Intermittent locomotion increases endurance in a gecko

Nocturnal geckos can actively forage at low temperatures. A low minimum cost of locomotion allows greater sustainable speeds by partially offsetting the decrease in maximal oxygen consumption (VO2max) associated with low nocturnal temperatures. The nocturnality hypothesis (Autumn et al. 1997) proposes that the reduced cost of continuous locomotion is a shared, derived characteristic that increases the capacity to sustain locomotion at low temperatures. Yet many lizards move intermittently at speeds exceeding those that elicit VO2max. We exercised the frog-eyed gecko, Teratoscincus przewalskii, continuously and intermittently on a treadmill. At an exercise speed of 0.90 km h-1 (270% maximum aerobic speed), lizards alternating a 15-s exercise period with a 30-s pause period exhibited a 1.7-fold increase in distance capacity (total distance traveled before fatigue) compared with lizards exercised continuously at the same average speed (0.30 km h-1). The average aerobic cost of intermittent exercise was not significantly different from VO2max. Locomoting intermittently could augment the increase in endurance resulting from the low minimum cost of continuous locomotion in nocturnal geckos. Intermittent behavior could increase the endurance of lizard movement in general.     

Metabolic implications of a 'run now,pay later' strategy in lizards: an analysis of post-exercise oxygen consumption

Lizards and many other animals often engage in locomotor behaviors that are of such short duration that physiological steady-state conditions are not attained. It is sometimes difficult to estimate the energetic costs of this type of locomotor activity. This difficulty is addressed by considering as reflective of the metabolic cost of activity (C(act)) not only the oxygen consumed during the activity itself, but also the excess post-exercise oxygen consumption (EPOC) and any excess metabolites persisting at the end of EPOC. Data from both lizards and mammals demonstrate that EPOC is the major energetic cost when activity is short and intense. This paper evaluates the major metabolic components of EPOC in lizards. We then examine how behavioral variables associated with locomotion (duration, intensity, frequency) can influence EPOC and C(act). Short and intense activity is much more expensive by this measure than is steady-state locomotion. Evidence is provided that intermittent activity of short duration can be more economical relative to single bouts of the same activity. Metabolic savings appear greatest when the pause period between behaviors is short. In contrast, endurance is enhanced by short activity periods and longer pause periods, suggesting a tradeoff between endurance and EPOC-related metabolic costs.     

Modeling the Metabolic Energetics of Brief and Intermittent Locomotion in Lizards and Rodents

When locomotor activity is brief, physiological steady stateconditions are not attained. It is therefore difficult to modelthe energetic costs of intermittent activity using standardmethods. This difficulty is addressed by considering as reflectiveof the metabolic costs of activity not only the oxygen consumedduring the activity itself, but also the excess post-exerciseoxygen consumption (EPOC) and any excess metabolites persistingat the end of EPOC. This paper briefly reviews the metabolicevents associated with EPOC, and then examines how this approachcan be applied to address questions of how behavioral variablesassociated with locomotion (activity duration, intensity, frequency)can influence the energetic costs to the animal per unit distance.Using data for lizards, mice, and others, EPOC can be shownto be the major component of energetic costs when durationsare short, regardless of exercise intensity. Brief activityis much more expensive by this measure than is steady statelocomotion, regardless of phylogeny or body mass. Three studiesof intermittent locomotion provide evidence that brief behaviorscan be undertaken at lower metabolic costs than predicted fromsingle bouts of activity when repeated in a frequent, repeatedpattern. Metabolic savings appear greatest when the pause periodbetween behaviors is short relative to EPOC duration, the timefor organismal metabolic rate to return to pre-exercise levels,although longer pause periods may increase endurance.     

The movement patterns of lacertid lizards: speed, gait and pauses in Lacerta vivipara

Lacerta vivipara moving across an open space at their normal activity temperature alternate bursts of locomotion with short pauses which tend to occur at the extremes of the limb cycle, i.e. when individual limbs are maximally adducted or retracted and the spinal cord is maximally flexed in the lateral plane. The movement bursts and pauses in adult lizards have mean durations of 0–30 and 012 s, respectively, and within bursts the lizards move at a mean speed of 14–6 cm s^-1. Movement in juvenile lizards is 2–5 times faster (relative to body length) and the pauses are of longer duration (mean = 019 s), giving the locomotion of juveniles a more jerky appearance. Lizards which are chasing crickets increase the speed and the duration of locomo-tory bursts, although the pauses persist. Lizards which are searching for a previously perceived cricket increase pause duration (mean = 0–40 s). Lizards which are fleeing from a sudden disturbance move at almost twice (juveniles) or 3–7 times (adults) the speed of foraging animals: the pauses persist, although at much reduced frequency. Increases in speed result from increases in both stride length (Λ) and stride frequency (n); the ratio Λ/ n appears to remain constant at 006. The significance of these observations is discussed, although the functions of the pauses cannot yet be explained.     

Analysis of the finescale timing of repeated signals: does shell rapping in hermit crabs signal stamina?

Hermit crabs, Pagurus bernhardus, sometimes exchange shells after a period of shell rapping, when the initiating or attacking crab brings its shell rapidly and repeatedly into contact with the shell of the noninitiator or defender in a series of bouts. Bouts are separated by pauses, and raps within bouts are separated by very short periods called 'gaps'. Since within-contest variation is missed when signals are studied by averaging performance rates over entire contests, we analysed the fine within-bout structure of this repeated, aggressive signal. We found that the pattern is consistent with high levels of fatigue in initiators. The duration of the gaps between individual raps increased both within bouts and from bout to bout, and we conclude that this activity is costly to perform. Furthermore, long pauses between bouts is correlated with increased vigour of rapping in the subsequent bout, which suggests that the pause allows for recovery from fatigue induced by rapping. These between-bout pauses may be assessed by noninitiators and provide a signal of stamina. Copyright 2000 The Association for the Study of Animal Behaviour.     

Recuperation after muscular fatigue by "diverting activities"

"Diverting activity" is defined as any physical or mental activity performed between or simultaneously with bouts of exhaustive, local muscular work. In the present experiments bouts of exhaustive work consisting of rhythmic lifting of weights were performed with the elbow flexors or with the flexors of the middle finger. Pauses of 2 min duration spent in complete rest or while performing diverting activities alternated between the bouts of work. As diverting activities were used: Physical activity, dynamic or static, performed with big or small muscle groups (other than the fatigued group), or mental activity (problem solving). It was found that the amount of work that could be performed after a pause with diverting activity was always larger than the amount of work performed after a passive pause. The beneficial effect was seen also when the blood flow to the exhausted muscles was interrupted by pneumatic cuffs. Determination of the blood flow in the exhausted muscles by means of Xe-133 clearance showed no systematic blood flow increases caused by the diverting activity. It is concluded that recuperation after local muscle fatigue is influenced by a central nervous factor (Setchenov phenomenon) that is largely independent of the local blood flow.     

Modulation of NK cell activity by moderate intensity endurance training and chronic ethanol consumption.

Chronic ethanol consumption can suppress natural killer (NK) cell activity. Exercise after ethanol administration may enhance blood ethanol clearance, which may benefit the immune response. This study examined the effects of moderate intensity endurance training and chronic ethanol consumption (20% wt/vol) on splenic NK cell activity. Mice were assigned to one of four groups: sedentary, water drinking (SED-H2O); sedentary, ethanol consuming (SED-EtOH); trained, water drinking (TR-H2O), and trained, ethanol consuming (TR-EtOH). TR groups ran 60 min/day, 5 days/wk, at 12 m/min for 10 wk. Mice were killed 48 h after exercise. Baseline NK cell activity was suppressed 30% in TR and EtOH groups compared with SED-H2O controls. Activation with recombinant human interleukin-2 increased cytolytic activity in all groups four- to fivefold. These results indicate that training did not abrogate the effects of chronic ethanol consumption on NK cell activity. Furthermore, moderate endurance training may contribute to suppressed nylon wool-enriched NK cell activity in murine splenocytes for as long as 48 h after exercise.     

Intermittent motion in desert locusts: behavioural complexity in simple environments

Animals can exhibit complex movement patterns that may be the result of interactions with their environment or may be directly the mechanism by which their behaviour is governed. In order to understand the drivers of these patterns we examine the movement behaviour of individual desert locusts in a homogenous experimental arena with minimal external cues. Locust motion is intermittent and we reveal that as pauses become longer, the probability that a locust changes direction from its previous direction of travel increases. Long pauses (of greater than 100 s) can be considered reorientation bouts, while shorter pauses (of less than 6 s) appear to act as periods of resting between displacements. We observe power-law behaviour in the distribution of move and pause lengths of over 1.5 orders of magnitude. While Lévy features do exist, locusts' movement patterns are more fully described by considering moves, pauses and turns in combination. Further analysis reveals that these combinations give rise to two behavioural modes that are organized in time: local search behaviour (long exploratory pauses with short moves) and relocation behaviour (long displacement moves with shorter resting pauses). These findings offer a new perspective on how complex animal movement patterns emerge in nature.     

Relationship between respiratory pauses and heart rate during sleep in normal premature and full-term newborns

To investigate the relationship between central respiratory pauses and heart rate, we performed polygraphic recordings in 23 normal newborns (35 to 41 weeks conceptional age). We monitored the electroencephalogram, rapid eye movements, movements of the upper and lower limbs, chin and diaphragmatic electromyogram, electrocardiogram, thoracic and abdominal respiratory movements, air flow and transcutaneous PO2. Heart rate changes were analysed by computer measurement of R-R intervals and by cardiotachography. Respiratory pauses occurring after body movements and those not preceded by movements were studied separately. We analysed 1128 respiratory pauses greater than 3 s duration. No respiratory pause lasted more than 12 s. Independently of age, sleep state and respiratory pause duration, heart rate was significantly lower at the onset of respiratory pause, compared to control periods (selected away from the pause: 10 s before its onset and 20 s after its end). Heart rate slowed still further through the respiratory pause and reverted toward the baseline level after its end. When no movements preceded the respiratory pause, heart rate just before the pause was lower compared to control periods. These findings suggest the existence of simultaneous central commands responsible for both respiratory pause and heart rate deceleration.     

Effects of high-intensity swimming training on GLUT-4 and glucose transport activity in rat skeletal muscle.

This study was performed to assess the effects of short-term, extremely high-intensity intermittent exercise training on the GLUT-4 content of rat skeletal muscle. Three- to four-week-old male Sprague-Dawley rats with an initial body weight ranging from 45 to 55 g were used for this study. These rats were randomly assigned to an 8-day period of high-intensity intermittent exercise training (HIT), relatively high-intensity intermittent prolonged exercise training (RHT), or low-intensity prolonged exercise training (LIT). Age-matched sedentary rats were used as a control. In the HIT group, the rats repeated fourteen 20-s swimming bouts with a weight equivalent to 14, 15, and 16% of body weight for the first 2, the next 4, and the last 2 days, respectively. Between exercise bouts, a 10-s pause was allowed. RHT consisted of five 17-min swimming bouts with a 3-min rest between bouts. During the first bout, the rat swam without weight, whereas during the following four bouts, the rat was attached to a weight equivalent to 4 and 5% of its body weight for the first 5 days and the following 3 days, respectively. Rats in the LIT group swam 6 h/day for 8 days in two 3-h bouts separated by 45 min of rest. In the first experiment, the HIT, LIT, and control rats were compared. GLUT-4 content in the epitrochlearis muscle in the HIT and LIT groups after training was significantly higher than that in the control rats by 83 and 91%, respectively. Furthermore, glucose transport activity, stimulated maximally by both insulin (2 mU/ml) (HIT: 48%, LIT: 75%) and contractions (25 10-s tetani) (HIT: 55%, LIT: 69%), was higher in the training groups than in the control rats. However, no significant differences in GLUT-4 content or in maximal glucose transport activity in response to both insulin and contractions were observed between the two training groups. The second experiment demonstrated that GLUT-4 content after HIT did not differ from that after RHT (66% higher in trained rats than in control). In conclusion, the present investigation demonstrated that 8 days of HIT lasting only 280 s elevated both GLUT-4 content and maximal glucose transport activity in rat skeletal muscle to a level similar to that attained after LIT, which has been considered a tool to increase GLUT-4 content maximally.     

Integrating the Physiology, Mechanics and Behavior of Rapid Running Ghost Crabs: Slow and Steady Doesn't Always Win the Race

In 1979 Bliss predicted that, "land crabs are and will undoubtedlycontinue to be promising objects of scientific research." Studiesof rapid running ghost crabs support her contention and haveresulted in several general findings relating to locomotionand activity. 1) Energy exchange mechanisms during walking aregeneral and not restricted to quadrupedal and bipedal morphologies.2) "Equivalent gaits," such as trots and gallops, may existin 4-, 6- and 8-legged animals that differ greatly in leg andskeletal (i.e., exo- vs. endoskeletal) design. These findingssupport the hypothesis that terrestrial locomotion in many speciescan modeled by an inverted pendulum or spring-mass system. 3)An open circulatory system and chitin-covered gills do not necessarilylimit the rate at which oxygen consumption can be increasedor the factorial increase oxygen consumption over resting rates.4) Interspecific and intraspecific i.e., ontogenetic) scalingof sub-maximal oxygen consumption and maximal aerobic speedcan differ significantly. 5) Locomotion at speeds above themaximal aerobic speed requiring non-aerobic contributions maybe far more costly than can be predicted from aerobic costsalone. The cost transport may attain a minimum at less thanmaximum speed. 6) The speed which elicits maximal oxygen consumptionduring continuous exercise is attained at moderate walking speedsin crabs and probably other ectotherms. Speeds 15- to 20-foldfaster are possible, but cannot be sustained. 7) The low enduranceassociated with the low maximal oxygen consumption and maximalaerobic speed of ectotherms moving continuously can be increasedor decreased by altering locomotor behavior and moving intermittently.Ectotherms can locomote at high speeds and travel for considerabledistances or remain active for long periods by including restpauses. Alternatively, intense activity with extended exerciseperiods with short pause periods may actually reduce behavioralcapacity or work accomplished relative to continuous activityduring which the behavior is carried out at a lower intensitylevel without pauses.     

How to climb a tree: lizards accelerate faster,but pause more,when escaping on vertical surfaces

Many species of lizards effectively traverse both two and three‐dimensional habitats. However, few studies have examined maximum locomotor performance on different inclines. Do maximum acceleration and velocity differ on a level and inclined surface? Do lizards pause more on an inclined surface? To address these questions, Sceloporus woodi lizards (N = 12) were run in the laboratory on a level trackway and a vertical tree trunk. This species is known to frequently utilize both vertical and horizontal aspects of its habitat. Average maximum acceleration on the vertical surface exceeded that on the level surface, although average maximum velocity exhibited the opposite pattern. The average number of pauses during level locomotion was lower compared to vertical locomotion. In addition, the average location of the first pause on the level surface was 0.51 m, which is farther than the average for vertical locomotion where the first pause was at 0.35 m. The combination of performance and pause data suggests that the relative lack of pausing during level locomotion allows individuals to reach higher maximum velocities on level surfaces because they accelerate over greater distances. The increased pausing when moving vertically could be a result of high energetic demands of vertical locomotion, or greater microhabitat complexity as a result of branching and/or refuges. The faster acceleration exhibited during vertical locomotion by S. woodi likely offsets the frequent pauses. © 2010 The Linnean Society of London, Biological Journal of the Linnean Society, 2011, 102 , 83–90.     

Progressive elevations in muscle blood flow during prolonged exercise in swine

Distribution of muscle blood flow has not been measured in man during prolonged exercise, but progressive elevations in skin flow coupled with constant cardiac output (QT) have suggested muscle blood flow may be compromised. However, previous experiments with rats demonstrated progressive increases in muscle blood flow over time during prolonged submaximal exercise. The present study was performed to study muscle blood flow in miniature swine during long-term exercise to shed light on this apparent anomaly. QT and distribution of QT were studied with radiolabeled microspheres while pigs ran on a level treadmill at a speed (10.5 km/h) requiring 71 +/- 4% of maximal O2 consumption (VO2 max). QT increased 23% from the 5th to the 30th min of exercise, whereas total skeletal muscle flow increased by 49%. Increases in flow in the muscles resulted from decreased resistance, since mean arterial pressure declined over this time period (-7%). In addition, the proportional increases in muscle flow were similar within synergistic muscle groups independent of fiber type composition (e.g., elbow extensors: 59-78%; elbow flexors: 26-40%). The factor that limited continued exercise appeared to be body temperature. Colonic temperature rose in linear fashion over time; the animals became exhausted at approximately 42 degrees C. These flow data are similar to previous findings in rats and indicate that during prolonged treadmill locomotion in quadrupedal animals muscle blood flow increases over time to near maximal levels.     

Terrestrial Intermittent Exercise: Common Issues for Human Athletics and Comparative Animal Locomotion

The earliest studies of intermittent exercise physiology notedthat moving intermittently (i.e., alternating brief movementswith brief pauses) could transform a heavy workload into a submaximalone that can be tolerated and sustained. The brief pauses thatcharacterize intermittent locomotion permit at least partialrecovery from prior activity. This research provided the foundationfor the development of interval training and more recently forthe re-evaluation of steady-state paradigms for comparativeanimal locomotion. In this paper I review key concepts underlyingthe performance of repeated activity. I provide examples fromhuman athletics and training and comparative animal locomotion.To explore the limits of intermittent exercise performance,I examine the performance limits for continuous exercise andthe rate and extent of the recovery of performance capacityfollowing activity. While it is evident that altering locomotorbehavior (i.e., moving intermittently) can alter the capacityof an animal to perform work, mathematical models of intermittentexercise could predict strategies (i.e., exercise intensity,exercise duration, and pause duration) that will increase performancelimits for intermittent activity.     

Influence of a period of inactivity on the duration of post-rest action potentials of the mammalian working ventricular myocardium in correlation to the preceding stimulation frequency

Experiments were carried out on the working right ventricular myocardium of adult cats, guinea-pigs and rabbits. Membrane voltage was recorded by the glass microelectrode technique and the preparations were stimulated with frequencies of 5, 1 and 0.2 Hz. After a steady state had been reached, a pause (TP) lasting 10-600 s was interpolated. The influence of TP on the duration (D) of post-rest action potentials (AP) was studied; the effect of the pause was measured at electric zero level (D0) and at further repolarization levels (-20, -40 and -60 mV, given here as D-20, D-40 and D-60). At 1 and 0.2 Hz frequency, the cat myocardium displayed lengthening of the AP proportional to the duration of the pause; at 5 Hz frequency, D0 reacted by lengthening up to TP = 120 s and to further pauses by slight shortening. D-60, at all frequencies, lengthened throughout the whole of the given TP range. The rabbit myocardium, at all the given frequencies, reacted up to TP = 60-120 s by marked shortening of post-rest AP at all repolarization levels; with longer pauses the AP lengthened. At 5 Hz frequency the guinea-pig myocardium reacted similarly to the cat myocardium; at the lower stimulation frequencies, the pause-induced changes in the post-rest AP were less strongly expressed. In all the given types of myocardium, the most pronounced post-rest AP reactions were those at electric zero level (the plateau phase of the AP); towards more negative repolarization values and with lower pre-pause stimulation frequencies they were less strongly expressed.(ABSTRACT TRUNCATED AT 250 WORDS)     

Arterial oxygen saturation and breathing movements during the first year of life.

Sixteen healthy term infants underwent 12 hour tape recordings of arterial oxygen saturation (SaO2)(Nellcor N100 in beat to beat mode) and breathing movements at around 6 weeks, 3 and 6 months of age. Six of these infants had an additional recording at around their first birthday. Recordings were analysed throughout for pauses in breathing movements of greater than or equal to 4 s (apnoeic pauses), episodes in which SaO2 fell to 80% (desaturations), and (only during regular breathing) baseline SaO2. In the 16 infants studied at 6 weeks, 3 and 6 months, the median frequency of both apnoeic pauses (5.6, 5.7, and 6.1/h, respectively) and desaturations (0.7, 0.4 and 0.5/h, respectively) showed little change. The majority of desaturations followed an apnoeic pause (median 73.2, 86.2 and 93.8% of desaturations). The median proportion of apnoeic pauses followed by a desaturation did not change significantly (9.0, 7.5 and 9.1%), despite an increase in the proportion of apnoeic pauses of greater than or equal to 8 s in duration from 2.0% at 6 weeks to 5.3% at 3 months (P less than 0.01). Baseline SaO2 was 97.3% or higher in all recordings. Median baseline SaO2 increased from 99.6 to 99.9% between 6 weeks and 3 months (P less than 0.02) and remained unchanged thereafter. In the subgroup of infants studied also at one year of age, again no significant differences were found with increasing age in the frequency of either apnoeic pauses or desaturations. The data show that in healthy subjects no major changes occur between 6 weeks and 1 year of life in apnoeic pause frequency or arterial oxygenation.(ABSTRACT TRUNCATED AT 250 WORDS)     

The anti-exhaustion hypothesis: a new hypothesis to explain song performance and song switching in the great tit

This paper describes the results of a detailed analysis of 52 song bouts, recorded from 22 great tits, Parus major, during the dawn chorus. A song bout consists of a number of song bursts (called strophes) separated by periods of silence. High quality males, as measured by average strophe length, sang their bouts with a higher percentage performance time (i.e. the percentage of time spent singing in a bout), but the average number of strophes per bout was not related to male quality. In 31 of 52 bouts there was a systematic decrease in the percentage performance time throughout the bout. This was mainly caused by a prolongation of the pauses between the strophes, and sometimes by a shortening of the strophes. Both high and low quality males sang bouts with and without this decrease in the percentage performance time. Bouts that started with longer strophes and/or shorter inter-strophe pauses showed on average a more rapid decrease in the percentage performance time, and contained fewer strophes, than bouts that started with shorter strophes and/or longer inter-strophe pauses. After switching to another song type the males again used longer strophes and/or shorter inter-strophe pauses. An ‘anti-exhaustion’ hypothesis is proposed and discussed. This hypothesis gives a mainly causal explanation for the existence of song switching and song repertoires in passerine birds.     

The Behavioral Ecology of Intermittent Locomotion

Most physiological and ecological approaches to animal locomotionare based on steady state assumptions, yet movements of manyanimals are interspersed with pauses lasting from millisecondsto minutes. Thus, pauses, along with changes in the durationand speed of moves, form part of a dynamic system of intermittentlocomotion by which animals adjust their locomotor behaviorto changing circumstances. Intermittent locomotion occurs ina wide array of organisms from protozoans to mammals. It isfound in aerial, aquatic and terrestrial locomotion and in manybehavioral contexts including search and pursuit of prey, matesearch, escape from predators, habitat assessment and generaltravel. In our survey, animals exhibiting intermittent locomotionpaused on average nearly 50% of their locomotion time (range6–94%). Although intermittent locomotion is usually expectedto increase energetic costs as a result of additional expenditurefor acceleration and deceleration, a variety of energetic benefitscan arise when forward movement continues during pauses. Endurancealso can be improved by partial recovery from fatigue duringpauses. Perceptual benefits can arise because pauses increasethe capacity of the sensory systems to detect relevant stimuli.Several processes, including velocity blur, relative motiondetection, foveation, attention and interference between sensorysystems are probably involved. In animals that do not pause,alternative mechanisms for stabilizing the perceptual fieldare often present. Because movement is an important cue forstimulus detection, pauses can also reduce unwanted detectionby an organism's predators or prey. Several models have attemptedto integrate energetic and perceptual processes, but many challengesremain. Future advances will require improved quantificationof the effects of speed on perception.     

Head raising during foraging and pausing during intermittent locomotion as components of antipredator vigilance in chipmunks

Although many studies of vigilance examine head raising in foraging, grooming or resting animals, pauses during intermittent locomotion are rarely considered from the perspective of vigilance, and no studies have compared head raising and pausing in the same system. We videotaped central place foraging chipmunks, Tamias striatus, as they approached a patch, collected sunflower seeds, and left to return to their burrows. There was a strong similarity between head raising during foraging and pausing during intermittent locomotion. Chipmunks paused more frequently when moving towards the patch than when leaving the patch. Chipmunks in the patch raised their heads at an intermediate rate, which tended to decrease with time in the patch. Pauses and the duration of motionless periods during head raises were very short (∼0.4 s), and their frequency distributions were similar. Animals remained motionless during 22% of the time spent approaching the patch, 14% of the time spent in the patch and 7% of the time spent leaving the patch. Rates of pausing and head raising generally decreased with short-term familiarity (number of trips to the patch) and with long-term familiarity (proximity of the patch to the burrow). Trials with higher pause rates when approaching the patch had higher head-raising rates in the patch. Whether the focal individual was solitary, dominant or subordinate in a dyad, or competing with multiple chipmunks in the patch had no effect on pausing or head raising. In a separate experiment, exposure to a model hawk increased pause and head-raising rates. We conclude that head raising during foraging and pausing during locomotion serve a similar vigilance function, that this vigilance is directed towards detection of predators rather than conspecifics, and that time allocated to vigilance is sufficient to significantly reduce foraging rates and affect many space use and foraging decisions.     

Roles of lactate and catecholamines in the energetics of brief locomotion in an ectothermic vertebrate

We have investigated the magnitude and duration of excess post-exercise oxygen consumption (EPOC) in a lizard following a single bout of vigorous exercise of 5-60 s, common activity durations for many ectothermic vertebrates. Desert iguanas (Dipsosaurus dorsalis) were run for 5 s, 15 s, 30 s, or 60 s. Oxygen consumption (VO2) increased from 0.16 ml O2 g(-1) h(-1) at rest to 1.3-1.6 ml O2 g(-1) h(-1) during 5-60 s of running. EPOC duration increased with activity duration, ranging from 35-63 min. EPOC volume, the excess oxygen consumed post-exercise, doubled from 0.13 ml O2 g(-1) following 5 s of activity to 0.25 ml O2 g(-1) after 60 s. EPOC represented 91-98% of the total metabolic expense of the activity. EPOC durations were always shorter than the period required for lactate removal, illustrating that these two processes are not causally related. Alpha- and beta-adrenergic receptor blockade by phentolamine and propranolol had no effect on resting VO2 but depressed excess post-exercise oxygen consumption volumes 2540%. The extent of catechol stimulation post-exercise may be motivation or stimulus dependent. The data indicate that metabolic elevations post-exercise represent the majority of activity costs in lizards. The study suggests that EPOC of ectothermic vertebrates is sensitive to exercise duration and catecholamine release post-activity, even when activity periods are less than 60 s in duration.