Characteristics of morphological changes in the myocardium of rats with different degrees of hereditary resistance to hypoxia during the development of adrenaline-induced myocardial dystrophy

By means of polarizational microscopy method morphological changes of the cardiac muscle have been studied in highly-(HS) and poorly-stable (PS) rats to hypoxia 1 h and 1 day after injection of cardiotoxic dose of adrenaline (1.5 mg/kg of body mass). One hour after injection of adrenaline in PS animals the II-III stages of contractive myofibrillar changes are revealed, while in HS rats--the I-II stages. In 1 day in the myocardium of PS animals contractures of the III-IV degree are observed, more foci of clumping decay and myocytolysis than in HS rats. Severity of the morphological changes of the cardiac muscle after cardiotoxic dose of adrenaline essentially depends on the organism's reactivity.     

Catecholamine content and electrolyte balance of the rabbit myocardium during poisoning with 2,4-dinitrophenol]

At the initial stages of energy deficiency in rabbits caused by an intravenous injection of 2,4-dinitrophenol (10 mg/kg) there occurred in the cardiac ventricles an increase in the noradrenalin content and a fall in the potassium level. In case of a more pronounced energy deficiency (20 and 30--40 mg/kg of 2,4-dinitrophenol) noradrenaline stores in the heart became exhaustated, whereas the potassium level in the myocardium became greater. There is a fall of adrenaline stores in the heart, whereas the potassium level in the myocardium increased. The amount of adrenaline in the heart and the adrenal glands decreased. Deep energy deficiency is accompanied by the syndrome of hyperkaliemia associated with the exit of potassium into the blood from the depot tissues.     

Peculiarities of Ca2+ regulation of functional activity of myocardium of frog Rana temporaria

To elucidate role of intra- and extracellular Ca2+ in regulation of rhythm and strength of frog heart contractions, there were studied ECC and isometric contraction of myocardium preparations in response to verapamil, adrenaline, and blockers of alpha- and beta-adrenoreceptors. It has been shown that after an intramuscular injection of verapamil (6 mg/kg), bradycardia develops, the heart rate (HR) decreasing by 50-70 %. Further, the cardiac arrest occurred; however, administration to the animals of adrenaline (100 mg/kg) restored the cardiac rhythm for a short while. After an intramuscular injection of adrenaline at doses of 0.1-10 mg/kg, no essential changes were observed in the potential action amplitude and HR; an increase of the administered adrenalin concentration to 100 mg/kg was not accompanied by the cardiac rhythm stimulation, as this takes place in homoiothermal animals and human; on the contrary, an essential HR deceleration was revealed. Phentolamine (5 mg/kg) gradually decelerated HR rhythm by 32-45 %. The potential amplitude changed insignificantly. A subsequent intracardiac injection of adrenaline (100 mg/kg) on the background of block of alpha-adrenoreceptors produced acceleration of the rhythm (by 13-21%) and fall of the electrogram amplitude. These results can indicate that in the frog heart, phentolamine interacts predominanty with alpha-adrenoreceptors. An intracardiac administration of propranolol (1 mg/kg) to frogs promoted inhibition of beta-adrenergic receptors and produced a gradual cardiac rhythm deceleration. In experiments on assessment of verapamil effect on the character of contractions this preparation at a concentration of 150 microM was established to produce a significant dosedependent decrease of the contraction strength. A rise of verapamil concentration in the sample to 200 microM led to a decrease of the amplitude, on average, by 68-70 % and in individual preparations -- by 80-85 %; however, administration into the sample of adrenaline (10 microM) restored the cardiac contraction strength. Adrenaline (1 nM--100 microM) increased markedly the contraction amplitude. Phentolamine (10 microM) did not inhibit transmission of contractile signal to cardiomyocytes; this was manifested in that the contraction amplitude after addition of adrenaline (10 microM) into the sample was approximately the same as in the sample containing no phentolamine. Propranolol (10 microM) eliminated the stimulatory action of adrenaline (10 microM). The results of these experiments indicate that in the frog ventricular cardiomyocytes the main adrenaline acceptors are beta-adrenoreceptors.     

Assessment of the protective effect of vitamin E during development of experimental myocardial damage

It was shown that creatinphosphokinase activity of blood serum might be used as a criterion for evaluating the level of sparsely distributed damage in myocardium as a result of adrenaline administration. The protective effect of vitamin E under adrenaline-induced myocarditis was studied. The best effect was obtained after triple intramuscular injection of vitamin E before administration of pathological agent. Intravenous injection of the preparation has no benefits over that of intramuscular way of administration. Preventive action of vitamin E shows functioning itself in an increase of the quantity and activity of ubiquinone--the component of electron transport chain in mitochondria.     

Inotropic effects of adrenaline on the anoxic or hypercapnic myocardium of rainbow trout and eel

Summary The effects of adrenaline on the development of force under anoxia and hypercapnic acidosis (13% CO₂ in 30 mM HCO ₃ ^– ) were examined in isolated, electrically stimulated cardiac ventricle strips of rainbow trout and eel.During anoxia or acidosis applied 15 min in advance, the adrenaline concentration of the bathing solution was increased in 5 steps from 0 to 10^–4 M with 5 min at each step. Before levelling off the contractile tension increased by 145±42% (mean±SE) in the anoxic, 80±14% in the acidotic and 152±41% in the control trout cardiac strips. Except for the acidotic strips the corresponding values tended to be lower for the eel strips being 46±9%, 57±17% and 57±9%, respectively. The inotropic affinity for adrenaline was lower in the trout than in the eel myocardium. For the trout myocardium it remained unchanged, while it decreased somewhat for the eel myocardium under anoxia or acidosis.Adding to the muscle bath 10^–5 M adrenaline resulted in an increase in force development by about 90% for the trout myocardium and 50% for the eel myocardium. 5 min later anoxia or hypercapnic acidosis was applied for 30 min followed by 30 min at control conditions. Relative to the force values recorded just before anoxia or acidosis was applied, the changes in contractile force during these periods were the same with and without adrenaline. Thus adrenaline appears to have a persistent positive inotropic effect in the fish myocardium during and after oxygen lack or acidosis.     

Peculiarities of Ca<Superscript>2+</Superscript>-regulation of functional activity of myocardium of frog <Emphasis Type="Italic">Rana temporaria</Emphasis>

To elucidate role of intra- and extracellular Ca²⁺ in regulation of rhythm and strength of frog heart contractions, there were studied ECC and isometric contraction of myocardium preparations in response to verapamil, adrenaline, and blockers of α- and β-adrenoreceptors. It has been shown that after an intramuscular injection of verapamil (6 mg/kg), bradycardia develops, the heart rate (HR) decreasing by 50–70%. Further, the cardiac arrest occurred; however, administration to the animals of adrenaline (100 mg/kg) restored the cardiac rhythm for a short while. After an intramuscular injection of adrenaline at doses of 0.1–10 mg/kg, no essential changes were observed in the potential action amplitude and HR; an increase of the administered adrenalin concentration to 100 mg/kg was not accompanied by the cardiac rhythm stimulation, as this takes place in homoiothermal animals and human; on the contrary, an essential HR deceleration was revealed. Phentolamine (5 mg/kg) gradually decelerated HR rhythm by 32–45%. The potential amplitude changed insignificantly. A subsequent intracardiac injection of adrenaline (100 mg/kg) on the background of block of α-adrenoreceptors produced acceleration of the rhythm (by 15–21%) and fall of the electrogram amplitude. These results can indicate that in the frog heart phentolamine interacts predominantly with α 1-adrenoreceptors. An intracardial administration of propranolol (1 mg/kg) to frogs promoted inhibition of β-adrenergic receptors and produced a gradual cardiac rhythm deceleration. In experiments on assessment of verapamil effect on the character of contractions this preparation at a concentration of 150 μM was established to produce a significant dose-dependent decrease of the contraction strength. A rise of verapamil concentration in the sample to 200 μM led to a decrease of the amplitude, on average, by 68–70% and in individual preparations—by 80–85%; however, administration into the sample of adrenaline (10 μM) restored the cardiac contraction strength. Adrenaline (1 nM–100 μM) increased markedly the contraction amplitude. Phentolamine (10 μM) did not inhibit transmission of contractile signal to cardiomyocytes; this was manifested in that the contraction amplitude after addition of adrenaline (10 μM) into the sample was approximately the same as in the sample containing no phentolamine. Propranolol (10 μM) eliminated the stimulatory action of adrenaline (10 μM). The results of these experiments indicate that in the frog ventricular cardiomyocytes the main adrenaline acceptors are β-adrenoreceptors.     

Heat production as a criterion of adrenergic regulation of metabolic processes of the myocardium

Bolus injection of adrenaline in coronary perfusion blood flow caused different-directed changes in coronary venous blood temperature. Directivity and myocardium heat production changes are determined by peculiarities of interactions between adrenergic and cholinergic mechanisms of cardiodynamics and myocardial metabolism regulation. Cholinergic blockade by atropine++ increases heat production and limits negative ino- and chronotropic components of cardiac adrenergic reactions. That increase is completely eliminated by subsequent obsidan blockade of beta-adrenoreceptors.     

Effect of lithium preparations on the toxic effects of adrenaline

Experiments on rats have shown that intravenous injection of adrenaline in a dose of 0.3-0.4 mg/kg causes cardiac arrhythmia. In this case the primary arrhythmia developing immediately after adrenaline injection is followed by the recovery of sinusal rhythm which was replaced by the secondary arrhythmia. Apart from arrhythmias, there developed pulmonary edema. The animals died 2--3 minutes after adrenaline injections. Lithium chloride and lithium hydroxybutyrate removed the secondary arrhythmia and pulmonary edema. Lithium hydroxybutyrate has proved to be more effective.     

Differential cardiovascular effects of central clonidine and B-HT 920 in conscious rats

The effect of intracerebroventricular (i.c.v.) injection of the alpha 2-adrenoceptor agonists clonidine and B-HT 920 on mean arterial pressure (MAP), heart rate (HR), and plasma concentrations of noradrenaline and adrenaline was examined in conscious unrestrained rats. The injection of 1.0 microgram clonidine significantly decreased MAP and slightly decreased HR. Plasma noradrenaline and adrenaline levels were slightly but not significantly decreased after the injection of 1 microgram clonidine. In contrast, the injection of 0.1-10.0 micrograms B-HT 920 increased MAP and decreased HR. Plasma noradrenaline and adrenaline levels were slightly increased after the injection of the 1- and 10-micrograms doses. The i.c.v. injection of the alpha 2-antagonist rauwolscine slightly but not significantly increased MAP and plasma noradrenaline and adrenaline levels. The responses to i.c.v. injection of clonidine and B-HT 920 were not changed by prior administration of rauwolscine. Neither the pressor response to B-HT 920 nor the depressor response to clonidine was abolished by rauwolscine, suggesting that neither response was mediated by alpha 2-adrenoceptors.     

Is the damaging action of catecholamines on the myocardium realized via hyperstimulation of the beta receptors?

Experiments on an isolated rat heart were made to compare the damaging action on the myocardium of catecholamines (noradrenaline, adrenaline and isoproterenol) differing in the affinity for beta-receptors. The damage to myocardial cells was evaluated from the release into the perfusate of intracellular enzymes (creatine phosphokinase and lactate dehydrogenase) and the number of contracture damaged myocytes. Noradrenaline exerted the most powerful damaging action on the myocardium at a concentration of 10(-6) M. Perfusion of the heart with isoproterenol at concentrations of 10(-6) M and 10(-5) M did not lead to the affection of cardiomyocytes. It was isoproterenol concentration exceeding noradrenaline concentration 100 times that produced an increase in the rate of the release of the enzymes to the perfusate and a rise of the number of contractures in the myocardium, with the above increase being less than that provoked by adrenaline and noradrenaline (10(-6) M). It is concluded that the mechanism of the cardiotoxic effect of catecholamines cannot be reduced only to their effect on myocardial beta-receptors.     

Adrenoreceptor-independent effect of thyroxine and adrenoxyl on myocardial adenyl cyclase activity and cAMP levels

A study was made of the effect of different concentrations of noradrenaline, adrenaline, adrenoxyl (stabilized adrenochrome) and thyroxin on the adenylate cyclase activity and cAMP content in the myocardium of intact animals and in neurogenous affections of the myocardium. It was shown that the content of cAMP in the myocardium drops in neurogenous affections and that thyroxin or adrenoxyl in combination with beta-adrenoblockers (propranolol) might be used for the recovery of the cAMP content and adenylate cyclase activity.     

Role of monoaminoxidase in the intensification of peroxidation of lipids in mitochondria during experimental myocardial necrosis

The relationship between lipid peroxidation and rat heart mitochondrial monoamine oxidase activity was studied in experimental myocardial necrosis induced by adrenaline injection. It has been established that both the intensity of peroxidation and the activity of monoamine oxidase in mitochondria from adrenaline-injured rat myocardium were essentially increased. The preliminary administration of antioxidants (vitamin E and ionol) was shown to decrease both the intensity of lipid peroxidation and the activity of monoamine oxidase. It is suggested that intensification of lipid peroxidation which is considered to be the main pathogenic factor in ischemic myocardial injury depends on mitochondrial monoamine oxidase activity. Protective effects of antioxidants are realized by the action on two subsequent chains during the formation of active oxygen forms and destruction of lipid peroxidation products.     

Effect of stress on calcium homeostasis in sheep

The acute effect of stress on the plasma and cerebrospinal fluid (CSF) immunoreactive parathyroid hormone (PTH) response was studied in 6 merino sheep. Stress was exerted by weak periodical electric square waves (PESW). In addition, the effect of intravenous injection of adrenaline was studied. Under stress conditions (PESW or adrenaline injection), plasma PTH increased up to 30% and up to 50%, respectively. Weak periodical electric square waves of 3-4 mA decreased CSF PTH concentrations by up to 50%. The effect of adrenaline injection on the CSF PTH was not significant. Total calcium and magnesium in plasma and CSF did not change. Our results showed that the effect of stress on the CSF PTH is opposite to the effect on plasma PTH, and suggest that both, PESW and adrenaline, affected PTH in plasma and CSF by a Ca-independent mechanism.     

Effects of adrenaline on the dynamics of carbohydrate metabolism in rats treated chronically with adrenaline.

Following a subcutaneous injection of adrenaline (300 mug/kg), blood-glucose levels were lower in rats treated chronically with adrenaline (300 mug/kg twice a day for 28 days) than in control rats during at least 2.5 h after the injection. To explain this difference of response, the turnover rate of glucose was measured in control and adrenaline-treated rats during adrenaline infusion (0.75 mug/kg- minus 1 min- minus 1), with [U- minus 14C]glucose as tracer. It was found that the rate of appearance of glucose was greater in the control than in the adrenaline-treated group after a 120-min infusion of adrenaline. The rate of disappearance of glucose in the treated rats increased during the first 60 min of infusion and stayed at this elevated level for a subsequent 2 h, whereas in the control rats, it remained unchanged at the beginning of adrenaline infusion and significantly increased only during the second and third hours of infusion. In addition, the metabolic- clearance rate of glucose was not modified by adrenaline in the treated group, but in the control group, the initial clearance rate was significantly less than in the treated group, and decreased during the first hour of adrenaline infusion even though blood glucose reached values of 244 mg/100 ml. ,rom these data, it is suggested that rats adapt to a chronic exogenous supply of adrenaline by a reduced increase in glucose production in response to adrenaline infusion and a better glucose utilization, which possibly indicates a decrease in the inhibitory effect of adrenaline on insulin secretion.     

Randomised comparison between adrenaline injection alone and adrenaline injection plus heat probe treatment for actively bleeding ulcers.

OBJECTIVE: To compare endoscopic adrenaline injection alone and adrenaline injection plus heat probe for the treatment of actively bleeding peptic ulcers. DESIGN: Randomised prospective study of patients admitted with actively bleeding peptic ulcers. SETTING: One university hospital. SUBJECTS: 276 patients with actively bleeding ulcers detected by endoscopy within 24 hours of admission: 136 patients were randomised to endoscopic adrenaline injection alone and 140 to adrenaline injection plus heat probe treatment. MAIN OUTCOME MEASURES: Initial endoscopic haemostasis; clinical rebleeding; requirement for operation; requirement for blood transfusion; hospital stay, ulcer healing at four weeks; and mortality in hospital. RESULTS: Initial haemostasis was achieved in 131/134 patients (98%) who received adrenaline injection alone and 135/136 patients (99%) who received additional heat probe treatment (P = 0.33). Outcome as measured by clinical rebleeding (12 v 5), requirement for emergency operation (14 v 8), blood transfusion (2 v 3 units), hospital stay (4 v 4 days), ulcer healing at four weeks (79.1% v 74%), and in hospital mortality (7 v 8) were not significantly different in the two groups. In the subgroup of patients with spurting haemorrhage 8/27 (29.6%; 14.5% to 50.3%) patients from the adrenaline injection alone group and 2/31 (6.5%; 1.1% to 22.9%) patients from the dual treatment group required operative intervention. The relative risk of this was lower in the dual treatment group (0.17; 0.03 to 0.87). Hospital stay was significantly shorter in the dual treatment group than the adrenaline injection alone group (4 v 6 days, P = 0.01). CONCLUSION: The addition of heat probe treatment after endoscopic adrenaline injection confers an advantage in ulcers with spurting haemorrhage.     

Failure of adrenaline to induce hyperglycaemia after fructose injection in young mice.

In control animals a 2-fold increase in liver phosphorylase activity 10min after adrenaline treatment was associated with a 55% increase in plasma glucose (P less than 0.001); at 20 min plasma glucose was 247% of the control value (P less than 0.001). Liver phosphorylase activity was decreased by 74%, 20 min after fructose injection (P less than 0.001), and, although phosphorylase activity increased 5-fold within 5 min of adrenaline injection, no increases in plasma glucose concentration over that found in fructose-injected animals which did not receive adrenaline occurred at either 5, 10 or 20 min. The data confirm inactivation of liver phosphorylase after fructose injection and suggest inhibition of the adrenaline-activated enzyme by the decrease in Pi and elevation of fructose 1-phosphate concentrations produced by the injection of fructose. These findings may be causally related to the hypoglycaemia and the lack of response to glucagon seen in patients with hereditary fructose intolerance after fructose ingestion.     

Simulation analysis of effects of adrenaline on spike generation in olfactory receptor cells

Adrenaline is known to affect action potentials induced by the step current injection in an olfactory receptor cell (ORC). It is unclear, however, whether it also modulates action potentials induced by odor stimuli. In the present study, the effects of adrenaline on action potentials in ORCs were investigated quantitatively using a computer simulation. Adrenaline suppressed simulated action potentials induced by step current injection near threshold, and increased spike frequency to strong stimuli by 8-25%. Similar effects were obtained by applying a pseudo-transduction current to a model cell. Surprisingly, adrenaline markedly increased spike frequency to strong stimuli by 30-140%, and increased the slope of the stimulus-response relation compared with that of the step current injection. This suggests that adrenaline enhances odorant contrast in olfactory perception by modulating signal encoding of ORCs.     

Effect of hypokinesia and muscle training on catecholamine levels of the myocardium of rats in postnatal ontogeny

Following muscular training and hypokinesia in postnatal ontogenesis (10 weeks) rats were examined by fluorometry for the content of catecholamines at rest and after extreme exertion (swimming). Regular muscular training led to an increase in catecholamine concentration in the myocardium. Hypokinesia decelerated catecholamine accumulation by the myocardium. A single extreme swimming exercise brought about a decrease in catecholamine concentration in the myocardium. The minimal adrenaline concentration was the same, being equal to 0.04 microgram/g crude tissue whatever the age and locomotion pattern.     

Activity of oil isolated from Amaranth seeds on energetic functions of rat liver mitochondria after adrenaline introduction

It has been shown that a three-week feeding of rats with oil derived from seeds of amaranth (Amaranthus cruentus L.) leads to a moderate activation of respiration of coupled and uncoupled rat liver mitochondria (MCh) that oxidize succinate and succinate + glutamate, as well as alpha-ketoglutarate and alpha-ketoglutarate + malonate. In animals receiving the amaranth oil, the injection of adrenaline did not affect the oil-activated respiration of MCh during succinate oxidation; i. e., animals prepared by an oil-enriched diet were resistant to the action of adrenaline, which prevented from possible hyperactivation of mitochondrial functions. In the group of control animals, which received no oil, the injection of adrenaline activated the rate of phosphorylating respiration of MCh during oxidation of succinate or succinate + glutamate: the rate of oxygen uptake in state 3 respiration (by Chance) increased, and the phosphorylation time decreased. The injection of adrenaline did not affect the parameters of respiration of MCh that oxidize a-ketoglutarate; however, in the presence of malonate, the oxidation of alpha-ketoglutarate in state 3 and uncoupled respiration have shown mild but significant increase in response to adrenaline. In animals receiving the amaranth oil, the oil-induced activation of respiration of MCh in response to adrenaline retained but did not increase; however, the phosphorylation time significantly decreased. Thus, concentrated oil of seeds activates the respiration of MCh. In addition, it enhances an energetic function of MCh, which prevents from the hyper-activation of mitochondrial respiration by adrenaline. Therefore an activation of energetic function of MCh by amaranth oil could explain its adaptogenic effect on rats.     

Participation of prostaglandins in regulating myocardial catecholamine absorption

In vitro experiments showed PGE1 (2.10(-6) and 5.10(-6) M) to decrease adrenaline and noradrenaline uptake by the rat myocardium homogenates. On the other hand, neither PGE1 nor PGA1 influenced the interaction between troponin and noradrenaline. Apparently, the capacity of PGs to decrease catecholamine uptake by the myocardium was not mediated by their effect on troponin.