Adrenergic and local control of O2 uptake during and after severe hypoxia

The distribution of whole-body O2 supply during severe hypoxia and recovery and its relation to the regional distribution of O2 deficit and repayment was studied. Mongrel dogs were anesthetized, paralyzed, and ventilated to maintain an end-tidal PCO2 between 35 and 40 Torr. In one group, the alpha- and beta-adrenergic receptors were blocked to eliminate neural and humoral adrenergic influences. In a second group, alpha-adrenergic receptors were stimulated to decrease O2 delivery by excessive vasoconstriction. In a third group, beta-adrenergic receptors were stimulated to increase O2 delivery. Whole-body and hindlimb muscle O2 uptake and vascular responses were measured during normoxic control, 15 or 30 min of severe hypoxia (9% O2 in N2), and 20 or 30 min of normoxic recovery, respectively. The whole-body O2 deficit and excess O2 uptake in recovery were partitioned into muscle and nonmuscle areas. The data showed that neural or humoral influences had little effect on the regional distribution of the total O2 deficit and O2 excess in recovery. The O2 deficit could be decreased somewhat by increasing delivery, but the amount of excess O2 used in recovery was unaffected. This suggested that the excess O2 use in recovery was more a function of an energy deficit during hypoxia and not an O2 deficit.     

Regional O2 uptake during hypoxia and recovery in hypermetabolic dogs

The regional distribution of O2 deficit in muscle and nonmuscle tissues was measured in hypermetabolic dogs ventilated with a low inspired O2 fraction and was compared with excess O2 used in these regions during normoxic recovery. O2 uptake was stimulated by 2,4-dinitrophenol (DNP). Arterial, mixed venous, and muscle venous blood samples were drawn before, during, and after severe hypoxia (9% O2-91% N2) for the calculation of hindlimb O2 uptake and cardiac output. The O2 deficit and excess O2 uptake in recovery were calculated as the cumulative differences between normoxic control and respective hypoxic and recovery O2 uptake values. The DNP data were compared with data previously obtained in our laboratory. A greater whole-body O2 deficit was incurred in the DNP group during hypoxia and was associated with a larger O2 use in recovery. The total O2 deficit was equally distributed between muscle and nonmuscle tissues, but more excess O2 use occurred in nonmuscle tissues. The greater excess O2 used by nonmuscle tissues may have been associated with the restoration of intracellular ion concentrations brought about by the increased activity of energy-using membrane pumps.     

Regional hemodynamic responses to hypoxia and hypermetabolism in polycythemic dogs

Normovolemic polycythemia did not improve the ability of either resting muscle or gut to maintain O2 uptake (VO2) during severe hypoxia because of the adverse effects of increased viscosity on blood flow to those regions. The present study tested whether increased metabolic demand would promote vasodilation sufficiently to overcome those effects. We measured whole body, muscle, and gut blood flow, O2 extraction, and VO2 in anesthetized dogs after increasing hematocrit to 65% and raising O2 demand with 2,4-dinitrophenol (n = 8). We also tested whether regional denervation (n = 8) and hypervolemia (n = 6) affected these responses. After raising hematocrit and metabolism, the dogs were ventilated with air, with 9% O2-91% N2, and again with air for 30-min periods. Reduced blood flow and increased O2 demand, caused by increased blood viscosity and 2,4-dinitrophenol, respectively, increased O2 extraction so that muscle VO2 was nearly supply limited in normoxia. Denervation showed that vasoconstriction had increased in gut and muscle with hypoxia onset but this was overcome after 15 min. By then, muscle was receiving a major portion of cardiac output, whereas gut showed little change. With hypervolemia cardiac output increased in hypoxia but neither gut nor muscle increased blood flow in those experiments. Because regional and whole body VO2 fell in all groups during hypoxia to the same extent found earlier in normocythemic dogs, any real benefit of polycythemia under the conditions of these experiments was dubious at best.     

The role aortic chemoreceptors during severe CO hypoxia

The importance of aortic chemoreceptors in the circulatory responses to severe carbon monoxide (CO) hypoxia was studied in anesthetized dogs. The aortic chemoreceptors were surgically denervated in eight dogs prior to the induction of CO hypoxia, with nine other dogs serving as intact controls. Values for both whole body and hindlimb blood flow, vascular resistance, and O2 uptake were determined prior to and at 30 min of CO hypoxia in the two groups. Arterial O2 content was reduced 65% using an in situ dialysis method to produce CO hypoxia. At 30 min of hypoxia, cardiac output increased but limb blood flow remained at prehypoxic levels in both groups. This indicated that aortic chemoreceptor input was not necessary for the increase in cardiac output during severe CO hypoxia, nor for the diversion of this increased flow to nonmuscle tissues. Limb O2 uptake decreased during CO hypoxia in the aortic-denervated group but remained at prehypoxic levels in the intact group. The lower resting values for limb blood flow in the aortic-denervated animals required a greater level of O2 extraction to maintain resting O2 uptake. When CO hypoxia was superimposed upon this compensation, an O2 supply limitation occurred because the limb failed to vasodilate even as maximal levels for O2 extraction were approached.     

Metabolic and circulatory responses of normoxic skeletal muscle to whole-body hypoxia

Whole-body hypoxia may increase peripheral O2 demand because it increases catecholamine calorigenesis, an effect attributable to beta 2-adrenoceptors. We tested these possibilities by pump-perfusing innervated hindlimbs in eight dogs with autologous blood kept normoxic by a membrane oxygenator while ventilating the animals for 40 min with 9% O2 in N2 (NOB group). Similar periods of normoxic ventilation preceded and followed the hypoxic period. A second group (n = 8, beta B) was pretreated with the specific beta 2 blocker ICI 118,551. Hindlimb O2 uptake was elevated by 25 min of hypoxia in NOB, whereas whole-body O2 uptake was reduced. Limb O2 uptake remained elevated in recovery, but all effects on limb O2 uptake were absent in beta B. Hindlimb resistance and perfusion pressure increased in hypoxia in both groups, and there was little evidence of local escape from reflex vasoconstriction. These results clearly indicated that global hypoxia increased O2 demand in muscle when the local O2 supply was not limited and that beta 2-receptors were necessary for this response. Autoregulatory escape of limb muscle blood flow from centrally mediated vasoconstriction during whole-body hypoxia was also shown to be practically nil, if normoxia was maintained in the limb.     

Regional hemodynamic responses to hypoxia in polycythemic dogs

Polycythemia increases blood viscosity so that systemic O2 delivery (QO2) decreases and its regional distribution changes. We examined whether hypoxia, by promoting local vasodilation, further modified these effects in resting skeletal muscle and gut in anesthetized dogs after hematocrit had been raised to 65%. One group (CON, n = 7) served as normoxic controls while another (HH, n = 6) was ventilated with 9% O2--91% N2 for 30 min between periods of normoxia. Polycythemia decreased cardiac output so that QO2 to both regions decreased approximately 50% in both groups. In compensation, O2 extraction fraction increased to 65% in muscle and to 50% in gut. When QO2 was reduced further during hypoxia, blood flow increased in muscle but not in gut. Unlike previously published normocythemic studies, there was no initial hypoxic vasoconstriction in muscle. Metabolic vasodilation during hypoxia was enhanced in muscle when blood O2 reserves were first lowered by increased extraction with polycythemia alone. The increase in resting muscle blood flow during hypoxia with no change in cardiac output may have decreased O2 availability to other more vital tissues. In that sense and under these experimental conditions, polycythemia caused a maladaptive response during hypoxic hypoxia.     

Increased normoxic ventilation induced by repetitive hypoxia in conscious dogs.

To determine if a long-lasting increase in normoxic ventilatory drive is induced in conscious animals by repetitive hypoxia, we examined the normoxic [arterial O2 saturation (SaO2) > 93%] ventilatory response following successive episodes of 2-min eucapnic hypoxic challenges (SaO2 = 80%) in awake tracheotomized dogs. End-tidal CO2 was maintained at the resting level during and after repetitive hypoxia. The experimental protocol was performed twice in each of five dogs on separate days. To determine if changes in normoxic ventilation occurred between episodes of repetitive hypoxia, data were compared from six periods (epochs) for all experiments. The mean minute ventilation (VI) during three normoxic periods between episodes of intermittent hypoxia was 135, 154, and 169% of control (P < 0.05). VI during a 30-min recovery period was still higher at 183 and 172% of control (P < 0.05). Normoxic VI between hypoxic and recovery periods was significantly higher than the corresponding values in sham experiments. Our results indicate that a long-lasting increase in normoxic ventilation can be evoked in an awake unanesthetized dog by a short exposure to repetitive hypoxia.     

Muscle O2 deficit during hypoxia and two levels of O2 demand

We have examined the relative deficits in tension development and O2 uptake in contracting skeletal muscle during severe hypoxic hypoxia. Anesthetized mongrel dogs were ventilated to maintain an end-tidal PCO2 between 35 and 40 Torr. Venous outflow from the gastrocnemius muscle was measured using an electromagnetic flow probe. The tendon was cut and attached to a strain gauge. The muscle was stimulated to contract isometrically at 2 or 4 Hz for 20 min. Hypoxia (9% O2 in N2) was then imposed for 30 min, followed by 30 min of normoxia. Blood flow first increased in proportion to the contraction frequency and then increased further a similar amount in both groups during hypoxia. O2 extraction and blood flow reached maximal levels during hypoxia in the 2-Hz group. The further O2 deficit that was accumulated during 4 Hz and hypoxia was, therefore, a result of the greater discrepancy between O2 supply and demand. O2 uptake decreased more in hypoxia than did developed tension. These results are best explained by ATP supplementation from nonaerobic energy sources that was promoted by the free-flow condition of hypoxic hypoxia.     

Ventilatory responses to specific CNS hypoxia in sleeping dogs.

Our study was concerned with the effect of brain hypoxia on cardiorespiratory control in the sleeping dog. Eleven unanesthetized dogs were studied; seven were prepared for vascular isolation and extracorporeal perfusion of the carotid body to assess the effects of systemic [and, therefore, central nervous system (CNS)] hypoxia (arterial PO(2) = 52, 45, and 38 Torr) in the presence of a normocapnic, normoxic, and normohydric carotid body during non-rapid eye movement sleep. A lack of ventilatory response to systemic boluses of sodium cyanide during carotid body perfusion demonstrated isolation of the perfused carotid body and lack of other significant peripheral chemosensitivity. Four additional dogs were carotid body denervated and exposed to whole body hypoxia for comparison. In the sleeping dog with an intact and perfused carotid body exposed to specific CNS hypoxia, we found the following. 1) CNS hypoxia for 5-25 min resulted in modest but significant hyperventilation and hypocapnia (minute ventilation increased 29 +/- 7% at arterial PO(2) = 38 Torr); carotid body-denervated dogs showed no ventilatory response to hypoxia. 2) The hyperventilation was caused by increased breathing frequency. 3) The hyperventilatory response developed rapidly (<30 s). 4) Most dogs maintained hyperventilation for up to 25 min of hypoxic exposure. 5) There were no significant changes in blood pressure or heart rate. We conclude that specific CNS hypoxia, in the presence of an intact carotid body maintained normoxic and normocapnic, does not depress and usually stimulates breathing during non-rapid eye movement sleep. The rapidity of the response suggests a chemoreflex meditated by hypoxia-sensitive respiratory-related neurons in the CNS.     

Increased lactate appearance and reduced clearance during hypoxia in dogs

In order to assess the effects of severe hypoxia on whole body glucose and lactate kinetics, nine experiments were performed on anesthetized, ventilated mongrel dogs. [U-13C]glucose and [1-14C]lactate (n = 5), or [6-14C]glucose and [U-13C]lactate (n = 4) were infused using the primed-continuous infusion method. Cardiac output was measured by thermodilution. After a control period with 21% O2, inspired O2 was reduced for 90 minutes. Three of the experiments resulted in unstable hemodynamics and lactate levels, and are excluded from the mean data. Arterial PO2 fell from a control level of 106.8 +/- 11.9 to 24.2 +/- 3.5 mmHg during the last 45 minutes of hypoxia, and O2 transport fell to 52% of normoxic values. Arterial lactate concentration and the rate of appearance increased by 428% and 182%, respectively, from control to hypoxia. The metabolic clearance rate for lactate fell by 34%. Arterial glucose levels did not change significantly with hypoxia, but the rate of glucose disappearance rose by 70%, and the rate of glucose conversion to lactate increased 3-fold. It is concluded that acute severe hypoxia in anesthetized dogs causes 1) a large increase in arterial lactate levels, but no significant change in glycemia, 2) a large increase in the rate of lactate disappearance and only a small increase in the rate of glucose disappearance and 3) a fall in the metabolic clearance rate of lactate.     

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.     

Circulatory responses to 2,4-dinitrophenol in dog limb during normoxia and hypoxia

We tested whether blood flow to skeletal muscle would increase in proportion to an increase in O2 uptake caused by 2,4-dinitrophenol (DNP). We further tested the metabolic control in the face of a central challenge, hypoxic hypoxia. Three injections of DNP were made at 30-min intervals into the arterial supply of the left hindlimb in anesthetized dogs. Similar experiments were done on a second group of dogs ventilated with 12% O2-88% N2 (DNP and hypoxia). A third group served as time controls. Limb O2 uptake increased in a linear fashion in the DNP group with each injection. The increase in limb O2 uptake fell off with the second and third injections in the DNP and hypoxia group and appeared to be limited by the hypoxia. Limb blood flow increased only with the last injection in that group and not at all in the DNP group. Limb vascular resistance decreased in both the experimental groups relative to the time-related changes in the control group. This became more marked as the O2 extraction ratio exceeded 0.5. Even in the absence of nerve stimulation and active muscle contractions, both distribution and resistance control vessels responded in a coordinated fashion to an increase in O2 uptake. Mild hypoxia enhanced these responses but also appeared to limit a fraction of O2 uptake that may not have been concerned with maintaining tissue energy levels.     

Cellular disposition of transported polyamines in hypoxic rat lung and pulmonary arteries

The polyamines putrescine, spermidine (SPD), and spermine are a family of low-molecular-weight organic cations essential for cell growth and differentiation and other aspects of signal transduction. Hypoxic pulmonary vascular remodeling is accompanied by depressed lung polyamine synthesis and markedly augmented polyamine uptake. Cell types in which hypoxia induces polyamine transport in intact lung have not been delineated. Accordingly, rat lung and rat main pulmonary arterial explants were incubated with [(14)C]SPD in either normoxic (21% O(2)) or hypoxic (2% O(2)) environments for 24 h. Autoradiographic evaluation confirmed previous studies showing that, in normoxia, alveolar epithelial cells are dominant sites of polyamine uptake. In contrast, hypoxia was accompanied by prominent localization of [(14)C]SPD in conduit, muscularized, and partially muscularized pulmonary arteries, which was not evident in normoxic lung tissue. Hypoxic main pulmonary arterial explants also exhibited substantial increases in [(14)C]SPD uptake relative to control explants, and autoradiography revealed that enhanced uptake was most evident in the medial layer. Main pulmonary arterial explants denuded of endothelium failed to increase polyamine transport in hypoxia. Conversely, medium conditioned by endothelial cells cultured in hypoxic, but not in normoxic, environments enabled hypoxic transport induction in denuded arterial explants. These findings in arterial explants were recapitulated in rat cultured main pulmonary artery cells, including the enhancing effect of a soluble endothelium-derived factor(s) on hypoxic induction of [(14)C]SPD uptake in smooth muscle cells. Viewed collectively, these results show in intact lung tissue that hypoxia enhances polyamine transport in pulmonary artery smooth muscle by a mechanism requiring elaboration of an unknown factor(s) from endothelial cells.     

Changes in the peptidergic innervation in the carotid body of rats chronically exposed to hypercapnic hypoxia: an effect of arterial CO2 tension

The abundance of neuropeptide Y (NPY)-, vasoactive intestinal polypeptide (VIP)-, substance P (SP)-, and calcitonin gene-related peptide (CGRP)-immunoreactive nerve fibers in the carotid body was examined in chronically hypercapnic hypoxic rats (10% O2 and 6-7% CO2 for 3 months), and the distribution and abundance of these four peptidergic fibers were compared with those of previously reported hypocapnic- and isocapnic hypoxic carotid bodies to evaluate the effect of arterial CO2 tension. The vasculature in the carotid body of chronically hypercapnic hypoxic rats was found to be enlarged in comparison with that of normoxic control rats, but the rate of vascular enlargement was smaller than that in the previously reported hypocapnic- and isocapnic hypoxic carotid bodies. In the chronically hypercapnic hypoxic carotid body, the density per unit area of parenchymal NPY fibers was significantly increased, and that of VIP fibers was unchanged, although the density of NPY and VIP fibers in the previously reportetd chronically hypocapnic and isocapnic hypoxic carotid bodies was opposite to that in hypercapnic hypoxia as observed in this study. The density of SP and CGRP fibers was decreased. These results along with previous reports suggest that different levels of arterial CO2 tension change the peptidergic innervation in the carotid body during chronically hypoxic exposure, and altered peptidergic innervation of the chronically hypercapnic hypoxic carotid body is one feature of hypoxic adaptation.     

Anaerobic energy provision does not limit Wingate exercise performance in endurance-trained cyclists.

The aim of this study was to evaluate the effects of severe acute hypoxia on exercise performance and metabolism during 30-s Wingate tests. Five endurance- (E) and five sprint- (S) trained track cyclists from the Spanish National Team performed 30-s Wingate tests in normoxia and hypoxia (inspired O(2) fraction = 0.10). Oxygen deficit was estimated from submaximal cycling economy tests by use of a nonlinear model. E cyclists showed higher maximal O(2) uptake than S (72 +/- 1 and 62 +/- 2 ml x kg(-1) x min(-1), P < 0.05). S cyclists achieved higher peak and mean power output, and 33% larger oxygen deficit than E (P < 0.05). During the Wingate test in normoxia, S relied more on anaerobic energy sources than E (P < 0.05); however, S showed a larger fatigue index in both conditions (P < 0.05). Compared with normoxia, hypoxia lowered O(2) uptake by 16% in E and S (P < 0.05). Peak power output, fatigue index, and exercise femoral vein blood lactate concentration were not altered by hypoxia in any group. Endurance cyclists, unlike S, maintained their mean power output in hypoxia by increasing their anaerobic energy production, as shown by 7% greater oxygen deficit and 11% higher postexercise lactate concentration. In conclusion, performance during 30-s Wingate tests in severe acute hypoxia is maintained or barely reduced owing to the enhancement of the anaerobic energy release. The effect of severe acute hypoxia on supramaximal exercise performance depends on training background.     

Effect of regional alveolar hypoxia on gas exchange in dogs

We studied the effects of left lower lobe (LLL) alveolar hypoxia on pulmonary gas exchange in anesthetized dogs using the multiple inert gas elimination technique (MIGET). The left upper lobe was removed, and a bronchial divider was placed. The right lung (RL) was continuously ventilated with 100% O2, and the LLL was ventilated with either 100% O2 (hyperoxia) or a hypoxic gas mixture (hypoxia). Whole lung and individual LLL and RL ventilation-perfusion (VA/Q) distributions were determined. LLL hypoxia reduced LLL blood flow and increased the perfusion-related indexes of VA/Q heterogeneity, such as the log standard deviation of the perfusion distribution (log SDQ), the retention component of the arterial-alveolar difference area [R(a-A)D], and the retention dispersion index (DISPR*) of the LLL. LLL hypoxia increased blood flow to the RL and reduced the VA/Q heterogeneity of the RL, indicated by significant reductions in log SDQ, R(a-A)D, and DISPR*. In contrast, LLL hypoxia had little effect on gas exchange of the lung when evaluated as a whole. We conclude that flow diversion induced by regional alveolar hypoxia preserves matching of ventilation to perfusion in the whole lung by increasing gas exchange heterogeneity of the hypoxic region and reducing heterogeneity in the normoxic lung.     

Hindlimb vascular responses to sympathetic augmentation during acute anemia

The effect of increased sympathetic activity on skeletal muscle blood flow during acute anemic hypoxia was studied in 16 anesthetized dogs. Sympathetic activity was altered by clamping the carotid arteries bilaterally below the carotid sinus. One group (n = 8) was beta blocked by administration of propranolol (1 mg/kg); a second group (n = 8) was untreated. Venous outflow from the left hindlimb was isolated for measurement of blood flow and O2 uptake (VO2). After a 20-min control period, both carotid arteries were clamped (CC) for 20 min followed by a 20-min recovery period. The sequence was repeated after hematocrit was lowered to about 15% by dextran exchange for blood. Prior to anemia, CC did not alter cardiac output or limb blood flow in either group. After induction of anemia, hindlimb resistance was higher with CC in the beta block than in the no block group. Both limb blood flow and VO2 fell in the beta-block group with CC during anemia. Beta block also prevented the additive increases in whole body VO2 seen with CC and induction of anemia. The data showed that the increased vasoconstrictor tone that was obtained with beta block during anemia was successful in redistributing the lower viscosity blood away from resting skeletal muscle, even to the point that muscle VO2 was decreased.     

Hypoxia-induced changes in shivering and body temperature

Experiments were carried out on conscious cats to evaluate the general characteristics and modes of action of hypoxia on thermoregulation during cold stress. Intact and carotid-denervated (CD) conscious cats were exposed to ambient hypoxia (low inspired O2 fraction) or CO hypoxia in prevailing laboratory (23-25 degrees C) or cold (5-8 degrees C) environments. In the cold, both groups promptly decreased shivering and body temperature when exposed to either type of hypoxia. Small increases in CO2 concentration reinstituted shivering in both groups. At the same inspired concentration of O2, CD animals decreased shivering and body temperature more than intact cats. While this difference resulted, in part, from a lower alveolar PO2 in CD cats, a difference between intact and CD cats was apparent when the two groups were compared at the same alveolar PO2. During more prolonged hypoxia (45 min), shivering returned but did not reach normoxic levels, and body temperature tended to stabilize at a hypothermic value. Exposure to various levels of hypoxia produced graded suppression of shivering, with the result that the change in body temperature varied directly with inspired O2 concentration. Hypoxia appears to act on the central nervous system to suppress shivering and sinus nerve afferents appear to counteract this direct effect of hypoxia. In intact cats, this counteraction appears to be sufficient to maintain body temperature under hypoxic conditions at room temperature but not in the cold.     

Effects of exercise in normoxia and acute hypoxia on respiratory muscle metabolites

We determined changes in rat plantaris, diaphragm, and intercostal muscle metabolites following exercise of various intensities and durations, in normoxia and hypoxia (FIO2 = 0.12). Marked alveolar hyperventilation occurred during all exercise conditions, suggesting that respiratory muscle motor activity was high. [ATP] was maintained at rest levels in all muscles during all normoxic and hypoxic exercise bouts, but at the expense of creatine phosphate (CP) in plantaris muscle and diaphragm muscle following brief exercise at maximum O2 uptake (VO2max) in normoxia. In normoxic exercise plantaris [glycogen] fell as exercise exceeded 60% VO2max, and was reduced to less than 50% control during exhaustive endurance exercise (68% VO2max for 54 min and 84% for 38 min). Respiratory muscle [glycogen] was unchanged at VO2max as well as during either type of endurance exercise. Glucose 6-phosphate (G6P) rose consistently during heavy exercise in diaphragm but not in plantaris. With all types of exercise greater than 84% VO2max, lactate concentration ([LA]) in all three muscles rose to the same extent as arterial [LA], except at VO2max, where respiratory muscle [LA] rose to less than half that in arterial blood or plantaris. Exhaustive exercise in hypoxia caused marked hyperventilation and reduced arterial O2 content; glycogen fell in plantaris (20% of control) and in diaphragm (58%) and intercostals (44%). We conclude that respiratory muscle glycogen stores are spared during exhaustive exercise in the face of substantial glycogen utilization in plantaris, even under conditions of extreme hyperventilation and reduced O2 transport. This sparing effect is due primarily to G6P inhibition of glycogen phosphorylase in diaphragm muscle. The presence of elevated [LA] in the absence of glycogen utilization suggests that increased lactate uptake, rather than lactate production, occurred in the respiratory muscles during exhaustive exercise.     

Nitric oxide contributes to right coronary vasodilation during systemic hypoxia

As arterial partial pressure of O(2) (Pa(O(2))) is reduced during systemic hypoxia, right ventricular (RV) work and myocardial O(2) consumption (MVo(2)) increase. Mechanisms responsible for maintaining RV O(2) demand/supply balance during hypoxia have not been delineated. To address this problem, right coronary (RC) blood flow and RV O(2) extraction were measured in nine conscious, instrumented dogs exposed to normobaric hypoxia. Catheters were implanted in the right ventricle for measuring pressure, in the ascending aorta for measuring arterial pressure and for sampling arterial blood, and in an RC vein. A flow transducer was placed around the RC artery. After recovery from surgery, dogs were exposed to hypoxia in a chamber ventilated with N(2), and blood samples and hemodynamic data were collected as chamber O(2) was reduced progressively to approximately 8%. After control measurements were made, the chamber was opened and the dog was allowed to recover. N(omega)-nitro-L-arginine (L-NNA) was then administered (35 mg/kg, via RV catheter) to inhibit nitric oxide (NO) production, and the hypoxia protocol was repeated. RC blood flow increased during hypoxia due to coronary vasodilation, because RC conductance increased from 0.65 +/- 0.05 to 1.32 +/- 0.12 ml x min(-1) x 100 g(-1) x L-NNA blunted the hypoxia-induced increase in RC conductance. RV O(2) extraction remained constant at 64 +/- 4% as Pa(O(2)) was decreased, but after L-NNA, extraction increased to 70 +/- 3% during normoxia and then to 78 +/- 3% during hypoxia. RV MVo(2) increased during hypoxia, but after L-NNA, MVo(2) was lower at any respective Pa(O(2)). The relationship between heart rate times RV systolic pressure (rate-pressure product) and RV MVo(2) was not altered by l-NNA. To account for L-NNA-mediated decreases in RV MVo(2), O(2) demand/supply variables were plotted as functions of MVo(2). Slope of the conductance-MVo(2) relationship was depressed by L-NNA (P = 0.03), whereas the slope of the extraction-MVo(2) relationship increased (P = 0.003). In summary, increases in RV MVo(2) during hypoxia are met normally by increasing RC blood flow. When NO synthesis is blocked, the large RV O(2) extraction reserve is mobilized to maintain RV O(2) demand/supply balance. We conclude that NO contributes to RC vasodilation during systemic hypoxia.