Insulin versus glucagon crosstalk: central plus peripheral mechanisms.

Plasma glucose level depends on the peripheral intra-islet crosstalk between A cells (glucagon) + B-cells (insulin) and D-cells (somatostatin). Gastrointestinal hormones (secretin, CCK-PZ, gastrin, and serotonin) modulate the glucose- and amino acids-induced secretions of insulin and glucagon, respectively. Serotonin (5-HT) arose from the enterochromaffin cells during postprandial periods excites basal but inhibits excited B-cells. Serotonin excites adrenal glands that release adrenaline (Ad) + dopamine (DA). The former is positively correlated with hyperglycemia, whereas DA antagonizes this effect. Noradrenaline (NA) released from both sympathetic nerves and adrenal glands modulates the Ad release from this latter and excites A-cells. Thus, NA attenuates the hyperglycemic effects triggered by Ad. Dopamine released from both sources, adrenal glands and peripheral sympathetic nerves, antagonizes Ad-induced hyperglycemia plus the NA-triggered glucagon secretion. Both plasma insulin and glucagon cross the blood-brain barrier and excite A5(NA) and C1(Ad) neurons, respectively. C1 (Ad) neurons send excitatory drives to both islet A-cells and adrenal glands. Both central nervous system A5(NA) and C1(Ad) nuclei interchange inhibitory axons. Predominance of the former redounds in hyperinsulinism plus hypoglycemia, whereas the latter axis is responsible for hyperglucagonemia + hyperglycemia. In addition, the dorsal raphe serotonergic and the median raphe serotonergic nuclei interchange excitatory axons with the C1 (Ad) and the A5(NA) neurons, respectively. Hence, the former binomial axis (responsible for uncoping stress) is positively correlated with the hyperglycemic syndrome, whereas the A5(NA) + median raphe serotonergic binomial is correlated with hypoglycemia. Hence, the insulin resistance disorder should be underlain by the overactivity of both axes simultaneously. The above pathophysiological mechanisms are consistent with the successful neuropharmacological manipulations addressed to treat these neuroendocrine syndromes. Finally, one of the showiest findings derived from our research work arises from the unbalance between the DA versus 5-HT circulating parameters demonstrating that absolute predominance of the former is always paralleled by hypoglycemia (endogenous depression syndrome), whereas the opposite profile is registered in mammals affected by hyperglycemia (dysthymic depression and uncoping stress syndromes).

Effects of amantadine on circulating neurotransmitters in healthy subjects.

Considering that glutamatergic axons innervate the C1(Ad) medullary nuclei, which are responsible for the excitation of the peripheral adrenal glands, we decided to investigate catecholamines (noradrenaline, adrenaline and dopamine) plus indolamines (plasma serotonin and platelet serotonin) at the blood level, before and after a small oral dose of amantadine, a selective NMDA antagonist. We found that the drug provoked a selective enhancement of noradrenaline plus a minimization of adrenaline, dopamine, plasma serotonin and platelet serotonin circulating levels. Significant enhancement of diastolic blood pressure plus reduction of systolic blood pressure and heart rate paralleled the circulating parameter changes. The above findings allow us to postulate that the drug was able to enhance the peripheral neural sympathetic activity. Minimization of both adrenal sympathetic and parasympathetic activities was also registered after the amantadine challenge. The above findings supported the postulation that this drug should be a powerful therapeutic tool for treating diseases affected by adrenal sympathetic hyperactivity.

Effects of an oral dose of l-glutamic acid on circulating neurotransmitters: Possible roles of the C1(Ad) and the A5(NA) pontomedullary nuclei.

OBJECTIVE: Investigation of the effects of an oral administration of a small dose of l-glutamic acid on the two peripheral sympathetic branches (neural and adrenal) of the autonomic nervous system. RESEARCH DESIGN AND METHODS: Circulating neurotransmitters and cardiovascular parameters were assessed in 28 healthy volunteers before and after the administration of 500 mg of l-glutamic acid or placebo. RESULTS: The drug triggered a significant and sustained enhancement of the noradrenaline and dopamine circulating levels which were paralleled and positively correlated with the diastolic blood pressure increases. Conversely, both platelet and plasma serotonin showed significant falls throughout the test. Significant positive correlations were registered between noradrenaline, dopamine, and noradrenaline/dopamine ratio versus diastolic blood pressure but not versus systolic blood pressure or heart rate. CONCLUSION: The above results allowed us to postulate that the drug provoked a significant enhancement of peripheral neural sympathetic activity and the reduction of adrenal sympathetic and parasympathetic drives. Both sympathetic branches are positively correlated with the A5 noradrenergic and the C1 adrenergic pontomedullary nuclei, which interchange inhibitory axons that act at post-synaptic α2 inhibitory autoreceptors. In addition, we discussed the mechanisms able to explain why the drug acted preferentially at the A5 noradrenergic rather than the C1 adrenergic nuclei.

Amantadine reduces glucagon and enhances insulin secretion throughout the oral glucose tolerance test: central plus peripheral nervous system mechanisms.

OBJECTIVE: The purpose of the trial was to examine the effects of amantadine, a N-methyl-D-aspartate (NMDA) antagonist, on the oral glucose tolerance test (OGTT) plus insulin, glucagon and neurotransmitters circulating levels. Previous findings showed that hyperinsulinism and type 2 diabetes are positively associated with neural sympathetic and adrenal sympathetic activities, respectively. These peripheral sympathetic branches depend on the pontine (A(5)-noradrenergic) and the rostral ventrolateral (C(1)-adrenergic) medullary nuclei. They are excited by glutamate axons which act at NMDA postsynaptic receptors. RESEARCH DESIGN AND METHODS: One OGTT plus placebo and one OGTT plus oral amantadine test were carried out two weeks apart in 15 caucasic normal voluntary humans. Noradrenaline, adrenaline, dopamine, plasma-free serotonin, platelet serotonin, glucose, glucagon, and insulin were measured throughout the 180-minute testing period. RESULTS: Maximal reductions of plasma glucose and glucagon plus exacerbated insulin rises were significantly greater throughout the oral glucose plus amantadine test than those registered throughout the oral glucose plus placebo challenge. The above findings were paralleled by greater than normal noradrenaline/adrenaline plasma ratio increases. In addition, maximal reductions of the platelet serotonin and plasma serotonin circulating values contrasted with the normal rises of these parameters, always registered during the glucose load plus placebo challenge. CONCLUSION: This study supports the theory that amantadine might be a powerful antidiabetic tool and could be added to the therapeutic arsenal against type 2 diabetes.

Central nervous system plus autonomic nervous system disorders responsible for gastrointestinal and pancreatobiliary diseases.

Clinical digestive disorders depend on the non-adequate coupling of functioning of the gastrointestinal tract with that of its affluent systems, namely, the pancreatic exocrine and the hepato-biliary secretions. The secretion of gastrointestinal hormones is monitored by the peripheral autonomic nervous system. However, the latter is regulated by the central nervous system (CNS) circuitry localized at the medullary pontine segment of the CNS. In turn, both parasympathetic and adrenergic medullary circuitries are regulated by the pontine A5 noradrenergic (NA) and the dorsal raphe serotonergic nuclei, respectively. DR-5HT is positively correlated with the C1-Ad medullary nuclei (responsible for adrenal gland secretion), whereas the MR-5HT nucleus is positively correlated with the A5-NA pontomedullary nucleus. The latter is responsible for neural sympathetic activity (sympathetic nerves). Both types of sympathetic activities maintain an alternation with the peripheral parasympathetic branch, which is positively correlated with the enterochromaffin cells that secrete serotonin. Serotonin displays hormonal antagonism to the circulating catecholamines.

Central nervous system circuitry involved in the hyperinsulinism syndrome.

Raised plasma levels of insulin, glucose and glucagon are found in patients affected by 'hyperinsulinism'. Obesity, hypertension, mammary plus ovary cysts and rheumatic symptoms are frequently observed in these patients. Sleep disorders and depression are also present in most subjects affected by this polysymptomatic disorder. The simultaneous increases of glucose, insulin and glucagon plasma levels seen in these patients indicate that the normal crosstalk between A cells, B cells and D cells is disrupted. With respect to this, it is well known that glucose excites B cells (which secrete insulin) and inhibits A cells (which secrete glucagon), which in turn excites D cells (which secrete somatostatin). Gastrointestinal hormones (incretins) modulate this crosstalk both directly and indirectly throughout pancreatic and hepatobiliary mechanisms. The above factors depend on autonomic nervous system mediation. For instance, acetylcholine released from parasympathetic nerves excites both B and A cells. Noradrenaline released from sympathetic nerves and adrenaline secreted from the adrenal glands inhibit B cells and excite A cells, which are crowded with beta(2)- and alpha(2)-receptors, respectively. Noradrenaline released from sympathetic nerves also excites A cells by acting at alpha(1)-receptors located at this level. According to this, the excessive release of noradrenaline from these nerves should provoke an enhancement of glucagon secretion which will result in overexcitation of insulin secretion from B cells. That is the disorder seen in the so-called 'hyperinsulinism', in which raised plasma levels of glucose, insulin and glucagon coexist. Taking into account that neural sympathetic activity is positively correlated to the A5 noradrenergic nucleus and median raphe serotonergic neurons, and negatively correlated to the A6 noradrenergic, the dorsal raphe serotonergic and the C1 adrenergic neurons, we postulate that this unbalanced central nervous system circuitry is responsible for the hyperinsulinism syndrome.

Central nervous system circuitry and peripheral neural sympathetic activity responsible for essential hypertension.

Both clinical and experimental studies dealing with patients affected by idiopathic or essential hypertension (EH) are devoted to the great deal of physiological, pharmacological and pathological as well as therapeutical issues of EH. However, most articles devoted to EH do not refer to the central nervous system mechanisms underlying this disease and the channels which allow that these mechanisms are funneled to the peripheral autonomic nervous system and trigger this cardiovascular disorder. In the present review article we attempted to reach this target devoted to the central nervous system circuitry involved in the cardiovascular pathophysiology. We postulated that EH depends on the predominance of the binomial A5 noradrenergic (NA) nucleus + median raphe serotonergic (5-HT) nucleus over the (A6)-NA + dorsal raphe-5HT nuclei. This hypothesis receives additional support from our results obtained throughout the neuropharmacological therapy of this type of neurophysiological disorder. Our therapeutical strategy is addressed to enhance the activity of the (A6)-NA + dorsal raphe-5HT binomial circuitry.

Dorsal raphe vs. median raphe serotonergic antagonism. Anatomical, physiological, behavioral, neuroendocrinological, neuropharmacological and clinical evidences: relevance for neuropharmacological therapy.

Monoaminergic neurons located in the central nervous system (CNS) are organized into complex circuits which include noradrenergic (NA), adrenergic (Ad), dopaminergic (DA), serotonergic (5-HT), histaminergic (H), GABA-ergic and glutamatergic systems. Most of these circuits are composed of more than one and often several types of the above neurons. Such physiologically flexible circuits respond appropriately to both external and internal stimuli which, if not modulated adequately, can trigger pathophysiologic responses. A great deal of research has been devoted to mapping the multiple functions of the CNS circuitry, thereby forming the basis for effective neuropharmacological therapeutic approaches. Such lineal strategies that seek to normalize complex and mixed physiological disorders, however, meet only partial therapeutic success and are often followed by undesirable side effects and/or total failure. In light of these, we have worked to develop possible models of CNS circuitry that are less affected by physiological interaction using the models to design more effective therapeutic approaches. In the present review, we cite and present evidence supporting the dorsal raphe versus median raphe serotonergic circuitry as one model of a reliable paradigm, necessary to the clear understanding and therapy of many psychiatric and even non-psychiatric disturbances.

Acute effects of tianeptine on circulating neurotransmitters and cardiovascular parameters.

Tianeptine is a serotonin-uptake enhancer drug whose antidepressant effectiveness is based on its ability to reduce rather than increase serotonin availability at the synaptic cleft. This paradoxical neuropharmacological mechanism has raised doubt among neuropharmacologists and psychiatrists as to the role of tianeptine as a trusty-reliable antidepressant drug. This controversial issue led us to investigate the acute effects of a single, oral dose (12.5 mg) of this drug on circulating neurotransmitters and cardiovascular parameters in 50 healthy subjects. The drug provoked a striking and significant reduction of plasma noradrenaline (NA) and plasma serotonin (f-5-HT) while it increased plasma dopamine (DA) and platelet serotonin (p-5-HT) concentrations within the 4-h study period. No adrenaline (Ad) changes were registered. The NA/Ad ratio and the f-5-HT/p-5-HT ratio showed significant reduction throughout the test. Finally, although diastolic blood pressure (DBP) showed significant decrease, neither systolic blood pressure (SBP) nor heart rate (HR) showed significant change. These findings are consistent with the postulation that tianeptine reduces both neural sympathetic activity and parasympathetic activity without affecting adrenal sympathetic activity, enabling us to discuss the possible mechanisms involved in the antidepressant effects of tianeptine. The well-known fact that major depressed patients always show raised NA plus lower than normal p-5-HT levels, both disorders which are normalized by tianeptine, gives neurochemical support to the clinical improvement triggered by the drug in these patients. Summarizing, the results presented in this study demonstrate that tianeptine triggers significant reduction of circulating noradrenaline and plasma serotonin while increasing circulating dopamine and platelet serotonin. Other possible neuropharmacological effects are also discussed.

Neurochemical, neuroautonomic and neuropharmacological acute effects of sibutramine in healthy subjects.

Sibutramine is a neuropharmacological drug that exerts central (CNS) and peripheral effects including noradrenaline (NA), and serotonin (5-HT) uptake inhibition. In addition, the drug is able to induce release from DA axons. We measured levels of circulating neurotransmitters in 20 healthy subjects during supine-resting (fasting) state before and after 15 mg of oral sibutramine. Systolic blood pressure (SBP), diastolic blood pressure (DBP), and heart rate (HR) were also monitored. Sibutramine triggered sustained and progressive increase of NA, NA/Ad ratio and DBP. Slight increases of DA were also registered between the 60 and 240 min periods. The rise in DA tended to fade progressively, reaching basal level at 360 min period. Diastolic blood pressure, but neither SBP nor HR, showed significant increases that correlated positively with NA/Ad ratios. Slight but significant negative correlation was also found between DBP and DA. This correlation tended to fade throughout the trial to show no significance at the 360 min period. Although neither plasma serotonin (f-5HT) nor platelet serotonin (p-5HT) values showed significant variation throughout the trial, the f-5HT/p-5HT ratio showed significant decrease throughout. Significant negative correlation was found between f-5HT/p-5HT ratio and NA/Ad ratio. Our results indicate that sibutramine stimulates neural sympathetic activity but not adrenal sympathetic activity in healthy individuals. Further, sibutramine lowers parasympathetic activity. The moderate rise in diastolic blood pressure triggered by sibutramine would be associated with CNS-NA enhancement plus parasympathetic inhibition.

Circulating neurotransmitters during the different wake-sleep stages in normal subjects.

We investigated the changes of circulating neurotransmitters during the wake-sleep cycle in order to find possible correlations with the activity of central neurocircuitry functioning. Noradrenaline (NA), adrenaline (Ad), dopamine (DA), platelet serotonin (p-5HT), plasma serotonin (f-5HT) and plasma tryptophan (TRP) were assessed during the morning (supine resting + 1-min orthostasis + 5-min exercise) and at night (supine resting + slow wave sleep (SWS) + REM sleep). Only NA increased in the plasma during short-lasting (1-min) orthostasis morning waking period. Both NA and Ad rose during moderate exercise. The nocturnal results demonstrated that whereas Ad dropped during the supine resting, NA did not fall until SWS period. Although DA did not show significant changes during the nocturnal test, the NA/DA ratio showed significant reduction. The analysis of correlations supports the postulation that this finding reflects the DA modulatory role on neural sympathetic activity. Both f-5HT and p-5HT values were lower during sleep cycle than wake periods. However, they showed progressive rises during sleep stages. Conversely, the f-5HT/p-5HT ratio showed significantly greater values during the SWS period than during supine resting and REM periods. These findings are consistent with the postulation that f-5HT/p-5HT ratio is positively associated with parasympathetic activity during the sleep-cycle. We concluded that the profile of sleep-cycle circulating neurotransmitters differs from that obtained during waking periods. According to the above, we attempted to correlate the profile of circulating neurotransmitters with the very well-known central neurocircuitry functioning during wake-sleep cycle, in experimental mammals.

Two types of irritable bowel syndrome: pathophysiologic and pharmacological considerations / Dos tipos del síndrome de intestino irritable: consideraciones patofisiológicas and farmacológicas

The investigation performed in 18 diarrheid and 24 spastic patients showed adrenal glands hyperactivity in the former and hypoactivity in the latter. The central noradrenergic system was unresponsive to glucose in both groups: probably due to glucose-insulin failure to rise in diarrheics, whereas a hyperactive parasympathetic system may have been resposible in spactics. Diarrheics had the lowest sigmoidal tone with rectal hyperactivity and the highest plasma catecholamines + cortisol + glucose + insulin values. Spastic patients, in turn, had the highest sigmoidal tone and the lowest catecholamine values. Plasma glucose, insulin, platelet serotocin and sigmoidal tone rose in spactics, after glucose ingestion, but failed to do so in diarrheics. Further, in spactic patients, sigmoidal tone correlated positively with platelet serotonin and negatively with noradrenaline. The clonidine test showed hyperresponsivenes of growth hormone, cortisol and diastolic blood pressure in diarrheics, compared to a normal response in spastics, alpha-adrenergic antagonists suppressed diarrhea and renal hiperactivity. Alpha adrenergic agonists (wich also deplete plattelet-and myentericplexa serotonin) reduced signoidal tone to zero, increased rectal activity and provoked diarrhea. These findings suggest that peripheral sympathetic activity (prevalent in diarrheics) and hyperparasympathetic activity (prevalent in spactics) trigger these physiological disorders by respectively suppressing and reinforcing the serotonin-plexa level functioning