Role of the sympathetic nervous system in cold-induced hypertension in rats

Hypertension develops in rats exposed chronically to cold [6 +/- 2 degrees C (SE)] and includes both an elevation of mean arterial pressure and cardiac hypertrophy. Previous studies suggest that cold-exposed animals, at least initially, have a large sustained increase in the activity of their sympathetic nervous system, suggesting a failure of the baroreceptor system to provide sufficient negative feedback to the central nervous system. The present study was designed to investigate whether alterations in the activity of the sympathetic nervous system, including the baroreceptor reflex, occur during exposure to cold and whether they contribute to cold-induced hypertension. Twenty male rats were prepared with indwelling catheters in the femoral artery and vein. Ten of the rats were exposed to cold (6 +/- 2 degrees C) chronically, while the remaining 10 were kept at 26 +/- 2 degrees C. Withdrawal of arterial blood samples (less than 5 ml/kg), measurement of direct arterial pressures, and measurement of baroreflex function were carried out at 0800 h at intervals throughout the experiment. Norepinephrine and epinephrine concentrations in plasma were also determined at intervals throughout the experiment. Systolic, diastolic, and mean blood pressures of cold-exposed rats were increased to levels significantly above those of controls. The sensitivity of the baroreflex (delta heart period/delta mean arterial pressure) was decreased in the cold-treated group. The concentration of norepinephrine in plasma increased after 24 h of exposure to cold and remained elevated throughout the experiment, whereas the concentration of epinephrine in plasma increased initially but returned to control levels after 19 days of exposure to cold.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of the sympathetic nervous system in the alcohol-guanabenz hemodynamic interaction.

The present study evaluated the contribution of the sympathetic nervous system to the adverse hemodynamic action of ethanol on hypotensive responses in conscious unrestrained spontaneously hypertensive rats. Ethanol caused a dose-related attenuation of the hypotensive effect of guanabenz. An equivalent hypotensive response to sodium nitroprusside was not influenced by ethanol, which indicates a potential specific interaction between ethanol and guanabenz. Alternatively, it is possible that a preexisting high sympathetic nervous system activity, which occurred during nitroprusside infusion, may mask a sympathoexcitatory action of ethanol. Further, ethanol (1 g/kg) failed to reverse the hypotensive effect of the ganglionic blocker hexamethonium. This suggests that a centrally mediated sympathoexcitatory action of ethanol is involved, at least partly, in the reversal of hypotension. In addition, the antagonistic interaction between ethanol and guanabenz seems to take place within the central nervous system and involves opposite effects on central sympathetic tone. Finally, changes in plasma catecholamines provide supportive evidence for the involvement of the sympathetic nervous system in this interaction. In a separate group of conscious spontaneously hypertensive rats, ethanol (1 g/kg) reversed the guanabenz-evoked decreases in blood pressure and plasma catecholamine levels. It is concluded that (i) ethanol adversely interacts with centrally acting antihypertensive drugs through a mechanism that involves a directionally opposite effect on sympathetic activity, and (ii) a sympathetically mediated pressor effect of ethanol is enhanced in the presence of an inhibited central sympathetic tone.     

Role of the sympathetic nervous system during reparative regeneration and compensation of heart function in experimental myocardial infarct

Experiments on chemically sympathectomized rats have revealed a double effect of the sympathetic nervous system on compensation and adaptation of heart function and reparative regeneration in myocardial infarction. It has been established that if the sympathetic influences are excluded, the elements of the connective tissue are activated, which leads to myocardial infarction healing at a shorter period of time. At the same time it has been demonstrated that sympathectomy inhibits the development of the compensatory reactions and limits adaptation possibilities of the heart.     

Effect of experimental hyperinsulinemia on sympathetic nervous system activity in the rat

Since insulin acutely stimulates the sympathetic nervous system, a role for sympathetic overactivity has been hypothesized to underlie the association between chronic hyperinsulinemia and hypertension. To assess the effect of sustained hyperinsulinemia on sympathetic function, [3H]norepinephrine (NE) turnover was measured in rats injected with insulin for 14d. NE turnover in insulin-treated animals given free access to lab chow and a 10% sucrose solution was compared with that obtained in rats fed chow alone or chow plus sucrose. Sucrose ingestion increased NE turnover in heart, brown adipose tissue, and liver, but exogenous insulin did not augment turnover beyond that seen in animals given sucrose alone. This study, therefore, provides no evidence that chronic hyperinsulinemia, sufficient to induce peripheral insulin resistance, stimulates sympathetic activity more than that produced by chronic sucrose ingestion.     

Role of angiotensin II in sympathetic nervous system induced left ventricular dysfunction

Experiments were undertaken to determine whether angiotensin (Ang) II concentration increases during massive sympathetic nervous system (SNS) activation and whether such an increase plays a role in the pathogenesis of SNS-induced left ventricular (LV) dysfunction. We also sought to determine whether excessive Ca2+ uptake through L-type channels due to intense adrenoceptor activation is responsible for the LV dysfunction. AngII concentration was measured in the plasma and myocardium before and after massively activating the SNS with an intracisternal injection of veratrine. In separate experiments, rabbits were given losartan, enalaprilat, enalaprilat plus HOE-140, nifedipine, -Bay K 4866, or saline before massively activating the SNS. LV function was evaluated 2.5 h later. The intense SNS activity caused plasma and myocardial AngII to increase by 400 and 437%, respectively. AngII receptor blockade did not prevent LV dysfunction. In contrast, enalaprilat reduced the degree of dysfunction, but its cardioprotection was abolished by HOE-140. Although nifedipine prevented SNS-induced LV dysfunction, administration of the Ca2+ channel opener, -Bay K 4866, did not increase its severity. Our results indicate that AngII is not involved in the pathogenesis of SNS-induced LV dysfunction and that the cardioprotection provided by angiotensin converting enzyme (ACE) inhibition is due to activation of a bradykinin pathway. Furthermore, the finding that the magnitude of the LV dysfunction was reduced by enalaprilat, and not increased by -Bay K 4866, suggests that intense adrenoceptor activation of L-type Ca2+ channels is not the primary pathogenetic mechanism.     

Role of oxidative damage in the pathogenesis of viral infections of the nervous system

Oxidative stress, primarily due to increased generation of reactive oxygen species (ROS) and reactive nitrogen species (RNS), is a feature of many viral infections. ROS and RNS modulate the permissiveness of cells to viral replication, regulate host inflammatory and immune responses, and cause oxidative damage to both host tissue and progeny virus. The lipid-rich nervous system is particularly susceptible to lipid peroxidation, an autocatalytic process that damages lipid-containing structures and yields reactive by-products, which can covalently modify and damage cellular macromolecules. Oxidative injury is a component of acute encephalitis caused by herpes simplex virus type 1 and reovirus, neurodegenerative disease caused by human immunodeficiency virus and murine leukemia virus, and subacute sclerosing panencephalitis caused by measles virus. The extent to which oxidative damage plays a beneficial role for the host by limiting viral replication is largely unknown. An enhanced understanding of the role of oxidative damage in viral infections of the nervous system may lead to therapeutic strategies to reduce tissue damage during viral infection without impeding the host antiviral response.     

Role of autoimmune processes in the pathogenesis of post-vaccinal lesions of the nervous system]

Subcutaneous sensitization of guinea pigs with -vaccine, and also an intracardiac injection of smallpox or measles vaccine induced production of brain autoantibodies, whereas subcutaneous or intradermal immunization of the animals with liver viral vaccines was not accompanied by the formation of autoantibodies and development of the pathological processes in the nervous system tissue. tthe greatest changes in the brain tissue in the form of circulatory disturbances and inflammatory-dystrophic phenomena in combination with high autoantibody titres in the blood were noted in intracardiac injection of smallpox vaccine and in subturbancessensitization with AK-Vaccine and the least (short-term circulatory disturbances, transitory signs of serous meningitis and neuron dystrophy against the background of low blood auto anitbody content)--in intracardiac injection of measles vaccine. Administration of live viral vaccines into the circulation of animals against the background of their sensitization with -vaccine led to reduction of blood autoantibody level coinciding in time with the periods of marked pathomorphological changes in the brain tissue.     

Role of autonomic nervous system on heart rate in experimental hypertension

Heart rate and the role of the autonomic nervous system in hypertensive conscious rats by subtotal nephrectomy were studied. Heart rate is significantly higher in the hypertensive rats. Sympathetic blockade with an intravenous injection of propranolol produces a higher decrease in heart rate of hypertensive rats than in control rats. Intravenous injection of atropine produces an increase in heart rate in both groups of animals. It is significantly higher in the control rats than in hypertensive animals. When the autonomic nervous system is blocked with atropine and propranolol, intrinsic heart rate is similar in both groups of animals. Similar results are obtained after blocking ganglionic transmission with hexamethonium. No significative differences are observed in heart rate after intracerebroventricular injection of hemicholinium-3 between both groups of rats. Results show an increased cardiac sympathetic tone, reduced parasympathetic activities, no alterations in the pacemaker activity and implications of central acetylcholine. These alterations in the autonomic nervous system have an important role in the maintenance of elevated heart rate in this experimental model of arterial hypertension.