Effects of ventromedial and lateral hypothalamic stimulation on chemically-induced liver injury in rats

The effects of hypothalamic stimulation on experimental liver injury induced by carbon tetrachloride (CCl4) or dimethylnitrosamine (DMN) were studied in rats, by measuring plasma alanine aminotransferase (ALT) activity as an index of acute liver injury. Electrical stimulation of the ventromedial hypothalamus (VMH) in CCl4-treated rats caused a marked increase in plasma ALT activity, accompanied by a significant decrease in ALT activity in the liver, although CCl4 treatment alone had no significant effect on plasma ALT activity. A similar effect of VMH stimulation on plasma ALT activity was observed in rats treated with DMN, another hepatotoxic chemical. No such exaggerated effect of VMH stimulation on plasma ALT activity was observed after stimulation of the lateral hypothalamic area (LH). Surgical sympathetic denervation of the liver greatly suppressed the increase in plasma ALT activity after CCl4 injection and VMH stimulation. Measurement of regional blood flow indicated that VMH stimulation did not produce a significant change in blood flow to the liver. These results suggest that the VMH is involved in the progress of chemically-induced liver injury through activation of the sympathetic nerve (hepatic nerves), possibly by affecting liver metabolism more than the blood flow change to the liver.     

Regulation of canine skeletal muscle and hindlimb blood flow in acute anemia

Redistribution of blood flow away from resting skeletal muscles does not occur during anemic hypoxia even when whole body oxygen uptake is not maintained. In the present study, the effects of sympathetic nerve stimulation on both skeletal muscle and hindlimb blood flow were studied prior to and during anemia in anesthetized, paralyzed, and ventilated dogs. In one series (skeletal muscle group, n = 8) paw blood flow was excluded by placing a tourniquet around the ankle; in a second series (hindlimb group, n = 8) no tourniquet was placed at the ankle. The distal end of the transected left sciatic nerve was stimulated to produce a maximal vasoconstrictor response for 4-min intervals at normal hematocrit (Hct.) and at 30 min of anemia (Hct. = 14%). Arterial blood pressure and hindlimb or muscle blood flow were measured; resistance and vascular hindrance were calculated. Nerve stimulation decreased blood flow (p less than 0.05) in the hindlimb and muscle groups at normal Hct. Blood flow rose (p less than 0.05) during anemia and was decreased (p less than 0.05) in both groups during nerve stimulation. However, the blood flow values in both groups during nerve stimulation in anemic animals were greater (p less than 0.05) than those at normal Hct. Hindlimb and muscle vascular resistance fell significantly during anemia and nerve stimulation produced a greater increase in vascular resistance at normal Hct. Vascular hindrance in muscle, but not hindlimb, was less during nerve stimulation in anemia than at normal Hct.(ABSTRACT TRUNCATED AT 250 WORDS)     

Fatigability and blood flow in the rat gastrocnemius-plantaris-soleus after hindlimb suspension.

The purpose of this study was to test the hypothesis that hindlimb suspension increases the fatigability of the soleus during intense contractile activity and determine whether the increased fatigue is associated with a reduced muscle blood flow. Cage-control (C) and 15-day hindlimb-suspended (HS) rats were anesthetized, and either the gastrocnemius-plantaris-soleus (G-P-S) muscle group or the soleus was stimulated (100 Hz, 100-ms trains at 120/min) for 10 min in situ. In the G-P-S preparation, blood flow was measured with radiolabeled microspheres before and at 2 and 10 min of contractile activity. The G-P-S fatigued markedly at this stimulation frequency, and the differences between C and HS animals were not significant until the 9th min of contractile activity. In contrast, the stimulation resulted in faster rates and significantly larger amounts of fatigue in the soleus from HS than from C animals. The atrophied soleus showed significant differences by 1 min of stimulation (C = 70 +/- 1% vs. HS = 57 +/- 2% of peak train force) and remained different at 10 min (C = 64 +/- 4% vs. HS = 45 +/- 2% peak train force). Relative blood flow to the soleus was similar between groups before and during contractile activity (rest: C = 20 +/- 3 vs. HS = 12 +/- 3; 2 min: C = 128 +/- 6 vs. HS = 118 +/- 4; 10 min: C = 123 +/- 11 vs. HS = 105 +/- 11 ml.min-1.100 g-1). In conclusion, these results established that 15 days of HS increased the fatigability of the soleus, but the effect was not caused by a reduced muscle blood flow.     

Role of the hypothalamus in regulating liver circulation

In acute experiments on nembutal anesthetized dogs stimulation of anterior hypothalamus elicited changes in the hepatic artery blood flow, which followed those of arterial pressure; the vascular resistance remaining unchanged. The stimulation of medial and posterior hypothalamus led to decrease in flow and increase in the resistance of the hepatic artery. In most cases of hypothalamic stimulation the portal blood flow diminished, portal pressure and vascular resistance increased. The opposite reactions were observed during stimulation of sympathoinhibitory area, paraventricular and lateral hypothalamic nuclei. The conclusion is made that the hypothalamus participates in integrative and differential control of the hepatic circulation.     

Regulation of glycogenolysis in human skeletal muscle

The role of inorganic phosphate on the regulation of glycogenolysis in resting and contracting muscle was studied in human quadriceps muscle. Increased Pi content was achieved by intermittent electrical stimulation of the muscle followed by occlusion of the blood flow. Occlusion resulted in the maintenance of a high Pi content over a 60-s observation period during which the muscle was either at rest or was stimulated electrically. The study was performed with and without infusion of epinephrine (EPI). In the absence of EPI the phosphorylase a fraction was 50% immediately at the end of the initial stimulation period, declining to 22% after 60 s. With EPI corresponding values for phosphorylase a were 91% initially, 56% after 30 s, and 33% after 60 s, respectively. In both cases the Pi content was increased by approximately 35 mmol/kg dry muscle during the stimulation and remained constant during the occlusion. In neither of these situations was significant degradation of glycogen observed during the occlusion. In the study performed with electrical stimulation during the occlusion period, muscle glycogen degradation was observed both with and without EPI. Phosphorylase a fractions and Pi contents in this study were similar to those observed when muscle was rested over the 60-s occlusion period. The paradox of a high Pi content and extensive transformation of phosphorylase to the a form but low glycogenolytic activity points to additional factors in the regulation of glycogen breakdown.     

Different responses in skin and muscle sympathetic nerve activity to static muscle contraction

We microneurographically recorded the traffic of sympathetic nerves leading to foot volar skin activity (SSA) and leg skeletal muscle activity (MSA) during isometric handgrip and simultaneously determined sweat rate by the ventilated capsule method and skin blood flow by laser-Doppler flowmetry in the innervating area of SSA. SSA increased abruptly and was almost constant during handgrip, accompanied by an increase in sweat rate, whereas skin blood flow showed no significant change during the handgrip. MSA showed a time-dependent increase during the course of handgrip. During arterial occlusion of the working forearm after handgrip, SSA decayed to the precontraction control level, whereas MSA remained at a higher level than during control. During involuntary biceps muscle contraction induced by electrical stimulation, both SSA and MSA increased. The results suggest that the SSA response during voluntary handgrip, which was demonstrated to contain mainly sudomotor activity, might be influenced by central command and input from peripheral mechanoreceptors but be influenced little by input from muscle chemoreceptors.     

Proceedings: The effects of hypothalamic and reflexogenic hypertension on renal and femoral circulation.

In anaesthetized dogs, electrical stimulation of the median posterior hypothalamus provoked hypertension accompanied by a decrease of renal blood flow and an increase of femoral blood flow. Similar hypothalamic reactions occurred after bilateral cervical vagotomy or after atropine, 2 mg/kg i.v. During reflexogenic hypertension induced by bilateral carotid occlusion in bivagotomized dogs, the renal and femoral blood flows were not significantly modified. The decrease of the renal blood flow and the increase of the femoral blood flow, during hypothalamic stimulation were greatly reduced or reversed after R 28935 equals erythro-1-(1--e12-(1,4-benzodioxan-2-yl)-2-OH-Et]-4-piperidyl)-2-benzimidaxolinone, 80 mug/kg i.v., but not after clonidine, 5 mug/kg i.v.     

Local blood flow in the emotiogenic structures of the brain in freely moving rats

The speed of local blood flow (SLBF) in positive emotiogenic hypothalamic zones was recorded in free-moving white rats, by the method of hydrogen clearance, in states of passive and active alertness, in conditions of artificial (local) activation (by cathode) and inactivation (by DC anode) and also during stimulation of other positive and negative emotiogenic structures. It was established that the natural or artificial activation of the emotiogenic brain zones elicits an increase of SLBF and the inactivation evokes its reduction. Blood flow of the positive emotiogenic brain zones is intensified by stimulation of other positive emotiogenic structures, is reduced by stimulation of the negative emotiogenic zones and does not change at stimulation of emotionally neutral zones. It is suggested, that the mechanism of vascular reactions elicited by activation of positive and negative emotiogenic brain structures has a neurogenic basis and is performed in the type of "axon-reflex" by collaterals of ascending and descending fibers of the forebrain medial bundle.     

Hypothalamic influences on unit activity in the cat sensomotor cortex

Experiments on unanesthetized, immobilized cats showed different effects of individual hypothalamic nuclei on spontaneous unit activity in the sensomotor cortex. Compared with the posterior hypothalamic nucleus (PHN) and its anteromedial region (AMH), in response to stimulation of the lateral hypothalamic nucleus (LHN) changes in spontaneous activity were more frequently found. The ratio between activation and inhibitory responses was 36 and 36% for AMH, 51 and 30% for LHN, and 47 and 28% for PHN. An approximately equal number of sensomotor neurons (27–34%) gave tonic responses. Phasic changes in spontaneous activity were observed more often in response to stimulation of LHN, less frequently to stimulation of AMH and PHN. Responses of "nonpyramidal" neurons to stimulation of AMH and LHN were identical. "Pyramidal" units were more sensitive to LHN stimulation. Variations in hypothalamic effects depending on the type of response of sensomotor neurons to sensory stimuli were detected. Cells with tonic responses were more susceptible to influences of LHN and AMH than cells which responded by phasic changes in spontaneous activity to sensory stimuli. Fewer still positive responses were recorded in areactive neurons.Medical Institute, Chita. Translated from Neirofiziologiya, Vol. 4, No. 2, pp. 115–122, March–April, 1972.     

Effects of stimulating the lumbar sympathetic trunk on cat hindlimb muscle spindles

1. The effect of stimulating the lumbar sympathetic trunk has been observed on cat lumbrical and tenuissimus muscle spindles. 2. Spindle afferent discharges were recorded either from single Ia fibers in teased dorsal root filaments or from a large number of spindles by integrating their discharges led from muscles nerves. 3. Blood flow in small arteries supplying the muscle was observed through a microscope during and after the stimulation of the sympathetic trunk. 4. In some spindles repetitive stimulation of the sympathetic trunk elicited, after a few seconds delay, a small increase in firing rate. This can be ascribed to a direct action of sympathetic axons on the spindles because it precedes by about 20-30 sec the reduction of blood flow observed in the muscle arteries. This effect is not accompanied by a change in dynamic sensitivity of the primary ending. 5. This early effect is followed, after 20-30 sec, by a later rise in firing frequency which still progresses after the end of stimulation and eventually terminates in an abrupt fall in firing often leading to interruption of the ending activity. Recovery takes places at a variable time after the blood flow has bee reestablished. These long lasting effects can be ascribed to reduction of blood flow in muscle spindles since they are always associated with changes in blood flow in muscle arteries and since they are mimicked by occlusion of the muscle circulation. 6. In some spindles, the amplitudes of frequencygrams elicited by stimulation of static gamma axons were slightly increased suggesting a weak facilitatory effect on the contraction of some intrafusal muscle fibers.     

Elevation in resting blood flow attenuates exercise hyperemia.

These experiments tested the hypothesis that elevating muscle blood flow before exercise would wash out vasoactive substances produced by muscle contraction and reduce the magnitude of exercise hyperemia and/or delay the response. In chronically instrumented dogs (n = 7), hindlimb blood flow was measured with chronically implanted flow probes during mild treadmill exercise. In an anesthetized preparation (n = 8), arterial and venous blood flows of a single hindlimb were obtained during 1-s tetanic contractions evoked by electrical stimulation of the cut sciatic nerve. Elevation of blood flow by intra-arterial infusion of adenosine attenuated the increase in flow during exercise and tetanic contraction by 48 and 47%, respectively. No delay was observed in the latency to peak flow. The attenuated hyperemic response to exercise or contraction is best explained by washout of vasoactive substance(s) produced by contracting muscle, but the residual response suggests that a metabolic mediator may not be the sole explanation for exercise hyperemia.     

Skeletal muscle blood flow and flow heterogeneity during dynamic and isometric exercise in humans

The effects of dynamic and intermittent isometric knee extension exercises on skeletal muscle blood flow and flow heterogeneity were studied in seven healthy endurance-trained men. Regional muscle blood flow was measured using positron emission tomography (PET) and an [(15)O]H(2)O tracer, and electromyographic (EMG) activity was recorded in the quadriceps femoris (QF) muscle during submaximal intermittent isometric and dynamic exercises. QF blood flow was 61% (P = 0.002) higher during dynamic exercise. Interestingly, flow heterogeneity was 13% (P = 0.024) lower during dynamic compared with intermittent isometric exercise. EMG activity was significantly higher (P < 0.001) during dynamic exercise, and the change in EMG activity from isometric to dynamic exercise was tightly related to the change in blood flow in the vastus lateralis muscle (r = 0.98, P < 0.001) but not in the rectus femoris muscle (r = -0.09, P = 0.942). In conclusion, dynamic exercise causes higher and less heterogeneous blood flow than intermittent isometric exercise at the same exercise intensity. These responses are, at least partly, related to the increased EMG activity.     

Blood flow and muscle fatigue in SCI individuals during electrical stimulation.

Our purpose was to measure blood flow and muscle fatigue in chronic, complete, spinal cord-injured (SCI) and able-bodied (AB) individuals during electrical stimulation. Electrical stimulation of the quadriceps muscles was used to elicit similar activated muscle mass. Blood flow was measured in the femoral artery by Doppler ultrasound. Muscle fatigue was significantly greater (three- to eightfold, P < or = 0.001) in the SCI vs. the AB individuals. The magnitude of blood flow was not significantly different between groups. A prolonged half-time to peak blood flow at the beginning of exercise (fivefold, P = 0.001) and recovery of blood flow at the end of exercise (threefold, P = 0.009) was found in the SCI vs. the AB group. In conclusion, the magnitude of the muscle blood flow to electrical stimulation was not associated with increased muscle fatigue in SCI individuals. However, the prolonged time to peak blood flow may be an explanation for increased fatigue in SCI individuals.     

Rapid force recovery in contracting skeletal muscle after brief ischemia is dependent on O(2) availability.

We tested the hypothesis that contracting skeletal muscle can rapidly restore force development during reperfusion after brief total ischemia and that this rapid recovery depends on O(2) availability and not an alternate factor related to blood flow. Isolated canine gastrocnemius muscle (n = 5) was stimulated to contract tetanically (isometric contraction elicited by 8 V, 0.2-ms duration, 200-ms trains, at 50-Hz stimulation) every 2 s until steady-state conditions of muscle blood flow (controlled by pump perfusion) and developed force were attained (3 min). While maintaining the same stimulation pattern, muscle blood flow was then reduced to zero (complete ischemia) for 2 min. Normal blood flow was then restored to the contracting muscle; however, two distinct conditions of oxygenation (at the same blood flow) were sequentially imposed: deoxygenated blood (30 s), blood with normal arterial O(2) content (30 s), a return to deoxygenated blood (30 s), and finally a return to normal arterial O(2) content (90 s). During the ischemic period, force development fell to 39 +/- 6 (SE)% of normal (from 460 +/- 40 to 170 +/- 20 N/100 g). When muscle blood flow was restored to normal by perfusion with deoxygenated blood, developed force continued to decline to 140 +/- 20 N/100 g. Muscle force rapidly recovered to 310 +/- 30 N/100 g (P < 0.05) during the 30 s in which the contracting muscle was perfused with oxygenated blood and then fell again to 180 +/- 30 N/100 g when perfused with blood with low PO(2). These findings demonstrate that contracting skeletal muscle has the capacity for rapid recovery of force development during reperfusion after a short period of complete ischemia and that this recovery depends on O(2) availability and not an alternate factor related to blood flow restoration.     

Local increase in trapezius muscle oxygenation during and after acupuncture

Purpose

This study aimed to compare the trapezius muscle blood volume and oxygenation in the stimulation region and in a distant region in the same muscle during acupuncture stimulation (AS). We hypothesized that AS provokes a localized increase in muscle blood volume and oxygenation in the stimulation region.

Methods

Two sets of near-infrared spectrometer (NIRS) probes, with 40-mm light-source detector spacing, were placed on the right trapezius muscle, with a 50-mm distance between the probes. Changes in muscle oxygenation (oxy-Hb) and blood volume (t-Hb) in stimulation and distant regions (50 mm away from the stimulation point) were measured using NIRS. Nine healthy acupuncture-experienced subjects were chosen as the experimental (AS) group, and 10 healthy acupuncture-experienced subjects were chosen for the control (no AS) group. Measurements began with a 3-min rest period, followed by "Jakutaku" (AS) for 2 min, and recovery after stimulation.

Results

There was a significant increase in oxy-Hb (60.7 μM at maximum) and t-Hb (48.1 μM at maximum) in the stimulation region compared to the distant region. In the stimulation region, a significant increase in oxy-Hb and t-Hb compared with the pre-stimulation level was first noted at 58.5 s and 13.5 s, respectively, after the onset of stimulation.

Conclusion

In conclusion, oxygenation and blood volume increased, indicating elevated blood flow to the small vessels, not in the distant region used in this study, but in the stimulation region of the trapezius muscle during and after a 2-min AS.

     

Mechanism of hypothalamic control of cardiac component of sinus nerve reflex.

The modulatory influence of hypothalamic structures on sinus nerve induced bradycardia was investigated in anaesthetized cats. Stimulation of the hypothalamic defence area inhibits the bradycardia produced by sinus nerve stimulation both in intact animals and also in animals with the spinal cord sectioned at C1 or C6. This inhibition was accompanied in the normal animal by an increased sympathetic discharge and by a sustained inspiration or tachypnoea. The same respiratory effects were noted in a spontaneously breathing C6 spinal animal, while an artificially ventilated C1 spinal animal still displayed a powerful central inspiratory drive in its recurrent laryngeal electroneurogram. The presence of central inspiratory activity was found to be an absolute impediment to the development of bradycardia. If this activity was eliminated by simultaneous stimulation of the superior laryngeal nerve, it was possible to obtain bradycardia during combined sinus nerve and hypothalamic defence area stimulation, though this bradycardia was modified by the presence of sympathetic discharge. The level of sympathetic neural discharge affects the magnitude of the bradycardia produced by sinus nerve stimulation. The bradycardia was less with normal or augmented level of sympathetic activity and was greater if this activity was reduced or absent. A lesion just caudal to the mammillary bodies disclosed a tonic hypothalamic influence both on respiration and on sympathetic discharge; stimulation of the sinus nerve produced a much more powerful bradycardia after the lesion. The existence of a respiratory "gate" through which afferent stimuli pass on their way to the nucleus ambiguus, and which can be operated by the hypothalamic defence and depressor areas, is postulated and discussed.     

Changes in thoracic and right duct lymph flow and enzyme content during skeletal muscle stimulation.

In the pentobarbital-anaesthetized dog the effect of electrical stimulation of hindlimb skeletal muscles on thoracic and right duct lymph flow and enzyme content was examined. Increase in plasma creatine kinase (CK), L-aspartate-aminotransferase (AST) and lactic dehydrogenase (LDH) during 30-min muscle stimulation were not significantly altered by draining lymph. Both right duct and thoracic duct lymph flow trebled during stimulation. At the same time, the activity of the three enzymes examined decreased in right duct lymph and increased in thoracic duct lymph. Of the latter, only the increase in lymph CK was of a sufficient magnitude to have resulted in a detectable increase in plasma CK. CK was the smallest of the three enzymes studied and apparently preferentially entered the lymph, suggesting that the larger AST and LDH molecules were not likely to have entered the blood plasma directly from skeletal muscle. Rather their entry from some other tissue, possibly the formed elements of the blood, is indicated.     

Blood flow distribution in dog gastrocnemius muscle at rest and during stimulation

The distribution of blood flow within the isolated perfused dog gastrocnemius muscle (weight 100-240 g) was studied by intra-arterial injection of radioactively labeled microspheres (diameter 15 micron) at rest and during supramaximal stimulation to rhythmic isotonic tetanic contractions of varied frequency against varied loads. After the experiment the muscle was cut into 180-250 pieces of approximately 0.75 g each, and the blood flow to each muscle piece was determined from its radioactivity. The inhomogeneity of blood flow was represented as the frequency distribution of the ratios of regional specific blood flow, i.e., blood flow per unit tissue weight of the piece, QR, to the overall specific blood flow of the muscle, Q. The QR/Q values for the individual pieces of a muscle were found to vary widely both at rest and during stimulation. With rising work load the frequency distribution had a tendency to broaden and flatten, indicating increasing perfusion inhomogeneity. On the average of the experiments, there was no significant difference in specific blood flow between the three anatomic components of the gastrocnemius (lateral and medial heads of gastrocnemius and flexor digitorum superficialis) nor between the superficial and deep portions within these anatomic components, only the distal third of the muscle was relatively less perfused compared with the proximal two-thirds. The considerable inhomogeneity of blood flow as revealed by microsphere embolization and by other methods is expected to exert important limiting effects on local O2 supply, particularly during exercise. Its neglect would lead to serious errors in the analysis of O2 supply to muscle tissue.     

O2 delivery at VO2max and oxidative capacity in muscles of standardbred horses.

The purpose of this study was to describe the relationships between 16 physiological, biochemical, and morphological variables presumed to relate to the oxidative capacity in quadriceps muscles or muscle parts in Standardbred horses. The variables included O2 delivery (blood flow) and mean capillary transit time (MTT) during treadmill locomotion at whole animal maximal O2 consumption (VO2max, 134 +/- 2 ml.min-1 x kg-1), capillary density and capillary-to-fiber ratio, myoglobin concentration, oxidative enzyme activities, glycolytic enzyme activities, fiber type populations, and fiber size. These components of muscle metabolic capacity were found to be interrelated to varying degrees using correlation matrix analysis, with lactate dehydrogenase activity showing the most significant correlations (n = 14) with other variables. Most of the "oxidative" variables occurred in the highest quantities in the deepest muscle of the group (vastus intermedius) and in the deepest parts of the other quadriceps muscles where the highest proportions of type I fibers were localized. The highest blood flow measured with microspheres in the muscle group during exercise was in vastus intermedius muscle (145 ml.min-1 x 100 g-1), and the lowest was in the superficial part of rectus femoris muscle (32 ml.min-1 x 100 g-1). Average muscle blood flow during exercise at whole animal VO2max was 116 ml.min-1 x 100 g-1. Because skeletal muscle comprised 43% of total body mass (453 +/- 34 kg), total muscle blood flow was estimated at 226 l/min, which was approximately 78% of total cardiac output (288 l/min).(ABSTRACT TRUNCATED AT 250 WORDS)     

Relationship of changes in diaphragmatic muscle blood flow to muscle contractile activity

The effect of increases in diaphragmatic muscle contractile activity on diaphragm blood flow remains unclear. The present study examined the effect of electrically induced isometric diaphragmatic muscle contractions on diaphragmatic blood flow. Studies were performed on diaphragmatic muscle strips prepared in anesthetized mechanically ventilated dogs. Diaphragmatic contractile activity was quantitated as the tension-time index (TTI) (i.e., the product of tension magnitude and duration). Blood flow to the strip (Qdi) was measured from the volume of the phrenic venous effluent using a drop counter. The separate effects on Qdi of 30-s periods of continuous and rhythmic contractions were examined. Qdi increased with increases in TTI and peaked at a TTI of 20-30% of maximum after which Qdi fell progressively with further increases in TTI. At levels of TTI greater than 30%, the pattern of muscle contraction significantly affected blood flow. Qdi was significantly lower during activity and the postcontraction hyperemia significantly greater at a given TTI when contractions were continuous than when contractions were intermittent. Above a TTI of 30%, Qdi during contraction decreased linearly with increases in duty cycle and curvilinearly with increases in tension. We conclude that during isometric diaphragmatic contractions, diaphragmatic blood flow may become mechanically impeded, and the magnitude of the impediment in blood flow depends on the pattern of diaphragmatic contractions. With increases in contractile activity above a critical level, changes in duty cycle exert progressively greater effects on diaphragmatic blood flow than changes in muscle tension.