Potassium and ventilation in exercise.

The drive to breathe in exercise is thought to result from a combination of neural and humoral factors, but the exact nature of the controlling signals is controversial. This review examines evidence suggesting that potassium could be a signal that drives ventilation (VE) in exercise. Potassium is lost from working muscle, which results in a marked hyperkalemia in the arterial plasma. The rise in potassium is directly proportional to the increase in carbon dioxide production during exercise and is also well correlated with VE in normal subjects and in subjects who do not produce acid (McArdle's syndrome). In the anesthetized and decerebrate cat, physiological levels of hyperkalemia stimulate VE by direct excitation of the peripheral arterial chemoreceptors, because surgical and chemical denervation of the chemoreceptors abolishes the increase in VE caused by potassium. The effect of hyperkalemia on chemoreceptor activity is further enhanced by hypoxia, but an abrupt switch to hyperoxia removes this effect. From these studies, it is suggested that potassium fulfills many of the criteria of being the special substance or "work factor" that was postulated over a century ago to stimulate VE in exercise. Although there is no direct proof that potassium causes an increase in breathing during exercise, circumstantial evidence strongly supports the idea that it should be considered as a stimulus to exercise hyperpnea.     

Temporal delay of venous blood correlates with onset of exercise hyperpnea

We tested the hypothesis that humoral factors contribute to the onset of exercise hyperpnea in an electrically induced model of isocapnic exercise in alpha-chloralose-anesthetized dogs. A cannula placed in the inferior vena cava (IVC) permitted hindlimb venous blood to flow either directly to the lungs or through a variable-length extracorporeal circuit. Mean transit times (MTT) of blood from exercising hindlimbs were measured from the arrival at the pulmonary artery of green dye injected into the saphenous vein. Onset of hyperpnea was determined by the half time of the ventilatory response (T 1/2), the time required to reach 50% of the steady-state ventilation. In seven dogs, T 1/2 was directly related to MTT (P less than 0.001), suggesting that blood-borne substances released at the onset of exercise contribute to the hyperpneic response. The T 1/2-MTT relation persisted following L2 cord transection (n = 4), suggesting that intraspinal afferents are not required for this response. Chemoreceptor denervation (n = 4) slowed the onset of exercise hyperpnea but did not alter the T 1/2-MTT relation. In this model of electrically induced "exercise" in which neurogenic influences have been minimized, humoral factors alone may stimulate ventilation sufficiently to produce arterial isocapnia.     

Cardiopulmonary control during exercise in the duck

To determine the importance of nonhumoral drives to exercise hyperpnea in birds, we exercised adult White Pekin ducks on a treadmill (3 degrees incline) at 1.44 km X h-1 for 15 min during unidirectional artificial ventilation. Intrapulmonary gas concentrations and arterial blood gases could be regulated with this ventilation procedure while allowing ventilatory effort to be measured during both rest and exercise. Ducks were ventilated with gases containing either 4.0 or 5.0% CO2 in 19% O2 (balance N2) at a flow rate of 12 l X min-1. At that flow rate, arterial CO2 partial pressure (PaCO2) could be maintained within +/- 2 Torr of resting values throughout exercise. Arterial O2 partial pressure did not change significantly with exercise. Heart rate, mean arterial blood pressure, and mean right ventricular pressure increased significantly during exercise. On the average, minute ventilation (used as an indicator of the output from the central nervous system) increased approximately 400% over resting levels because of an increase in both tidal volume and respiratory frequency. CO2-sensitivity curves were obtained for each bird during rest. If the CO2 sensitivity remained unchanged during exercise, then the observed 1.5 Torr increase in PaCO2 during exercise would account for only about 6% of the total increase in ventilation over resting levels. During exercise, arterial [H+] increased approximately 4 nmol X l-1; this increase could account for about 18% of the total rise in ventilation. We conclude that only a minor component of the exercise hyperpnea in birds can be accounted for by a humoral mechanism; other factors, possibly from muscle afferents, appear responsible for most of the hyperpnea observed in the running duck.     

Pulmonary control systems in exercise

We reviewed the response and regulation of alveolar ventilation, chest wall mechanics, and alveolar-to-arterial gas exchange to the demands imposed by increases in tissue metabolic rate. The primary mediator of iso-capnic exercise hyperpnea remains a dilemma--with conflicting evidence presented on both sides of a "CO2 flow" humoral hypothesis versus a "neurogenic" non-humoral hypothesis. The increased expiratory flows and tidal volumes at any given level of hyperpnea are achieved at a "minimum" of increased mechanical work exerted on the lung and chest wall, owing to a control system that has multiple levels of nervous integration (from cortex to spinal motor neuron) readily accessible to a wide variety of sensory information concerning the mechanical status of the lung and respiratory muscles. The maintenance of arterial PO2 in the face of a falling CVO2 during exercise was attributed to a precise regulation over factors that limit diffusion equilibrium and intra- and interregional ventilation: perfusion distributions in the lung. Finally, we noted that the near-optimal nature of these responses and their control during exercise had many exceptions in the real world of physical exercise outside of the laboratory.     

Cerebrospinal fluid acid-base balance during muscular exercise

Ventilation, metabolism, arterial blood gases, and blood and cerebrospinal fluid (CSF) acid-base status were measured in exercise studies on seven ponies during mild, moderate, and near-maximal treadmill exercise. CSF and arterial blood were sampled via indwelling catheters. Generally measurements were made during the 3rd, 6th, and 9th minute of steady-state exercise, with CSF sampled only during the 9th minute. Alveolar ventilation (VA) and metabolic rate (VO2) increased proportionately during exercise below the anaerobic threshold, but above this threshold, VA increased at a faster rate than VO2. The similarity of these response to those observed in man suggests the pony is a suitable animal model for study of exercise hyperpnea. No change in CSF acid-base balance occurred with light-to-moderate work; however, with near-maximal work a fall in CSF carbon dioxide partial pressure due to hyperventilation caused CSF to become alkaline (pH = 7.380) relative to rest (pH = 7.330). CSF lactate increased slightly with exercise but had no effect on CSF [HCO3-], which remained constant from rest to severe exercise. We conclude that it is unlikely the hyperpnea at any intensity of exercise results from an increased H+ stimulation at the medullary chemoreceptor.     

Greater serum GH response to arm than to leg exercise performed at equivalent oxygen uptake

The aim of this study was to provide information concerning the mechanism of exercise-induced stimulation of growth hormone (GH) release in human subjects. For this reason serum GH as well as some hemodynamic variables and blood concentrations of noradrenaline (NA), insulin (IRI), lactate (LA), glucose (BG), and free fatty acids (FFA) were determined in seven healthy male subjects exercising on a bicycle ergometer with arms or legs and running on a treadmill at equivalent oxygen consumption levels. Significantly greater increases in serum GH concentration accompanied arm exercises than those observed during the leg exercises. This was accompanied by greater increases in heart rate, blood pressure, and plasma NA and blood lactate concentrations. Serum IRI decreased during both leg exercises and did not change during the arm exercise. There were no differences in BG and plasma FFA concentrations between the three types of exercise. The role of humoral and neural signals responsible for the greater GH response to arm exercise is discussed. The findings are consistent with the hypothesis that neural afferent signals sent by muscle "metabolic receptors" participate in the activation of GH release during physical exercise. It seems likely that the stimulation of these chemoreceptors is more pronounced when smaller muscle groups are engaged at a given work load. However, a contribution of efferent impulses derived from the brain motor centres to the control system of GH secretion during exercise is also possible.     

Breathing pattern and metabolic behavior during anticipation of exercise

The mechanisms responsible for the marked increase in ventilation at the onset of exercise are incompletely defined. A conditioned response to exercise anticipation has been suggested as an influencing factor, but systematic measurements have not been made during the transition from rest to the time when exercise is anticipated but has not yet commenced. We tested the hypothesis that cortical activity associated with the anticipation of exercise causes hyperpnea, which is at least partly responsible for the increased ventilation at the onset of exercise. To assess the influence of continuous cortical activity in the absence of exercise anticipation the subjects performed mental arithmetic tasks. Fifteen subjects performed the two experiments in a random order. Ventilation was measured noninvasively using a calibrated respiratory inductive plethysmograph and end-tidal CO2 concentration (FETCO2) was monitored at the nasal vestibule. Both exercise anticipation and mental arithmetic caused an increase in minute ventilation (VI) (P less than 0.01) and mean inspiratory flow (VT/TI, P less than 0.01), which reflects respiratory center drive, although the derivation differed in that the former was volume based, whereas the latter was due to alteration in timing. Despite the increase in VI, FETCO2 remained constant in both instances. In a complementary study the constant FETCO2 in the face of increased VI was shown to be due to increased CO2 output. The results show that the mere anticipation of exercise causes an increase in ventilation. The mechanism responsible for this hyperpnea cannot be due solely to respiratory center activation because of the constancy of FETCO2 and the associated alterations in cardiac and metabolic behavior.     

Regulation of respiration during muscular exertion

A brief critical review of literature shows that many authors still follow a classical theory that the respiration control is performed by feedback (by deviation of PCO2, PO2 and pH in blood). This point of view does not account for the exercise hyperpnea. The present paper contains the various data and considerations which show that respiration during muscular exercise is controlled by a combined self-learning system. The system is based on both disturbance (open-loop) control and feedback control. The signals of disturbance (of central origin and from receptors of exercising muscles) cause the increase of respiration during exercise. The signals of deviations (from peripheral and central chemoreceptors) correct the response of respiratory centre to disturbance signals. The self-learning takes place by the formation of conditioned reflexes that ensures the control of respiration (the stability of gaseous composition of blood during exercise).     

Interactions between growth factor receptors and adhesion molecules: breaking the rules

Adhesion molecules, although catalytically inactive, are able to translate environmental cues into complex intracellular signals. They can do this by associating with tyrosine kinase receptors for growth factors, which can prime, integrate or feedback adhesion-based signals. Recent results show that reciprocal crosstalk between the two systems is only one facet of such a collaboration, and that unconventional and alternative hierarchies can be established in which, on the one hand, cell adhesion can trigger ligand-independent activation of growth factor receptors, and, on the other, growth factors can induce adhesion molecules to propagate adhesion-independent signals.     

Oxygen cost of exercise hyperpnea: measurement.

To quantitate the O2 cost of maximal exercise hyperpnea, we required eight healthy adult subjects to mimic, at rest, the important mechanical components of submaximal and maximal exercise hyperpnea. Expired minute ventilation (VE), transpulmonary and transdiaphragmatic (Pdi) pressures, and end-expiratory lung volume (EELV) were measured during exercise at 70 and 100% of maximal O2 uptake. At rest, subjects were given visual feedback of their exercise transpulmonary pressure-tidal volume loop (WV), breathing frequency, and EELV, which they mimicked repeatedly for 5 min per trial over several trials, while hypocapnia was prevented. The change in total body O2 uptake (VO2) was measured and presumed to represent the O2 cost of the hyperpnea. In 61 mimicking trials with VE of 115-167 l/min and WV of 124-544 J/min, VE, WV, duty cycle of the breath, and expiratory gastric pressure (Pga) integrated with respect to time (integral of Pga.dt/min) were not different from those observed during maximum exercise. integral of Pdi.dt/min was 14% less and EELV was 6% greater during maximum exercise than during mimicking. The O2 cost measurements within a subject were reproducible over 3-12 trials (coefficient of variation +/- 10% range 5-16%). The O2 costs of hyperpnea correlated highly and positively with VE and WV and less, but significantly, with integral of Pdi.dt and integral of Pga.dt. The O2 cost of VE rose out of proportion to the increasing hyperpnea, so that between 70 and 100% of maximal VO2 delta VO2/delta VE increased 40-60% (1.8 +/- 0.2 to 2.9 +/- 0.1 ml O2/l VE) as VE doubled.(ABSTRACT TRUNCATED AT 250 WORDS)     

Oxygen cost of exercise hyperpnea: implications for performance.

We addressed two questions concerned with the metabolic cost and performance of respiratory muscles in healthy young subjects during exercise: 1) does exercise hyperpnea ever attain a "critical useful level"? and 2) is the work of breathing (WV) at maximum O2 uptake (VO2max) fatiguing to the respiratory muscles? During progressive exercise to maximum, we measured tidal expiratory flow-volume and transpulmonary pressure- (Ptp) volume loops. At rest, subjects mimicked their maximum and moderate exercise Ptp-volume loops, and we measured the O2 cost of the hyperpnea (VO2RM) and the length of time subjects could maintain reproduction of their maximum exercise loop. At maximum exercise, the O2 cost of ventilation (VE) averaged 10 +/- 0.7% of the VO2max. In subjects who used most of their maximum reserve for expiratory flow and for inspiratory muscle pressure development during maximum exercise, the VO2RM required 13-15% of VO2max. The O2 cost of increasing VE from one work rate to the next rose from 8% of the increase in total body VO2 (VO2T) during moderate exercise to 39 +/- 10% in the transition from heavy to maximum exercise; but in only one case of extreme hyperventilation, combined with a plateauing of the VO2T, did the increase in VO2RM equal the increase in VO2T. All subjects were able to voluntarily mimic maximum exercise WV for 3-10 times longer than the duration of the maximum exercise. We conclude that the O2 cost of exercise hyperpnea is a significant fraction of the total VO2max but is not sufficient to cause a critical level of "useful" hyperpnea to be achieved in healthy subjects.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mechanical signal transduction in skeletal muscle growth and adaptation.

The adaptability of skeletal muscle to changes in the mechanical environment has been well characterized at the tissue and system levels, but the mechanisms through which mechanical signals are transduced to chemical signals that influence muscle growth and metabolism remain largely unidentified. However, several findings have suggested that mechanical signal transduction in muscle may occur through signaling pathways that are shared with insulin-like growth factor (IGF)-I. The involvement of IGF-I-mediated signaling for mechanical signal transduction in muscle was originally suggested by the observations that muscle releases IGF-I on mechanical stimulation, that IGF-I is a potent agent for promoting muscle growth and affecting phenotype, and that IGF-I can function as an autocrine hormone in muscle. Accumulating evidence shows that at least two signaling pathways downstream of IGF-I binding can influence muscle growth and adaptation. Signaling via the calcineurin/nuclear factor of activated T-cell pathway has been shown to have a powerful influence on promoting the slow/type I phenotype in muscle but can also increase muscle mass. Neural stimulation of muscle can activate this pathway, although whether neural activation of the pathway can occur independent of mechanical activation or independent of IGF-I-mediated signaling remains to be explored. Signaling via the Akt/mammalian target of rapamycin pathway can also increase muscle growth, and recent findings show that activation of this pathway can occur as a response to mechanical stimulation applied directly to muscle cells, independent of signals derived from other cells. In addition, mechanical activation of mammalian target of rapamycin, Akt, and other downstream signals is apparently independent of autocrine factors, which suggests that activation of the mechanical pathway occurs independent of muscle-mediated IGF-I release.     

Transient ventilatory and heart rate responses to moderate nonabrupt pseudorandom exercise

Dynamic responses of inspired minute ventilation, CO2 and O2 end-tidal gas fractions, and heart rate were obtained from six normal human volunteers in response to a complex dynamic exercise challenge. Subjects pedalled a chair ergometer at constant frequency. The retarding torque applied to the ergometer pedals was controlled by a low-pass-filtered pseudorandom binary sequence (fPRBS), which provided a complex, nonanticipatory exercise stimulus containing sufficient high- and low-frequency energy to excite the small signal, broadband ventilatory response. The exercise range was chosen to produce a mean level of O2 consumption at or below 50% maximum O2 consumption. Cross-covariant analysis of the fPRBS exercise with breath-by-breath ventilation provided an estimate of the dynamic (impulse) response to exercise, which contained both fast phase 1 and slow phase 2 components. The initial, phase one, hyperpnea occurred within the same breath as the exercise transition and preceded a hypocapnic response. The phase one hyperpnea represented 26% of the total ventilatory response. The secondary, phase 2, hyperpnea was delayed several breaths from the onset of phase 1. It contained slower dynamics and followed a hypercapnic response. Heart rate increased abruptly during phase 1, peaked near the phase 1-to-2 boundary, and then decreased rapidly. The experimental protocol was designed to minimize the subjective response and provide an adequate stimulus for the faster time constants. Results obtained from these experiments were consistent with a nonhumoral induced phase 1 exercise hyperpnea.     

Computer simulation of experiments in responses to intravenous and inhaled CO2

A simulation of ventilatory responses to infused and inhaled CO2 at controlled cardiac output and high and low levels of neural excitation mimics comparable experiments in animals. The model suggests that at low levels of endogenous and exogenous CO2 load the alert quiescent animal will show hyperpnea to both test states associated with hypercapnia. The nonalert quiescent animal simulated will show an isocapnic response to endogenous load and hypercapnic response to exogenous load. The explanation of this behavior lies in the model formulation, which allows the neural signal from metabolically active sources to drive the proportional component of the controller below an operating level established by its set point. By this reasoning the excited but metabolically inactive animal should be paradoxically less sensitive to small changes in CO2, whether exogenous or endogenous, than the quiescent animal. The model demonstrates further that a neural "exercise" signal in proportion to venous return better simulates observations in which CO2 load and venous return are dissociated than one in which the neural signal is computed from metabolism. The use of delta V/delta P slopes as estimates of sensitivity go awry in experiment and simulation when blood flow, CO2 level, and neural excitatory state are dissociated. This is particularly true when the organism is operating at and below the hypothesized set point.     

Effect of carotid body resection on ventilatory and acid-base control during exercise.

To investigate the role of the carotid bodies in exercise hyperpnea and acid-base control, normal and carotid body-resected subjects (CBR) were studied during constant-load and incremental exercise. There was no significant difference in the first-breath ventilatory responses to exercise between the groups; some subjects in each reproducibly exhibited abrupt responses. The subsequent change in Ve toward steady state was slower in the CBR group. The steady-state ventilatory responses were the same in both groups at work rates below the anaerobic threshold (AT). However, above the AT, the hyperpnea was less marked in the CBR group. Ve and acid-base measurements revealed that the CBR group failed to hyperventilate in response to the metabolic acidosis of either constant-load or incremental exercise. We conclude that the carotid bodies 1) are not responsible for the initial exercise hyperpnea, 2) do affect the time course of Ve to its steady state, and 3) are responsible for the respiratory compensation for the metabolic acidosis of exercise.     

The Insulin-Like Growth Factor (IGF) Receptor Type 1 (IGF1R) as an Essential Component of the Signalling Network Regulating Neurogenesis

The insulin-like growth factor receptor type 1 (IGF1R) signalling pathway is activated in the mammalian nervous system from early developmental stages. Its major effect on developing neural cells is to promote their growth and survival. This pathway can integrate its action with signalling pathways of growth and morphogenetic factors that induce cell fate specification and selective expansion of specified neural cell subsets. This suggests that during developmental and adult neurogenesis cellular responses to many signalling factors, including ligands of Notch, sonic hedgehog, fibroblast growth factor family members, ligands of the epidermal growth factor receptor, bone morphogenetic proteins and Wingless and Int-1, may be modified by co-activation of the IGF1R. Modulation of cell migration is another possible role that IGF1R activation may play in neurogenesis. Here, I briefly overview neurogenesis and discuss a role for IGF1R-mediated signalling in the developing and mature nervous system with emphasis on crosstalk between the signalling pathways of the IGF1R and other factors regulating neural cell development and migration. Studies on neural as well as on non-neural cells are highlighted because it may be interesting to test in neurogenic paradigms some of the models based on the information obtained in studies on non-neural cell types.