Тиреоидная функция до и после лечения психотического эпизода

Background
Endocrine function in psychiatric patients may be affected by mental disorder itself as well as by antipsychotic medications.
The aim of this naturalistic observational study was to determine if treatment of acute psychotic episode with antipsychotic medication affects thyroid axis hormone concentrations and if such changes are associated with symptomatic improvement.
Methods
Eighty six adult acute psychotic patients, consecutively admitted to a mental hospital, were recruited for the study. All patients were physically healthy and without thyroid disease. During the hospitalization period all study patients received treatment with antipsychotic medication according to clinical need. Severity of the psychotic episode was evaluated using the Brief Psychiatric Rating Scale (BPRS) and venous blood samples were drawn for analysis of free triiodothyronine (FT3), free thyroxine (FT4), and thyroid stimulating hormone (TSH) concentrations on the day of admission and on the day of discharge from the hospital.
Results
Antipsychotic drug treatment was associated with decrease of mean FT3 (p < 0.001) and FT4 (p = 0.002) concentrations; and with increase of mean TSH (p = 0.016) concentrations. Changes in thyroid hormone concentrations were mostly predicted by baseline hormone concentrations. Individual changes were not limited to decrease in high hormone concentrations; in patients who had low FT3 or FT4 concentrations, treatment resulted in increase in concentrations. Such an increase was established in one-quarter of patients for FT3 concentrations and in one-third of patients for FT4 concentrations. Fall in FT4 concentrations negatively correlated with the improvement in the BPRS score (r = −0.235, p = 0.023).
Conclusions
The study indicates that antipsychotic treatment resulted in a decrease in mean FT3 concentrations and in an increase in mean TSH concentrations after recovery from acute psychosis. Symptomatic improvement was less evident in patients who experienced a decrease in FT4 concentrations.

 Thyroid axis function after in-patient treatment of acute psychosis with antipsychotics: a naturalistic study

Тестирование тиреоидной функции у больных депрессией

In Depression & Your Thyroid, Ross lays out a step-by-step guide for testing and diagnosis. The first step is to figure out if you have any of the symptoms of low thyroid and to discuss this with your doctor. These are some of the signs of thyroid dysfunction. (You may experience only a few of these.)

• Fatigue
• Puffy face
• Oversensitivity to cold
• Difficulty concentrating or remembering things
• Tingling or numbness in hands and legs
• Hair loss
• Dry skin
• Weight gain
• Difficulty breathing
• Low blood pressure
• Low body temperature
• Slow pulse
• Slow reflexes
• Infertility or repeated miscarriages

Next, your doctor should conduct a physical examination, which will include checking your blood pressure, pulse, reflexes and thyroid gland. In people with low thyroid, blood pressure and pulse are low and reflexes are sluggish. Ross notes that during your physical exam, your thyroid gland tends to be normal.
Because people with low thyroid typically get cold easily and have a low temperature, Ross suggests keeping a record of your temperature every morning for five days. Keep a thermometer by your bed and check it before getting up or moving.
The first round of tests should include: Free T3; free T4; TSH (thyroid-stimulating hormone); antiperoxidase antibody and antithyroglobulin antibody. (Learn more here.)
The second round of tests includes a 24-hour urine sample for T3 and T4 hormones. (Sometimes the tests will include a TBII or thyroid-binding inhibitory immunoglobulin, but it’s not typically ordered.)
Doctors perform the third round of tests to absolutely confirm that a person has hypothyroidism. They may look at adrenal function, male and female hormones, virus and bacterial infections, intestinal parasites, molds, food sensitivities, minerals, toxic metals, liver, coagulation, antioxidants, amino acids and organic acids. Whether you have any of these tests will depend on your symptoms and the previous tests.

 Is Thyroid Dysfunction Driving Your Depression?

левотироксин натрия, взаимодейсвия

Table 2: Drug– Thyroidal Axis Interactions

Drug or Drug Class	Effect
Drugs that may reduce TSH secretion -the reduction is not sustained; therefore, hypothyroidism does not occur
Dopamine / Dopamine Agonists Glucocorticoids Octreotide	Use of these agents may result in a transient reduction in TSH secretion when administered at the following doses: Dopamine(≥ 1 mcg/kg/min); Glucocorticoids (hydrocortisone≥ 100 mg/day or equivalent); Octreotide (> 100 mcg/day).
Drugs that alter thyroid hormone secretion
Drugs that may decrease thyroid hormone secretion, which may result in hypothyroidism
Aminoglutethimide Amiodarone Iodide (including iodine- Containing Radiographic contrast agents) Lithium Methimazole Propylthiouracil (PTU) Sulfonamides Tolbutamide	Long-term lithium therapy can result in goiter in up to 50% of patients, and either subclinical or overt hypothyroidism, each in up to 20% of patients. The fetus, neonate, elderly and euthyroid patients with underlying thyroid disease (e.g., Hashimoto's thyroiditis or with Grave's disease previously treated with radioiodine or surgery) are among those individuals who are particularly susceptible to iodine-induced hypothyroidism. Oral cholecystographic agents and amiodarone are slowly excreted, producing more prolonged hypothyroidism than parenterally administered iodinated contrast agents. Long-term aminoglutethimide therapy may minimally decrease T4 and T3 levels and increase TSH, although all values remain within normal limits in most patients.
Drugs that may increase thyroid hormone secretion, which may result in hyperthyroidism
Amiodarone Iodide (including iodine- containing Radiographic contrast agents)	Iodide and drugs that contain pharmacologic amounts of iodide may cause hyperthyroidism in euthyroid patients with Grave's disease previously treated with antithyroid drugs or in euthyroid patients with thyroid autonomy (e.g., multinodular goiter or hyperfunctioning thyroid adenoma). Hyperthyroidism may develop over several weeks and may persist for several months after therapy discontinuation. Amiodarone may induce hyperthyroidism by causing thyroiditis.
Drugs that may decrease T4 absorption, which may result in hypothyroidism
Antacids - Aluminum & Magnesium Hydroxides - Simethicone Bile Acid Sequestrants - Cholestyramine - Colestipol Calcium Carbonate Cation Exchange Resins - Kayexalate Ferrous Sulfate Sucralfate	Concurrent use may reduce the efficacy of levothyroxine by binding and delaying or preventing absorption, potentially resulting in hypothyroidism. Calcium carbonate may form an insoluble chelate with levothyroxine, and ferrous sulfate likely forms a ferric-thyroxine complex. Administer levothyroxine at least 4 hours apart from these agents.
Drugs that may alter T4 and T3 serum transport – but FT4 concentration remains normal; and, therefore, the patient remains euthyroid
Drugs that may decrease serum TBG concentration	Drugs that may increase serum TBG concentration
Clofibrate Estrogen-containing oral contraceptives Estrogens (oral) Heroin / Methadone 5-Fluorouracil Mitotane Tamoxifen	Androgens / Anabolic Steroids Asparaginase Glucocorticoids Slow-Release Nicotinic Acid
Drugs that may cause protein-binding site displacement
Furosemide ( > 80 mg IV) Heparin Hydantoins Non Steroidal Anti-Inflammatory Drugs - Fenamates - Phenylbutazone Salicylates ( > 2 g/day)	Administration of these agents with levothyroxine results in an initial transient increase in FT4. Continued administration results in a decrease in serum T4 and normal FT4 and TSH concentrations and, therefore, patients are clinically euthyroid. Salicylates inhibit binding of T4 and T3 to TBG and transthyretin. An initial increase in serum FT4 is followed by return of FT4 to normal levels with sustained therapeutic serum salicylate concentrations, although total-T4 levels may decrease by as much as 30%.
Drugs that may alter T4 and T3 metabolism
Drugs that may increase hepatic metabolism, which may result in hypothyroidism
Carbamazepine Hydantoins Phenobarbital Rifampin	Stimulation of hepatic microsomal drug-metabolizing enzyme activity may cause increased hepatic degradation of levothyroxine, resulting in increased levothyroxine requirements. Phenytoin and carbamazepine reduce serum protein binding of levothyroxine, and total- and free-T4 may be reduced by 20% to 40%, but most patients have normal serum TSH levels and are clinically euthyroid.
Drugs that may decrease T4 5'-deiodinase activity
Amiodarone Beta-adrenergic antagonists - (e.g., Propranolol> 160 mg/day) Glucocorticoids - (e.g., Dexamethasone > 4 mg/day) Propylthiouracil (PTU)	Administration of these enzyme inhibitors decreases the peripheral conversion of T4 to T3, leading to decreased T3 levels. However, serum T4 levels are usually normal but may occasionally be slightly increased. In patients treated with large doses of propranolol ( > 160 mg/day), T3 and T4 levels change slightly, TSH levels remain normal, and patients are clinically euthyroid. It should be noted that actions of particular beta-adrenergic antagonists may be impaired when the hypothyroid patient is converted to the euthyroid state. Short-term administration of large doses of glucocorticoids may decrease serum T3 concentrations by 30% with minimal change in serum T4 levels. However, long-term glucocorticoid therapy may result in slightly decreased T3 and T4 levels due to decreased TBG production (see above).
Miscellaneous
Anticoagulants (oral) - Coumarin Derivatives - Indandione Derivatives	Thyroid hormones appear to increase the catabolism of vitamin K-dependent clotting factors, thereby increasing the anticoagulant activity of oral anticoagulants. Concomitant use of these agents impairs the compensatory increases in clotting factor synthesis. Prothrombin time should be carefully monitored in patients taking levothyroxine and oral anticoagulants and the dose of anticoagulant therapy adjusted accordingly.
Antidepressants - Tricyclics (e.g., Amitriptyline) - Tetracyclics (e.g., Maprotiline) - Selective Serotonin Reuptake Inhibitors (SSRIs; e.g., Sertraline)	Concurrent use of tri/tetracyclic antidepressants and levothyroxine may increase the therapeutic and toxic effects of both drugs, possibly due to increased receptor sensitivity to catecholamines. Toxic effects may include increased risk of cardiac arrhythmias and CNS stimulation; onset of action of tricyclics may be accelerated. Administration of sertraline in patients stabilized on levothyroxine may result in increased levothyroxine requirements.
Antidiabetic Agents - Biguanides - Meglitinides - Sulfonylureas - Thiazolidediones - Insulin	Addition of levothyroxine to antidiabetic or insulin therapy may result in increased antidiabetic agent or insulin requirements. Careful monitoring of diabetic control is recommended, especially when thyroid therapy is started, changed, or discontinued.
Cardiac Glycosides	Serum digitalis glycoside levels may be reduced in hyperthyroidism or when the hypothyroid patient is converted to the euthyroid state. Therapeutic effect of digitalis glycosides may be reduced.
Cytokines - Interferon-α - Interleukin-2	Thereapy wih interferon-α has been associated with the development of antithyroid microsomal antibodies in 20% of patients and some have transient hypothyroidism, hyperthyroidism, or both. Patients who have antithyroid antibodies before treatment are at higher risk for thyroid dysfunction during treatment. Interleukin-2 has been associated with transient painless thyroiditis in 20% of patients. Interferon-β and -γ have not been reported to cause thyroid dysfunction.
Growth Hormones - Somatrem - Somatropin	Excessive use of thyroid hormones with growth hormones may accelerate epiphyseal closure. However, untreated hypothyroidism may interfere with growth response to growth hormone.
Ketamine	Concurrent use may produce marked hypertension and tachycardia; cautious administration to patients receiving thyroid hormone therapy is recommended.
Methylxanthine Bronchodilators - (e.g., Theophylline)	Decreased theophylline clearance may occur in hypothyroid patients; clearance returns to normal when the euthyroid state is achieved.
Radiographic Agents	Thyroid hormones may reduce the uptake of 123I, 131I, and 99mTc
Sympathomimetics	Concurrent use may increase the effects of sympathomimetics or thyroid hormone. Thyroid hormones may increase the risk of coronary insufficiency when sympathomimetic agents are administered to patients with coronary artery disease.
Chloral Hydrate Diazepam Ethionamide Lovastatin Metoclopramide 6-Mercaptopurine Nitroprusside Para-aminosalicylate sodium Perphenazine Resorcinol (excessive topical use) Thiazide Diuretics	These agents have been associated with thyroid hormone and / or TSH level alterations by various mechanisms.

LEVOXYL® (levothyroxine sodium tablets, USP)

эндокринные эффекты нормотимиков

Both seizures and antiepileptic drugs may induce disturbances in hormonal system. Regarding endocrine effects of anticonvulsants, an interaction of these drugs with gonadal, thyroid, and adrenal axis deserves attention. Since majority of antiepileptic drugs block voltage dependent sodium and calcium channels, enhance GABAergic transmission and/or antagonize glutamate receptors, one may expect that similar neurochemical mechanisms are engaged in the interaction of these drugs with synthesis of hypothalamic neurohormones such as gonadotropin-releasing hormone (GnRH), thyrotropin-releasing hormone (TRH), corticotropin-releasing hormone (CRH) and growth hormone releasing hormone (GHRH). Moreover some antiepileptic drugs may affect hormone metabolism via inhibiting or stimulating cytochrome P-450 iso-enzymes. An influence of antiepileptic drugs on hypothalamic-pituitary-gonadal axis appears to be sex-dependent. In males, valproate decreased follicle-stimulating hormone (FSH) and luteinizing hormone (LH) but elevated dehydroepiandrosterone sulfate (DHEAS) concentrations. Carbamazepine decreased testosterone/sex-hormone binding globulin (SHBG) ratio, whereas its active metabolite--oxcarbazepine--had no effect on androgens. In females, valproate decreased FSH-stimulated estradiol release and enhanced testosterone level. On the other hand, carbamazepine decreased testosterone level but enhanced SHBG concentration. It has been reported that carbamazepine, oxcarbazepine or joined administration of carbamazepine and valproate decrease thyroxine (T4) level in patients with no effect on thyrotropin (TSH). While valproate itself has no effect on T4, phenytoin, phenobarbital and primidone, as metabolic enzyme inducers, can decrease the level of free and bound thyroxine. On the other hand, new antiepileptics such as levetiracetam, tiagabine, vigabatrine or lamotrigine had no effect on thyroid hormones. With respect to hormonal regulation of metabolic processes, valproate was reported to enhance leptin and insulin blood level and increased body weight, whereas topiramate showed an opposite effect. In contrast to thyroid and gonadal hormones, only a few data concern antiepileptic drug action in HPA axis. To this end, no effect of antiepileptic drugs on adrenocorticotropic hormone (ACTH)/cortisol circadian rhytmicity was found. Valproate decreased CRH release in rats, whereas lamotrigine stabilized ACTH/cortisol secretion. Moreover, felbamate was found to inhibit stress-induced corticosterone release in mice. Interestingly, recent data suggest that felbamat and some other new antiepileptic drugs may inhibit transcriptional activity of glucocorticoid receptors. Summing up, the above data suggest that traditional antiepileptic drugs may cause endocrine disturbances, especially in gonadal hormones.
Endocrine effects of antiepileptic drugs

+ Effects of antiepileptic drugs on immune system