Effect of vagotomy on plasma levels of growth hormone, free fatty acids and glucose in the pigeon

Plasma levels of growth hormone (GH), free fatty acids (FFA) and glucose were measured in vagotomized (VgX) and sham-operated (VgS) control pigeons. In VgX pigeons, GH level was significantly lower whereas FFA and glucose levels were higher than in VgS pigeons. The depression in GH level in VgX pigeons has been attributed to the significantly high levels of norepinephrine (NE) and corticosterone in these Birds. The higher plasma FFA concentration in VgX pigeons was therefore due to adipokinetic hormonal action other than of GH. It has been suggested that the adrenocorticotrophic hormone (ACTH) and/or NE could have produced the increase in plasma FFA in VgX pigeons. The pronounced hyperglycemia seen in VgX pigeons has been attributed to catecholamine action in the absence of the vagal tone.     

Effect of thermal stress and dehydration on plasma levels of glucose, free fatty acids and growth hormone in the pigeon.

Pigeons were subjected to high ambient temperature and water deprivation for 3 days (28 degrees C, 31 degrees C and 36.5 degrees C respectively). After 3 days of heat stress and dehydration, the plasma levels of glucose, free fatty acids (FFA) and growth hormone (GH) were measured. Although the level of plasma glucose was not significantly altered, FFA and GH were found to be significantly increased. The possible mediation of the neurohypophysial hormone, vasotocin, in the syndhronous rise in plasma GH and FFA, is suggested.     

The effect of vasotocin on plasma glucose, free fatty acids and growth hormone in the frog, Rana catesbeiana

Injections of arginine vasotocin into bullfrogs had no effect on plasma glucose after 30 min. but caused hyperplycemia after 120 min. Plasma levels of growth hormone were elevated earlier (30 min.) and returned to control levels after 120 min. Plasma free fatty acids were unaltered following vasotocin administration. It is suggested that the hyperglycemic effect of vasotocin may be mediated via growth hormone.     

Effects of prostaglandin E1 on lipolysis and plasma free fatty acids in the fasted rat

Contrary to published reports, prostaglandin E(1) (PGE(1)) in vitro and in vivo inhibited fasting lipolysis in rats. Adipose tissue lipolysis was inhibited when the tissue was incubated in the presence of PGE(1) and when the compound was administered intravenously. A biphasic plasma free fatty acid (FFA) response was obtained in fasted rats after intravenous injection of 80 micrograms of PGE(1) per kg body weight; plasma FFA concentrations were lowered at 7 min, elevated at 15 min, and at normal concentrations at 30 min. The FFA depression at 7 min was independent of the animal's nutritional state, but the rebound at 15 min did not occur in fed rats. The plasma FFA rebound in fasted rats at 15 min may be a consequence of rapid inactivation of PGE(1), followed by unopposed activity of factors which enhance fasting lipolysis.     

Flight effects on plasma levels of free fatty acids, growth hormone and thyroid hormones in homing pigeons

Significant increases in circulating levels of free fatty acids (FFA) and growth hormone (GH), were observed in homing pigeons after a flight of 48 km, lasting 60-80 min. No significant change in plasma levels of thyroxine (T4) and triiodothyronine (T3) was observed. Nor was there any change in T3/T4 ratio. The increase in plasma FFA is attributed to the increased release into circulation of at least one adipokinetic hormone, GH. It may be concluded that in free sustained homing flight under normal weather conditions and within the specific distance and duration, metabolic fuel and hormonal homeostasis is maintained.     

The effect of prostaglandin E1 on free fatty acid mobilization and transport

Summary Prostaglandin E₁ (administered by intravenous infusion at the dosis of 5.6g/kg/min.) (markedly decreases plasma free fatty acids in Sprague-Dawley rats treated with ACTH or norepinephrine or exposed to cold.The blocking effect is absent in fasted animals, indicating a specific effect of PGE₁ on the hormone-activated lipase.     

Serum glucose and free fatty acids modulate growth hormone and luteinizing hormone secretion in the pig

Two experiments were conducted to determine the effect of free fatty acids (FFA) and glucose treatment on growth hormone (GH) and luteinizing hormone secretion in the pig. In Experiment (Exp) 1, 15 prepuberal gilts received an intravenous infusion of FFA (n = 5; 3 ml of 10% Liposyn II/kg), glucose (n = 5; 1 g/kg), or saline (n = 5; 3 ml of 0.9%/kg). Jugular blood samples were collected every 15 min for 2 hr before and 3 hr after intravenous infusion of saline, FFA, and glucose. Synthetic [Ala15]-h growth hormone-releasing factor-(1-29)NH2 (1 microgram/kg) and gonadotropin-releasing hormone (0.2 micrograms/kg) were administered 30 min after infusion (Time 0 = infusion). In Exp 2, eight prepuberal gilts received either FFA (n = 4) or saline (n = 4) as described in Exp 1, except that treatments were given every hour ove a 10-hr period. Blood samples were collected every 15 min from 1 hr before to 10 hr after the start of FFA or saline infusion. In Exp 1, the peak GH response to growth hormone-releasing factor was delayed by 45 min (P less than 0.01) by glucose treatment and suppressed (P less than 0.01) by FFA treatment. The luteinizing hormone response to gonadotroph-releasing hormone was suppressed (P less than 0.03) by glucose and enhanced (P less than 0.03) by FFA. In Exp 2, the number of GH pulses was increased (P less than 0.05) by FFA infusion and GH concentrations were positively correlated (r = 0.58, P less than 0.0003) with FFA concentrations, while luteinizing hormone pulse amplitude was greater (P less than 0.01) in FFA gilts than in saline gilts. These results indicate that FFA are more effective modulators of GH secretion than acute hyperglycemia, while metabolic status can alter pituitary responsiveness to gonadotropin-releasing hormone.     

Adrenergic effects on plasma levels of glucagon, insulin, glucose and free fatty acids in rabbits

Adrenergic effects on plasma levels of glucagon, insulin, glucose and free fatty acids were studied in fasted rabbits by infusing epinephrine, norepinephrine, isoproterenol, phentolamine (an adrenergic alpha-receptor blocking drug) and propranolol (an adrenergic beta-receptor blocking drug). The adrenergic effects on the plasma levels of insulin, glucose and free fatty acids were similar to those found in other species. The plasma levels of insulin were increased by beta-receptor stimulation (isoproterenol, phentolamine + epinephrine) and decreased by alpha-receptor stimulation (epinephrine, norepinephrine, propranolol + epinephrine). The plasma levels of glucose were increased by both alpha- and beta-receptor stimulation, and the epinephrine-induced hyperglycaemia was only blocked by combined infusions with phentolamine and propranolol. The plasma levels of free fatty acids were increased by saline and further increased by beta-receptor stimulation (isoproterenol), while epinephrine and norepinephrine gave variable results. Alpha-receptor stimulation (propranolol + epinephrine) slightly decreased the plasma levels of free fatty acids. The plasma levels of glucagon, however, were mainly increased by alpha-receptor stimulation (epinephrine, norepinephrine, propranolol + epinephrine) and increased only to a minor extent by beta-receptor stimulation (isoproterenol, phentolamine + epinephrine) in rabbits. This is in contrast to results reported for humans, where beta-receptor stimulation seems to be most important in stimulating glucagon release.     

The role of insulin, glucagon and growth hormone in the regulation of plasma glucose and free fatty acid levels in anorexia nervosa

It is well established that glucagon plays an important role in the regulation of fuel supplies as its plasma level increases during the first days of a complete fast. However, it is not certain that glucagon is involved in the adaptation to chronic starvation. In the present study, this problem was investigated by the determination of the changes in the plasma glucagon level elicited by an i.v. glucose tolerance test followed by an i.v. arginine perfusion in 26 self starved patients suffering from anorexia nervosa (AN) and 14 control patients having only minor neurotic disorders. The basal plasma glucagon level tended to be higher in the AN patients than in the controls; but the difference was not statistically significant. Glucagon responses to glucose and arginine observed in the AN patients were not significantly different from those seen in the control patients. In the AN patients, the insulin response to both loads was reduced and the plasma GH level increased paradoxically after the glucose load, whereas it rose normally after the arginine load. It may be concluded that in chronic starvation by AN the regulation of fuel supplies depends mainly on decreased insulin and increased growth hormone secretion. The role of glucagon seems to be of minor importance in this condition.     

Effects of prostaglandin B1 on basal and stimulated circulating levels of insulin, glucose and free fatty acids

The influence of an infusion of PGB₁ upon circulating levels of insulin, glucose and free fatty acids in anesthetized dogs both in the basal state and following stimulation with intravenous glucose or norepinephrine was not significantly different from saline-treated controls. Since no increment in immunoreactive PGE was found in thoracic aorta plasma during PGB₁ infusion, it is unlikely that the observed trends in the insulin, glucose and free fatty acid data during PGB₁ infusion were due to simultaneous endogenous PGE formation.     

Diurnal variation in circulating levels of free fatty acids and growth hormone during crop gland activity in the pigeon (Columba livia).

1. Circulating levels of free fatty acids (FFA) and growth hormone (GH) were measured over a 24 hr period during the crop gland cycle of domestic pigeons (Columba livia). 2. Plasma FFA levels showed a marked circadian rhythm (p less than 0.004) with the peak level (considerably higher than that previously reported in nonbreeding pigeons) occurring at approximately 2400 hr. 3. It is suggested that these elevated levels reflect the increased demands for energy during incubation and crop "curd" production. 4. Diurnal fluctuations of plasma GH synchronizing with those of plasma FFA were not significant though peak concentrations were noted 4 hr previous to those of FFA. 5. Pigeons studied 12 days after hatching of young had the lowest levels of both plasma GH (p less than 0.06) and FFA (p less than 0.02) indicating their interacting relationship. 6. A consistently higher FFA level (p less than 0.02) was observed in the crop glands of male pigeons.