faster-moving elephants may thus be additional evidence of
a mechanical transition.
Elephants never have a whole-body aerial phase so in a classical sense they
do not run. Yet numerous studies have shown that an aerial phase is not a
sine qua non of bouncing (i.e. running) gaits
(Clark and Alexander, 1975;
Gatesy and Biewener, 1991;
McMahon et al., 1987;
Parchman et al., 2003;
Robilliard et al., 2006; Rubenson et al.,
2004). Additionally, an aerial phase for one rather than both
fore/hindlimb pairs may impart enough limb compression for a transition to
bouncing mechanics. At around Fr>1 (ß<0.5), elephant fore-
or hindlimb pairs attain their own aerial phases, so the dynamics of their
fore/hind quarters could biomechanically be running. Considering that
ßdiff tended to remain positive (0.03), assuming a
ß=0.5 boundary between walking and running
(Cartmill et al., 2002;
Hildebrand, 1976;
Hildebrand, 1980) would give
one (just using the mean duty factor ß) or two (fore- and hindlimb)
potential gait transition points, which is problematic.
Using our duty factor and limb phase data we can determine when each
left-right limb pair (fore/hind) gained its own aerial phase, and at what
speed elephants should have an aerial phase in their locomotion, if they move
appreciably faster than observed speeds. An aerial phase must occur in any
quadruped if ß falls below 0.25, because four feet cannot be spaced out
more evenly than relative limb phases of 0.0, 0.25, 0.50 and 0.75. If ß
were less than the longest gap between foot falls, then there would be an
aerial phase for the whole body. The longest gap was always between a hind
foot contact and the contact of the diagonal fore foot. Hence it is either
(Prh-Plf) or
(Plh-Prf); fortunately these
quantities are equal, so either suffices. Substituting 1.0 for
Plh (same as 0.0), and plotting these data against
û (Fig. 9), we
find that at slow speeds the decrease of ß required in order to have a
whole-body aerial phase is greater than at fast speeds. This is not surprising
as slower speeds involve greater ß
(Fig. 4), and the possibility
of an aerial phase is not a concern at most P values. At fast speeds,
however, ß would need to be only 0.1 less for an aerial phase to
occur. As ß decreased less steeply with increasing speed (especially past
Fr2), we infer that this pattern helps prevent the attainment of
an aerial phase in elephants. This conclusion holds whether one considers the
mean ß or ß for individual limbs.
|
)]. This
could lengthen tst and keep ß values greater [and
rates of force application smaller (Hoyt
et al., 2000)] than they would be if ß decreased linearly
with dimensionless speed. In the latter case, elephants would be more likely
to attain whole-body aerial phases, and attendant increases in peak vertical
ground reaction forces and/or potentially injurious limb vibrations (e.g.
McMahon et al., 1987).
Most animals change gait at Fr0.4-0.6
(Ahlborn and Blake, 2002;
Alexander and Jayes, 1983;
Gatesy and Biewener, 1991),
and theoretically a shift must occur at Fr1
(Alexander and Maloiy, 1989;
Usherwood, 2005). On these
grounds elephants, which routinely attain Fr>0.6 or even
Fr>2.5 [where most quadrupeds switch from trotting to galloping
(Alexander and Jayes, 1983)],
should change gait at some point. Elephants show no diagnostic kinematic
characteristics of running at Fr0.5, but at Fr>1
(see above) exhibit an increasingly compliant hindlimb and an aerial phase for
the hindquarters, followed by an aerial phase for the forequarters at slightly
faster speeds.
Additionally, like Hutchinson et al.
(Hutchinson et al., 2003) we
find kinematic evidence that the hindlimbs of elephants are generally less
pendular (in terms of rigidity) in their stance phase motions than the
forelimbs, indicating that limb function may differ among these limbs,
particularly at moderately fast speeds. Gambaryan supposed that the motion of
the center of mass of the body was horizontal
[(Gambaryan, 1974) p. 169].
Yet he depicted [(Gambaryan,
1974) fig. 117] the vertical displacements of the limb joints of a
`fast walking' (unknown speed) elephant as having inverted pendulum-like
scapular (presumably comparable to shoulder) motion. Unusually, the same
elephant also had a hip joint that raised vertically throughout stance. This
is similar to some patterns in elephants that we measured at intermediate
speeds (Fr1); also for an elephant `running' at unknown speed
(Marey and Pagès,
1887).
Elephants show some subtle discontinuities in how their stride parameters
change with speed. Such discontinuities can be viewed as evidence for a gait
shift (Alexander, 1989;
Gatesy, 1999). In particular,
stride lengths and frequencies showed a noticeable change of slope close to
Fr=1, and possibly Fr0.3 as well
(Fig. 5B,
Fig. 7). Additionally, the
gradual shift toward more evenly spread P values coincided with a
shortening of tsw toward a minimum of 0.28 s. As ß
never dropped below 0.37, there may be some overlap (about 10% of a stride)
required for elephants to comfortably shift weight-bearing from one limb to
another (Hildebrand, 1965;
Hildebrand, 1966). Avoiding
ipsilateral limb interference is another likely explanation for this limb
phase shift (Gambaryan, 1974;
Hildebrand, 1966;
Hildebrand, 1976;
Hildebrand, 1980).
Interestingly, at û>1, values of tst and
tsw approached asymptotic values
(Fig. 5A). Thus at their
fastest speeds, the elephants were not taking much faster steps, and were not
using a whole-body aerial phase, so some other mechanism to extend stride
length was used to increase velocity. Altered angular excursions of the limb
joints are a likely candidate (Hildebrand,
1984; Schwerda,
2003; Usherwood,
2005). Our findings are consistent with the observation of
Christian et al. that elephants change speed largely by decreasing swing times
and increasing stride frequency (Christian
et al., 1999), which helps to keep stance times large and peak
limb forces small. Yet at fast speeds, increased limb displacement (or
compliance) may contribute to stride length and speed increases, as swing time
and stride frequency, respectively, approach their minimum and maximum
values.
The minimal metabolic cost of transport for three mid-sized African
elephants (1500 kg) was at 1.0 m s-1
(Langman et al., 1995). If
elephants do not change gait, they should face high energetic costs at their
maximal speed, which is almost seven times the energetic optimum. The latter
would be rather unusual compared to other animals. Changing gait would allow
them to reach a second minimal metabolic cost of transport (e.g.
Hoyt and Taylor, 1981).
Elephants do not habitually use speeds anywhere near their maximum. One reason
may be energetic.
Like Hutchinson et al. (Hutchinson et
al., 2003) we still consider it prudent to avoid characterizing
fast-moving elephants as truly running (i.e. as having bouncing kinetics of
the whole-body center of mass) until kinetic force platform data are
available. Even the classical dichotomy between pendular walking and springy
running gaits may be blurred in, or overly simplistic for, animals like
elephants that use widely out-of-phase limb motions at fast speeds or change
kinematic parameters smoothly with increasing speed (e.g.
Ahn et al., 2004;
Clark and Alexander, 1975;
Gatesy and Biewener, 1991;
Parchman et al., 2003;
Riskin et al., 2006;
Rubenson et al., 2004) (J. J.
Robilliard, T. Pfau and A. Wilson, manuscript submitted for publication).
Regardless, elephants seem to change their limb, and possibly body, mechanics
near a Froude number of 1, although a shift at a lower Fr cannot be
ruled out as the kinematic patterns are almost a continuum.
Do Asian and African elephants have different kinematics?
Although we found statistically significant differences in all but relative
limb phases and fore-minus hindlimb duty factors, we doubt that these
differences have tremendous biological significance. The differences in
absolute terms are all quite small and our sample was not ideally
representative (or random) for African elephants (14 individuals vs
48 Asian). Because African and Asian elephants share a common ancestry with
extinct mammoths (Mammuthus spp.) as members of the Elephantidae
(Krause et al., 2006;
Thomas et al., 2000), we
expect that mammoths and other extinct elephantids moved similarly to extant
elephants, except where there are major size, shape or other mechanically
relevant differences. We expect that even dwarf insular forms, if
morphologically similar to baby elephants, would have moved similarly. This is
because small baby elephants only differ in their relative locomotor abilities
compared to large adults; they do not use drastically different kinematics.
This common elephantid pattern of locomotion provides a baseline from which
evolutionary changes within Proboscidea can be reconstructed backwards toward
the much smaller, probably semi-aquatic distant ancestors of all elephants, or
to infer how strange proboscideans such as mastodons and deinotheres may have
stood and moved.
Comparison with other animals
Elephant locomotor kinematics have many patterns in common with typical
tetrapods, especially larger quadrupeds, such as increasing velocity primarily
by increasing stride frequency until a near-maximal stride frequency is
reached (at around the walk-run transition in other animals), then relying
relatively more on increasing stride length
(Pennycuick, 1975;
Heglund and Taylor, 1988).
Additionally, size seems to influence their locomotion in ways similar to
other animals: smaller elephants have relatively greater locomotor performance
such as greater near-maximal relative stride lengths
(Hoyt et al., 2000;
Pennycuick, 1975) and
frequencies or Froude numbers, and smaller minimal duty factors. Elephants use
relative stride lengths and duty factors that are expected
(Table 6) for corresponding
Fr in smaller animals (Alexander,
1977; Alexander and Jayes,
1983), and likewise use stride frequencies that are expected for
their body mass (Heglund et al.,
1974) or for animals galloping at maximal observed speed
(Heglund and Taylor, 1988).
Hence despite their obvious non-geometric similarity with other quadrupedal
mammals, especially cursorial ones
(Christiansen, 2002;
Coombs, 1978;
Gregory, 1912), elephants tend
to meet many predictions of dynamic similarity theory. At their faster speeds,
elephant stride parameters likewise match those of running quadrupeds
(Alexander and Jayes, 1983;
Heglund and Taylor, 1988).
This adds credence to our inference that elephants are not simply walking at
their near-maximal speeds (Table
5).
|
However, elephants also display some kinematic patterns that are unusual
for terrestrial quadrupeds (Table
6). They reach absolute stride lengths and near-maximal speeds
that are smaller than predicted for their size
(Heglund and Taylor, 1988).
Although elephants can reach moderate speeds, they do not change their
footfall patterns, so this is another striking feature in which they violate
expectations from dynamic similarity theory.
A comparison of elephants with the second heaviest land mammals,
rhinoceroses, reveals important differences in locomotor function whose
underlying mechanical and anatomical explanations remain poorly understood.
For example, unlike elephants, rhinoceroses can trot and gallop, reaching
Fr>3 (Alexander and Jayes,
1983; Alexander and Pond,
1992). This underscores the great difference between these
animals: size differences aside, rhinoceros locomotion is fairly typical for
cursorial quadrupeds in general (Alexander
and Jayes, 1983) whereas elephants move somewhat differently and
are more limited in their range of locomotor performance (near-maximal speed
in particular; as above). Differences in limb proportions and other anatomical
parameters help explain some of these differences
(Christiansen, 2002;
Coombs, 1978;
Paul, 1998), but not all.
Differential scaling [discontinuously stronger allometry at larger sizes
(Bertram and Biewener, 1990;
Christiansen, 2002; Iriarte
and Díaz, 2002)] is likely a major factor underlying these differences.
Unlike elephants, rhinoceroses scale with strong positive allometry [following
static stress similarity (Bertram and
Biewener, 1990)], which would facilitate relatively greater
locomotor performance (Alexander et al.,
1979a,
b;
Alexander and Pond, 1992).
Elephants are the exemplar of living animals with graviportal limb design,
whereas horses are among the largest living animals with very cursorial limb
design. Despite these major anatomical differences, some horses use footfall
patterns that are very similar to elephants: the `running walk' or tölt
[(Biknevicius et al., 2004;
Zips et al., 2001); J. J.
Robilliard, T. Pfau and A. Wilson, manuscript submitted for publication]. Do
these horses that maintain singlefoot with lateral sequence footfall patterns
across a wide speed range move the same as elephants? Indeed there are
striking similarities. Both taxa show a fairly smooth change of stride
parameters (although with some subtle discontinuties) with speed across the
boundary of Fr=1 [3 m s-1
(Biknevicius et al., 2004); J.
J. Robilliard, T. Pfau and A. Wilson, manuscript submitted for publication].
Both reach small duty factors while avoiding a whole-body aerial phase, yet
increasing limb compliance. Finally, both taxa rely mainly on linear increases
of stride length to increase speed, particularly at faster speeds where stride
frequency reaches a plateau (Biknevicius
et al., 2004). However, differences are also evident: unlike
elephants, tölting horses have greater hindlimb than forelimb duty
factors and stance times (Biknevicius et
al., 2004) (J. J. Robilliard, T. Pfau and A. Wilson, manuscript
submitted for publication), occasionally attain aerial phases [albeit at
greater Fr than measured for elephants
(Zips et al., 2001;
Biknevicius et al., 2004)],
and do not seem to have consistent changes of relative forelimb phase with
speed (Zips et al., 2001).
This divergence of fore- and hindlimb mechanics inferred for horses and
elephants may be even more commonplace among animals - for example, some cows
have been shown to have strongly different ground reaction force profiles for
their fore- and hindlimbs (Scott,
1988). Slow normal walking and slow tölting in horses have
quite different kinematics (J. J. Robilliard, T. Pfau and A. Wilson,
manuscript submitted for publication), whereas elephants increase speed from a
slow walk to faster locomotion more smoothly. Additionally, although
comparable data are limited, elephants seem to reach smaller duty factors
(ß=0.37 at Fr=3.4) than horses at greater Fr [ß=0.41 at
Fr=4.5 (Biknevicius et al.,
2004)]. Hence it would be premature to infer that the horses and
elephants have very similar center of mass or limb dynamics, particularly as
the linkage between limb compliance (i.e. spring-like limb function) and
center of mass movement (i.e. spring-mass whole-body mechanics) is complex
(Ahn et al., 2004;
Alexander, 1980;
Griffin et al., 2004). Yet the
noted similarities underscore the underlying physical mechanisms that are
presumably common to many animals that maintain lateral sequence gaits at fast
speeds (Alexander, 1980;
Hildebrand, 1976).
Conclusions
We have shown how elephant kinematics are related to size, speed and
species, yet many general kinematic patterns are maintained across all of
these spectra. Most stride parameters change smoothly with increasing speed in
both species of extant elephants regardless of size - there is no discrete
transition where many parameters change in tandem. Yet we find evidence that
limb mechanics (e.g. hindlimb compression, aerial phases for contralateral
limb pairs) change near a Froude number of 1, suggesting at least more
compliant hindlimb function. Although force platform data on center of mass
dynamics are needed, our kinematic data are vital for an integrative solution
to the mystery of how elephant locomotor dynamics change with speed. Larger or
smaller elephants do not
