Endocrine System Notes PDF
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Summary
These notes provide an overview of the endocrine system, covering topics such as the hypothalamus, pituitary gland, pineal gland, growth hormone, and related functions. The notes include detailed descriptions and diagrams.
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**Content** Week 1........................................2 Week 2........................................14 Week 3........................................34 Week 4........................................43 Prac: 20772 PR02 Seminar: 21991 SE03 Week 1 1. hypothalamus and pituitary gland Pit...
**Content** Week 1........................................2 Week 2........................................14 Week 3........................................34 Week 4........................................43 Prac: 20772 PR02 Seminar: 21991 SE03 Week 1 1. hypothalamus and pituitary gland Pituitary gland: - also known as hypophysis - covered on the top by a layer of dura mater - 2 parts: anterior pituitary (adenohypophysis -\> made up of pars distalis and pars intermedia), posterior pituitary (neurohypophysis -\> made up of pars nervosa) - Located in the hypophyseal fossa on the sphenoid bone, posterior to the optic chiasm - Sphenoid sinus sits below the gland and is surrounded by the cavernous sinus Vasculature of the pituitary gland: - ICA -\> superior hypophyseal artery -\> adenohypophysis (predominantly) - Inferior hypophyseal artery -\> neurohypophysis (predominantly) - ![](media/image2.png)Portal system: superior hypophyseal artery first forms a capillary system around the hypothalamus, then forms a second capillary system around the anterior pituitary gland - Veins drains mostly to surrounding cavernous sinus Release of hormones: - Anterior pituitary: - Hormones released by epithelial cells - Controlled by the parvocellular neurons from the hypothalamus - Releases stimulating and inhibiting hormones to the hypothalamic artery - Hormones pass through the first capillary system and travel to the second capillary system through the portal vessel, then acting on the epithelial cells - Hormones released into veins then drained through the cavernous sinus then internal jugular vein. =\> gland controlling =\> direct controlling \*hormones are produced in the anterior pituitary - Posterior pituitary: - Controlled by paraventricular nucleus and magnocellular neurons in hypothalamus - Oxytocin and ADH are produced in magnocellular neurons and stored in vesicles in the magnocellular nerve terminal - Upon activation of the magnocellular neurons, ADH and oxytocin are released from terminals and taken up by adjacent capillaries. - The posterior pituitary is comprised primarily of glial-like cells called pituicytes - Function: milk ejection: aids contraction of the myoepithelial cells in the mammillary alveoli - Delivery: contraction of smooth muscle and reduce bleeding during labour - Tempering fear responses - Acts on collecting duct in kidney and induces an increase - Which increases BP and increases osmolality - Detected changes by baroreceptors in carotid and aortic bodies and osmoreceptors in hypothalamus - Negative feedback - Also increases the release of ACTH in anterior pituitary Anterior pituitary: arise from the oral ectodermal cells that forms the mouth cavity-\> sphenoid bone growth separates the oral cavity and the gland -\> cells proliferate and separates the connection with mouth cavity ![](media/image4.png)Posterior pituitary: Arise from neural ectodermal cells -\> extension of the 3^rd^ ventricle 2. pineal gland (also known as the epiphysis ceribri - Neuroendocrine organ - Innervated by the sympathetic fibres from superior cervical ganglion - Located around the diencephalon, inferior to the posterior part of the corpus collosum - Supplied by the PCA and drained into the - Great cerebral vein of Galen Function: - Release of Melatonin with the effects of the circadian rhythm - Melatonin cycle: increased production in the evening, levels peaks in the middle of the night then drops in the morning with daylight - Potentially help with jet-lag if taken orally 3. growth hormone and its regulation Definition of growth: - increasing size and complexity and the number of cells Growth hormones: - regulated by GHRH (growth hormone regulating hormone) and GHIH / somatostatin (growth hormone inhibiting hormone) - target tissues with fuel metabolism, primarily the liver - overall effects: promote protein synthesis by using up fat storage Insulin-like Growth Factors (IGFs) - peptide hormones that encourages mitosis - mediates the effects of growth hormone - IGF-I: affects most cells in the body. induce proliferation and inhibit apoptosis - IGF-II :growth hormone during gestation (from zygote to foetus) Growth hormone release pattern: - Irregular pulses, amplified by exercise and sleep - Regulated by GHRH and somatostatin Mech of GH: JAK/STAT: binding on surface membrane receptors -\> activating JAK enzymes and phosphorylates STAT - Turns on gene transcription and promote protein synthesis - On bone growth: - Stimulating growth of epiphyseal cartilage - Increases conversion from cartilage to new bone - Increasing osteoblast proliferation and bone remodelling Other endocrine factors affecting growth: - Thyroid hormone, insulin, gonadotrophins and glucocorticoid Hypersecretion of growth hormone : - In childhood -\> gigantism (body remains in proportion) - In adulthood -\> acromegaly (bone thickens and soft tissue proliferation increases) - More prominent bony features in the face, increased maxillary sinus size, enlarged lips and tongue - Could be caused by pituitary adenoma -\> surgery through the nose Hyposecretion of growth hormone: - Pituitary dwarfism - Causes: congenital, head trauma, - Treated by GH injection or cortisol 4. Hypothalamic-Pituitary-Gonadal (HPG) Axis GnRH and LH: - GnRH is secreted pulsatile, continuous secretion will lead to the desensitisation of GnRH receptors - LH secretion is positively related to GnRH release - The desensitisation of GnRH receptors will lead to castration -\> the destruction of reproductive tissues (e.g. prostate, mamillary gland) - Possible treatment options to sex organ cancer Glycoproteins - Examples: TSH, gonadotrophins (LH, FSH, HCG) - Protein with a sugar sharing a common alpha chain Structure of gonadotrophins: - alpha subunits are identical between the 2 gonadotrophins - specific differences exist in the beta subunits - a subunit -92 amino acids, b subunit -115 amino acids - overall molecular weight \~ 35 kDa -\> relatively large proteins-\> won't be suspectable in oral forms - several glycosylation sites exist on both chains - glycosylations have an important effect on half-life and biopotency LH and FSH control in male, - GnRH from hypothalamus triggers the release of LH and FSH - LH acts on Leydig cells -\> triggers release of testosterone - FSH acts on Sertoli cells in the testes -\> stimulates production of spermatozoa - Sertoli cells secrete inhibin to inhibit the release of GnRH and testosterone inhibits the release of GnRH in pituitary Female: - GnRH from hypothalamus triggers the release of LH and FSH - High levels of LH triggers ovulation -\> development of corpus luteum - Production of progesterone and oestrodiol inhibits the release of GnRH Effects of sex steroid: 1. Oestrogen - Trophic effects (nourishment) of female reproductive organs and breast tissue - Increasing bone density - Effects upon brain memory and mood, blood lipids 2. Progesterone - Maintains thickness of endometrium - Enhance nervous system on sexual behaviour 3. Androgens - Increase in muscle mass, decrease in fat mass, increased red blood cell mass, - increase in bone density (effect of Estrogens), effects on hair growth - ![](media/image6.png)Important effects on the male reproductive tract and sexual behaviour 5. Steroids - 4-ringed structured lipid hormone derived from cholesterol - Functions: maintaining homeostasis, stimulating tissue development, reproductive functions 5 groups of steroids: - Cholesterol: precursor of other steroids - Progestagens: maintaining pregnancy and female reproductive organs - Secreted from: ovarian follicles, corpus luteum, placenta - Corticosteroids: suppress cell-mediated immunity (glucocorticoid) and regulate the electrolytes in the body (mineralocorticoid -\> aldosterone) - Secreted from the adrenal cortex - Androgens: male sexual differentiation, male reproductive organs functioning, anabolic effects - Secreted from Leydig cells, ovary, adrenal cortex - Oestrogens: female secondary sexual differentiation, maintenance of female reproductive organ - Secreted from ovarian follicles, placenta, fat tissues Steroid synthesis: - Inside mitochondria - Mediated by steroid acute regulatory protein -\> controlled the amount of acetate or cholesterol entering the mitochondria - The type of steroid synthesised depends on the enzyme in the cell - E.g. different enzyme levels in the adrenal cortex regulate the amount of aldosterone, androgens, and glucocorticoid released. - Congenital adrenal hyperplasia: lack of the enzyme that converts the precursor to aldosterone and glucocorticoid -\> increased secretion of androgens Oestrogen synthesis in ovary: - From high levels of LH -\> cholesterol is taken up into mitochondria to synthesise androgens -\> androgens then re-enter the ovarian follicles and synthesise into oestrogens -\> circulation Steroid transportations: - Hormones binds into a transport protein -\> with weak associations so it can easily disassociate and enters target cells in capillaries - The binding protein protects the hormone from renal filtrations and enzyme attacks -\> prolongs the half life of the hormone - It also allows the hormone to be evenly distributed into the target cells as free-flowing hormones would be all solely taken up by the distal part of the cells Tissue-specific regulation of steroid action: - Cortisol and aldosterone has similar structure and shares the same mineralocorticoid receptors - Cortisol concentration is 100 times of that of aldosterone - Therefore cortisol is temporarily disabled into cortisone until blood circulates back to the liver, where cortisone can be converted back to cortisol for its use - Such that aldosterone can still be taken up in the kidneys and act as the primart mineralocorticoid Transport of thyroid hormones: - Binded to TBG (Thyroxine binding globulin), albumin, and TBPA(thyroxine binding pre-albumin) - Factors: - Pregnancy, Estrogen Treatment, - Liver disease, major illness, nephrotic syndrome - Other related drugs (anti-epileptics, anti-inflammatories) Peripheral deiodination of T4 - Majority of thyroid hormone is T4, but T3 is more biologically active - T4 has a better half-life then T3 - Deiodination of T4 in the outer ring gives T3 - Maintaining half life while also maintaining the activity of the hormone 6. pituitary gland pathology: tumours in the pituitary gland: 1. pituitary adenomas: - most common cause of hyperpituitarism - hyperpituitarism can also be caused by hyperplasia, carcinomas, secretion by extra pituitary tumours, or hypothalamic disorders - the excess hormone might vary from the location of the tumour - if tumour is present in the prolactin-producing part it will lead to increased prolactin secretion - can also be plurihormonal tumour (involving multiple hormones) - sometimes present with no clinical significance - autosomal dominant inheritance - Histology: usually benign: with functional cells, relatively uniform cells arranged in sheets and cords, functional status does not correlate with the histological findings, with unpredictable growth rate Specific adenomas: Prolactinomas: most frequent type of hyperpituitary adenomas - Most common within women in child-bearing age - Subdivided into weak acidophillic (more common and sparsely granulated) and strong acidophillic (less common and densely granulated) - Hyperprolactinaemia can also be caused by other secondary causes - Head trauma, pregnancy, hyperplasia, drugs(inhibit the dopamine control of prolactin inhibition from dopamine), other disorders Growth hormone adenomas: - Second most common - Subdivided into - densely granulated - slow-growing and well-differentiated tumour - sparsely granulated - in younger patient, more aggressive and potential to be invasive - sometimes prolactinomas and growth hormone adenomas are mixed and presented in the same tumour Corticotrophs cell adenomas: - underlying cause of cushing's disease - also be subdivided into sparsely and densely granulated - usually monohormonal - usually associated with hyperprolactinaemia pituitary apoplexy: - sudden haemorrhage to the adenoma - clinical features: sudden onset of severe headache with diplopia and hypopituitarism - could even cause loss of consciousness or death Null cell adenomas (non-functioning pituitary adenomas) - commonly presented in elderly patient with visual problems pituitary carcinoma - primary tumour with metastasis potential - non-functioning and very rare secondary tumour - most commonly metastasise from breast, lung, GI Tract ischaemic necrosis: - during pregnancy as the pituitary gland enlarge to secrete more prolactin to prepare for lactation - usually not accompanied with increased blood supply -\> more susceptible to ischaemia Craniopharyngiomas: - slow growing - a bimodal distribution, common in children present in 5-15 years old and adults over 50 with visual problems - presented with hypopituitarism and diabetes incidius - usually with calcification on X-rays and cysts containing viscous oil with sparkling cholesterol crystals SBL prep: Differentials: Galatorrhoea: - prolactinomas -\> hypersensitivity of pituitary gland - drugs: anti-depressants, oral contraceptives, methyldopa(anti-hypertensive) - pituitary gland disorder: pituitary adenomas Amenorrhoea: - congenital adrenal hyperplasia -\> too much testosterone - FSH and LH deficiency - Mental health disorder Prolactin control and regulation: - Dopamine inhibits the release of prolactin 2.1 Thyroid and parathyroid gland Thyroid gland: - 2 lobes and an isthmus (bridge), a pyramidal lobe in (10-30% of individuals) - Females have larger thyroid glands - Medial to the common carotid artery, internal jugular vein and vagus nerve - T3 (triiodothyronine, 20%), T4 (thyroxin, 80%)-\> controlled by hypothalmus - Hypothalamus (Thyrotropin releasing hormone) -\> anterior pituitary (Thyroid stimulating hormone) - and calcitonin secreted here -\> released when blood Ca2+ level is high - supplied by the autonomic nervous system - sym: post ganglionic fibres enter via arteries - para: vagus nerve enter via superior pharyngeal nerve Blood supply: - Superior thyroid artery: - First branch from the external carotid artery - Enters via superior poles - Inferior - Originates from thyrocervical branch from subclavian artery - Enters inferiorly and posteriorly - 3-10% of individuals have an unpaired thyroidea ima artery 3. main veins: - ![](media/image8.png)superior thyroid veins, middle thyroid veins: both drain into internal jugular veins - inferior thyroid veins: drain into brachiocephalic veins Activation of T4 to T3 in individual organs - then T3 is converted into other hormones in individual - follicle - follicular epithelial cell -\> release T3 and T4 -\> requires iodine - parafollicular C-cells -\> calcitonin thyroid gland development: - first gland to develop (starting from week 4) - connected to the tongue by thyroglossal duct - From week 11 epithelial cells - From week 20 on TSH kicks in and T3/T4 are produced Parathyroid gland: - 2 superior and 2 inferior gland: - superior: superiorlateral part of the thyroid gland. - Inferior: 1-2cm from the entry of the inferior thyroid gland - Blood supply via thyroid arteries and veins - Produce parathormone (PTH) -\> produced by chief cells - Produced when calcium levels are low - Also regulates vitamin D levels Anatomical Variations of the Thyroid and Parathyroid Glands: - Most humans (\>80%) have four parathyroid glands - 1-12 parathyroid glands can be present - most common deviations are three glands and five glands - more commonly seen in the inferior glands - less commonly for the superior parathyroids, 2.2 Thyroid hormones Thyroid hormone stimulation: - Regulation in the hypothalamus -\> Thyrotropin releasing hormone (TRH) - Released by anterior pituitary -\> release thyroid stimulating hormone (TSH) - Stimulating thyroid to release T3 (triiodothyronine )and T4 (thyroxin) - Levels of TSH, T3 and T4 increase during early morning (12-3) and drops as the day goes on, shows circadian rhythm as with all other hormones released in the anterior pituitary - T3 and T4 provide negative feedback and inhibits TSH and TRH Thyroid hormone synthesis: - Amino acids form peptides in rough ER - Peptides and carbohydrates forms thyroglobulin (large protein without iodine) in golgi apparatus - Vesicles are formed and the thyroglobulin are released via exocytosis - At the same time, iodide is taken up by Na+/I- symporter when activated by TSH - Iodide is oxidized into iodine before entering the colloid - Iodine is then attached to thyroglobulin with the presence of thyroperoxidase (TPO) into monoiodotyrosine (MIT) and diiodotyrosine(DIT) - MIT and DIT then form T3 and T4 - T3 and T4 are then endocytosed into follicular cells - Proteolytic enzymes then cleaves T3 and T4 from the thyroglobulin - T3 and T4 are then released into blood stream Transport of thyroid hormones: - ![](media/image7.png)T3 and T4 are lipophillic -\> require protein transporter thyroxine-binding globulin (TBG), transthyretin, and albumin. - T3 and T4 can dissociate from binding proteins to enter - T3 or T4 then bind to intracellular receptors and cause - Thyroid hormone is then degraded in the liver Effects of thyroid hormone: - **Cardiovascular system** - have a permissive effect on catecholamines; increases the expression of beta-receptors to increase heart rate, stroke volume, cardiac output, and contractility. - **Lungs** - thyroid hormones stimulate the respiratory centres and lead to increased oxygenation because of increased perfusion. - **Nervous system** -- important for the development and operation of the central nervous system; helps with brain maturation by axonal growth and the formation of the myelin sheath; also important for maintaining excitability of autonomic and enteric nerves. - **Skeletal muscles** - increases development of type II (fast twitch) muscle fibres. - **Bone **- act synergistically with growth hormone to stimulate bone growth. It induces chondrocytes, osteoblasts, and osteoclasts. - **Gastrointestinal system** -- lack of thyroid hormone leads to reduced GI motility due to diminished activity of enteric neurons and GI smooth muscle. Live Lecture: Anatomy and histology of the endocrine system: Endocrine gland are derived from epithelium, surrounded by capillaries - Hormones and factors - Factors: molecules produced outside of glands from many different cell types and released next to the cells but also present in blood Control: Cortex -\> hypothalamus -\> anteior pituitary gland -\> target organ (GH and prolactin) from acidophil cells or target gland (ACTH, TSH, FSH, LH,) from basophil cells / posterior pituitary gland -\> target organ (ADH and oxytocin) - Hormones produced from hypothalamus are stored in herring bodies in posterior pituitary cells Or Metabolic signal (change in ion levels or glucose levels) -\> detected by receptors in glands -\> target organ Or Autonomic nervous system -\> glands -\> target organs Hypothalamus: - Circadian rhythm, Hunger/thirst, Body temp, Cortical arousal - Mediated by different nuclei in the hypothalamus Adrenal gland: - Left gland is pyramidal and hidden behind liver and IVC - Right gland is semilunar and usually larger - Cortex: produce corticosteroid hormones - Medulla is neuronal and for receiving preganglionic sympathetic innervation and releases adrenalin and lower levels of noradrenalin Ovaries: - Bloody supply via ovarian artery running in suspensory ligament - Theca external cells: fibroblast and smooth muscle cells - theca internal cells: sensitive to LH and produce androgen - granulosa cells: sensitive to FSH and convert androgens into estrogens 2.3 Thyroid disorder Negative feedback loop of thyroid hormone: - TRH from hypothalamus - TSH from anterior pituitary - T3 and T4 from thyroid gland - Inhibits TRH and TSH Summary of disorders ![](media/image11.png)Signs and symptoms of thyroid disorder: In short: - Hyperthyroidism: increased sympathetic drive, - hypo -\> reduced sympathetic drive Causes of hyperthyroidism: - graves disease - Toxic nodules - Thyroiditis -\> breakdown of thyroid tissue -\> increased release of preformed thyroid hormones in follicles - Important to differentiate between increasing release of thyroid hormone or preformed hormones stored in follicles \*Thyroid storm: - life-threatening situation - storm of thyroid hormones leading to severe signs and symptoms such as hyperpyrexia, cardiovascular compromised, altered mental state - rare condition (\