Contribution of prostaglandins to the dilation that follows isometric forearm contraction in human subjects: effects of aspirin and hyperoxia.

In 11 healthy volunteers, we evaluated, in a double-blind crossover study, whether the vasodilation that follows isometric contraction is mediated by prostaglandins (PGs) and/or is O2 dependent. Subjects performed isometric handgrip for 2 min at 60% maximal voluntary contraction (MVC), after pretreatment with placebo or aspirin (600 mg orally), when breathing air or 40% O2. Forearm blood flow was measured in the dominant forearm by venous occlusion plethysmography. Arterial blood pressure was also recorded, allowing calculation of forearm vascular conductance (FVC; forearm blood flow/arterial blood pressure). During air breathing, aspirin significantly reduced the increase in FVC that followed contraction at 60% MVC: from a baseline of 0.09 +/- 0.011 [mean +/- SE, conductance units (CU)], the peak value was reduced from 0.24 +/- 0.03 to 0.14 +/- 0.01 CU. Breathing 40% O2 similarly reduced the increase in FVC relative to that evoked when breathing air; the peak value was 0.24 +/- 0.03 vs. 0.15 +/- 0.02 CU. However, after aspirin, breathing 40% O2 had no further effect on the contraction-evoked increase in FVC (the peak value was 0.15 +/- 0.02 vs. 0.16 +/- 0.02 CU). Thus the present study indicates that prostaglandins make a substantial contribution to the peak of the vasodilation that follows isometric contraction of forearm muscles at 60% MVC. Given that hyperoxia similarly reduced the vasodilation and attenuated the effect of aspirin, we propose that the stimulus for prostaglandin synthesis and release is hypoxia of the endothelium.     

Collateral sources of costal and crural diaphragmatic blood flow

We measured the contribution of aortic, internal mammary, and intercostal arteries to the blood flow to the costal and crural segments of the diaphragm and other respiratory muscles in seven dogs breathing against a fixed inspiratory elastic load. We used radiolabeled microspheres to measure the blood flow with control circulation, occlusion of the aorta distal to the left subclavian artery, combined occlusion of the aorta and both internal mammary arteries, and occlusion of internal mammary arteries alone. With occlusion of the aorta distal to the left subclavian artery, blood flow to the crural diaphragm decreased from 40.3 to 23.5 ml . min-1 X 100 g-1, whereas costal flow did not change significantly (from 41.7 to 38.1 ml . min-1 . 100 g-1). Blood flows to the sternomastoid and scalene muscles (above the occlusion) increased by 200 and 340%, respectively, whereas flows to the other respiratory muscles did not change significantly. Blood flows to organs above the occlusion either remained unchanged or increased, whereas flows to those below the occlusion all decreased. When the internal mammary artery was also occluded, flows to the crural segment decreased further to 12.1 and costal flow decreased to 20.4 ml X min-1 X 100 g-1. Internal mammary arterial occlusion alone in two dogs had no effect on diaphragmatic flow. In conclusion, intercostal collateral vessels are capable of supplying a significant proportion of blood flow to both segments of the diaphragm but the costal segment is better served than the crural segment.     

Respiratory muscle blood flow in exercising dogs after pneumonectomy.

In three foxhounds after left pneumonectomy, the relationships of ventilatory work and respiratory muscle (RM) blood flow to ventilation (VE) during steady-state exercise were examined. VE was measured using a specially constructed respiratory mask and a pneumotach; work of breathing was measured by the esophageal balloon technique. Blood flow to RM was measured by the radionuclide-labeled microsphere technique. Lung compliance after pneumonectomy was 55% of that before pneumonectomy; compliance of the thorax was unchanged. O2 uptake (VO2) of RM comprised only 5% of total body VO2 at exercise. At rest, inspiratory muscles received 62% and expiratory muscles 38% of the total O2 delivered to the RM (QO2RM). During exercise, inspiratory muscles received 59% and expiratory muscles 41% of total QO2RM. Blood flow per gram of muscle to the costal diaphragm was significantly higher than that to the crural diaphragm. The diaphragm, parasternals, and posterior cricoarytenoids were the most important inspiratory muscles, and internal intercostals and external obliques were the most important expiratory muscles for exercise. Up to a VE of 120 l/min through one lung, QO2RM constituted only a small fraction of total body VO2 during exercise and maximal vasodilation in the diaphragm was never approached.     

Ratio of active to passive muscle shortening in the canine diaphragm.

Active and passive shortening of muscle bundles in the canine diaphragm were measured with the objective of testing a consequence of the minimal-work hypothesis: namely, that the ratio of active to passive shortening is the same for all active muscles. Lengths of six muscle bundles in the costal diaphragm and two muscle bundles in the crural diaphragm of each of four bred-for-research beagle dogs were measured by the radiopaque marker technique during the following maneuvers: a passive deflation maneuver from total lung capacity to functional residual capacity, quiet breathing, and forceful inspiratory efforts against an occluded airway at different lung volumes. Shortening per liter increase in lung volume was, on average, 70% greater during quiet breathing than during passive inflation in the prone posture and 40% greater in the supine posture. For the prone posture, the ratio of active to passive shortening was larger in the ventral and midcostal diaphragm than at the dorsal end of the costal diaphragm. For both postures, active shortening during quiet breathing was poorly correlated with passive shortening. However, shortening during forceful inspiratory efforts was highly correlated with passive shortening. The average ratios of active to passive shortening were 1.23 +/- 0.02 and 1.32 +/- 0.03 for the prone and supine postures, respectively. These data, taken together with the data reported in the companion paper (T. A. Wilson, M. Angelillo, A. Legrand, and A. De Troyer, J. Appl. Physiol. 87: 554-560, 1999), support the hypothesis that, during forceful inspiratory efforts, the inspiratory muscles drive the chest wall along the minimal-work trajectory.     

Effects of exercise training on coronary transport capacity

Coronary transport capacity was estimated in eight sedentary control and eight exercise-trained anesthetized dogs by determining the differences between base line and the highest coronary blood flow and permeability-surface area product (PS) obtained during maximal adenosine vasodilation with coronary perfusion pressure constant. The anterior descending branch of the left coronary artery was cannulated and pump-perfused under constant-pressure conditions (approximately equal to 100 Torr) while aortic, central venous, and coronary perfusion pressures, heart rate, electrocardiogram, and coronary flow were monitored. Myocardial extraction and PS of 51Cr-labeled ethylenediaminetetraacetic acid were determined with the single-injection indicator-diffusion method. The efficacy of the 16 +/- 1 wk exercise training program was shown by significant increases in the succinate dehydrogenase activities of the gastrocnemius, gluteus medialis, and long head of triceps brachii muscles. There were no differences between control and trained dogs for either resting coronary blood flow or PS. During maximal vasodilation with adenosine, the trained dogs had significantly lower perfusion pressures with constant flow and, with constant-pressure vasodilation, greater coronary blood flow and PS. It is concluded that exercise training in dogs induces an increased coronary transport capacity that includes increases in coronary blood flow capacity (26% of control) and capillary diffusion capacity (82% of control).     

Respiratory muscle and organ blood flow with inspiratory elastic loading and shock

Since respiratory muscles fail when blood flow is inadequate, we asked whether their blood flow would be maintained in severe hypotensive states at the expense of other vital organs (brain, heart, kidney, gut, spleen). We measured blood flow (radiolabeled microspheres) to respiratory muscles and vital organs in 11 dogs breathing against an inspiratory elastic load, first with normal blood pressure (BP) and then hypotension produced by cardiac tamponade. With the elastic load alone, there was no change in BP or cardiac output; diaphragmatic blood flow (Qdi) increased from 12.8 +/- 7.0 to 34.1 +/- 15.6 ml/100 g, and total respiratory muscle flow (QTR) increased from 56.5 +/- 19.1 to 97.4 +/- 36.5 ml/100 g, but except for the brain, there was no change in blood flow to other organs. With tamponade (mean BP = 79 +/- 16 mmHg), flow decreased to all organs, whereas Qdi (39.0 +/- 19.4) did not change. QTR decreased, but not significantly, to 88.6 +/- 49.5. With more tamponade (mean BP = 53 +/- 13 mmHg), flow to all vital organs decreased as well as QTR (57.9 +/- 47.18), but Qdi did not significantly decrease and had the same relationship to respiratory force as with normal BP. Thus, with severe inspiratory elastic loading and severe hypotension, the diaphragm and external intercostal muscles did most of the respiratory work, and their flow was maintained at the expense of other vital organs.     

The marine mammal dive response is exercise modulated to maximize aerobic dive duration

When aquatically adapted mammals and birds swim submerged, they exhibit a dive response in which breathing ceases, heart rate slows, and blood flow to peripheral tissues and organs is reduced. The most intense dive response occurs during forced submersion which conserves blood oxygen for the brain and heart, thereby preventing asphyxiation. In free-diving animals, the dive response is less profound, and energy metabolism remains aerobic. However, even this relatively moderate bradycardia seems diametrically opposed to the normal cardiovascular response (i.e., tachycardia and peripheral vasodilation) during physical exertion. As a result, there has been a long-standing paradox regarding how aquatic mammals and birds exercise while submerged. We hypothesized based on cardiovascular modeling that heart rate must increase to ensure adequate oxygen delivery to active muscles. Here, we show that heart rate (HR) does indeed increase with flipper or fluke stroke frequency (SF) during voluntary, aerobic dives in Weddell seals (HR?=?1.48SF?-?8.87) and bottlenose dolphins (HR?=?0.99SF?+?2.46), respectively, two marine mammal species with different evolutionary lineages. These results support our hypothesis that marine mammals maintain aerobic muscle metabolism while swimming submerged by combining elements of both dive and exercise responses, with one or the other predominating depending on the level of exertion.     

Differentiated interaction of hypothalamic and bulbar mechanisms in regulating blood flow in skeletal muscles

Acute experiments on dogs anesthetized with chloralose and numbutal were made to examine the changes in the blood flow in the muscles of hind limbs in response to stimulation of different parts of the hypothalamus before and after elimination of the effects of the main reflexogenic zones. Vasodilatation in leg muscles evoked by stimulation of the anterior hypothalamus (supraoptic dorso- and ventro-medial nuclei) increased after elimination of baroceptor effects. Qualitatively, the same response evoked by stimulation of the mamillary nuclei diminished. A conclusion has been made about differential interaction of the hypothalamic and bulbar mechanisms in muscle circulation control. It is assumed that vasodilatation of the skeletal muscles evoked by stimulation of the posterior hypothalamus might be determined by reflex inhibition of the vascular tone.     

Effect of head-down tilt on respiratory responses and human inspiratory muscle activity

The effect of a head-down tilt on the responses of the external respiration system and the functional capacity of the diaphragm and parasternal muscles were investigated in 11 healthy subjects. A 30-min head-down tilt posture (−30° relative to the horizontal) significantly increased the inspiratory time, decreased the respiration rate and the inspiratory and expiratory flow rates; and increased the airway resistance compared to these values in the vertical posture. There were no significant changes in tidal volume or minute ventilation. The electromyograms (EMGs) of the diaphragm and parasternal muscles showed that the constant values of tidal volume and minute ventilation during head-down tilt could be provided by an increase in the electric activity of the thoracic inspiratory muscles. It was established that the contribution of the thoracic inspiratory muscles increased, while the diaphragms’ contribution decreased, during patient, spontaneous breathing. The maximal inspiratory effort (Muller’s maneuver) during a head-down tilt evoked the opposite EMG-activity pattern: the contribution of inspiratory thoracic muscles was decreased and the diaphragm EMG activity was increased compared to the vertical posture. These results suggest that coordinated modulations in inspiratory muscle activity make it possible to preserve the functional reserve of human inspiratory muscles during a short-term head-down tilt.     

Coronary and systemic vascular response to inspiratory resistive breathing.

To evaluate the coronary and systemic cardiovascular response to graded inspiratory resistive breathing, seven dogs were studied 2-4 wk after chronic instrumentation to measure circumflex coronary artery and ascending aortic blood flows as well as aortic and left ventricular (LV) blood pressures. The experiments were performed under chloralose anesthesia (to exclude any confounding emotional effects by dyspnea on cardiovascular variables) and hyperoxic conditions (to prevent chemoreflex activation by hypoxemia). In a randomized fashion, the dogs were subjected to graded inspiratory resistive breathing (spontaneous breathing alone and moderate and severe resistive loading, corresponding to resistances of approximately 0, 40, and 110 cmH2O.s.l-1, respectively). Each run lasted 10 min. Compared with mechanical ventilation with the respiratory muscles at rest, spontaneous breathing alone and moderate and severe inspiratory resistive loading induced pronounced and significant increases in circumflex coronary blood flow (19, 32, and 62%, respectively), which were almost exclusively accounted for by significant decrements in coronary vascular resistance and were paralleled (r = 0.88, P less than 0.0001) by significant increments (18, 31, and 57%) in heart rate transmural-aortic pressure product, an indicator of LV myocardial O2 demand. An increase in myocardial O2 consumption during resistive breathing was confirmed by analysis of coronary sinus blood samples in additional experiments (n = 3). Cardiac output significantly increased (10, 14, and 35%) because of increases in heart rate (15, 24, and 49%), with LV stroke volume and diastolic dimensions remaining unchanged.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of bronchoconstriction on respiratory muscle activity during expiration

The effect of methacholine-induced bronchoconstriction on the electrical activity of respiratory muscles during expiration was studied in 12 anesthetized spontaneously breathing dogs. Before and after aerosols of methacholine, diaphragm, parasternal intercostal, internal intercostal, and external oblique electromyograms were recorded during 100% O2 breathing and CO2 rebreathing. While breathing 100% O2, five dogs showed prolonged electrical activity of the diaphragm and parasternal intercostals in early expiration, postinspiratory inspiratory activity (PIIA). Aerosols of methacholine increased pulmonary resistance, decreased tidal volume, and elevated arterial PCO2. During bronchoconstriction, when PCO2 was varied by CO2 rebreathing, PIIA was shorter at low levels of PCO2, and external oblique and internal intercostal were higher at all levels of PCO2. Vagotomy shortened PIIA in dogs with prolonged PIIA. After vagotomy, methacholine had no effects on PIIA but continued to increase external oblique and internal intercostal activity at all levels of PCO2. These findings indicate that bronchoconstriction influences PIIA through a vagal reflex but augments expiratory activity, at least in part, by extravagal mechanisms.     

Electrical activation of expiratory muscles increases with time in pentobarbital-anesthetized dogs.

Although the pentobarbital-anesthetized dog is often used as a model in studies of respiratory muscle activity during spontaneous breathing, there is no information regarding the stability of the pattern of breathing of this model over time. The electromyograms of several inspiratory and expiratory muscle groups were measured in six dogs over a 4-h period by use of chronically implanted electrodes. Anesthesia was induced with pentobarbital sodium (25 mg/kg iv), with supplemental doses to maintain constant plasma pentobarbital concentrations. Phasic electrical activity increased over time in the triangularis sterni, transversus abdominis, and external oblique muscles (expiratory muscles). The electrical activity of the costal diaphragm, crural diaphragm, and parasternal intercostal muscles (inspiratory muscles) was unchanged. These changes in electrical activity occurred despite stable plasma levels of pentobarbital and arterial PCO2. They were associated with changes in chest wall motion and an increased tidal volume with unchanged breathing frequency. We conclude that expiratory muscle groups are selectively activated with time in pentobarbital-anesthetized dogs lying supine. Therefore the duration of anesthesia is an important variable in studies using this model.     

Breathing strategy of the adult horse (Equus caballus) at rest

To investigate the mechanism underlying the polyphasic airflow pattern of the equine species, we recorded airflow, tidal volum, rib cage and abdominal motion, and the sequence of activation of the diaphragm, intercostal, and abdominal muscles during quiet breathing in nine adult horses standing at rest. In addition, esophageal, abdominal, and transdiaphragmatic pressures were simultaneously recorded using balloon-tipped catheters. Analysis of tidal flow-volume loops showed that, unlike humans, the horse at rest breathes around, rather than from, the relaxed volume of the respiratory system (Vrx). Analysis of the pattern of electromyographic activities and changes in generated pressures during the breathing cycle indicate that the first part of expiration is passive, as in humans, with deflation toward Vrx, but subsequent abdominal activity is responsible for a second phase of expiration: active deflation to below Vrx. From this end-expiratory volume, passive inflation occurs toward Vrx, followed by a second phase of inspiration: active inflation to above Vrx, brought about by inspiratory muscle contraction. Under these conditions the abdominal muscles appear to share the principal pumping duties with the diaphragm. Adoption of this breathing strategy by the horse may relate to its peculiar thoracoabdominal anatomic arrangement and to its very low passive chest wall compliance. We conclude that there is a passive and active phase to both inspiration and expiration due to the coordinated action of the respiratory pump muscles responsible for the resting adult horse's biphasic inspiratory and expiratory airflow pattern. This unique breathing pattern perhaps represents a strategy of minimizing the high elastic work of breathing in this species, at least at resting breathing frequencies.     

Pressure-flow relations of diaphragm and vital organs with nitroprusside-induced vasodilatation

We determined maximal conductance in the diaphragm and other vital organs in 14 anesthetized dogs, weighing 22.8 +/- 4.2 kg, which were given maximal vasodilating doses of nitroprusside (mean dose 13.9 +/- 4.3 micrograms X kg-1 X min-1) and the blood pressure was lowered in stages by hemorrhage. Blood flow in the diaphragm, brain, heart, kidney, gut, and quadriceps was measured with radiolabeled microspheres. To ensure maximal vasodilatation of diaphragmatic vessels, we stimulated the phrenic nerves to produce diaphragmatic contractions at 0.3 Hz. The mean cardiac output was 2.13 +/- 0.42 l/min (thermodilution) before nitroprusside and 4.68 +/- 1.45 after (P less than 0.001). Nitroprusside failed to break the autoregulation of the brain. Pressure-flow relations (P-F) in other regions were linear (r = 0.70 +/- 0.03, P less than 0.001) and blood pressure at zero flow (X-intercept) was always greater than venous pressure (diaphragm = 11, kidney = 19, heart = 8, gut = 8, quadriceps = 32 mmHg). The flow to the diaphragm (Qdi) could be predicted by Qdi (ml X min-1 X g-1) = [(3.13 +/- 0.56) X Pa X 10(-2)] -0.52 (r = 0.71), where Pa is mean arterial pressure. The maximal vascular conductance (i.e., slope of the P-F relation) of the diaphragm was 27% of the conductance in the kidney, 87% of the value in the gut, and 42% of that in the heart. In conclusion the maximal diaphragmatic blood flow at a given blood pressure is much larger when the muscle is stimulated than is observed in spontaneously breathing animals.     

Does the pressor response to ischemic exercise improve blood flow to contracting muscles in humans?

The purpose of this study was to determine in humans 1) the gain for the reflex pressor response that occurs when perfusion pressure to rhythmically contracting muscles is reduced and 2) whether the pressor response improves blood flow to the contracting muscles. Six normal subjects performed light, moderate, and heavy rhythmic forearm contractions (30/min) with the forearm enclosed in a Plexiglas box. Pressure in the box was increased 10 mmHg each minute up to 50 mmHg to reduce transmural pressure in the arterial system of the forearm. Mean arterial pressure (MAP) was measured continuously. During light exercise no reflex increase in MAP occurred until box pressure was 50 mmHg. During moderate and heavy exercise MAP began to increase with only 10- to 20-mmHg increases in box pressure. The slope of this increase was 3.5-3.9 mmHg per 10 mmHg of box pressure (approximately 60% of that in dogs). In a further study on six subjects a deep vein draining the active forearm muscles was cannulated and deep venous O2 saturation measured to assess how a 50-mmHg increase in box pressure and subsequent reflex increase in MAP altered blood flow to the contracting muscles during heavy rhythmic exercise. The increase in box pressure reduced blood flow to contracting forearm muscles by 20-25% and was followed by a 19-mmHg increase in MAP that did not appear to improve perfusion of the active muscles. This finding was unexpected, because studies in dogs suggest that the pressor response to rhythmic exercise with restricted muscle blood flow can improve perfusion of the active muscles.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of pituitary adenylate cyclase-activating polypeptide on cardiovascular and respiratory responses in anaesthetised dogs

This study examines some of the cardiovascular and respiratory effects of pituitary adenylate cyclase-activating polypeptide (PACAP) in anaesthetised dogs. Intravenous injection of PACAP 27 caused an increase in arterial blood pressure and an increase in heart rate. The blood pressure response was significantly reduced by adrenoceptor blockade suggesting a mechanism of action mediated in part via catecholamines. The heart rate increase was unaltered by adrenoceptor blockade suggesting a direct effect of PACAP 27. PACAP 27 also caused potentiation of cardiac slowing caused by stimulation of the vagus nerve. In addition, PACAP 27 powerfully stimulated breathing. This was probably evoked by stimulation of arterial chemoreceptors, because bilateral section of the carotid sinus nerves abolished this effect. PACAP 27 had no effect on the ability of the cardiac sympathetic nerve to increase heart rate, nor on the interaction between the sympathetic and parasympathetic systems in the heart.     

Function of mature coronary collateral vessels and cardiac performance in the exercising dog

Formation of extensive collateral vessels after chronic constriction of a coronary artery in dogs can provide for similar increases in blood flow to native and collateralized regions of myocardium during exertion. Previous investigations have not compared myocardial blood flow and cardiac functional responses during exercise in constricted and nonconstricted (sham) animals. Thus we evaluated left ventricular performance and myocardial blood flow at rest and during mild, moderate, and severe exertion in sham-operated dogs and in dogs 2-3 mo after placement of an Ameroid occluder around the proximal left circumflex artery. Changes in double product, maximal left ventricular dP/dt, and pressure-work index were similar in both groups for each level of exertion. Despite similar increases in estimated myocardial O2 demand and similar diastolic perfusion pressures, average transmural myocardial blood flow increased less in the constrictor animals, particularly during severe exercise (2.74 +/- 0.22 vs. 1.45 +/- 0.29 ml X min-1 X g-1). The smaller increases in blood flow occurred equally in native and collateralized regions as well as in the papillary muscles and boundary areas between the native and collateralized regions. The differences in flow in the native and collateralized regions were uniform across the wall of the myocardium. We also observed smaller increases in stroke volume and cardiac output in the constrictor group, disparities which increased with increasing exertion (stroke volume, severe exercise = 0.92 +/- 0.13 vs. 0.53 +/- 0.09 ml/kg). We postulate that myocardial active hyperemia is limited either because the coronary vessels remaining after chronic circumflex occlusion cannot dilate sufficiently or that there is inappropriate active vasoconstriction during severe exertion.(ABSTRACT TRUNCATED AT 250 WORDS)     

Matching coronary blood flow to myocardial oxygen consumption.

At rest the myocardium extracts approximately 75% of the oxygen delivered by coronary blood flow. Thus there is little extraction reserve when myocardial oxygen consumption is augmented severalfold during exercise. There are local metabolic feedback and sympathetic feedforward control mechanisms that match coronary blood flow to myocardial oxygen consumption. Despite intensive research the local feedback control mechanism remains unknown. Physiological local metabolic control is not due to adenosine, ATP-dependent K(+) channels, nitric oxide, prostaglandins, or inhibition of endothelin. Adenosine and ATP-dependent K(+) channels are involved in pathophysiological ischemic or hypoxic coronary dilation and myocardial protection during ischemia. Sympathetic beta-adrenoceptor-mediated feedforward arteriolar vasodilation contributes approximately 25% of the increase in coronary blood flow during exercise. Sympathetic alpha-adrenoceptor-mediated vasoconstriction in medium and large coronary arteries during exercise helps maintain blood flow to the vulnerable subendocardium when cardiac contractility, heart rate, and myocardial oxygen consumption are high. In conclusion, several potential mediators of local metabolic control of the coronary circulation have been evaluated without success. More research is needed.     

Adaptation of respiratory muscle perfusion during exercise to chronically elevated ventilatory work.

Pneumonectomy (PNX) leads to chronic asymmetric ventilatory loading of respiratory muscles (RM). We measured RM energy requirements during exercise from RM blood flow (Q) using a fluorescent microsphere technique in dogs that had undergone right PNX as adults (adult R-PNX) or as puppies (puppy R-PNX), compared with dogs subjected to right thoracotomy without PNX as puppies (Sham) and to left PNX as adults (adult L-PNX). Ventilatory work (W) was measured during exercise. RM weight was determined post mortem. After adult and puppy R-PNX, the right hemidiaphragm becomes grossly distorted, but W and right costal muscle mass increased only after adult R-PNX. After adult L-PNX, the diaphragm was undistorted; W and left hemidiaphragm RM Q were elevated, but muscle mass did not increase. Mass of parasternal muscle did not increase after adult R-PNX, despite increased Q. Thus muscle mass increased only in response to the combination of chronic stretch and dynamic loading. There was a dorsal-to-ventral gradient of increasing Q within the diaphragm, but the distribution was unaffected by anatomic distortion, hypertrophy, or workload, suggesting a fixed pattern of neural activation. The diaphragm and parasternals were the primary muscles compensating for the asymmetric loading from PNX.     

Changes of rat respiratory and locomotory muscles during aerobic exercise training in continuous and interval regimens

Male Wistar rats were treadmill-trained for 8 weeks using one of the two regimens: with the constant running speed or with alternating high-speed and low-speed intervals. Both training regimens led to an increase of rat aerobic capacities and to a higher citrate synthase activity in the medial head of gastrocnemius muscle. No differences between the effects of two training regimens were observed. However, in contrast to constant-speed training the interval one resulted in myocardium hypertrophy and also in less pronounced changes in diaphragm muscle, such as slow-direction shift of myosin phenotype and reduction of muscle fiber cross-sectional area. Neither of the training regimens had an effect on corticosterone and thyroid hormones levels in rat blood, whereas the interval training resulted in a higher level of testosterone. Anabolic influence of testosterone during interval aerobic training may be favorable for heart hemodynamic capacity and force characteristics of the diaphragm.