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First published online August 17, 2007
Journal of Experimental Biology 210, 3117-3125 (2007)
Published by The Company of Biologists 2007
doi: 10.1242/jeb.006544
Increased non-linear locomotion alters diaphyseal bone shape
1 Department of Anatomy, New York College of Osteopathic Medicine, Northern
Boulevard, Old Westbury, NY 11568-8000, USA
2 Department of Biomedical Engineering, Stony Brook University, Stony Brook,
NY 11794, USA
* Author for correspondence (e-mail: kcarlson{at}nyit.edu)
Accepted 30 June 2007
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Summary |
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Key words: cortical bone, turning, femur, mouse, bone adaptation, force
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Introduction |
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TOPSummaryIntroductionMaterials and methodsResultsDiscussionReferences |
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; Alexander,
2002; Demes et al.,
2006; Jindrich et al.,
2007). One fundamental aspect of this variability is the ability
of an organism to change its direction of travel, or maneuver through an
obstacle-filled environment. Proficiency in turning would confer tremendous
selective advantage to free-ranging animals through predator avoidance,
resource acquisition or competitive exclusion strategies. Quadrupedal animals
that inhabit spatially complex arboreal habitats or mountainous areas,
particularly those characterized by rugged vertical relief, may benefit from
adaptations facilitating the capacity to change travel direction. Despite the
seemingly integral importance of turning to locomotor performance, and despite
the development of a descriptive protocol for categorizing turning behavior
(Eilam, 1994;
Walter, 2003;
Demes et al., 2006;
Jindrich et al., 2006;
Jindrich et al., 2007),
turning as a locomotor mode is rarely integrated into consensus frameworks for
recording locomotor behavior in free-ranging animals (e.g.
Prost, 1965;
Hunt et al., 1996;
Thorpe and Crompton, 2006).
The lack of attention devoted toward documenting turning frequency in
free-ranging quadrupedal vertebrates may be related to the dearth of attention
received by this locomotor mode in experimental studies that model animal
locomotion.
Since turning has received comparatively less attention than linear
locomotion, the potential effects of elevated turning frequency on bending
loads and external forces, as well as their potential effects on the
appendicular skeleton, are not well understood. Higher bone strain magnitudes
have been reported in the human tibia during zig-zag locomotion compared to
linear locomotion (Burr et al.,
1996). Strain orientations, however, were not documented in this
study for methodological reasons, nor were site-specific strain magnitudes
compared (e.g. anterior versus medial cortex). In a study of the
radial midshaft of goats, higher strain magnitudes and less predictable
loading overall were found during non-steady behaviors compared to steady
state locomotion on a treadmill (Moreno et
al., 2007).
Further inferences about mechanical loading of the appendicular skeleton
during turning can be made using measurements of substrate reaction forces
(SRFs) (Rubin and Lanyon,
1982; Biewener et al.,
1983; Rubin and Lanyon,
1984; Biewener et al.,
1988; Demes et al.,
1998; Demes et al.,
2001). High mediolateral (ML) forces have been observed in animals
that adopt waddling gaits (e.g. penguins) or habitually abducted or sprawling
limb postures (e.g. alligators) during linear locomotion
(Blob and Biewener, 1999;
Griffin and Kram, 2000;
Blob and Biewener, 2001).
Lemurs that were enticed to perform turns of approximately 30° experienced
elevated ML components of SRFs (Demes et
al., 2006) compared to ML components experienced during linear
locomotion (Carlson et al.,
2005). Limb orientation relative to the SRF resultant was not
quantified in these lemur studies so bending moments could not be ascertained.
The lemurs, however, did appear to position their limbs more laterally during
side-step turns to the opposite direction, probably through relatively greater
abduction at proximal limb joints. In an experiment designed to demonstrate
the effect of limb abduction on external forces, ML forces increased as
abduction at proximal limb joints (i.e. shoulder and hip) progressively
increased in lemurs that were enticed to walk along simulated arboreal
substrates (Carlson, 2005b).
Although not all quadrupeds may exhibit relatively high ML forces during
turning, the available data on quadruped turning
(Demes et al., 2006) indicate
that elevated ML external forces are associated with redirection of travel
paths (e.g. side-step turns). Presumably this magnifies ML bending loads
experienced by long bone diaphyses relative to those experienced by long bone
diaphyses when limbs are moving in parasagittal planes.
Mice share several gait characteristics of linear locomotion with other
quadrupedal mammals (e.g. forelimb vertical SRF components exceed hindlimb
vertical SRF components; hindlimb duty factors exceed forelimb duty factors)
(Heglund et al., 1974;
Biewener, 1983;
Clarke and Still, 1999;
Clarke and Still, 2001;
Clarke et al., 2001;
Zumwalt et al., 2006). This
similarity extends to horizontal components of SRFs as well, including ML
forces (Carlson et al., 2005;
Zumwalt et al., 2006). Mice
have been observed to abduct their limbs when initiating side-step turns
(Walter, 2003), which
presumably increases ML forces experienced by their limb bones during
laterally directed applied forces that are responsible for redirecting travel
paths. While the relative degree of ML bending, AP bending, or torsion that
the mouse femur experiences during either turning or linear locomotion is
undocumented to our knowledge, Wallace and colleagues
[(Wallace et al., 2007), p.
1125] qualitatively described mice as tending to run on treadmills with their
hindlimbs flared laterally. This led them to speculate that bending loads in
the mouse femur may predominate over torsional loads
(Wallace et al., 2007).
Not all vertebrates emphasize ML external forces during turning. Humans, by
adopting a different gait (i.e. bipedalism) relative to most other
vertebrates, utilize a different mechanism for turns. While high ML forces
during lateral movements described as shuffling have been documented in human
athletes (McClay et al.,
1994), humans emphasize the anteroposterior (AP)-directed force
during turning. Humans achieve side-step turns first by using AP-directed
forces to unilaterally decelerate (i.e. counteract over- or under-rotation of
the body), which consequentially rotates (yaw) the body about its longitudinal
axis into a new direction of travel, and second by using AP-directed forces in
order to accelerate into the new travel direction
(Jindrich et al., 2006). Not
all bipeds, however, utilize a similar mechanism to change direction.
Ostriches emphasize ML horizontal forces
(Jindrich et al., 2007),
despite being a biped, similar to quadrupedal mammals
(Demes et al., 2006).
It is commonly assumed that applied mechanical loads have to exceed a
specific formation threshold to become anabolic
(Rubin and Lanyon, 1987;
Turner et al., 1994;
Cullen et al., 2001), but an
unusual loading condition by itself, without an increase in the level of
loading, also may have an anabolic effect
(Rubin and Lanyon, 1987).
Thus, the appendicular skeleton of an animal that experiences changes in its
locomotor patterns, such as increased turning activity, may adjust its
diaphyseal morphology through bone functional adaptations (cf.
Ruff et al., 2006).
The goal of this study was to test for the presence of specific,
quantifiable bone functional adaptations to increased turning behavior (e.g.
redistribution of bone mass resulting in femoral diaphyseal shape changes) by
exposing a model species to different habitual locomotor modes. By choosing an
inbred mouse strain as the animal model (e.g. BALB/cByJ), the potential
influence of genetic variability on musculoskeletal adaptations can be
eliminated. Furthermore, by emphasizing different habitual locomotor modes
rather than differences in the overall activity levels, as induced by
exercise, our experimental design differs from the approach of many animal
models that investigate the response to exercise in terms of net bone mass
gains or losses (e.g. Lee et al.,
2002; Mori et al.,
2003; Wu et al.,
2004; Kelly et al.,
2006; Wallace et al.,
2007). In the absence of differences in the quantitative activity
levels between groups, functional adaptations of the femur (e.g. shape
changes) likely reflect osseous responses to behavioral differences (i.e.
turning frequency) over the experimental period.
The overall hypothesis that an increase in habitual turning activity affects the cross-sectional shape of long bones is tested by two sub-hypotheses: (1) subjects with predominantly linear locomotion as well as subjects in which turning is emphasized in the locomotor repertoire will exhibit more elliptical femoral diaphyses than controls; (2) compared to the other two groups, linear subjects will have greater AP rigidity in their femoral diaphyses and turning subjects will have greater ML rigidity.
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Materials and methods |
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). In the
two experimental groups, food pellets (standard mouse chow) were placed on the
floor at the end of the cage opposite the water source in order to stimulate
use of the intervening tunnel.
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All mice were introduced to enclosures approximately 30 days after birth. Mice were subject to 12 h:12 h (light:dark) cycles during the protocol period. Body mass and food intake were monitored each week for each individual to ensure acceptable health and activity levels over the duration of the protocol period. Monitoring individual body mass gains and food consumption also provided a mechanism for comparing mouse stress levels in response to enclosure type.
Daily behavioral assessments were performed over the course of the protocol
period. Positional behavior (Prost,
1965) was documented approximately twice per day for each subject
(n=92 observations per individual). Behavioral observations for a
given day were usually performed at least 8 h apart, but always at least 5 h
apart (mean difference in daily observation times=10.8±2.3 h).
Observation times between days were varied in order to prevent oversampling
particular periods of active or sleep cycles of subjects. Behavioral
observations were recorded using an instantaneous focal sampling strategy
(Altmann, 1974). Briefly, this
consisted of carefully recording the behavior of a focal animal at a
pre-arranged time. During a behavioral assessment, mice served sequentially as
focal animals until the behavior of each subject was recorded quickly.
Behavioral categories were constructed from standard positional behavior modes
used previously for quantifying primate behavioral repertoires
(Hunt et al., 1996;
Carlson, 2005a;
Carlson et al., 2006). Modes
were devised to be self-descriptive and sufficient to represent an
overwhelming majority of all observed behaviors. Behavioral categories were
divided into locomotor behaviors (i.e. walk, run, jump, climb) and postural
behaviors (i.e. lie, sit, stand using three or four limbs, stand using both
forelimbs only, stand using both hind limbs only). Percentage locomotor
behavior was used as a proxy measure for activity level
(Table 1).
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Additional behavioral observations using an instantaneous focal sampling strategy with 1 min intervals over 1 h were applied to randomly selected individuals from each experimental group. The purpose of this set of behavioral observations (n=9 h per experimental group) was twofold: to verify that rare behaviors in daily observations were not underestimated in frequency (e.g. jump), and to assess whether experimental groups used tunnels with equivalent frequencies. Mice usually traversed tunnels 20 or more times within an hour regardless of the experimental group, though linear mice tended to traverse the tunnel at a higher frequency (linear group mean tunnel passes ±1 s.d.=63.3±29.8; turning group mean tunnel passes ±1 s.d.=40.7±22.8). While the linear tunnel was approximately 34.5 cm in length, the winding tunnel was approximately 48.0 cm in length. Thus, the higher frequency of tunnel use by the linear group was somewhat equalized by the longer distance the turning group traveled through the tunnel in one pass (mean linear travel distance per hour=2183.85 cm; mean turning travel distance per hour=1953.6 cm). Furthermore, three individuals per experimental group were observed twice in order to assess intraindividual variation in tunnel use. Ultimately, intraindividual differences in tunnel use (22.7±14.3) were similar in scale to intergroup differences in tunnel use (22.6). Thus, we believe that it is reasonable to assume similar tunnel use by subjects from the two experimental groups (i.e. no exercise effect was present).
At the termination of the experimental protocol (i.e. day 57), mice were
sacrificed and limbs were disarticulated. The left femur was stored in 70%
ethanol and scanned in a microCT system (Scanco µCT 40: Scanco Medical AG,
Bassersdorf, Switzerland). To create 3D volumes, digital image stacks
representing whole femora were exported as DICOM files into AmiraTM
imaging software (Berlin, Germany). Once 3D volumes representing individual
femora were segmented, they were imported into custom-designed software
(FoRM-IT) (Zollikofer et al.,
1995). While we did not use commercially available software, such
software is available (i.e. AmiraTM) and is preferable for subsequent
studies. Digitally rendered volumes representing femora were positioned in a
standardized fashion according to anatomically relevant orientations that have
been used for similar structural comparisons among other taxa
(Ruff, 2002;
Carlson, 2005a). Femoral
mechanical lengths (see Carlson,
2005a) were measured from 3D volumes after they were positioned
since voxels were of known dimensions. Camera options of the software program
were used subsequently to digitally re-slice elements in order to obtain cross
sections at the desired regions of interest (ROIs): 35%, 50%, and 65% lengths.
The most distal point of the femur while in the standardized position
corresponded to 0% length.
Once a digital cross section was produced, the image was imported into
Scion Image (release Beta 4.0.2) for analysis using custom-written macros
modeled after the SLICE program (Nagurka
and Hayes, 1980). Scion Image was ported from NIH Image for the
Macintosh by Scion Corporation and is available on the Internet at
http://www.scioncorp.com.
Standard cross-sectional properties calculated for all femora included:
subperiosteal area (Ps.Ar), cortical area (Ct.Ar), second moments of area
about AP (Iy) and ML (Ix) anatomical
axes, principal moments of area (Imax,
Imin), and the principal angle (
)
(Parfitt et al., 1987). Since
body mass (P=0.330) and bone length (P=0.299) did not differ
significantly between groups (Table
2), comparisons of structural properties across groups were
consistent with the definition of narrow allometry
(Smith, 1980;
Smith, 1984;
Jungers, 1987). Unstandardized
cross-sectional properties, therefore, were used in comparisons of group
structural properties.
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Shape ratios (i.e. Iy/Ix and
Imax/Imin) were calculated from
several structural properties. The
Imax/Imin ratio reflects deviation of
cross-sectional shape from circularity, while the
Iy/Ix ratio reflects differences in
AP/ML rigidity (Carlson,
2005a). Theta (), the principal angle, is defined as the
angle between the ML anatomical axis and the maximum principal axis. Maximum
divergence of principal and anatomical axes occurs when approaches
45°, but when approaches 0° these ratios will provide
convergent measures of overall cross-sectional shape. Theta for femoral ROIs
in this study ranged between 0° and 10°. Only second moments of area
in anatomical planes (Iy and Ix),
therefore, are reported in Table
2 since these offer intuitive anatomical interpretations.
Standard descriptive statistics were computed for all variables of interest. Normal distribution of data was verified with one-sample Kolmogorov–Smirnov tests. Since the distributions of behavioral variables (i.e. % postural behavior, % locomotor behavior), terminal body mass and cross-sectional properties did not differ significantly from normal distributions, parametric statistical analyses were selected for evaluating group mean differences in these properties. Equality of group variances for a variable of interest was verified using a Levene's test for homogeneity of variances. Since data fit the assumptions of a one-way analysis of variance (ANOVA), this statistical procedure was chosen to assess null hypotheses that group means were equal for given variables. If an ANOVA indicated statistically significant differences between groups for any variable, Fisher's least significant difference (LSD) post-hoc analyses were used to determine which groups differed significantly from one another. Statistical significance levels were set at P<0.05 for all statistical analyses. All statistical analyses were performed within SPSS 15.0 (SPSS, Inc., Chicago, IL, USA).
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Groups did not differ significantly in overall activity level as measured by percent locomotor behavior over the duration of the experimental period (P=0.82) (Table 1), nor in average body mass at the end of the experimental period (P=0.33) (Table 2). Measures of cortical bone quantity in the femoral diaphysis – total subperiosteal area (Ps.Ar) and cortical area (Ct.Ar) – also were not significantly different between groups (P>0.5) (Table 2). Groups did not differ significantly in their second moments of area about the anatomical AP and ML axes (P>0.6) (Table 2). These measures approximate ML (Iy) and AP (Ix) bending rigidity, respectively.
In contrast to measures of bone quantity or structural rigidity, diaphyseal shapes effectively distinguished groups (Figs 2, 3; Table 2). Although individual structural properties were not significantly different between groups, the femoral midshaft exhibited a significant shape difference according to Iy/Ix ratios (P=0.049), and was borderline non-significant according to Imax/Imin ratios (P=0.053). Post-hoc testing confirmed the hypothesis that the femoral midshaft shape of turning mice is different from the other two groups (i.e. turning mice had more elliptical cross sections than control mice and were most ML-elliptical of any group) (Fig. 3). The Iy/Ix ratio was 5.6% greater (P=0.030) in turning mice than in linear mice and 5.6% greater (P=0.032) in turning mice than in control mice (Fig. 3). The comparisons of the Imax/Imin ratio revealed essentially the same pattern as for the Iy/Ix ratio. In post-hoc testing, the Imax/Imin shape ratio was 4.8% greater (P=0.049) in turning mice than in linear mice and 5.6% greater (P=0.025) in turning mice than in control mice.
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Although linear subjects on average had relatively less ML-elliptical femoral midshafts (i.e. higher Ix and lower Iy) than turning subjects, this was not the case when comparing linear and control subjects. Linear and control mice were differentiated neither by their structural properties (Fig. 2) nor by their diaphyseal shapes (Fig. 3). The Iy/Ix ratio of control mice was within 0.1% (P=0.98) of linear mice, which did not support the hypothesis that control subjects would have the most circular femora (i.e. lowest shape ratios) and that linear subjects would have more AP-elliptical femora. Similarly, the Imax/Imin shape ratios of linear and control mice were not significantly different (P=0.750) and within 1% of each other.
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Since ML and AP bending rigidities of the mouse femoral diaphyses
consistently corresponded to maximum and minimum rigidities, respectively, it
is appropriate to discuss general diaphyseal shape differences between the
groups in terms of the more intuitive anatomical properties
(Carlson, 2005a). Relative to
mice in the linear group or mice in the `free-ranging' control group, mice in
the turning group exhibited a significantly more elliptical femoral midshaft.
This shape change was attributable to a combination of small (non-significant)
but cumulative differences in both higher ML rigidity among turning subjects
relative to other groups, and lower AP rigidity among turning subjects
relative to the other groups. This result is consistent with studies reporting
higher strain magnitudes (presumably in ML directions) and higher ML external
forces during turning relative to linear locomotion
(Burr et al., 1996;
Demes et al., 2006). The drop
in AP rigidity among turning subjects may have been a consequence of reduced
opportunities for linear locomotion relative to other groups.
Relative to subjects in the turning group, subjects in the linear group exhibited shape differences in the predicted direction – higher AP rigidity and lower ML rigidity. When comparing control subjects and the lower AP and ML rigidities of linear subjects, however, group differences were not significant. Furthermore, linear and control groups did not differ significantly in overall shape differences of the femoral diaphysis. This contradicted the hypothesis that linear subjects would exhibit more elliptical diaphyses, and specifically more AP-elliptical diaphyses than control subjects. An explanation for similarity in the structural properties and shape ratios of these groups is unclear. That the frequency of turning behaviors in `free-ranging' conditions (i.e. control subjects) is unknown, however, could be relevant. For example, the possibility that turning frequency was performed by control subjects to the same extent as the restricted turning frequency of linear subjects cannot be excluded. Data on turning frequency in `free-ranging' animals would be extremely helpful in evaluating this possibility.
Turning mice were the most distinctive group in terms of shape ratios. While linear locomotion could not be eliminated entirely from the locomotor repertoire of turning mice in either end of the modified enclosures, they experienced substantially reduced opportunities for linear locomotion relative to linear subjects (Fig. 1). Likewise, while turning behavior could not be eliminated entirely from the locomotor repertoire of linear mice upon entering or exiting tunnels, they had substantially reduced opportunities for altering travel direction relative to turning mice (Fig. 1). Inclusion of what are probably low frequencies of these restricted behaviors in their locomotor repertoires ultimately could be responsible for some of the overlap in measures of structural rigidity (e.g. Iy or Ix) and shape ratios of the experimental groups (Fig. 2A,B), and thus may be partially responsible for the relatively low absolute magnitude of femoral shape difference between groups (i.e. 5–6%).
Factors other than behavioral differences have the potential to confound
comparisons of femoral shape differences between groups. Bone mass and
structural properties are regulated in part by heredity (e.g.
Judex et al., 2004a;
Judex et al., 2004b;
Wergedal et al., 2005). All
mice used in this study were from the same genetic inbred strain, and thus
genetic variability, a potentially confounding variable in some functional
morphology studies, did not play a role here. Levels of physical activity also
are known to affect bone mass and morphology (e.g.
Forwood and Burr, 1993). On
average, however, groups did not differ in body mass or activity level (i.e.
no significant group differences in % locomotor behavior) and thus exercise
per se could not account for the observed shape differences. Since
the sample was composed of only female individuals from a single inbred
strain, variation in hormonal levels (e.g.
Devlin and Lieberman, 2007)
likely had at most only a minor contribution to shape differences between
groups that expose femora to different mechanical loading environments.
Similarities in average Ps.Ar and Ct.Ar of groups is consistent with the view
that our experimental design eliminated most confounding variables. Therefore,
in our view, group differences in the shape of the femoral midshaft,
particularly between turning subjects and other subjects, are most
parsimoniously attributable to differential distributions of bone resulting
from locomotor behavior differences between groups (i.e. mode
differences).
Simultaneous documentation of bone functional adaptations and changes in
the mechanical loading environments of the femur was technically not feasible
within the experimental design of this study. Considering the mechanical
similarities in locomotion (including turning) between mice and other
mammalian quadrupeds (Rubin and Lanyon,
1984; Biewener and Taylor,
1986; Clarke and Still,
1999; Clarke and Still,
2001; Clarke et al.,
2001; Walter,
2003; Carlson et al.,
2005; Demes et al.,
2006; Zumwalt et al.,
2006), we hypothesize that, compared to the other two groups,
turning mice experienced elevated ML external forces during turning that in
turn may have generated their distinct femoral cross-sectional shape.
Verification of such differences in the mechanical loading environment (i.e.
differences in ML bending), however, is required to verify this
hypothesis.
Implications for comparative studies of bone morphology
The observed group differences in average shape ratios have two potential
implications. First, we are unaware of published data reporting turning
frequencies for any `free-ranging' quadrupedal animal. It was anticipated that
control subjects (i.e. `free-ranging' individuals) would display intermediate
frequencies of both turning and linear locomotor behaviors in their locomotor
repertoire compared to the two experimental groups. Given greater structural
similarity between control and linear subjects than was observed between
control and turning subjects, `free-ranging' control subjects presumably
performed turning behaviors at frequencies more similar to linear subjects. In
other words, turning behavior may have been relatively less frequent within
the overall behavioral repertoire of `free-ranging' subjects than was
expected. A necessary caveat here is that the experimental `free-ranging'
conditions did not incorporate natural incentives for changing direction such
as predator avoidance and intraspecific competition. Clearly it would be
helpful to quantify turning frequency and its context as part of behavioral
data collection in observational studies of free-ranging animals.
A second implication is that femoral cross-sectional shape may be more
sensitive to certain locomotor modes compared to others, although expected
shape outcomes remain difficult to predict for most modes. Arboreal locomotor
modes such as scrambling, which is characterized specifically by multiple
rapid changes in the direction of travel in both vertical and horizontal
planes (Hunt et al., 1996),
could be particularly relevant to diaphyseal shape adaptations in the
musculoskeletal system of arboreal quadrupeds, particularly among primates
(Carlson, 2005a;
Carlson et al., 2006). If load
magnitudes are high enough, even a small number of loads (e.g. five or more)
have been shown to evoke an anabolic response in the musculoskeletal system
(Umemara et al., 1997). Local strain magnitudes may be greater during turning
in comparison to linear locomotion (Burr et
al., 1996). Furthermore, fewer load cycles are sufficient to
initiate an osseous response when the load regime is novel in orientation
(Turner, 1998;
Burr et al., 2002), as may be
the case during turning if load orientations vary widely relative to linear
locomotion. Our study did not attempt to address whether the distinctive shape
of the femoral midshaft in turning subjects is driven by higher local strain
magnitudes associated with turning or whether potential novel orientations of
the load regime associated with this behavior are more relevant to
cross-sectional shape change. Either or both impetuses are plausible in the
current study design.
Since the absolute effect of turning on diaphyseal shape difference was
relatively small in this study (i.e. around 5–6% difference), it is not
surprising that significant shape differences were observed only at the
femoral midshaft. Experimental studies have shown that bone responses to load
stimuli vary between diaphyseal locations
(Gross et al., 1997;
Judex et al., 1997). The
midshaft is theoretically the location experiencing the greatest bending
strains in long bone diaphyses (Martin et
al., 1998) and hence, changes in cellular activity driven by
altered mechanical loading can be expected to be most visible at this
location. Accordingly, shape differences, particularly those of small absolute
magnitudes (i.e. 5–6%), may be difficult to discern at other diaphyseal
locations (i.e. 35% or 65% diaphyseal locations). In a more genetically
diverse population than an inbred strain of laboratory mouse, or in a sample
generated from museum specimens, shape signals of turning frequency even in
the femoral midshaft could be more subtle, and afflicted with greater data
variability, than those that were observed in the present study.
In order to fully appreciate the potential importance of turning to
interpretations of skeletal morphology in free-ranging taxa, its context
within the locomotor repertoire of a taxon should be contemplated. Turns
performed by extant `free-ranging' animals likely occur across a broad range
of angles. Winding turns, such as those elicited in the present study, may
involve different mechanical consequences than turns of 90°
(Walter, 2003) or
approximately 30° (Demes et al.,
2006). Habitat variability may be linked to variability in turning
frequency (e.g. higher frequency in closed forest versus lower
frequency in open savanna). Furthermore, habitually abducted limb postures
have been used as explanations for increased ML rigidity in extinct taxa [e.g.
Megaladapis edwardsi (Jungers and
Minns, 1979), multituberculate mammals
(Kielan-Jawaroska and Gambaryan,
1994)]. One also must be mindful of limb postural differences,
therefore, when attempting to infer the frequency of turning behaviors in
locomotor repertoires, particularly when behavioral observations are no longer
possible (i.e. extinct taxa).
Though the absolute effective shape change we observed may be relatively
small, this proof-of-principle study demonstrates that increasing the ratio of
turning to linear locomotion alters diaphyseal cross-sectional shape in a
predictable fashion. In order to further explore the usefulness of this
relationship for comparative biologists, several points would be worthwhile
for investigation. The effect of turning could be more dramatic in larger
quadrupeds if they encounter higher strain magnitudes relative to their body
size during changes in direction, though studies of linear locomotion find
clear evidence for dynamic strain similarity across adult animals of varying
body sizes (Rubin and Lanyon,
1984; Biewener and Taylor,
1986). Additionally, subjects encountering a longer experimental
period (e.g. 12 weeks rather than 8 weeks) could produce a more exaggerated
shape change as bone modeling and remodeling continues into adulthood.
Ultimately, extending the experimental period may provide a more appropriate
context for comparisons of extant or extinct vertebrate adults, whose femoral
diaphyseal shapes reflect a behavioral contribution from summed locomotor
input over a lifetime. Shape changes also could be more dramatic in mouse
strains that are known to exhibit greater sensitivity in osteogenic responses
to given functional loads than those exhibited by BALB/cByJ mice
(Judex et al., 2004b;
Wergedal et al., 2005), or in
mouse strains that exhibit higher levels of physical activity
(Kaye and Kusy, 1995). Even in
the absence of any potential improvement to the strength of the
form–function signal demonstrated here, these data provide direct
evidence that increased turning can alter the distribution of bone mass in the
femoral diaphysis and that, in addition to quantitative exercise-based
differences, qualitative differences between locomotor repertoires (e.g.
amount of turning versus linear locomotion) should be considered
among the factors that determine bone morphology of an individual.
List of abbreviations and symbols
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Acknowledgments |
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References |
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TOPSummaryIntroductionMaterials and methodsResultsDiscussionReferences |
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