Cardiorespiratory responses of the woodchuck and porcupine to CO2 and hypoxia

Summary The burrow-dwelling woodchuck (Marmota monax) (mean body wt.=4.45±1 kg) was compared to a similar-sized (5.87±1.5 kg) but arboreal rodent, the porcupine (Erithrizon dorsatum), in terms of its ventilatory and heart rate responses to hypoxia and hypercapnia, and its blood characteristics.V _T,f,T _I andT _E were measured by whole-body plethysmography in four awake individuals of each species. The woodchuck has a longerT _E/T _TOT (0.76±0.03) than the porcupine (0.61±0.03). The woodchuck had a higher threshold and significantly smaller slope to its CO₂ ventilatory response compared to the porcupine, but showed no difference in its hypoxic ventilatory response. The woodchuck P₅₀ of 27.8 was hardly different from the porcupine value of 30.7, but the Bohr factor, –0.72, was greater than the porcupine's, –0.413. The woodchuck breathing air has PaCO₂=48 (±2) torr, PaO₂=72 (±6), pHa=7.357 (±0.01); the porcupine blood gases are PaCO₂=34.6 (±2.8), PaO₂=94.9 (±5), pHa=7.419 (±0.03), suggesting a difference in PaCO₂/pH set points. The woodchuck exhibited no reduction in heart rate with hypoxia, nor did it have the low normoxic heart rate observed in other burrowing mammals.     

Ventilatory and metabolic responses to ambient hypoxia or hypercapnia in rats exposed to CO hypoxia

Gautier, Henry, Cristina Murariu, and Monique Bonora.Ventilatory and metabolic responses to ambient hypoxia orhypercapnia in rats exposed to CO hypoxia. J. Appl. Physiol.83(1): 253-261, 1997.We have investigated at ambienttemperatures (T_am) of 25 and5°C the effects of ambient hypoxia(Hx_am; fractional inspired O₂ = 0.14) and hypercapnia(fractional inspiredCO₂ = 0.04) on ventilation (),O₂ uptake(O₂), andcolonic temperature (T_c) in 12 conscious rats before and after carotid body denervation (CBD). Therats were concomitantly exposed to CO hypoxia (Hx_CO; fractional inspired CO = 0.03-0.05%), which decreases arterial O₂ saturation by ~25-40%.The results demonstrate the following. 1) AtT_am of 5°C, in both intact andCBD rats,/O₂ islarger when Hx_am orCO₂ is associated withHx_CO than with normoxia. At T_am of 25°C, this is also thecase except for CO₂ in CBD rats. 2) AtT_am of 5°C, the changes inO₂ andT_c seem to result from additiveeffects of the separate changes induced byHx_am,CO₂, andHx_CO. It is concluded that, inconscious rats, central hypoxia does not depress respiratory activity.On the contrary, particularly whenO₂ is augmented during acold stress, both/O₂during Hx_CO and the ventilatoryresponses to Hx_am andCO₂ are increased. The mechanismsinvolved in this relative hyperventilation are likely to involvediencephalic integrative structures.

     

Crop responses to CO2 enrichment

Carbon dioxide is rising in the global atmosphere, and this increase can be expected to continue into the foreseeable future. This compound is an essential input to plant life. Crop function is affected across all scales from biochemical to agro-ecosystem. An array of methods (leaf cuvettes, field chambers, free-air release systems) are available for experimental studies of CO₂ effects. Carbon dioxide enrichment of the air in which crops grow usually stimulates their growth and yield. Plant structure and physiology are markedly altered. Interactions between CO₂ and environmental factors that influence plants are known to occur. Implications for crop growth and yield are enormous. Strategies designed to assure future global food security must include a consideration of crop responses to elevated atmospheric CO₂. Future research should include these targets: search for new insights, development of new techniques, construction of better simulation models, investigation of belowground processes, study of interactions, and the elimination of major discrepancies in the scientific knowledge base.     

Changes in breath 13CO2/12CO2 consequent to exercise and hypoxia

Because the natural enrichment of carbohydrate with 13C is greater than that of lipid, we hypothesized that the natural enrichment of exhaled CO2 with 13C (EN) could be used to gauge endogenous substrate utilization in exercising human subjects. To test this, EN and the respiratory exchange ratio (R) which equals the respiratory quotient (RQ) in the steady state, were measured simultaneously in seven subjects. Rest and exercise protocols, performed under conditions of room air (sea level) and hypoxic (inspired O2 fraction = 0.15) breathing, were chosen to cause a variety of patterns of oxidative substrate utilization. Work rates were performed both below and above the subject's lactate threshold (LT). Work above the LT was expected to cause the greatest increase in EN reflecting greater utilization of glucose. There was significant intersubject (P less than 0.05) but not intrasubject variability in resting EN. By 40 min of exercise, EN increased significantly (P less than 0.05) over resting values in all exercise protocols during both room air and hypoxia conditions. In the room air studies, we found no difference in EN during the below-LT work, even though there were significant increases in O2 uptake (VO2). In contrast, above-LT work resulted in significantly greater increases in EN by 20 and 40 min of exercise (P less than 0.05). Contrary to our expectations, we observed no separate effect by hypoxia on the EN during exercise. Both EN and R tended to increase from rest to exercise, but during exercise there was no overall correlation between R and the EN. EN reflects changes in endogenous substrate utilization over relatively long periods of time such as at rest, but delays in the appearance of 13CO2 at the mouth due to dilution in body CO2 pools, and possibly isotopic fractionation, preclude the usefulness of EN as an indicator of endogenous fuel mix during short-term exercise.     

Selected contribution: chemoreflex responses to CO2 before and after an 8-h exposure to hypoxia in humans.

The ventilatory sensitivity to CO2, in hyperoxia, is increased after an 8-h exposure to hypoxia. The purpose of the present study was to determine whether this increase arises through an increase in peripheral or central chemosensitivity. Ten healthy volunteers each underwent 8-h exposures to 1) isocapnic hypoxia, with end-tidal PO2 (PET(O2)) = 55 Torr and end-tidal PCO2 (PET(CO2)) = eucapnia; 2) poikilocapnic hypoxia, with PET(O2) = 55 Torr and PET(CO2) = uncontrolled; and 3) air-breathing control. The ventilatory response to CO2 was measured before and after each exposure with the use of a multifrequency binary sequence with two levels of PET(CO2): 1.5 and 10 Torr above the normal resting value. PET(O2) was held at 250 Torr. The peripheral (Gp) and the central (Gc) sensitivities were calculated by fitting the ventilatory data to a two-compartment model. There were increases in combined Gp + Gc (26%, P < 0.05), Gp (33%, P < 0.01), and Gc (23%, P = not significant) after exposure to hypoxia. There were no significant differences between isocapnic and poikilocapnic hypoxia. We conclude that sustained hypoxia induces a significant increase in chemosensitivity to CO2 within the peripheral chemoreflex.     

Plant responses to past concentrations of CO2

The influence of recent historical changes in atmospheric CO₂ have been investigated by two methods: 1, the responses of leaf development and physiology as indicated by leaves stored in herbaria and 2, by investigating the differential growth responses of populations originating from naturally different CO₂ concentrations. Herbarium leaves indicate that stomatal density and leaf nitrogen have decreased over the last 150 to 200 years, while water use efficiency, estimated from leaf ¹³C and historical measurements of climate, has increased.Natural populations ofBoehmeria cylindrica were found growing at sites, in Florida, with CO₂ mole fractions varying naturally from 350 µmol mol^-1 to 505 µmol mol^-1. Plants were grown in the controlled environment, using seeds originating from populations occurring in the different CO₂ mole fractions. Plants from the different ambient CO₂ mole fractions showed different rates of growth and different non-linear responses of the shoot to root ratio in response to changes in the CO₂ mole fraction from 350 to 675 µmol mol^-1.The proposal that plants originating from high altitude will whow greater stimulations of growth with an increase in CO₂, than plants from low altitude, was rejected in experiments which simulated the atmospheric pressure at altitudes of 0 and 2000m, at CO₂ mole fractions of 350 and 700 µmol mol^-1 and on populations ofPlantago major originating from altitudes of 0 and 3335 m.     

O2 delivery to contracting muscle during hypoxic or CO hypoxia

The consequences of a decreased O2 supply to a contracting canine gastrocnemius muscle preparation were investigated during two forms of hypoxia: hypoxic hypoxia (HH) (n = 6) and CO hypoxia (COH) (n = 6). Muscle O2 uptake, blood flow, O2 extraction, and developed tension were measured at rest and at 1 twitch/s isometric contractions in normoxia and in hypoxia. No differences were observed between the two groups at rest. During contractions and hypoxia, however, O2 uptake decreased from the normoxic level in the COH group but not in the HH group. Blood flow increased in both groups during hypoxia, but more so in the COH group. O2 extraction increased further with hypoxia (P less than 0.05) during concentrations in the HH group but actually fell (P less than 0.05) in the COH group. The O2 uptake limitation during COH and contractions was associated with a lesser O2 extraction. The leftward shift in the oxyhemoglobin dissociation curve during COH may have impeded tissue O2 extraction. Other factors, however, such as decreased myoglobin function or perfusion heterogeneity must have contributed to the inability to utilize the O2 reserve more fully.     

Neuromuscular responses to exercise investigated through surface EMG

Physical exercise promotes a wide spectrum of short and long term responses of different organs and apparatuses. While skeletal muscle adaptations to the different training regimens are conveniently known and described, the neural counterpart of them are still to be described in full. In this paper, an attempt is made to fix the state of the art and particularly to point out the contribution derived from the analysis of the surface electromyographic signal.

In this paper, some examples of sEMG applications in exercise physiology will be reported from studies where only strictly non-invasive techniques (or of very limited invasivity) were applied. A consistent amount of space in this lecture will be dedicated to the advanced analysis of sEMG using non linear tools.     

Avian ventilatory responses to dynamic CO2 signals.

This study uses an awake unidirectionally ventilated avian preparation to examine the effects of dynamic CO2 signals on the respiratory drive. Results show that minute ventilation is affected by both 1) mean CO2 level and 2) amplitude of CO2 oscillations at the frequency of breathing. An increase in mean CO2 level increased minute ventilation. Comparisons of the effects of CO2 oscillations at the same mean CO2 level, however, showed minute ventilation to be less with the larger amplitudes of oscillations than with smaller ones. Graphs of minute ventilation (V) versus mean CO2 for families of oscillation sizes (0.5%, 1% and 2%) showed that the ventilatory sensitivity (slop) was least for the 2% oscillations and greatest for the 0.5% oscillations. Therefore, a static model for the respiratory regulator is not adequate. However, the apneic level of CO2 (V = O intercept) was independent of the size of the CO2 oscillations.