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Hypothalamic–pituitary–thyroid axis

March 17, 2024

The hypothalamic–pituitary–thyroid axis (HPT axis for short, a.k.a. thyroid homeostasis or thyrotropic feedback control) is part of the neuroendocrine system responsible for the regulation of metabolism and also responds to stress.

Short overview of thyroid homeostasis.[1]

As its name suggests, it depends upon the hypothalamus, the pituitary gland, and the thyroid gland.

The hypothalamus senses low circulating levels of thyroid hormone (Triiodothyronine (T3) and Thyroxine (T4)) and responds by releasing thyrotropin-releasing hormone (TRH). The TRH stimulates the anterior pituitary to produce thyroid-stimulating hormone (TSH). The TSH, in turn, stimulates the thyroid to produce thyroid hormone until levels in the blood return to normal. Thyroid hormone exerts negative feedback control over the hypothalamus as well as anterior pituitary, thus controlling the release of both TRH from hypothalamus and TSH from anterior pituitary gland.[2]

The HPA, HPG, and HPT axes are three pathways in which the hypothalamus and pituitary direct neuroendocrine function.

Physiology edit

 
Thyrotropic feedback control on a more detailed and quantitative level.[3]

Thyroid homeostasis results from a multi-loop feedback system that is found in virtually all higher vertebrates. Proper function of thyrotropic feedback control is indispensable for growth, differentiation, reproduction and intelligence. Very few animals (e.g. axolotls and sloths) have impaired thyroid homeostasis that exhibits a very low set-point that is assumed to underlie the metabolic and ontogenetic anomalies of these animals.

The pituitary gland secretes thyrotropin (TSH; Thyroid Stimulating Hormone) that stimulates the thyroid to secrete thyroxine (T4) and, to a lesser degree, triiodothyronine (T3). The major portion of T3, however, is produced in peripheral organs, e.g. liver, adipose tissue, glia and skeletal muscle by deiodination from circulating T4. Deiodination is controlled by numerous hormones and nerval signals including TSH, vasopressin and catecholamines.

Both peripheral thyroid hormones (iodothyronines) inhibit thyrotropin secretion from the pituitary (negative feedback). Consequently, equilibrium concentrations for all hormones are attained.

TSH secretion is also controlled by thyrotropin releasing hormone (thyroliberin, TRH), whose secretion itself is again suppressed by plasma T4 and T3 in CSF (long feedback, Fekete–Lechan loop).[4] Additional feedback loops are ultrashort feedback control of TSH secretion (Brokken-Wiersinga-Prummel loop)[5] and linear feedback loops controlling plasma protein binding.

Recent research suggested the existence of an additional feedforward motif linking TSH release to deiodinase activity in humans.[6][7][8] The existence of this TSH-T3 shunt could explain why deiodinase activity is higher in hypothyroid patients and why a minor fraction of affected individuals may benefit from substitution therapy with T3.[9]

Convergence of multiple afferent signals in the control of TSH release including but not limited to T3,[10] cytokines[11][12] and TSH receptor antibodies[13] may be the reason for the observation that the relation between free T4 concentration and TSH levels deviates[14][15][16][17] from a pure loglinear relation that has previously been proposed.[18] Recent research suggests that ghrelin also plays a role in the stimulation of T4 production and the subsequent suppression of TSH directly and by negative feedback.[19]

Functional states of thyrotropic feedback control edit

Diagnostics edit

Standard procedures cover the determination of serum levels of the following hormones:

  • TSH (thyrotropin, thyroid stimulating hormone)
  • Free T4
  • Free T3

For special conditions the following assays and procedures may be required:

See also edit

References edit

  1. ^ References used in overview figure are found in image article in Commons: References.
  2. ^ Dietrich JW, Landgrafe G, Fotiadou EH (2012). "TSH and Thyrotropic Agonists: Key Actors in Thyroid Homeostasis". Journal of Thyroid Research. 2012: 1–29. doi:10.1155/2012/351864. PMC 3544290. PMID 23365787.
  3. ^ References used in detailed figure are found in image article in Commons: References.
  4. ^ Lechan, Ronald M.; Fekete, C (2004). "Feedback regulation of thyrotropin-releasing hormone (TRH): mechanisms for the non-thyroidal illness syndrome". Journal of Endocrinological Investigation. 27 (6 Suppl): 105–19. PMID 15481810.
  5. ^ Prummel MF, Brokken LJ, Wiersinga WM (2004). "Ultra short-loop feedback control of thyrotropin secretion". Thyroid. 14 (10): 825–9. doi:10.1089/thy.2004.14.825. PMID 15588378.
  6. ^ Hoermann R, Midgley JE, Giacobino A, Eckl WA, Wahl HG, Dietrich JW, Larisch R (2014). "Homeostatic equilibria between free thyroid hormones and pituitary thyrotropin are modulated by various influences including age, body mass index and treatment". Clinical Endocrinology. 81 (6): 907–15. doi:10.1111/cen.12527. PMID 24953754. S2CID 19341039.
  7. ^ Dietrich, JW; Midgley, JE; Larisch, R; Hoermann, R (December 2015). "Of rats and men: thyroid homeostasis in rodents and human beings". The Lancet Diabetes & Endocrinology. 3 (12): 932–933. doi:10.1016/S2213-8587(15)00421-0. PMID 26590684.
  8. ^ Hoermann, R; Midgley, JE; Larisch, R; Dietrich, JW (2015). "Homeostatic Control of the Thyroid-Pituitary Axis: Perspectives for Diagnosis and Treatment". Frontiers in Endocrinology. 6: 177. doi:10.3389/fendo.2015.00177. PMC 4653296. PMID 26635726.
  9. ^ Hoermann R, Midgley JE, Larisch R, Dietrich JW (2015). "Integration of Peripheral and Glandular Regulation of Triiodothyronine Production by Thyrotropin in Untreated and Thyroxine-Treated Subjects". Hormone and Metabolic Research. 47 (9): 674–80. doi:10.1055/s-0034-1398616. PMID 25750078. S2CID 9824656.
  10. ^ Hoermann, R; Midgley, JEM; Dietrich, JW; Larisch, R (June 2017). "Dual control of pituitary thyroid stimulating hormone secretion by thyroxine and triiodothyronine in athyreotic patients". Therapeutic Advances in Endocrinology and Metabolism. 8 (6): 83–95. doi:10.1177/2042018817716401. PMC 5524252. PMID 28794850.
  11. ^ Fliers, E; Kalsbeek, A; Boelen, A (November 2014). "Beyond the fixed setpoint of the hypothalamus-pituitary-thyroid axis" (PDF). European Journal of Endocrinology. 171 (5): R197–208. doi:10.1530/EJE-14-0285. PMID 25005935.
  12. ^ a b Chatzitomaris, Apostolos; Hoermann, Rudolf; Midgley, John E.; Hering, Steffen; Urban, Aline; Dietrich, Barbara; Abood, Assjana; Klein, Harald H.; Dietrich, Johannes W. (20 July 2017). "Thyroid Allostasis–Adaptive Responses of Thyrotropic Feedback Control to Conditions of Strain, Stress, and Developmental Programming". Frontiers in Endocrinology. 8: 163. doi:10.3389/fendo.2017.00163. PMC 5517413. PMID 28775711.
  13. ^ Brokken LJ, Wiersinga WM, Prummel MF (2003). "Thyrotropin receptor autoantibodies are associated with continued thyrotropin suppression in treated euthyroid Graves' disease patients". Journal of Clinical Endocrinology & Metabolism. 88 (9): 4135–4138. doi:10.1210/jc.2003-030430. PMID 12970276.
  14. ^ Hoermann R, Eckl W, Hoermann C, Larisch R (2010). "Complex relationship between free thyroxine and TSH in the regulation of thyroid function". European Journal of Endocrinology. 162 (6): 1123–9. doi:10.1530/EJE-10-0106. PMID 20299491.
  15. ^ Clark PM, Holder RL, Haque SM, Hobbs FD, Roberts LM, Franklyn JA (2012). "The relationship between serum TSH and free T4 in older people". Journal of Clinical Pathology. 65 (5): 463–5. doi:10.1136/jclinpath-2011-200433. PMID 22287691. S2CID 43886378.
  16. ^ Hoermann R, Midgley JE, Larisch R, Dietrich JW (2012). "Is pituitary TSH an adequate measure of thyroid hormone-controlled homoeostasis during thyroxine treatment?". European Journal of Endocrinology. 168 (2): 271–80. doi:10.1530/EJE-12-0819. PMID 23184912.
  17. ^ Midgley JE, Hoermann R, Larisch R, Dietrich JW (2013). "Physiological states and functional relation between thyrotropin and free thyroxine in thyroid health and disease: In vivo and in silico data suggest a hierarchical model". Journal of Clinical Pathology. 66 (4): 335–42. doi:10.1136/jclinpath-2012-201213. PMID 23423518. S2CID 46291947.
  18. ^ Reichlin S, Utiger RD (1967). "Regulation of the pituitary-thyroid axis in man: Relationship of TSH concentration to concentration of free and total thyroxine in plasma". The Journal of Clinical Endocrinology and Metabolism. 27 (2): 251–5. doi:10.1210/jcem-27-2-251. PMID 4163614.
  19. ^ Kluge M, et al. (2010). "Ghrelin affects the hypothalamus–pituitary–thyroid axis in humans by increasing free thyroxine and decreasing TSH in plasma". European Journal of Endocrinology. 162 (6): 1059–1065. doi:10.1530/EJE-10-0094. PMID 20423986. S2CID 5237852.
  20. ^ Liu S, Ren J, Zhao Y, Han G, Hong Z, Yan D, Chen J, Gu G, Wang G, Wang X, Fan C, Li J (2013). "Nonthyroidal illness syndrome: Is it far away from Crohn's disease?". Journal of Clinical Gastroenterology. 47 (2): 153–9. doi:10.1097/MCG.0b013e318254ea8a. PMID 22874844. S2CID 35344744.
  21. ^ a b Dietrich, J. W. (2002). Der Hypophysen-Schilddrüsen-Regelkreis. Berlin, Germany: Logos-Verlag Berlin. ISBN 978-3-89722-850-4. OCLC 50451543. OL 24586469M. 3897228505.
  22. ^ Jostel A, Ryder WD, Shalet SM (2009). "The use of thyroid function tests in the diagnosis of hypopituitarism: Definition and evaluation of the TSH Index". Clinical Endocrinology. 71 (4): 529–34. doi:10.1111/j.1365-2265.2009.03534.x. PMID 19226261. S2CID 10827131.

Further reading edit

  • Dietrich J W, Tesche A, Pickardt C R, Mitzdorf U (2004). "Thyrotropic Feedback Control: Evidence for an Additional Ultrashort Feedback Loop from Fractal Analysis". Cybernetics and Systems. 35 (4): 315–331. doi:10.1080/01969720490443354. S2CID 13421388.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  • Gauna C, van den Berghe G H, van der Lely A J (2005). "Pituitary Function During Severe and Life-threatening Illnesses". Pituitary. 8 (3–4): 213–217. doi:10.1007/s11102-006-6043-3. PMID 16508715. S2CID 22305001.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  • Dietrich, Johannes W.; Midgley, John E. M.; Hoermann, Rudolf (2018). Homeostasis and allostasis of thyroid function. Lausanne: Frontiers Media SA. ISBN 9782889455706.

March 17, 2024
hypothalamic, pituitary, thyroid, axis, hypothalamic, pituitary, thyroid, axis, axis, short, thyroid, homeostasis, thyrotropic, feedback, control, part, neuroendocrine, system, responsible, regulation, metabolism, also, responds, stress, short, overview, thyro. The hypothalamic pituitary thyroid axis HPT axis for short a k a thyroid homeostasis or thyrotropic feedback control is part of the neuroendocrine system responsible for the regulation of metabolism and also responds to stress Short overview of thyroid homeostasis 1 As its name suggests it depends upon the hypothalamus the pituitary gland and the thyroid gland The hypothalamus senses low circulating levels of thyroid hormone Triiodothyronine T3 and Thyroxine T4 and responds by releasing thyrotropin releasing hormone TRH The TRH stimulates the anterior pituitary to produce thyroid stimulating hormone TSH The TSH in turn stimulates the thyroid to produce thyroid hormone until levels in the blood return to normal Thyroid hormone exerts negative feedback control over the hypothalamus as well as anterior pituitary thus controlling the release of both TRH from hypothalamus and TSH from anterior pituitary gland 2 The HPA HPG and HPT axes are three pathways in which the hypothalamus and pituitary direct neuroendocrine function Contents 1 Physiology 2 Functional states of thyrotropic feedback control 3 Diagnostics 4 See also 5 References 6 Further readingPhysiology edit nbsp Thyrotropic feedback control on a more detailed and quantitative level 3 Thyroid homeostasis results from a multi loop feedback system that is found in virtually all higher vertebrates Proper function of thyrotropic feedback control is indispensable for growth differentiation reproduction and intelligence Very few animals e g axolotls and sloths have impaired thyroid homeostasis that exhibits a very low set point that is assumed to underlie the metabolic and ontogenetic anomalies of these animals The pituitary gland secretes thyrotropin TSH Thyroid Stimulating Hormone that stimulates the thyroid to secrete thyroxine T4 and to a lesser degree triiodothyronine T3 The major portion of T3 however is produced in peripheral organs e g liver adipose tissue glia and skeletal muscle by deiodination from circulating T4 Deiodination is controlled by numerous hormones and nerval signals including TSH vasopressin and catecholamines Both peripheral thyroid hormones iodothyronines inhibit thyrotropin secretion from the pituitary negative feedback Consequently equilibrium concentrations for all hormones are attained TSH secretion is also controlled by thyrotropin releasing hormone thyroliberin TRH whose secretion itself is again suppressed by plasma T4 and T3 in CSF long feedback Fekete Lechan loop 4 Additional feedback loops are ultrashort feedback control of TSH secretion Brokken Wiersinga Prummel loop 5 and linear feedback loops controlling plasma protein binding Recent research suggested the existence of an additional feedforward motif linking TSH release to deiodinase activity in humans 6 7 8 The existence of this TSH T3 shunt could explain why deiodinase activity is higher in hypothyroid patients and why a minor fraction of affected individuals may benefit from substitution therapy with T3 9 Convergence of multiple afferent signals in the control of TSH release including but not limited to T3 10 cytokines 11 12 and TSH receptor antibodies 13 may be the reason for the observation that the relation between free T4 concentration and TSH levels deviates 14 15 16 17 from a pure loglinear relation that has previously been proposed 18 Recent research suggests that ghrelin also plays a role in the stimulation of T4 production and the subsequent suppression of TSH directly and by negative feedback 19 Functional states of thyrotropic feedback control editEuthyroidism Normal thyroid function Hypothyroidism Reduced thyroid function primary hypothyroidism Feedback loop interrupted by low thyroid secretory capacity e g after thyroid surgery or in case of autoimmune thyroiditis secondary hypothyroidism Feedback loop interrupted on the level of pituitary e g in anterior pituitary failure tertiary hypothyroidism Lacking stimulation by TRH e g in hypothalamic failure Pickardt Fahlbusch syndrome or euthyroid sick syndrome Hyperthyroidism Inappropriately increased thyroid function primary hyperthyroidism Inappropriate secretion of thyroid hormones e g in case of Graves disease secondary hyperthyroidism Rare condition e g in case of TSH producing pituitary adenoma or partial thyroid hormone resistance Thyrotoxicosis Over supply with thyroid hormones e g by overdosed exogenously levothyroxine supplementation Low T3 syndrome and high T3 syndrome Consequences of step up hypodeiodination e g in critical illness as an example for type 1 allostasis 20 or hyperdeiodination as in type 2 allostasis including posttraumatic stress disorder 12 Resistance to thyroid hormone Feedback loop interrupted on the level of pituitary thyroid hormone receptors Diagnostics editStandard procedures cover the determination of serum levels of the following hormones TSH thyrotropin thyroid stimulating hormone Free T4 Free T3For special conditions the following assays and procedures may be required Total T4 Total T3 TBG TRH test Thyroid s secretory capacity GT 21 Sum activity of peripheral deiodinases GD 21 TSH Index TSHI 22 See also editThyroid function tests Hypothalamic pituitary adrenal axis Hypothalamic pituitary gonadal axis Hypothalamic neurohypophyseal system SimThyr a free computer simulation for thyroid homeostasis in humansReferences edit References used in overview figure are found in image article in Commons References Dietrich JW Landgrafe G Fotiadou EH 2012 TSH and Thyrotropic Agonists Key Actors in Thyroid Homeostasis Journal of Thyroid Research 2012 1 29 doi 10 1155 2012 351864 PMC 3544290 PMID 23365787 References used in detailed figure are found in image article in Commons References Lechan Ronald M Fekete C 2004 Feedback regulation of thyrotropin releasing hormone TRH mechanisms for the non thyroidal illness syndrome Journal of Endocrinological Investigation 27 6 Suppl 105 19 PMID 15481810 Prummel MF Brokken LJ Wiersinga WM 2004 Ultra short loop feedback control of thyrotropin secretion Thyroid 14 10 825 9 doi 10 1089 thy 2004 14 825 PMID 15588378 Hoermann R Midgley JE Giacobino A Eckl WA Wahl HG Dietrich JW Larisch R 2014 Homeostatic equilibria between free thyroid hormones and pituitary thyrotropin are modulated by various influences including age body mass index and treatment Clinical Endocrinology 81 6 907 15 doi 10 1111 cen 12527 PMID 24953754 S2CID 19341039 Dietrich JW Midgley JE Larisch R Hoermann R December 2015 Of rats and men thyroid homeostasis in rodents and human beings The Lancet Diabetes amp Endocrinology 3 12 932 933 doi 10 1016 S2213 8587 15 00421 0 PMID 26590684 Hoermann R Midgley JE Larisch R Dietrich JW 2015 Homeostatic Control of the Thyroid Pituitary Axis Perspectives for Diagnosis and Treatment Frontiers in Endocrinology 6 177 doi 10 3389 fendo 2015 00177 PMC 4653296 PMID 26635726 Hoermann R Midgley JE Larisch R Dietrich JW 2015 Integration of Peripheral and Glandular Regulation of Triiodothyronine Production by Thyrotropin in Untreated and Thyroxine Treated Subjects Hormone and Metabolic Research 47 9 674 80 doi 10 1055 s 0034 1398616 PMID 25750078 S2CID 9824656 Hoermann R Midgley JEM Dietrich JW Larisch R June 2017 Dual control of pituitary thyroid stimulating hormone secretion by thyroxine and triiodothyronine in athyreotic patients Therapeutic Advances in Endocrinology and Metabolism 8 6 83 95 doi 10 1177 2042018817716401 PMC 5524252 PMID 28794850 Fliers E Kalsbeek A Boelen A November 2014 Beyond the fixed setpoint of the hypothalamus pituitary thyroid axis PDF European Journal of Endocrinology 171 5 R197 208 doi 10 1530 EJE 14 0285 PMID 25005935 a b Chatzitomaris Apostolos Hoermann Rudolf Midgley John E Hering Steffen Urban Aline Dietrich Barbara Abood Assjana Klein Harald H Dietrich Johannes W 20 July 2017 Thyroid Allostasis Adaptive Responses of Thyrotropic Feedback Control to Conditions of Strain Stress and Developmental Programming Frontiers in Endocrinology 8 163 doi 10 3389 fendo 2017 00163 PMC 5517413 PMID 28775711 Brokken LJ Wiersinga WM Prummel MF 2003 Thyrotropin receptor autoantibodies are associated with continued thyrotropin suppression in treated euthyroid Graves disease patients Journal of Clinical Endocrinology amp Metabolism 88 9 4135 4138 doi 10 1210 jc 2003 030430 PMID 12970276 Hoermann R Eckl W Hoermann C Larisch R 2010 Complex relationship between free thyroxine and TSH in the regulation of thyroid function European Journal of Endocrinology 162 6 1123 9 doi 10 1530 EJE 10 0106 PMID 20299491 Clark PM Holder RL Haque SM Hobbs FD Roberts LM Franklyn JA 2012 The relationship between serum TSH and free T4 in older people Journal of Clinical Pathology 65 5 463 5 doi 10 1136 jclinpath 2011 200433 PMID 22287691 S2CID 43886378 Hoermann R Midgley JE Larisch R Dietrich JW 2012 Is pituitary TSH an adequate measure of thyroid hormone controlled homoeostasis during thyroxine treatment European Journal of Endocrinology 168 2 271 80 doi 10 1530 EJE 12 0819 PMID 23184912 Midgley JE Hoermann R Larisch R Dietrich JW 2013 Physiological states and functional relation between thyrotropin and free thyroxine in thyroid health and disease In vivo and in silico data suggest a hierarchical model Journal of Clinical Pathology 66 4 335 42 doi 10 1136 jclinpath 2012 201213 PMID 23423518 S2CID 46291947 Reichlin S Utiger RD 1967 Regulation of the pituitary thyroid axis in man Relationship of TSH concentration to concentration of free and total thyroxine in plasma The Journal of Clinical Endocrinology and Metabolism 27 2 251 5 doi 10 1210 jcem 27 2 251 PMID 4163614 Kluge M et al 2010 Ghrelin affects the hypothalamus pituitary thyroid axis in humans by increasing free thyroxine and decreasing TSH in plasma European Journal of Endocrinology 162 6 1059 1065 doi 10 1530 EJE 10 0094 PMID 20423986 S2CID 5237852 Liu S Ren J Zhao Y Han G Hong Z Yan D Chen J Gu G Wang G Wang X Fan C Li J 2013 Nonthyroidal illness syndrome Is it far away from Crohn s disease Journal of Clinical Gastroenterology 47 2 153 9 doi 10 1097 MCG 0b013e318254ea8a PMID 22874844 S2CID 35344744 a b Dietrich J W 2002 Der Hypophysen Schilddrusen Regelkreis Berlin Germany Logos Verlag Berlin ISBN 978 3 89722 850 4 OCLC 50451543 OL 24586469M 3897228505 Jostel A Ryder WD Shalet SM 2009 The use of thyroid function tests in the diagnosis of hypopituitarism Definition and evaluation of the TSH Index Clinical Endocrinology 71 4 529 34 doi 10 1111 j 1365 2265 2009 03534 x PMID 19226261 S2CID 10827131 Further reading editDietrich J W Tesche A Pickardt C R Mitzdorf U 2004 Thyrotropic Feedback Control Evidence for an Additional Ultrashort Feedback Loop from Fractal Analysis Cybernetics and Systems 35 4 315 331 doi 10 1080 01969720490443354 S2CID 13421388 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Gauna C van den Berghe G H van der Lely A J 2005 Pituitary Function During Severe and Life threatening Illnesses Pituitary 8 3 4 213 217 doi 10 1007 s11102 006 6043 3 PMID 16508715 S2CID 22305001 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint multiple names authors list link Dietrich Johannes W Midgley John E M Hoermann Rudolf 2018 Homeostasis and allostasis of thyroid function Lausanne Frontiers Media SA ISBN 9782889455706 Retrieved from https en wikipedia org w index php title Hypothalamic pituitary thyroid axis amp oldid 1184209249, wikipedia, wiki, book, books, library,

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