Participants

Seven healthy male participants (mean ± SD, age = 25 ± 3 years; height = 178 ± 6 cm; mass = 77 ± 7 kg) volunteered, providing written informed consent to participate. The study was approved by the Liverpool Hope University Research Ethics Committee in accordance with the Declaration of Helsinki. All participants were recreationally physically active, but not highly trained. All benefits and risks of the protocol, as well as rights to confidentiality and withdrawal, were explained to each participant prior to participation. Participants were asked not to consume alcohol or caffeine within the preceding 24 and 3 h, respectively, prior to each test, as well as to not perform strenuous exercise within the preceding 24 h and to arrive 3 h postprandial.

Procedures

All tests took place in a well‐ventilated laboratory that was maintained between 18 and 21°C. Participants visited the laboratory on nine occasions during a 3–6 week period, with each test scheduled at the same time of day (±2 h) and with at least 24 h between visits. Participants completed one preliminary trial and eight experimental trials. All exercise tests were performed on an electronically braked cycle ergometer (Lode Excalibur Sport, Groningen, The Netherlands). Saddle and handlebar height/ angle were recorded at the first visit and replicated during each subsequent visit for each individual participant. Throughout all exercise tests, participants were instructed to maintain a cadence of 80 rev min⁻¹, and exhaustion was defined as when the participant's cadence dropped below 70 rev min⁻¹. Time to exhaustion was measured to the nearest second in all tests.

Preliminary trial

Upon arrival to the laboratory, participant's height and weight were recorded. Following this, each participant undertook an incremental ramp test until the limit of tolerance to establish $\dot{V}{\mathrm{O}}_2\text{max}$, the gas exchange threshold (GET), and the power outputs for subsequent tests. The ramp test consisted of 3‐min of baseline pedaling at 30 W, followed by a continuous, ramped increase in power output of 30 W min⁻¹ until the limit of tolerance was established. Gas exchange and ventilatory variables were measured continuously at the mouth breath‐by‐breath throughout each test. $\dot{V}{\mathrm{O}}_2\text{max}$was defined as the highest $\dot{V}{\mathrm{O}}_2$ value measured over 30 sec. The GET was taken as a non‐invasive estimate of the lactate threshold using a collection of previously established criteria (Beaver et al. ); including (1) a disproportionate rise in CO₂ production ($\dot{V}{\text{CO}}_2$) relative to $\dot{V}{\mathrm{O}}_2$; (2) an increase in minute ventilation ($\dot{V}\mathrm{E}$) relative to $\dot{V}{\mathrm{O}}_2$ ($\dot{V}\mathrm{E}/\dot{V}{\mathrm{O}}_2$) without an increase in $\dot{V}\mathrm{E}$ relative to $\dot{V}{\text{CO}}_2$ ($\dot{V}\mathrm{E}/\dot{V}{\mathrm{O}}_2$); and (3) an increase in end tidal O₂ tension without decreasing end tidal CO₂ tension. The mean response time (MRT) of $\dot{V}{\mathrm{O}}_2$ during ramp exercise was defined as the time between the beginning of the ramp test and the intersection between baseline $\dot{V}{\mathrm{O}}_2$ ($\dot{V}{\mathrm{O}}_{2\mathrm{b}}$) and backwards extrapolation of the regression line of the $\dot{V}{\mathrm{O}}_2$ – time relationship as described previously (Boone et al. ; Goulding et al. ). Work rates for subsequent tests were therefore calculated using the linear regression of the $\dot{V}{\mathrm{O}}_2$– time relationship and solving for $\dot{V}{\mathrm{O}}_2$, with account taken of the MRT.

Experimental trials

For the following eight visits, participants were required to exercise to exhaustion at four fixed severe‐intensity power outputs each performed twice, once from a baseline of moderate intensity cycling, and once from a baseline of unloaded cycling. The power outputs of these severe‐intensity bouts of exercise were selected based upon performance during the incremental ramp test and were calculated to be in the range of 50%∆ (i.e., a work rate calculated to require 50% of the difference between the GET and $\dot{V}{\mathrm{O}}_2\text{max}$ ) to 110% $\dot{V}{\mathrm{O}}_2\text{max}$. The goal of this range of power outputs was to ensure that the tolerable duration of exercise was between 2 and 15 min in all cases, with at least 5 min separating the tolerable durations of the longest and shortest tests (Hill ). Furthermore, exercise durations <2 min were avoided because these have been shown to overestimate critical power (Mattioni Maturana et al. ). These power outputs are subsequently referred to as WR 1, WR 2, WR 3, and WR 4, with WR 1 being the lowest and WR 4 being the highest power outputs, respectively. On occasion, adjustments were made to the required power output of the subsequent exercise tests based upon performance in the initial tests. Participants alternated between conditions and the power outputs were presented in random order to prevent an order effect. Participants were not informed of their work rate or performance until the entire project had been completed. Each power output was performed once in each condition; that is, once with exercise initiated from an unloaded baseline (U→S), and once with exercise initiated from a moderate intensity baseline at 90% of the GET (M→S). U→S consisted of 3 min of unloaded baseline pedaling at 7 W (unloaded cycling on this ergometer elicits a power output of 7 W), after which an instantaneous step increase to the required severe‐intensity power output was abruptly applied, and participants exercised until the limit of tolerance. In M→S, participants performed 3 min of unloaded baseline pedaling at 0 W before an instantaneous step increase to a power output of 90% GET for 6 min (U→M). Subsequent to these 6 min of moderate‐intensity cycling, a further step increase in power output to the required severe intensity was abruptly applied, with participants exercising until they reached the limit of tolerance. $\dot{V}{\mathrm{O}}_2$ peak for the constant work rate tests was defined as the mean $\dot{V}{\mathrm{O}}_2$ value during the final 30 sec of exercise.

During all exercise tests, pulmonary gas exchange and ventilation were measured at the mouth breath‐by‐breath using a metabolic cart (Blue Cherry, Geratherm Respiratory, GmbH, Germany). Participants wore a silicone face mask (Hans Rudolph, Kansas) of known dead space attached to a low‐dead space flow sensor (Geratherm Respiratory, GmbH, Germany).The metabolic cart was connected to the participant via a capillary line connected to the flow sensor. The gas analyzers were calibrated before each test using gases of known concentrations and the flow sensors were calibrated using a 3‐L syringe (Hans Rudolph, Kansas City, MO). Heart rate was determined for every 1 sec during all tests using short‐range radiotelemetry (Garmin FR70, Garmin Ltd., Switzerland). For both U→S and M→S, blood was sampled from the thumb of the right hand into glass capillary tubes at rest, during the last minute of baseline pedaling preceding the severe‐intensity constant work rate bout, and immediately following exhaustion. Whole blood [L⁻] was determined using a Biosen lactate analyzer (Biosen C‐Line, EKF, Germany).

During experimental visits, continuous non‐invasive measurements of muscle oxygenation/deoxygenation status were made via a frequency‐domain multidistance near‐infrared spectroscopy (NIRS) system (Oxiplex TS, ISS, Champaign). The OxiplexTS uses one light‐emitting diode (LED) detector fiber bundle and eight LEDs functioning at wavelengths of 690 and 830 nm (four LEDs per wavelength). Light‐source detector separation distances of 2.25–3.75 cm for each wavelength were utilized with cell water concentration assumed constant at 70% and data sampled at 2 Hz. This NIRS device measures and incorporates the dynamic reduced scattering coefficients to provide absolute concentrations (μmol/L) of deoxygenated hemoglobin + myoglobin ([HHb + Mb]), which is relatively unaffected by changes in blood volume during exercise (De Blasi et al. ; Ferrari et al. ; Grassi et al. ). NIRS has been demonstrated to produce valid estimates of O₂ extraction (De Blasi et al. ; Ferrari et al. ; DeLorey et al. ; Grassi et al. ; Ferreira et al. ). However, the absorption spectrum of [Mb] converges with that of [HHb]; therefore at present, NIRS is unable to differentiate between the relative contributions of [Mb] and [HHb] to the overall NIRS signal (De Blasi et al. ). In referring to the NIRS deoxygenation signal as [HHb + Mb], the contribution of [Mb] is therefore also acknowledged. The NIRS device also provides measures of [oxygenated hemoglobin + myoglobin] ([HbO₂ + MbO₂]) and [total hemoglobin + myoglobin] ([THb + Mb]) concentration (as [HbO₂ + MbO₂] + [HHb + Mb]) and thus, an indication of O₂ availability. The flexible NIRS probe was placed longitudinally along the belly of the right vastus lateralis muscle midway between the greater trochanter and the lateral condyle of the tibia. The area underneath the probe was shaved and marked with washable pen such that the probe position could be replicated for each subsequent visit. The probe was held firmly in place by elastic Velcro strapping. Following each trial, depressions of the probe on the participant's skin were examined to confirm that the probe did not move during the trial, which was the case for every exercise transition. The NIRS probe was calibrated prior to each testing session using a calibration block of known absorption and scattering coefficients. Calibration was then verified using a second block of known but distinctly different absorption and scattering coefficients. Each of these procedures was according to the manufacturer's recommendations.

Data analysis

The raw breath‐by‐breath $\dot{V}{\mathrm{O}}_2$ data from each constant‐power exercise bout were first inspected to identify data points deemed atypical of the underlying response (i.e., due to coughs, swallows, sighs etc.) by removing data points lying more than four standard deviations from the local mean determined using a 5‐breath moving average. Edited $\dot{V}{\mathrm{O}}_2$ data were then subsequently linearly interpolated to yield second‐by‐second values. For $\dot{V}{\mathrm{O}}_2$ responses to the U→M transitions, the four identical transitions were ensemble‐averaged to produce a single dataset; the criterion severe‐intensity bouts for determination of critical power and W' in each condition were not repeated, therefore each were modeled separately. For each exercise transition, all data points preceding a sharp drop in respiratory exchange ratio and end‐tidal O₂ pressure were omitted to exclude the phase I (cardiodynamic) component (Whipp and Ward ), and a single exponential equation (eq. ) with time delay was then fitted to the data:$$\dot{V}{O}_{2(t)}=\dot{V}{O}_{2(b)}+A_{V{O}_2}\ast (1-e^{-(t-T{D}_{V{O}_2}/{\tau }_{V{O}_2})})$$where $\dot{V}{\mathrm{O}}_{2(t)}$ is the $\dot{V}{\mathrm{O}}_2$ at any time t; $\dot{V}{\mathrm{O}}_{2(b)}$ is the baseline $\dot{V}{\mathrm{O}}_2$ which was taken as the mean $\dot{V}{\mathrm{O}}_2$ from the last 30 sec of the baseline cycling period preceding the exercise bout, $A_{{\dot{V}}_{O_2}}$ is the amplitude of the fundamental response, $T{D}_{{\dot{V}}_{O_2}}$ is the time delay of the fundamental response relative to exercise onset, and ${\tau }_{\dot{V}{O}_2}$ is the time constant of the fundamental response. For U→M and U→S transitions, $\dot{V}{\mathrm{O}}_{2(b)}$ was taken as the average $\dot{V}{\mathrm{O}}_2$ from the final 30 sec of unloaded baseline cycling whereas for M→S, $\dot{V}{\mathrm{O}}_{2(b)}$ was taken as the average $\dot{V}{\mathrm{O}}_2$ from the final 30 sec of moderate intensity baseline cycling. For the U→M transitions, the exponential model was fitted to 360 sec. For U→S and M→S transitions, the onset of the $\dot{V}{\mathrm{O}}_2$ slow component () was identified using purpose‐designed programming in Microsoft Excel (Microsoft Corporation, Redmond, WA) which iteratively fitted a single exponential function to the $\dot{V}{\mathrm{O}}_2$ data, starting at 60 sec and extending the fitting window until the window encompasses the entire exercise bout. The resulting ${\tau }_{\dot{V}{O}_2}$ values were plotted against time, with the identified using the following criteria: (1) the point at which ${\tau }_{\dot{V}{O}_2}$ demonstrates a sustained increase from a previously “flat” profile, and (2) the demonstration of a local threshold in the X² value (Rossiter et al. ). This method allows the fitting of Equation  to the isolated fundamental component of the response before the slow component becomes discernible, thus avoiding the possibility of arbitrarily parameterizing the slow component. The isolated fundamental responses were then fitted with the same exponential function as shown in Equation  using Origin 6.0 (OriginLab Corporation, MA) to obtain the 95% confidence intervals for the derived parameter estimates. The $\dot{V}{\mathrm{O}}_2$ slow component amplitude ($S{C}_{{\dot{V}}_{O_2}}$) was determined by calculating the difference between the end exercise $\dot{V}{\mathrm{O}}_2$ (i.e., mean $\dot{V}{\mathrm{O}}_2$ over final 30 sec of exercise) and ($A_{{\dot{V}}_{O_2}}$+ $\dot{V}{\mathrm{O}}_{2(b)}$). In instances where exercise duration was too short to allow the slow component to be discerned (typically at WR 3 and 4 in M→S), the $\dot{V}{\mathrm{O}}_2$ response was modeled using Equation  to the end of exercise and the slow component was assigned a value of 0. The functional gain of the fundamental $\dot{V}{\mathrm{O}}_2$ response was also calculated by dividing $A_{{\dot{V}}_{O_2}}$ by the change in work rate (i.e., $A_{{\dot{V}}_{O_2}}$/Δ work rate).

The NIRS derived [HHb + Mb] responses to U→S and M→S exercise transitions were also modeled to provide information on the kinetics of muscle deoxygenation. Since [HHb + Mb] increases after a short delay following the onset of square‐wave exercise, the time delay before the onset of the exponential increase in [HHb + Mb] (i.e., TD_[HHb + Mb]) was defined as when [HHb + Mb] had risen more than 1 SD above the mean baseline value obtained during the final 30 sec of baseline cycling (DeLorey et al. ). On occasions where [HHb + Mb] decreased after the exercise onset, TD_[HHb + Mb] was taken as the first point following the nadir showing a sustained increase in [HHb + Mb]. Data prior to this point were removed, and the [HHb + Mb] data was then fit with a single exponential equation (eq. ) of the form:$$\begin{array}{c}\hfill [\end{array}\text{HHb + Mb}](t)=[\text{HHb + Mb}](b)+\mathrm{A}[\text{HHb + Mb}]\ast (1-e(t-\text{TD}[H\text{Hb + Mb]})\tau [\text{HHb+Mb}])$$where [HHb + Mb]_(b) is the mean [HHb + Mb] measured over the final 30 sec of baseline cycling, A_[HHb + Mb] is the asymptotic amplitude of the response, TD_[HHb + Mb] is the time delay relative to the onset of exercise and τ_[HHb + Mb] is the time constant for the response. The model fitting window was constrained to ${\text{TD}}_{S\dot{C}{V}_{O_2}}$. The amplitude of the [HHb + Mb] “slow component” was calculated by subtracting [HHb + Mb]_(b) + A_[HHb + Mb] from the mean value of [HHb + Mb] during the final 30 sec of exercise. To indicate changes in muscle oxygenation and total blood volume, the mean values for [HbO₂ + MbO₂] and [THb + Mb] were determined at baseline (30 sec preceding each transition), at 30 sec and 120 sec into the exercise transition (15 sec bins centerd on 30 and 120 sec), and at end exercise (final 30 sec) to allow comparisons between conditions. These specific time points were selected to permit comparisons between conditions early in the transition (during the fundamental rise of $\dot{V}{\mathrm{O}}_2$ before the onset of the $\dot{V}{\mathrm{O}}_2$ slow component) and after the $\dot{V}{\mathrm{O}}_2$ slow component had developed fully (i.e., at exercise termination). In addition to modeling the $\dot{V}{\mathrm{O}}_2$ and [HHb + Mb] responses to exercise, we also calculated the ratio of change in [HHb + Mb] to change in $\dot{V}{\mathrm{O}}_2$ (Δ[HHb + Mb]/Δ$\dot{V}{\mathrm{O}}_2$) to provide further information on the degree of reliance on O₂ extraction to satisfy a given $\dot{V}{\mathrm{O}}_2$ in each transition. First, the second‐by‐second $\dot{V}{\mathrm{O}}_2$ and [HHb + Mb] were linearly interpolated to give 5 sec averages, and these 5 sec averaged data were normalized for each transition (with 0% reflecting the baseline value and 100% reflecting the final amplitude of the fundamental response). The normalized $\dot{V}{\mathrm{O}}_2$ data were then left‐shifted by the duration of phase I (previously determined) so that the fundamental phase $\dot{V}{\mathrm{O}}_2$ increase was aligned with exercise onset. A mean value of the Δ[HHb + Mb]/Δ$\dot{V}{\mathrm{O}}_2$ ratio was calculated for each transition as the average ratio value across the duration of the fundamental phase (Murias et al. ).

Heart‐rate kinetic responses to U→S and M→S exercise transitions were also modeled using a single exponential function (Eq. ) with the response constrained to the start of exercise (at t = 0; i.e., with no time delay):$$\text{HR}(t)=\text{HR}(b)+\text{AHR}\ast (1-e(t/\tau \text{HR})$$where HR_(b) is the mean HR measured over the final 30 sec of baseline cycling, A_HR is the asymptotic amplitude of the response and τ_HR is the time constant of the response. The fitting window was constrained to ${\text{TD}}_{S\dot{C}{V}_{O_2}}$.

Critical power and W′ were estimated using three models: the hyperbolic power‐time (P‐T) model (Eq. ); the linear work‐time (W‐T) model, where the total work done is plotted against time (Eq. ); and the linear inverse‐of‐time (1/T) model (eq. ), where power output is plotted against the inverse of time:$$\mathrm{P}={\mathrm{W}}^{\prime }/\mathrm{T}+\text{CP}$$$$\mathrm{W}=\text{CP}\ast \text{T +}{\mathrm{W}}^{\prime }$$$$\mathrm{P}={\mathrm{W}}^{\prime }\ast (1/\mathrm{T})+\text{CP}$$

The standard errors of the estimates (SEE) associated with CP and W′ were expressed as a coefficient of variation (CV) relative to the parameter estimate. The total error associated with the obtained parameters was calculated as the sum of the CV associated with the critical power and W′ across both conditions for each individual participant. The sum of the CV was optimized for each individual by selecting the model with the lowest total error to produce the “best individual fit” parameter estimates. The model producing the best individual fit estimates was the same in both conditions for each participant.

Statistical analyses

Two‐way repeated measures ANOVAs (condition * work rate) were used to compare differences in all kinetic parameters (i.e., $\dot{V}{\mathrm{O}}_2$_, [HHb + Mb] and heart rate) and Δ[HHb + Mb]/Δ$\dot{V}{\mathrm{O}}_2$. Three‐way repeated measures ANOVAs (condition * work rate * time) were used to compare differences in blood [L⁻], [HbO₂ + MbO₂], and [THb + Mb] between tests. Planned repeated and simple contrasts were used to locate any significant main or interaction effects. Mauchly's test was used to test for the assumption of sphericity for repeated measures factors. Where this assumption was violated, the Greenhouse‐Geisser correction factor was applied to adjust the degrees of freedom. Student's paired t tests were used to compare differences in critical power and W' between conditions. Pearson's product‐moment correlation coefficient was used to assess the relationship between critical power and ${\tau }_{\dot{V}{O}_2}$. All data are presented as mean ± SD unless otherwise stated, and 95% confidence intervals (95% CI) are presented for modeled time constant parameters. For clarity, and to highlight values for parameters measured across all four severe‐intensity work rates, the overall mean across work rates ± SD is presented in text, with work rate‐specific mean ± SD presented in tables. Statistical significance was accepted at P < 0.05.

Effects of oxygen uptake kinetics on critical power

In this study, we observed a ~50% increase of ${\tau }_{\dot{V}{O}_2}$ when exercise was initiated from an elevated baseline work rate (M→S) compared with a baseline of unloaded cycling (U→S), consistent with previous research (Hughson and Morrissey ; di Prampero et al. ; Brittain et al. ; Wilkerson and Jones ; DiMenna et al. , ; Bowen et al. ; Breese et al. ). This slowing of the $\dot{V}{\mathrm{O}}_2$ kinetics occurred with a concomitant ~10 W reduction in critical power. Additionally, and also consistent with previous research (Murgatroyd et al. ; Goulding et al. ), we observed a strong inverse relationship (R² = 0.90) between ${\tau }_{\dot{V}{O}_2}$ and critical power. Since the NIRS data suggest that the increase in ${\tau }_{\dot{V}{O}_2}$ in M→S compared with U→S was not due to insufficient O₂ availability (see below), collectively, the data suggest that ${\tau }_{\dot{V}{O}_2}$ is an independent determinant of critical power.

Because critical power represents the upper limit for which a metabolic steady state is obtainable (Poole et al. ; Jones et al. ; Vanhatalo et al. ), critical power may be regarded as the highest work rate for which the O₂ deficit and mechanical efficiency can be stabilized. For a given power output, ${\tau }_{\dot{V}{O}_2}$ is the primary determinant of the size of the O₂ deficit, with more rapid $\dot{V}{\mathrm{O}}_2$ kinetics enabling a smaller O₂ deficit to be incurred (Whipp et al. ). Consequently, the greater ${\tau }_{\dot{V}{O}_2}$ observed in M→S may have reduced critical power by virtue of a reduction in the highest power output for which the O₂ deficit could be stabilized. Inherent within this interpretation, is that the magnitude of metabolic perturbation during the rest‐to‐exercise transition determines whether or not a steady state can be attained. Presumably beyond some “critical” level of metabolic perturbation there is a continued reduction in mechanical efficiency, thus preventing the attainment of a steady state. Hence the slower $\dot{V}{\mathrm{O}}_2$ kinetics observed during M→S, would exacerbate the degree of metabolic perturbation during a given exercise transition and cause a reduction in the highest power output for which a steady state can be obtained.

The signaling processes that cause the inability to attain a metabolic steady state during exercise above the critical power likely relate to the accumulation of the products of ATP breakdown. [ADP] is below its Michaelis constant (K_m) in resting skeletal muscle, and its increase as a consequence of ATP breakdown causes large increases in the rate of oxidative phosphorylation (Chance and Williams ; Connett et al. ; Honig et al. ), with the relationship between [ADP] and $\dot{V}{\mathrm{O}}_2$ previously observed as hyperbolic (Jeneson et al. ; Glancy et al. ; Schmitz et al. ) (or sigmoidal in vivo; Wüst et al. ). However, high‐intensity exercise also results in a decline in muscle efficiency due to an increase in ATP turnover per unit of work performed (Zoladz et al. ; Cannon et al. ; Vanhatalo et al. ) and/or additional recruitment of inefficient type II fibers (Krustrup et al. ,b, ), each causing further rises in [ADP]. These combined effects of high‐intensity exercise result in [ADP] encroaching further toward the flat region of the [ADP]‐$\dot{V}{\mathrm{O}}_2$ relationship, where $\dot{V}{\mathrm{O}}_2$ becomes progressively less sensitive to further increases in [ADP]. Critical power, therefore, might represent the work rate at which some “critical” [ADP] is achieved during the rest‐exercise transition. Once this critical [ADP] has been attained, the loss of sensitivity of $\dot{V}{\mathrm{O}}_2$ to rising [ADP] is such that there is a continually increasing reliance on non‐oxidative metabolism and thus the inability to attain a physiological steady state. In turn, this triggers a cascade of fatigue‐related physiological events that eventually result in task failure (Demarle et al. ), including increased muscle ATP demand (Rossiter et al. ), progressive recruitment of additional motor units (Shinohara and Moritani ; Barstow et al. ; Scheuermann et al. ; Krustrup et al. ,b; Endo et al. ), and the attainment of $\dot{V}{\mathrm{O}}_2\text{max}$ max (Poole et al. ).

In this study therefore, the greater ${\tau }_{\dot{V}{O}_2}$ observed in M→S compared with U→S would have led to a greater rise in [ADP] for any given increase in power output due to increased reliance on non‐oxidative phosphorylation. Hence, the concomitant reduction in critical power in M→S compared to U→S is a consequence of the greater ${\tau }_{\dot{V}{O}_2}$ reducing the power output at which some critical level of [ADP], and thus a physiological steady state, is attained. When considered in the context of the current hypothesis therefore, ${\tau }_{\dot{V}{O}_2}$ is an independent determinant of critical power, because a smaller ${\tau }_{\dot{V}{O}_2}$ would lessen the disturbances in intracellular [ADP] during the exercise transition, thus permitting a physiological steady state to be attained at a higher power output and raising critical power.

Mechanistic bases of the work‐to‐work exercise effect

It has previously been suggested that the slower fundamental phase $\dot{V}{\mathrm{O}}_2$ kinetics observed with work‐to‐work exercise are the result of a slowed rate of adaptation of O₂ delivery (Hughson and Morrissey , ). However, in the present study, and consistent with previous literature (Spencer et al. ; Breese et al. ; Williams et al. ; Keir et al. , ; Wüst et al. ; Nederveen et al. ), we found that τ_[HHb + Mb] was greater in M→S when compared with U→S. The NIRS‐derived [HHb + Mb] signal represents the relative balance between O₂ delivery and utilization in the microvasculature within the field of interrogation. Hence the greater τ_[HHb + Mb] reflects slower muscle deoxygenation kinetics and thus indicates a greater O₂ availability relative to the increasing demand for $\dot{V}{\mathrm{O}}_2$ during the exercise transient in M→S compared with U→S. Furthermore, we observed a lower Δ[HHb + Mb]/Δ$\dot{V}{\mathrm{O}}_2$ ratio, and an elevated [HbO₂ + MbO₂] in M→S compared with U→S during the severe exercise bout. Taken together therefore, our data derived from NIRS are suggestive of a relative improvement in O₂ availability and thus better matching of microvascular O₂ distribution to muscle O₂ utilization in the active tissues during M→S compared with U→S.

Given that our data do not implicate an O₂ delivery limitation as the mechanism responsible for the slower fundamental phase $\dot{V}{\mathrm{O}}_2$ kinetics observed with work‐to‐work exercise, the physiological mechanisms contributing to the slowed $\dot{V}{\mathrm{O}}_2$ dynamics in M→S likely reflect the direct influence of a raised metabolism and/or the recruitment of higher order muscle fibers at the onset of severe exercise (Brittain et al. ; DiMenna et al. ). The elevation in metabolic rate prior to the severe‐intensity exercise transition in M→S will reduce the cellular energetic state in already active fibers (i.e., reduced PO₂ and [PCr], increased [ADP] and [P_i], and less negative changes in the Gibbs free energy of ATP hydrolysis [ΔG_ATP]), thus slowing the $\dot{V}{\mathrm{O}}_2$ response in the subsequent exercise transition (Meyer and Foley ). Alternatively, Henneman's size principle (Henneman and Mendell ) predicts that motor units are recruited in an orderly fashion, with smaller, more oxidative fibers recruited first. Thus, when an exercise transition is made from an elevated baseline work rate, the newly recruited muscle fibers will reside at the higher end of the recruitment hierarchy, particularly during transition to severe‐intensity exercise. These muscle fibers have a greater O₂ cost of contraction and possess slower $\dot{V}{\mathrm{O}}_2$ kinetics relative to the smaller, more oxidative fibers (Crow and Kushmerick ; Willis and Jackman ; Reggiani et al. ; Behnke et al. ), and thus could also account for the slowing of the $\dot{V}{\mathrm{O}}_2$ response in M→S.

Whether muscle fiber recruitment patterns and/or raised muscle metabolism were primarily responsible for the slowed $\dot{V}{\mathrm{O}}_2$ kinetics during the work‐to‐work exercise is presently unclear, and may be intensity‐domain dependent (DiMenna et al. ; Bowen et al. );. Furthermore, the present study does not permit conclusions regarding the mechanisms underpinning the slower $\dot{V}{\mathrm{O}}_2$ kinetics during M→S compared with U→S. Hence, both potential mechanisms may independently account for the greater ${\tau }_{\dot{V}{O}_2}$, and thus critical power, in M→S. However, regardless of which of these mechanisms was responsible for the slower $\dot{V}{\mathrm{O}}_2$ kinetics in M→S, the present data suggest that the slowing of $\dot{V}{\mathrm{O}}_2$ kinetics observed when exercise was initiated from an elevated baseline reduced critical power independently of O₂ availability, demonstrating that ${\tau }_{\dot{V}{O}_2}$ is an independent determinant of critical power.

Limitations

The use of single transitions to characterize the $\dot{V}{\mathrm{O}}_2$ responses to exercise presents a limitation for the present study, as we were unable to improve the signal‐to‐noise ratio through the use of repeat transitions. However, repeat transitions were not feasible due to the undue requirements this would place on participants; repeating each transition would also create a greater risk of a training effect confounding the results. Despite this, the 95% CI associated with the ${\tau }_{\dot{V}{O}_2}$ was ~4 sec; a level of confidence that was likely aided by the high amplitude of the individual $\dot{V}{\mathrm{O}}_2$ responses, which would have increased the signal‐to‐noise ratio in each transition. Additionally, the level of confidence reported in the ${\tau }_{\dot{V}{O}_2}$ parameter in the present study is less than the recently suggested minimally important difference to determine significant changes in intervention studies (Benson et al. ), and the 95% CI's were smaller than the mean difference in ${\tau }_{\dot{V}{O}_2}$ at all four work‐rates. Therefore, despite the use of single transitions at each work rate, we are confident in our reported effects of baseline work rate on ${\tau }_{\dot{V}{O}_2}$. Finally, our NIRS measurements were taken from a single site on a superficial portion of the vastus lateralis muscle. Muscle perfusion and deoxygenation are spatially heterogeneous during cycle exercise (Koga et al. ), therefore it is possible that O₂ availability was limiting in other muscle regions that were not interrogated. However, type II fibers are more prevalent in superficial muscle (Johnson et al. ), and these muscle fibers rely more on elevated diffusive as opposed to perfusive O₂ transport strategies to satisfy an increase in metabolic demand when compared with deeper muscle (Koga et al. ). Therefore, if any O₂ delivery limitations were present, we would have been more likely to have detected them in the superficial region of the vastus lateralis that we interrogated, as opposed to deeper muscle groups.