Continuous measurement of oxygen tensions in the air-breathing organ of Pacific tarpon (Megalops cyprinoides) in relation to aquatic hypoxia and exercise

The Pacific tarpon is an elopomorph teleost fish with an air-breathing organ (ABO) derived from a physostomous gas bladder. Oxygen partial pressure (PO₂) in the ABO was measured on juveniles (238 g) with fiber-optic sensors during exposure to selected aquatic PO₂ and swimming speeds. At slow speed (0.65 BL s⁻¹), progressive aquatic hypoxia triggered the first breath at a mean PO₂ of 8.3 kPa. Below this, opercular movements declined sharply and visibly ceased in most fish below 6 kPa. At aquatic PO₂ of 6.1 kPa and swimming slowly, mean air-breathing frequency was 0.73 min⁻¹, ABO PO₂ was 10.9 kPa, breath volume was 23.8 ml kg⁻¹, rate of oxygen uptake from the ABO was 1.19 ml kg⁻¹ min⁻¹, and oxygen uptake per breath was 2.32 ml kg⁻¹. At the fastest experimental speed (2.4 BL s⁻¹) at 6.1 kPa, ABO oxygen uptake increased to about 1.90 ml kg⁻¹ min⁻¹, through a variable combination of breathing frequency and oxygen uptake per breath. In normoxic water, tarpon rarely breathed air and apparently closed down ABO perfusion, indicated by a drop in ABO oxygen uptake rate to about 1% of that in hypoxic water. This occurred at a wide range of ABO PO₂ (1.7–26.4 kPa), suggesting that oxygen level in the ABO was not regulated by intrinsic receptors.     

Gas secretion and resorption in the swimbladder of the codGadus morhua

Summary The codGadus morhua has a closed, compliant swimbladder which occupies 5% of its volume. Pressure changes caused by vertical movements lead to the expansion and compression of the swimbladder gas, and the fish responds to the accompanying changes in density with compensatory swimming movements and the resorption or secretion of gas. A simple physiological model, based on estimates of cardiac output, the blood supply to the swimbladder and the oxygen-carrying capacity of the blood, is developed to set limits to these processes.An apparatus is described for making observations on the rate of buoyancy adaptation by cod subjected to pressure changes within the range 1.15 to 7.50 ATA at temperatures from 0 to 17°C. One hundred and twenty eight experiments were made with 38 cod ranging in length from 25 to 50 cm and in weight from 138 to 1440 g.The results showed that the rate of gas resorption increased markedly with the pressure to which the fish were adapted (from 0.14 ml kg^–1 min^–1 at 1.5 ATA to 1.54 ml kg^–1 min^–1 at 7.0 ATA), but not significantly with the weight of the fish or with temperature. In contrast, the rate of gas secretion increased markedly with temperature (from 0.02 ml kg^–1 min^–1 at 0°C to 0.11 ml kg^–1 min^–1 at 17°C), increased slightly with pressure, and decreased with the weight of the fish.The rate of gas resorption was much faster than that of gas secretion, and the difference between the two rates increased with pressure. The difference in performance is discussed in relation to the restriction that the swimbladder might impose to the speed and extent of vertical movements. It is suggested that when a closed swimbladder has a hydrostatic function it may be advantageous if neutral buoyancy is maintained only at the upper limit to the diurnal vertical range.     

Hand-Held Tidal Breathing Nasal Nitric Oxide Measurement – A Promising Targeted Case-Finding Tool for the Diagnosis of Primary Ciliary Dyskinesia

Background

Nasal nitric oxide (nNO) measurement is an established first line test in the work-up for primary ciliary dyskinesia (PCD). Tidal breathing nNO (TB-nNO) measurements require minimal cooperation and are potentially useful even in young children. Hand-held NO devices are becoming increasingly widespread for asthma management. Therefore, we chose to assess whether hand-held TB-nNO measurements reliably discriminate between PCD, and Healthy Subjects (HS) and included Cystic Fibrosis (CF) patients as a disease control group known to have intermediate nNO levels.

Methods

In this cross sectional, single centre, single occasion, proof-of-concept study in children and adults with PCD and CF, and in HS we compared feasibility, success rates, discriminatory capacity, repeatability and agreement between a hand-held electrochemical device equipped with a nNO software application sampling at flow rates 2 ml/s or 5 ml/s, and two stationary chemiluminescence devices, applying both tidal breathing and velum closure techniques.

Results

Measurements were done in 16 PCD patients, 21 patients with CF and 20 HS aged between 3.8 and 60.9 years. Hand-held TB-nNO showed high success rate (96.5–100%) vs. velum closure nNO techniques (70.2–89.5%). Hand-held TB-nNO sampling at flow rate 5 ml/s showed equally high discriminative power (PCD vs. HS [p<0.0001] and PCD vs. CF [p<0.0001]) and reaching close to 100% sensitivity and specificity, superior repeatability (CV% = 10%) and equal limits of agreement compared to TB-nNO by stationary devices and even compared to velum closure sampling.

Conclusion

Hand-held TB-nNO discriminates significantly between PCD, CF and HS and shows promising potential as a widespread targeted case-finding tool for PCD, although further studies are warranted before implementation.     

Heart rate as an indicator of stress during the critical swimming speed test of farmed Atlantic salmon (Salmo salar L.)

A swim tunnel is to fish as a treadmill is to humans, and is a device used for indirect measuring of the metabolic rate. This study aims to explore the fish stress (if any) during the critical swimming test routines (fish handling, confinement, and swimming) using heart rate (f_H, heartbeat per minute) bio-loggers in farmed Atlantic salmon (Salmo salar L.). In addition, the recovery dynamics of exercised fish using f_H were explored for 48 h post swim tests. Continuous f_H data were acquired following the surgical implantation and throughout the trials, such as during fish handling, swim tests (critical swimming speed, U_crit), and 48 h post swim tests. After 3 weeks of surgical recovery, f_H stabilized at 46.20 ± 1.26 beats min⁻¹, equalizing a ~38% reduction in f_H recorded post-surgical tachycardia (74.13 ± 1.44 beats min⁻¹). Interestingly, f_H was elevated by ~200% compared to baseline levels not only due to the U_crit (92.04 ± 0.23 beats min⁻¹) but also due to fish handling and confinement in the swim tunnel, which was 66% above the baseline levels (77.48 ± 0.34 beats min⁻¹), suggesting fish stress. Moreover, significantly higher plasma cortisol levels (199.56 ± 77.17 ng mL⁻¹) corresponding to a ~300% increase compared to baseline levels (47.92 ± 27.70 ng mL⁻¹) were identified after U_crit, predicting post-swim test stress (physiological exhaustion). These findings reinforce the importance of fish acclimation in the swim tunnel prior to the swimming tests. However, f_H dropped over the course of the 48-h post-swim test, but remained comparatively higher than the basal levels, suggesting fish should be given at least 48 h to recover from handling stress for better fish welfare. This study further explored the influence of fish tagging on U_crit, which resulted in reduced swimming capabilities of tagged fish (1.95 ± 0.37 body lengths s⁻¹) compared to untagged fish (2.54 ± 0.42 body length s⁻¹), although this was not significant (p = 0.06), and therefore future tagging studies are warranted.     

An aid to the determination of the ventilatory threshold

Detection of the ventilatory threshold during an incremental load exercise test by eye can be difficult. Although various alternative methods employing information other than the ventilation can be used to assist in determining the ventilatory threshold, they rely on underlying assumptions about the physiological basis for the ventilatory threshold. The method presented here (CUSUM) uses only the ventilation data, and therefore avoids such assumptions. Twelve subjects performed a total of 47 incremental exercise tests to exhaustion. Determinations of the ventilatory thresholds made by eye from the ventilation data (mean of three independent observers) were used as a standard for comparison with determinations using the modified V-slope method and the CUSUM method. A mean (SD) difference of 0.6 (2.84) ml·min^–1·kg^–1 was found between the standard ventilatory thresholds and those determined using the modified V-slope method. A similar comparison between the standard ventilatory thresholds and those determined using the CUSUM method yielded a difference of –0.11 (2.35) ml min^–1·kg^–1. It was concluded that the CUSUM method was a useful aid for the detection of the ventilatory threshold using the ventilation data alone.     

Estimation of cardiac output and stroke volume from thermal equilibration and heartbeat rates in fish

Cardiac output and stroke volume were estimated for a 200 g largemouth blackbass (Micropterus salmoides) by a modified whole-body thermodilution method using the relation between thermal equilibration rates and heartbeat frequencies. The reciprocal of the thermal time constant, k (min^–1), was related to the heartbeat frequency, F (beats min^–1), by the equation k=0.00146 F + 0.309; the slope is the weight-specific stroke volume (ml g^–1) and the intercept is the weight-specific heat transfer constant (cal °C^–1 min^–1 g^–1). Stroke volume was 0.292 ml (0.00146 ml/g body weight), yielding cardiac output values ranging from 44 ml kg^–1 min^–1 (at 30 beats min) to 158 ml kg^–1 min^–1 (at 108 beats min^–1), or 4.4 to 15.8% of body weight. Active (convective) heat transfer due to blood flow constituted an estimated 11 to 34% (mean 22.5%) of total heat transfer, depending on heartbeat frequency; this variability constitutes physiological thermoregulation.     

Human nonshivering thermogenesis

Metabolic responses, skin temperatures and changes in heart rate and blood pressure were measured in a control group and in “polar swimmers” after infusion of different doses of epinephrine, norepinephrine and isoprenaline. In controls the highest infusion dose of isoprenaline (0.1 μg min⁻¹ kg⁻¹) increased metabolic rate in normal humans by 36%, while the highest infusion doses of epinephrine and norepinephrine (0.45 μg min⁻¹ kg⁻¹) increased metabolic rate by 24%, only. In “polar swimmers” the epinephrine thermogenesis was potentiated significantly, reaching about 45% of the basal metabolic rate. The norepinephrine and isoprenaline thermogenesis were not different from that of the control group. It is concluded that in humans the epinephrine thermogenesis is probably located in muscles and in the white fat (Simonsen et al., 1992), and may be the principal mechanism of metabolic adaptation to cold. It was calculated that the increased capacity of epinephrine thermogenesis in cold exposed “polar swimmers” could theoretically shift the survival limit downwards to lower environmental temperatures by about 5°C.     

Performance of the isolated rainbow trout heart perfused under self-controlled coronary pressure conditions: effects of high and low oxygen tension, arachidonic acid and indomethacin

The effects of arachidonic acid (AA) and indomethacin (IM) on performance, oxygen consumption and lactate release of the trout heart were studied in vitro TPa s m⁻³ using a perfusion system, which allowed the evaluation of the integrated function of ventricle and coronary system by continuously setting the input coronary flow and pressure proportional to the pressure and flow output of the heart. The heart was working against a fixed resistance. A reduction of input oxygen partial pressure (P_O2) from 175 torr (high P_O2) to 76 torr (low P_O2) increased the coronary flow (from 0.51 ml min⁻¹ kg⁻¹ to 1.21 ml min⁻¹ kg⁻¹, respectively) due to a strong reduction in coronary resistance (from 0.60 TPa s m⁻³ to 0.19 TPa s m⁻³, respectively). Oxygen consumption by the heart was significantly reduced from 20.7 ml min⁻¹ g⁻¹ at high P_O2 to 4.6 ml min⁻¹ g⁻¹ at low P_O2, while lactate production was increased from 24 μmol h⁻¹ g⁻¹ to 42 μmol h⁻¹ g⁻¹, indicating a higher contribution of anaerobic respiration to mechanical work. Mechanical efficiency was significantly higher at low than at high P_O2. Exogenous AA caused a depression of inotropism and a reduction in the aerobic metabolic rate (by 25–35%), which was not accompanied by increased lactate production. IM enhanced the depression of both inotropism and aerobic metabolism. The effect of AA and IM on the heart were amplified at low P_O2. Accepted: 20 October 1997     

Heart rates of Atlantic salmon Salmo salar during a critical swim speed test and subsequent recovery

In this study, heart rate (HR) bio-loggers were implanted in the abdominal cavity of 12 post-smolt Atlantic salmon Salmo salar weighing 1024 ± 31 g and acclimated to 12°C sea water. One week after the surgical procedure, a critical swim speed (U_crit) test was performed on tagged and untagged conspecifics, whereafter tagged fish were maintained in their holding tanks for another week. The U_crit was statistically similar between tagged and untagged fish (2.67 ± 0.04 and 2.74 ± 0.05 body lengths s⁻¹, respectively) showing that the bio-logger did not compromise the swimming performance. In the pre-swim week, a diurnal cycle was apparent with HR peaking at 65 beats min⁻¹ during the day and approaching 40 beats min⁻¹ at night. In the U_crit test, HR increased approximately exponentially with swimming speed until a plateau was reached at the final speed before fatigue with a maximum of 85.2 ± 0.7 beats min⁻¹. During subsequent recovery tagged fish could be divided into a surviving group (N = 8) and a moribund group (N = 4). In surviving fish HR had fully recovered to pre-swim levels after 24 h, including reestablishment of a diurnal HR cycle. In moribund fish HR never recovered and remained elevated at c. 80 beats min⁻¹ for 4 days, whereafter they started dying. We did not identify a proximal cause of death in moribund fish, but possible explanations are discussed. Tail beat frequency (TBF) was also measured and showed a more consistent response to increased swimming speeds. As such, when exploring correlations between HR, TBF and metabolic rates at different swimming speeds, TBF provides better predictions. On the contrary, HR measurements in free swimming fish over extended periods of time are useful for other purposes such as assessing the accumulative burden of various stressors and recovery trajectories from exhaustive exercise.     

Responses of aerial ventilation to hypoxia and hypercapnia inChanna argus,an air-breathing fish

Summary The snake-head fish (Channa argus) is an obligate air-breather inhabiting fresh waters in the temperate zone of East Asia.Ventilation of the air-breathing organ and aerial gas exchange were measured in 1 to 2 kg specimens at 15 and 25°C. Additionally, the ventilatory responses to hypoxia and hypercapnia were studied. Aerial ventilation increased from 1.1 to 2.9 mlbtps·kg^–1·min^–1 when temperature rose from 15 to 25°C. Concomitantly, O₂-uptake through airbreathing increased from 0.1 mlstpd·kg^–1·min^–1 (15°C) to 0.28 mlstpd·kg^–1·min^–1 (25°C), whereas aerial gas exchange was less important for CO₂-climination as evident from low gas exchange ratios (0.16 at 15°C, 0.29 at 25°C).Ventilation increases only slightly in response to inspiration of hypercapnic gas mixtures or to hypoxic conditions in water. By contrast, inspiration of hypoxic gas mixtures caused marked increases of ventilation in particular at the higher temperature.Aerial ventilation inChanna is low compared to values for ectothermic pulmonary breathers. However, its ventilatory responses to hypoxia strikingly resemble those of reptiles: The most marked ventilatory response to hypoxia occurs at the higher temperature where the demands for O₂ are greatest.     

Swimming Speed of Larval Snail Does Not Correlate with Size and Ciliary Beat Frequency

Many marine invertebrates have planktonic larvae with cilia used for both propulsion and capturing of food particles. Hence, changes in ciliary activity have implications for larval nutrition and ability to navigate the water column, which in turn affect survival and dispersal. Using high-speed high-resolution microvideography, we examined the relationship between swimming speed, velar arrangements, and ciliary beat frequency of freely swimming veliger larvae of the gastropod Crepidula fornicata over the course of larval development. Average swimming speed was greatest 6 days post hatching, suggesting a reduction in swimming speed towards settlement. At a given age, veliger larvae have highly variable speeds (0.8–4 body lengths s⁻¹) that are independent of shell size. Contrary to the hypothesis that an increase in ciliary beat frequency increases work done, and therefore speed, there was no significant correlation between swimming speed and ciliary beat frequency. Instead, there are significant correlations between swimming speed and visible area of the velar lobe, and distance between centroids of velum and larval shell. These observations suggest an alternative hypothesis that, instead of modifying ciliary beat frequency, larval C. fornicata modify swimming through adjustment of velum extension or orientation. The ability to adjust velum position could influence particle capture efficiency and fluid disturbance and help promote survival in the plankton.     

Differences in swimming pattern between life cycle stages of the toxic dinoflagellate Alexandrium fundyense

Different life stages of Alexandrium fundyense have different swimming behavior; gametes often are said to “swarm” or “dance” before mating. This behavior was studied, and quantitative measures of these motility patterns in two-dimensions were generated using motion-analysis software applied to video records of individual-cell movements. Behavior, swimming patterns, and growth were studied in two strains of A. fundyense and compared in encystment medium and growth medium. Vegetative cells swam straight, rotating around the apical axis until they hit something and then swam straight in a different direction. Gamete swimming behavior was slower and characterized by frequent direction changes and circular motion. Gametes contacted other cells frequently (>5 cell contacts min⁻¹ cell⁻¹). Zygotes swam slowly when newly formed and later became nearly immobile; these cells continued to contact other cells and also surfaces. The results are in accordance with field observations of long swimming distances for vegetative cells, accumulation in thin layers of gametes, and sinking of developing resting cysts attached to marine snow for zygotes.     

An automated continuous determination of oxygen with high sensitivity

A sensitive, rapid, and precise method is described for the continuous determination of oxygen in gases. The principle of the method is based on the reaction of O₂ with an alkaline catechol or pyrogallol solution, which is combined with a Fe²⁺ solution to increase the sensitivity of the color reaction. The development of the color takes place in a tube system provided with a proportioning pump and is read automatically on a recorder after passing a flow cell of a photometer. The lower limit of sensitivity of this method is 0.05 μl of O₂ min^?1. Thus, in a gas flow of ≈0.5 ml min^?1, an oxygen concentration of ≥0.01% (v/v) can be determined. If the gas flow is increased to ≈2.5 ml min^?1, this limit of sensitivity is lowered to ≥0.002% (v/v). Since a 2-min period is necessary for the measurement, the volume of the sample has to be 1 ml in the first case and 5 ml in the second.     

Respirometry and swimming dynamics of the giant australian cuttlefish,sepia apama (mollusca,cephalopoda)

Swimming dynamics of the giant Australian cuttlefish, Sepia apama, were investigated using swimtunnel respirometry. Relationships between jet pressure, fin frequency, swimming speed and oxygen consumption were defined. Laboratory calibration of swimming parameters is necessary to allow estimates of swimming costs in the field.

Jet pressure was the best predictor of oxygen consumption with an averaged equation of MO₂?=?722 (jet pressure)?+?107?r ²?=?0.51. Individually, fin frequency and jet pressure correlated highly to swimming speed, but due to the complicated usage of finning and jetting, the correlation between swimming speed and oxygen consumption was weaker. Cuttlefish were not optimal swimtunnel subjects and could not swim at high speeds for extended periods. At 15°C and a swimming speed of 0.06?m?s^?1, the gross cost of transport was calculated to be 10.1?kg^?1?m?^?1, with a net cost of 4.1?kg^?1?m^?1.     

Ventilation and gas exchange in the diamondback water snake,Natrix rhombifera

Summary Simultaneous measurements of pulmonary and cutaneous oxygen and carbon dioxide exchange, pulmonary ventilation and heart rate were made on the diamondback water snake,Natrix rhombifera at 28°C using body plethysmography. Resting lung volume, maximum lung volume and tracheal volume were also measured.The following mean values were measured in undisturbed snakes breathing room air: total (pulmonary and cutaneous) O₂ uptake 46 mol · (kg min)^–1; total CO₂ output, 49 mol · (kg min)^–1; tidal volume, 12 ml (BTPS) · kg^–1; ventilatory rate, 6.9 min^–1; heart rate, 42 min^–1. From the measurements of tracheal volume, the effective (alveolar) ventilation was estimated as approximately 70% of total ventilation resulting in effective pulmonary and of 130 Torr and 20 Torr respectively. Cutaneous exchange accounted for 8.1% of the total and 12.4% of the total .Resting lung volume of anaesthetized snakes was 75 ml (BTPS) · kg^–1, maximum lung volume was 341 ml (BTPS) · kg^–1 and tracheal volume was 3.9 ml (BTPS) · kg^–1.     

Influence of experimental set-up and methodology for measurements of metabolic rates and critical swimming speed in Atlantic salmon Salmo salar

In this study, swim-tunnel respirometry was performed on Atlantic salmon Salmo salar post-smolts in a 90 l respirometer on individuals and compared with groups or individuals of similar sizes tested in a 1905 l respirometer, to determine if differences between set-ups and protocols exist. Standard metabolic rate (SMR) derived from the lowest oxygen uptake rate cycles over a 20 h period was statistically similar to SMR derived from back extrapolating to zero swim speed. However, maximum metabolic rate (MMR) estimates varied significantly between swimming at maximum speed, following an exhaustive chase protocol and during confinement stress. Most notably, the mean (±SE) MMR was 511 ± 15 mg O₂ kg⁻¹ h⁻¹ in the swim test which was 52% higher compared with 337 ± 9 mg O₂ kg⁻¹ in the chase protocol, showing that the latter approach causes a substantial underestimation. Performing group respirometry in the larger swim tunnel provided statistically similar estimates of SMR and MMR as for individual fish tested in the smaller tunnel. While we hypothesised a larger swim section and swimming in groups would improve swimming performance, U_crit was statistically similar between both set-ups and statistically similar between swimming alone v. swimming in groups in the larger set-up, suggesting that this species does not benefit hydrodynamically from swimming in a school in these conditions. Different methods and set-ups have their own respective limitations and advantages depending on the questions being addressed, the time available, the number of replicates required and if supplementary samplings such as blood or gill tissues are needed. Hence, method choice should be carefully considered when planning experiments and when comparing previous studies.     

Coordination between ventilatory pressure oscillations and venous return in the cephalopod <Emphasis Type="Italic">Sepia officinalis</Emphasis> under control conditions,spontaneous exercise and recovery

Venous blood flow was measured for the first time in a cephalopod. Blood velocity was determined in the anterior vena cava (AVC) of cuttlefish S. officinalis with a Doppler, while simultaneously, ventilatory pressure oscillations were recorded in the mantle cavity. In addition, magnetic resonance imaging (MRI) was employed to investigate pulsatile flow in other major vessels. Blood pulses in the AVC are obligatorily coupled to ventilatory pressure pulses, both in frequency and phase. AVC peak blood velocity (v_AVC) in animals of 232 (± 30 SD) g wet mass at 15°C was found to be 14.2 (± 7.1) cm s⁻¹, AVC stroke volume (SV_AVC) was 0.2 (± 0.1) ml stroke⁻¹, AVC minute volume (MV_AVC) amounted to 5.5 (± 2.8) ml min⁻¹. Intense exercise bouts of 1–2 min resulted in 2.2-fold increases in MV_AVC, enabled by 1.6-fold increments in both, AVC pulse frequency (f _AVC) and v_AVC. As increases in blood flow occurred delayed in time by 1.7 min with regard to exercise periods, we concluded that it is not direct mantle cavity pressure conveyance that drives venous return in this cephalopod blood vessel. However, during jetting at high pressure amplitude (> 1 kPa), AVC blood flow and mantle cavity pressure pulse shapes completely overlap, suggesting that under these conditions, blood transport must be driven passively by mantle cavity pressure. MRI measurements at 15°C also revealed that under resting conditions, f _AVC and ventilation frequency (f _V) match at 31.6 (± 2.1) strokes min⁻¹. In addition, rates of pulsations in the cephalic artery and in afferent branchial vessels did not significantly differ from f _AVC and f _V. It is suggested that these adaptations are beneficial for high rates of oxygen extraction observed in S. officinalis and the energy conserving mode of life of the cuttlefish ecotype in general.     

Cardiac output and stroke volume in swimming harbor seals

Summary Cardiac output was measured by the thermodilution method in three young harbor seals, at rest and while swimming up to the maximum effort for which they could be trained. Stroke volume was determined by counting heart rate simultaneously with determination of cardiac output. Cardiac outputs varied widely between surface breathing (7.8 ml · kg^–1 · s^–1) and breath-holding while swimming under water (1.8 ml · kg^–1 · s^–1). Stroke volume while at the surface was almost twice the volume white submerged. Surface cardiac output was always near maximal despite work effort, whereas submerged cardiac output gradually increased at higher work efforts. The cardiovascular performance of seals at the maximum MO₂ we could induce from them is equivalent to that of the domestic goat.Abbreviations CO Cardiac output - HR Heart rate - SV Stroke volume - MO ₂ Metabolic rate - FS Forced sumersion - V Velocity - C _DF Frontal drag coefficient - CV Cardiovascular Present address: Institute of Marine Science, University of Alaska, Fairbanks, AK, USA     

Metabolic and hormonal responses during exercise at 20°, 0° and −20°C

This study was designed to clarify the effects of cold air exposure on metabolic and hormonal responses during progressive incremental exercise. Eight healthy males volunteered for the study. Informed consent was obtained from every participant. The following protocol was administered to each subject on three occasions in a climatic chamber in which the temperature was 20°, 0° or –20°C with relative humidity at 60%±1%. Exercise tests were conducted on an electrically braked ergocycle, and consisted of a propressive incremental maximal exercise. Respiratory parameters were continuously monitored by an automated open-circuit sampling system Exercise blood lactate (LA), free fatty acids (FFA), glucose levels, bicarbonate concentration (HCO ₃ ^– ), acidbase balance, plasma epinephrine (E) and norepinephrine (NE) were determined from venous blood samples obtained through an indwelling brachial catheter. Maximal oxygen uptake was significantly different between conditions: 72.0±5.4 ml kg^–1 min^–1 at 20°C; 68.9±5.1 ml kg^–1 min^–1 at 0°C and 68.5±4.6 ml kg^–1 min^–1 at –20°C. Workload, time to exhaustion, glucose levels and rectal Catecholamines and lactate values were not significantly altered by thermal conditions after maximal exercise but the catecholamines were decreased during rest. Bicarbonate, respiratory quotient, lactate and ventilatory thresholds increased significantly at –20°C. The data support the contention that metabolic and hormonal responses following progressive incremental exercise are altered by cold exposure and they indicate a marked decrease in maximal oxygen uptake, time to exhaustion and workload.This study was supported by grants from CSR, Univesité du Québec; FIR, Université du Québec à Trois-Rivières and NATO no, 86.0435.     

Effect of thermo-velocity barriers on fish: influence of water temperature,flow velocity and body size on the volitional swimming capacity of northern straight-mouth nase (Pseudochondrostoma duriense)

Water temperature and flow velocity directly affect the fish swimming capacity, and thus, both variables influence the fish passage through river barriers. Nonetheless, their effects are usually disregarded in fishway engineering and management. This study aims to evaluate the volitional swimming capacity of the northern straight-mouth nase (Pseudochondrostoma duriense), considering the possible effects of water temperature, flow velocity and body size. For this, the maximum distance, swim speed and fatigue time (FT) were studied in an outdoor open-channel flume in the Duero River (Burgos, Spain) against three nominal velocities (1.5, 2.5 and 3 m s⁻¹) and temperatures (5.5, 13.5 and 18.5°C), also including the changes between swimming modes (prolonged and sprint). Results showed that a nase of 20.8 cm mean fork length can develop a median swim speed that exceeds 20.7 BL s⁻¹ (4.31 m s⁻¹) during a median time of 3.4 s in sprint mode, or 12.2 BL s⁻¹ (2.55 m s⁻¹) for 23.7 s in prolonged mode under the warmest scenario. During prolonged swimming mode, fish were able to reach further distances in warmer water conditions for all situations, due to a greater swimming speed and FT, whereas during sprint mode, warmer conditions increased the swim speed maintaining the FT. In conclusion, the studied temperature range and flow velocity range influence fish swimming performance, endurance and distance travelled, although with some differences depending on the swimming mode. The provided information goes a step forward in the definition of real fish swimming capacities, and in turn, will contribute to establish clear passage criteria for thermo-velocity barriers, allowing the calculation of the proportion of fish able to pass a barrier under different working scenarios, as well designing of the optimized solutions to improve the fish passage through river barriers.