Tomlin DL, Wenger HA.
Sports Med. 2001;31(1):1-11. Review.
The ability to recover quickly is critical if subsequent bouts of all-out activity are required, as in many team sports. It has been suggested that adaptations associated with endurance training should enhance recovery from high-intensity intermittent exercise, and since the theoretical basis is so compelling, coaches and athletes alike invest a great deal of time into training and maintaining aerobic fitness. As will be seen, the literature supports aerobic fitness as a means of improving recovery from high-intensity intermittent exercise.
1. Exercise Recovery
The return of the muscle to its pre-exercise state following exercise is a process known as recovery. The recovery process is biphasic, with an initial rapid phase of recovery lasting 10 seconds to a few minutes followed by a slower second recovery phase lasting anywhere from a few minutes to a number of hours. During recovery, oxygen consumption (VO2) is elevated to help restore metabolic processes to pre-exercise conditions. The post-exercise VO2 beyond that required at rest has been termed excess post-exercise oxygen consumption (EPOC).
The fast phase of recovery is marked by rapidly declining VO2 and heart rate. It is during this period that tissue stores of oxygen are quickly replenished, and most of the ATP and phosphocreatine (PCr) depleted in the muscle are restored, with 70% of the phosphagens restored within 30 seconds and 100% restored within 3 to 5 minutes. Once depleted, PCr is not restored until exercise concludes. Additionally, no replenishment of PCr occurs when the circulation is occluded, suggesting that oxygen is required for the process.
The increased metabolism marking the slow recovery period has been associated with the removal of lactate and H+, elevated body temperature, the cost of increased respiratory and cardiac functions, the effect of catecholamines and the cost of glycogen resynthesis. Recovery is not complete until metabolism has returned to pre-exercise levels.
2. Recovery from High Intensity Intermittent Exercise
The ability to perform maximally on repeated exercise bouts is influenced by the nature of both exercise and recovery periods. Generally, the more that exercise disrupts homeostasis, the greater the effect on recovery metabolism. The more complete these restorative processes, the greater the ability to generate force or maintain power on subsequent work intervals.
Although a single bout of high-intensity exercise lasting a few seconds results in decreased ATP/PCr stores, if the bout exceeds more than a few seconds anaerobic glycolysis will also be required to provide energy. The metabolic consequence of increased anaerobic glycolysis is an increase in H+ concentration and depressed pH, which may adversely affect performance by disrupting contractile processes. Following exercise, complete phosphagen recovery may require 3 to 5 minutes, but complete restoration of pH and lactate to pre-exercise levels may take an hour or more. In repeated exercise bouts, if the subsequent recovery interval is less than a few minutes long, as in many team sports, the ATP/PCr stores may be only partially restored before the onset of subsequent exercise demands, resulting in compromised performance on successive bouts. Moreover, as ATP/PCr stores are progressively depleted with subsequent high intensity work bouts, there will be increased reliance on anaerobic glycolysis. Following exercise that results in both the depletion of ATP/PCr stores and increased lactate and H+ accumulation, it will require longer to return to the pre-exercise state. Once H+ has accumulated, existing transport and metabolic pathways are less efficient, slowing the rate of recovery from exercise.
The length of the recovery interval between repeats of high-intensity bouts of exercise will also
affect recovery. Wooton and Williams found that, although power output decreased over repeated 6-second all-out sprints with either 30 or 60 seconds of recovery between sprints, power output declined less when 60 seconds of recovery was allowed. A longer recovery interval ensures more complete recovery; however, in sports requiring intermittent bursts of all-out effort the recovery periods may last only a few seconds, so performance on subsequent bouts may suffer. During brief intervals of recovery, at least some of the ATP, PCr and oxymyoglobin is restored. While restoration of the oxygen-myoglobin stores can take 10 to 80 seconds complete phosphagen recovery may require 3 to 5 or even 8 minutes. The rate of post-exercise PCr resynthesis appears to be controlled by the rate of oxidative metabolism within the muscle, and in the absence of circulation, little PCr is regenerated.
The ability to recover from exercise resulting in lactate production depends on the capacity to tolerate, buffer and/or rapidly remove H+ from working muscle. Important buffers within muscle include PCr, inorganic phosphate, protein-bound histidine residues and carnosine. Once in the blood, lactic acid is effectively buffered by sodium bicarbonate. Approximately 65% of the lactate is converted to pyruvate by lactate dehydrogenase (LDH), then undergoes aerobic degradation via the Krebs cycle and electron transport system, with the remaining 35% converted to glucose and/or glycogen, secreted in urine and sweat or converted to protein. Most of lactate oxidation occurs in skeletal muscle, particularly the slow-twitch fibres. The restoration of muscle pH is critical for optimal force production on subsequent exercise, since the rate of PCr resynthesis is influenced by the metabolic environment of muscle, especially the concentration of H+ but also the ATP concentration and the rate of oxidative phosphorylation within working muscle.
3. Possible Role of Aerobic Fitness in Enhancing Recovery
The most widely accepted measure of aerobic fitness, VO2max, represents the maximum rate at which aerobic metabolism can supply energy. Another widely used index of aerobic fitness, aerobic capacity, identifies by blood lactate or ventilatory parameters the maximal steady-state exercise speed or workload that can be sustained for extended periods of time. Increases in VO2max and aerobic capacity result from endurance training. Aerobic capacity measures have proven useful in predicting success in distance running events, with some scientists regarding it as superior to VO2max as a measure of endurance fitness.
Thoden proposes that aerobic training may enhance the ability of the muscle to recover following anaerobic exercise, suggesting that an athlete with higher aerobic fitness will tax nonoxidative sources less and thereby recover at a more rapid rate from exercise. Theoretically, an increase in aerobic fitness could enhance recovery from anaerobic performance both by supplementing anaerobic energy during the exercise and by providing aerobically derived energy at a faster rate during the recovery period. Additionally, any improvements that aid in transport to or from the muscle, such as increased blood flow, could enhance the removal of lactate, H+ and heat.
Individuals with high maximal aerobic power exhibit increased concentrations of aerobic enzymes, increased mitochondrial number, size and surface area and increased myoglobin, all contributing to improved oxygen extraction by muscle. Aerobic training also results in increased muscle blood flow, which is accomplished through elevated cardiac output, increased capillarisation of muscle tissue and an improved ability to vasodilate. Oxygen delivery in the endurance-trained athlete is further improved by increases in blood volume and total haemoglobin volume. Together, these enhancements result in an increased rate of VO2 during high intensity exercise and decreased time to reach peak VO2 during exercise, which may result in less lactic acid accumulation. In conjunction with enhanced ATP/PCr stores and elevated myokinase and creatine kinase concentrations seen in trained athletes, these adaptations should result in an ability to supply more energy through the phosphagen and aerobic systems, thus decreasing the reliance on anaerobic glycolysis and thereby stemming the rise in H+ during high intensity intermittent work. Endurance training results in lower blood and muscle lactate levels for the same absolute submaximal workload because of decreased production of lactate as a result of increased reliance on other energy systems and/or
increased lactate clearance. With reduced anaerobic glycolysis during exercise, less energy is required during the recovery period to rid the muscle of H+ and lactate, potentially hastening the recovery process.
Lactate removal from muscle is enhanced by increased buffering capacity and increased blood flow. Increased capillary density, as seen in endurance-trained individuals, provides a decreased diffusion distance between capillaries and muscle fibres, enhancing movement of oxygen and nutrients to, and the removal of H+ and lactate from, the muscle. Enhanced oxygen delivery to muscles post-exercise potentially accelerates the rate of PCr resynthesis, an
oxygen-dependent process. Tesch and Wright found a significant correlation between capillary
density and blood lactate concentration, suggesting an improved efflux of lactate as a result of increased capillary density.
Other training effects seen in aerobically trained individuals that may hasten recovery are improved temperature regulation during and after exercise, better mobilisation and utilisation of fuel substrates and increased hypertrophy of and selective recruitment of slow-twitch and fast-twitch type A muscle fibres. The increased activity of the H form of LDH associated with endurance training should also facilitate recovery by favouring the oxidation of lactate to pyruvate. This adaptation provides ready fuel, in the form of pyruvate, for aerobic metabolism and helps normalise pH by consuming H+. Thus, it appears that the metabolic and circulatory adaptations associated with high levels of aerobic power should facilitate faster recovery from high intensity exercise.
4. The Relationship Between Aerobic Fitness and Recovery from High Intensity Exercise
Numerous indicators have been used to assess recovery from exercise, including VO2, blood lactates, force or power recovery, muscle pH and muscle PCr. When relevant, research on single bouts of submaximal and maximal exercise will be presented, but it is the intention of this review to focus predominantly on the relationship between aerobic fitness and recovery from high intensity intermittent exercise.
4.1 Aerobic Response
Hamilton et al. compared the aerobic response of endurance-trained runners (VO2max 60.8 ± 4.1 ml/kg/min) and games players (VO2max 52.5 ± 4.9 ml/kg/min) during repeated all-out 6-second treadmill sprints. Although assignment to games players and endurance-trained groups was on the basis of the chosen sport rather than VO2max, VO2max was considerably different, allowing for comparisons on the basis of aerobic power. Both groups attained similar peak (mean 6 seconds) power, but endurance-trained athletes consumed significantly more oxygen during repeated intervals of all-out sprinting and demonstrated a significantly smaller percentage decrement in power over the 10 sprints than did games players. Similar results were reported by Tomlin, who examined the aerobic response of female recreational soccer players to repeated 6-second all-out cycle sprints. Grouped on the basis of VO2max, both the high (HAP) and low (LAP) aerobic power groups attained similar peak power, yet the HAP group consumed significantly more oxygen over 10 sprint-recovery cycles and displayed a smaller percentage decrement over the 10 sprints. Perhaps, consuming more oxygen during sprinting results in less reliance on anaerobic glycolysis and thus less lactic acid production, manifesting itself in less lactic acid and H+ accumulation and thus superior power maintenance.
An increase in VO2max has been associated with an increase in VO2 during repeated bouts of
supramaximal exercise. Additionally, in individuals who completed two 30-second all-out cycle sprints, Bogdanis et al. found a high correlation between VO2max and the percentage of energy contributed by aerobic metabolism on sprint 1 (r = 0.79) and sprint 2 (r = 0.87). Thus, VO2max appears to determine the magnitude of the aerobic response to repeated sprints.
Balsom et al. reported that following erythropoietin administration, individuals performing 15
× 6-second treadmill sprints showed reduced accumulations of blood lactate and the adenosine degradation product, hypoxanthine, despite performing the same amount of exercise when compared with the control condition. Additionally, Balsom et al. demonstrated that by decreasing oxygen availability via a hypobaric chamber, individuals consumed less oxygen, accumulated more lactate and experienced larger power decrements during intense intermittent exercise than under normoxic conditions. These findings suggest that increased oxygen availability, as also happens with increases in VO2max, results in increased aerobic and reduced anaerobic contribution, whereas decreased oxygen availability results in decreased aerobic and increased anaerobic contribution to sprinting.
4.2 Excess Post-Exercise Oxygen Consumption
When exercising at the same percent age of VO2 max, trained individuals consume more oxygen than untrained individuals because of their higher VO2max. Therefore, at the start of the recovery period VO2 is elevated, resulting in a greater potential magnitude for the fast EPOC. As well,
ATP/PCr stores in trained individuals tend to be
higher[39] and since PCr replenishment has been
coupled to fast EPOC,[4, 53] it is not surprising that
fast EPOC following submaximal exercise of the
same relative intensity is demonstrably higher in
endurance-trained individuals.[37,54-56] Given the same
percentage of V. O2max, trained individuals have a
larger magnitude of fast EPOC whereas total EPOC
tends to be about the same and total recovery time
shorter.[37,54-56] Hamilton et al.[48] found that fol-
lowing 10 repeated all-out treadmill sprints where
endurance-trained athletes consumed significantly
more oxygen than games players during the sprint-
recovery cycles, endurance-trained athletes appeared
to consume more oxygen immediately after exer-
cise, whereas games players consumed more oxy-
gen during the remaining 14 minutes of recovery,
resulting in a similar net EPOC, supporting similar
patterns of EPOC seen in submaximal studies. With
more oxygen consumed sooner, the fit individual
should be able to restore more ATP/PCr. The high
post-exercise V. O2 associated with higher aerobic
power may be advantageous in priming the aerobic
system to consume more oxygen immediately after
exercise which, if used to replenish ATP/PCr stores,
should be advantageous for repeated exercise, es-
pecially when subsequent exercise is primarily de-
pendent on PCr breakdown. This may at least par-
tially explain why the endurance-trained athletes
were more successful in maintaining initial power
output throughout the 10 repeats. Although the
endurance-trained athletes and games players av-
eraged similar power over the 10 sprints (612 vs
603W, respectively), and the games players gen-
erated higher power outputs on the initial 4 sprints,
the endurance-trained athletes’ power output on the
final 6 sprints exceeded that of the games players.
LeMasurier[57] investigated the relationship be-
tween V. O2max and 3 minute EPOC following high
intensity intermittent cycle sprints with 21 active
males. He failed to find a significant correlation
between relative VO2max and 3-minute EPOC fol-
lowing 12 × 5-second sprints (r = 0.19),
but confi r med moder at e rel at i onshi ps bet ween
V. O2max and EPOC following 6 × 10-second sprints
(r = 0. 47) and 3 × 20-second sprint s (r
= 0.67). With a lower volume of post-
exercise oxygen consumed following the shorter
sprints, the EPOC response of the participants may
have been more homogeneous and thereby decreas-
ed the likelihood of a significant correlation. Fur-
thermore, with 62% of the total EPOC occurring in
the first minute, a V. O2max–1-minute EPOC com-
parison may have better characterised the relation-
ship.
Bell et al.[58] investigated the relationship be-
tween recovery from high intensity intermittent ex-
ercise and 2 different measures of aerobic fitness;
aerobic capacity and VO2max. Highly trained en-
durance athletes performed 3 × 1-minute sprints at
125% VO2max, after which EPOC was measured.
Using ventilatory threshold as the measure of aer-
obic capacity, the authors failed to find a significant relationship between aerobic capacity and re-
covery or between V. O2max and recovery.
In failing to find significant relationships be-
tween aerobic fitness and EPOC (the rate of EPOC
recovery and the magnitude of EPOC) following the
sprints, Bell et al.[58] concluded that there does not
appear to be a relationship between aerobic fitness
and recovery from repeated bouts of high intensity
exercise in highly trained endurance runners. How-
ever, as conceded by the authors, the population
studied were highly trained (mean V. O2max 63.1
ml/kg/min, range 54.4 to 70.3 ml/kg/min), so even
individuals with ‘low’ aerobic power scores were
quite fit and may have had an aerobic fitness level
sufficient to result in enhanced recovery. The pos-
sibility of an aerobic fitness threshold exists, be-
yond which recovery is enhanced; however, this
hypothesis remains to be tested. Unfortunately, the
interpretation of the EPOC results may have been
hampered by an apparent lack of pre-exercise con-
trols in terms of circadian effects, previous exercise
or the thermic effect of food, all of which affect
resting V. O2 [59] and therefore net EPOC. Moreover,
conclusions on the rate of recovery were based on
the half-time recovery of EPOC, which may not be
appropriate. Although it has been shown that the
half-time EPOC recovery for submaximal exercise
improves with training,[37,60, 61] this index may be
inappropriate for cross-sectional studies. It may be
that rate of recovery is determined somewhat by
genetic factors, such as the percentage of slow ox-
idative fibres, in that while rate of recovery can be
improved, V. O2max is only one of the contributing
factors. For example, Colliander et al.[20] demon-
strated that individuals in a ‘low fast twitch’ group
were superior to a ‘high fast twitch’ group in restor-
ing force between sets of concentric contractions.
Also, the metabolic profile of muscle fibres can be
altered with endurance training through conversion
of fast glycolytic fibres to fast oxidative glycolytic
fibres,[62] thereby enhancing the oxidative capacity
of the muscle, but the enhancements do not always
translate into improvements in V. O2max.[31] Further-
more, improvements in half-time recovery may in-
dicate better recovery; however, similar half-time
recovery scores do not necessari l y suggest that
recovery rat e was the same for different i ndivi d-
u al s. If hal f-t i me EPOC recovery i s t he same for
2 individuals who differ in aerobic power, clearly
the one with higher V. O2 at the end of exercise,
which is likely to be the one with superior aerobic
power,[48,50] will utilise more oxygen in the same
period of time. Therefore, use of the half-time re-
covery rate may not accurately reflect differences
in the rate of recovery.
4.3 Lactate Removal
Since the accumulation of H+ is implicated in
fatigue, decreased accumulations create a more fa-
vourable contractile environment.[8] If, as well, lac-
tate is removed faster from muscle by an efficient
aerobic system, as hypothesised to happen in the
aerobically fit, even less lactate will accumulate,
resulting in less disruption of baseline pH levels.
Unfortunately, all of the studies examining differ-
ences in lactate response rely on measurements of
blood lactate, which only reflect muscle lactate,
providing indirect evidence about lactate produc-
tion and removal in the muscle from lactate accu-
mulation in blood. Some authors have reported en-
hanced blood lactate clearance in endurance-trained
athletes, but others have failed to find a relation-
ship between blood lactate removal and V. O2max.
When examining post-exercise blood lactate re-
sponse, methods vary, with some authors using a bi-
exponential model to describe lactate clearance[63-66]
and others using linear regression, logarithmic or
other methods.[67-69] These differences, in conjunc-
tion with the difficulties in assigning comparable
work bouts to trained and untrained, makes the com-
parison of results difficult.
It appears that aerobically fit individuals attain
peak lactate levels sooner in the post-exercise pe-
riod with passive[63, 64] and active[66] recovery, sug-
gesting a more rapid efflux of lactate from muscle
to blood in trained individuals. Some studies fail to
support a relationship between improved blood lac-
tate clearance and endurance training[68] or between
blood lactate dissipation in well-trained versus un-
trained individuals;[69] however, in both of these
studies post-exercise blood lactate was not sam-
pled until 3 minutes following the exercise bout.
This may have resulted in missing peak lactate,
especially in trained individuals,[63, 66] which is an
important variable in determining the rate of dis-
appearance of blood lactate, regardless of the mathe-
matical model used.
During passive recovery following an incre-
mental procedure to exhaustion, in which endur-
ance at hl et es worked at hi gher workloads t han
sprint-trained athletes, the endurance-trained ath-
letes also had higher blood lactate accumulations
than the sprint-trained individuals.[66] Bassett et al.[63]
demonstrated similar results, whereby trained in-
dividuals cycling for 3 minutes at 85% V. O2max work-
ed at higher workloads and accumulated more blood
lactate sooner than untrained individuals cycling at
80% V. O2max. Although both authors reported sim-
ilar rates of lactate clearance between their respec-
tive groups, it must be emphasised that since both
power output and lactate accumulation were higher
in the groups with higher aerobic fitness and there
is an inverse relationship between the rate of lac-
tate clearance and absolute work,[70] this should be
seen as superior recovery ability in the aerobically
fit. Taoutaou et al.[66] also found that when the first
20 minutes of recovery was active, post-exercise
time to peak lactate and the rate of blood lactate re-
moval was faster in the endurance-trained athletes
even though end-exercise blood lactate levels were
similar between the groups. It may be that through
active recovery some of the enhancements associ-
ated with endurance training, such as increased cap-
illary density,[34] may be reflected more readily.
Freund et al.[64] found that highly trained ath-
l etes could cl ear lactate from working muscles
faster than sedentary controls, and Oyono-Enguelle
et al.[65] suggested that aerobic training may en-
hance lactate removal following anaerobic exer-
cise. By comparing blood lactate disappearance rates
of trained versus less trained individuals from dif-
ferent studies, Bonen and Belcastro[23] also con-
cluded that trained individuals have faster lactate
disappearance rates.
4.4 Power and Force Recovery
Bogdanis et al. found that power recovery on repeated 30-second cycle sprints and resynthesis of PCr proceeds in parallel, confirming the relevance of PCr availability for power recovery. Subsequently, Bogdanis et al. analysed pre- and post-exercise
muscle biopsies from individuals who performed 2 × 30-second sprints separated by 4 minutes of passive recovery. From these results they demonstrated strong relationships between power recovery in the first 10 seconds of the second sprint and
the resynthesis of PCr (r = 0.84) and between power recovery and endurance fitness (r = 0.94), as represented by the percentage of VO2max corresponding to a blood lactate concentration of 4 mmol/L. Effectively these results link PCr resynthesis to both power recovery and endurance fitness. Unfortunately, no relationship was reported between VO2max
and power recovery or power recovery and PCr restoration.
Hakkinen and Myllyla found that power and strength athletes generated higher peak force, whereas endurance athletes were able to maintain a 60% isometric contraction for longer and exhibited better relative force recovery following a 3-minute rest period. Neither VO2max or fibre type were measured but the results imply that differences in force recovery are at least partially the result of differences in aerobic fitness, as aerobic fitness is generally superior in endurance-trained athletes. It is likely that differences in force recovery also reflect peak power differences resulting from the different training regimens of strength, power and endurance athletes.
Gaiga and Docherty found that individuals who participated in 9 weeks of interval training that successfully increased VO2max by 6 to 7% displayed increases in peak power and mean power in all 4 repeated 30-second maximal cycling sprints, with slightly greater improvements seen in the final 2 sprints. However, from the results it is difficult to establish if recovery improved or if the interval training merely enhanced the ability to generate peak power, since total work and peak power improved in all 4 repeats, with little change in the absolute power decrement from sprint 1 to sprint 4.
Caution must be exercised when comparing individuals on relative power recovery such as percentage decrement over trials, as is conventionally done, especially when peak power varies considerably between athletes. Since individuals who produce higher peak power on initial trials have the potential to display greater absolute power decrement, a power recovery index may misrepresent the data. For example, greater percentage decrement trends have been associated with more powerful initial efforts. It may be that percentage decrement is more appropriate when comparing athletes that can be matched on initial peak force; however, this is not always possible. A comparison between VO2max and percentage decrement by Tomlin was based on the results from 2 groups who generated similar peak power on the first of 10 cycle sprints; however, the group with higher aerobic power clearly demonstrated a smaller percentage decrement over the 10 sprints when compared with the LAP group.
Other researchers have investigated the relationship between VO2max and power maintenance for repeated cycle ergometer sprints. Moderate relationships have been reported between relative VO2max and percentage decrement during 6 × 6-second cycle sprints (r = –0.56), 12 × 5-second cycle sprints (r = –0.44) and 6 × all-out 40m treadmill sprints (r = –0.62).
Using a protocol with 90 seconds active recovery between 6 × 15-second sprints, McMahon and Wenger verified a significant VO2max–percentagedecrement relationship (r = –0.63). All of these studies appear to support the notion that higher aerobic power may contribute to improving power recovery over repeated intervals.
Hoffman estimated the aerobic fitness of 197 infantry soldiers on a 2000m run, then compared this to their performance on a field test of anaerobic ability, which consisted of 3 repeats of a 143m line drill sprint. He found that aerobic fitness had a low
but significant correlation with the fatigue index based on the increase in sprint times over the 3 sprints (r = – 0.33). Unfortunately, with 7 directional changes in the field test, skill may have had a larger impact on performance than the ability
to recover between sprints and this may have contributed to the low correlation coefficient. However, when the participants were divided into 5 fitness categories based on their 2000m run times, clearly the fatigue index of the low fitness group
was inferior to the fatigue index of the 3 fittest groups, supporting aerobic fitness as a contributor to power maintenance.
In a subsequent study, Hoffman et al. investigated the influence of directly measured VO2max on the ability of 20 basketball players to recover during the same 143m field test and failed to establish a significant relationship (r = 0.01, nonsignificant). It may be that the impact of skill on performance is even greater in such a small group, and that the VO2max of the basketball players was too similar (mean 50.2 ± 3.8 ml/kg/min) to show differences in recovery.
4.5 Phosphocreatine Restoration
Increased rates of PCr resynthesis following submaximal exercise have been documented in endurance-trained athletes versus individuals in a control group and in endurance-trained athletes versus sprinters, middle-distance runners and individuals in the control group.[81] Furthermore, McCully and Posner demonstrated enhanced PCr resynthesis following only 2 weeks of muscle-specific aerobic training. Unfortunately, VO2max was not measured in any of these studies, so extrapolation of the findings to VO2max is somewhat limited. Even though most endurance-trained athletes possess high levels of aerobic power, enhanced aerobic power is not necessarily the only feature associated with endurance training.
Few studies have investigated the relationship between aerobic fitness and PCr resynthesis following a single bout of high intensity exercise or high intensity intermittent exercise. 31P magnetic resonance spectroscopy (31P-MRS) was utilised
to investigate differences in PCr resynthesis in the gastrocnemius between HAP and LAP groups and between endurance-trained and sedentary individuals following single 2-minute bouts of high-intensity exercise. Neither study demonstrated differences in PCr recovery between the groups when PCr recovery was expressed as a percentage of resting levels or by using nonlinear regression model results, so it was concluded that VO2max was a poor predictor of PCr recovery. It may be more appropriate to interpret the lack of difference in the percentage PCr recovery as a better recovery rate in the endurance-trained individuals and HAP groups since they would probably have had higher initial PCr levels and would therefore have replenished more PCr in the same time. Furthermore, as a weight-bearing muscle the gastrocnemius may have been a poor choice for comparison where groups not only differed in VO2max but also in bodyweight, with the sedentary and LAP groups significantly heavier than their aerobically fit counterparts. It may also be unrealistic to expect a whole body measure of VO2max to correlate well with PCr recovery in a small muscle such as the gastrocnemius. In contrast to the results from Petersen and Cooke and Cooke et al., Takahashi et al. found VO2max to be significantly correlated to the rate of PCr recovery in the quadriceps muscle following exhaustive exercise in endurance-trained and untrained individuals.
It may also be that the impact of aerobic power becomes more obvious with repeated bouts of high-intensity exercise. Using 31P-MRS to examine PCr resynthesis following 4 repeats of 2 minutes of moderately high intensity exercise, Yoshida and Watari clearly demonstrated that endurance-trained individuals (VO2max 73.6 ml/kg/min) had significantly faster PCr recovery than control individuals (VO2max 46.6 ml/kg/min), which became increasingly apparent after the first bout of exercise.
5. Conclusion
The literature suggests that aerobic fitness probably enhances recovery from high intensity intermittent exercise through enhanced aerobic contribution, increased post-exercise VO2, and possibly by increased lactate removal and increased PCr restoration, which has been linked to improved power recovery. Now the challenge is to determine which of these relationships are cause and effect and which variables are coincidental.
