Studies have shown the levels of free serotonin in plasma are increased in symptomatic patients with asthma. In addition, the concentration of free serotonin in symptomatic children with asthma correlates positively with clinical status and negatively with pulmonary function (forced expiratory volume in 1 second [FEV1]). Thus, reducing the concentration of free serotonin in plasma may be useful in treating children with asthma. We studied the effectiveness of tianeptine in treating these patients. Tianeptine is the only drug known to be able to reduce the level of free serotonin in plasma and to enhance the uptake by platelets. Sixty-nine of the 82 children with asthma initially enrolled participated in this study. Children were randomized to receive tianeptine or placebo or both in a double-blind crossover trial. The trial lasted 52 weeks. Tianeptine provoked a dramatic and sudden decrease of both clinical rating and free serotonin plasma levels and an increase in pulmonary function.
Studies have shown that levels of free serotonin in plasma are increased in symptomatic patients with asthma. In addition, the concentration of free serotonin in symptomatic patients with asthma correlates positively with clinical status and negatively with pulmonary function. Thus, reducing the concentration of free serotonin in plasma might be useful in treating patients with asthma. We studied the effectiveness of tianeptine in treating patients with asthma. Tianeptine is the only drug known to be able to reduce levels of free serotonin in plasma and to enhance uptake by platelets. In this study, 69 children with asthma were assigned in randomized fashion to receive tianeptine and/or placebo in a double-blind crossover trial that lasted 52 weeks. Tianeptine provoked a dramatic and sudden decrease in both clinical rating and free serotonin plasma levels and an increase in pulmonary function.
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 β2- and α2-receptors, respectively. Noradrenaline released from sympathetic nerves also excites A cells by acting at α1-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.
Although the concept of functional illness has blurred boundaries, some consensus exists on its understanding among clinicians. In short, it is easier to conceive than to define functional illness. Semantic and conceptual discussion concerning this issue have been endless. Many links exist that connect brain and body (mind and organs, psyche and soma). Amongst them, neurotransmitters, released by peripheral neurons and some glandular cells (adrenal, enterochromaffm cells, mast cells), are diverted into the bloodstream. Although neurotransmitters cannot cross the blood-brain barrier, basic and clinical research has progressively established the relationship between central and peripheral neurochemical activities. Hence, it is possible to obtain some approach to the central profile through the measurement of circulating neurotransmitters. However, this approach is more reliable if we can measure all circulating factors and, in addition, test the responses to different kinds of challenges (stressors, drugs, etc.). All diseases (somatic, psychiatric and psychosomatic) present some kind of plasma neurotransmitter disturbance; however, only in some has the whole abnormal profile been established. Technical difficulties as well as expensive procedures have interfered with the generalization of this research area. In the present review article, we summarize data quoted from current scientific literature reporting exhaustive research in this area.
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