3.1 - Hypopituitarism

Question 1

What are the hormones the anterior pituitary gland makes?

Answer 1

• growth hormone (somatotrophin)
• prolactin
• thyroid stimulating hormone (TSH)
• luteinising hormone (LH)
• follicle stimulating hormone (FSH)
• adrenocorticotrophic hormone (ACTH, corticotrophin)

Question 2

How does the hypothalamus control the anterior pituitary?

Answer 2

• hypothalamus produces hypothalamic releasing or inhibitory factors which travel in hypothalamo-pituitary portal circulation to the anterior pituitary to regulate anterior pituitary hormone production
• portal system has leaky, fenestrated blood vessels

Question 3

What does growth hormone release lead to?

Answer 3

• growth
• GHRH from hypothalamus –> GH –> IGF-1 –> growth

Question 4

What does prolactin release lead to?

Answer 4

• milk production
• negatively regulated by dopamine

Question 5

What does LH release lead to?

Answer 5

• acts on ovary –> oestrogen and progesterone release in women
• acts on testes –> testosterone release in men

Question 6

What does FSH release lead to?

Answer 6

• acts on ovary –> oestrogen and progesterone release in women
• acts on testes –> testosterone and spermatogenesis in men

Question 7

What does TSH release lead to?

Answer 7

• triiodothyronine (T3) and thyroxine (T4) from thyroid gland
• regulated by TRH

Question 8

What does ACTH release lead to?

Answer 8

• cortisol release from adrenal gland
• regulated by CRH

Question 9

What are the two types of anterior pituitary failure?

Answer 9

• primary disease - the gland itself fails e.g. gonads, adrenal cortex, thyroid
• secondary disease - no signals from hypothalamus or anterior pituitary

Question 10

What happens in primary hypothyroidism and give an example?

Answer 10

• problem with thyroid gland - T3 and T4 fall, TSH increases due to no -ve feedback
• TRH would also be high but we do not measure it
• e.g. autoimmune destruction of thyroid gland

Question 11

What happens in secondary hypothyroidism and give an example?

Answer 11

• problem with anterior pituitary or hypothalamus = TSH cannot be made
• TSH falls –> T3 and T4 fall
• e.g. pituitary tumour damaging thyrotrophs

Question 12

What happens in primary hypoadrenalism and give an example?

Answer 12

• problem with adrenal gland - cortisol falls, ACTH increases due to no -ve feedback
• CRH would also be high but we do not measure it
• e.g. autoimmune destruction of adrenal cortex e.g. Addison’s

Question 13

What happens in secondary hypoadrenalism and give an example?

Answer 13

• problem with anterior pituitary or hypothalamus so ACTH cannot be made
• ACTH falls –> cortisol falls
• e.g. pituitary tumour damaging corticotrophs

Question 14

What happens in primary hypogonadism and give an example?

Answer 14

• problem with testes/ovaries - testosterone (men) or oestrogen (women) falls, LH and FSH increase due to no -ve feedback
• GnRH would also be high but we do not measure it
• e.g. destruction of testes (e.g. mumps) or ovaries (e.g. chemotherapy)

Question 15

What happens in secondary hypogonadism and give an example?

Answer 15

• problem with anterior pituitary or hypothalamus so LH/FSH cannot be made
• LH/FSH fall –> testosterone/oestrogen fall
• e.g. pituitary tumour damaging gonadotrophs

Question 16

What are the two types of causes of hypopituitarism?

Answer 16

Congenital and acquired

Question 17

What is congenital hypopituitarism?

Answer 17

• pituitary gland has not developed properly in utero
• usually due to mutations of transcription factor genes needed for normal APG development

Question 18

What are the features of congenital hypopituitarism?

Answer 18

• deficient in GH and at least one more anterior pituitary hormone
• short stature

Question 19

What does an MRI show in congenital hypopituitarism?

Answer 19

Hypoplastic (underdeveloped) anterior pituitary gland

Question 20

What are examples of acquired hypopituitarism? (8)

Answer 20

• tumours e.g. adenomas, metastases. cysts
• radiation (hypothalamic/pituitary damage)
• infection e.g. meningitis
• traumatic brain injury
• pituitary surgery
• inflammatory (hypophysitis)
• pituitary apoplexy - haemorrhage/less commonly infection
• peri-partum infarction (Sheehan’s syndrome)

Question 21

What is the occurrence of congenital vs acquired hypopituitarism?

Answer 21

Congenital is rare, acquired is much more common

Question 22

What does hypopituitarism usually describe?

Answer 22

• anterior pituitary dysfunction
• but, certain processes - especially inflammation (hypophysitis) or surgery may cause posterior pituitary dysfunction too

Question 23

What is panhypopituitarism?

Answer 23

Total loss of anterior and posterior pituitary function

Question 24

How can radiotherapy cause radiotherapy induced hypopituitarism?

Answer 24

• pituitary and hypothalamus are both sensitive to radiation
• radiotherapy could be direct to pituitary (e.g. to treat acromegaly)
• radiotherapy could be indirect to pituitary (e.g. to treat CNS tumour nearby) = pituitary innocent bystander

Question 25

What does the extent of damage to the pituitary caused by radiation depend on?

Answer 25

Total dose of radiotherapy delivered to hypothalamo-pituitary axis - higher dose = higher risk of HPA axis damage

Question 26

What happens to GH, gonadotrophins and prolactin due to radiotherapy induced hypopituitarism?

Answer 26

• GH and gonadotrophins are most sensitive to damage
• prolactin can increase after radiotherapy due to loss of hypothalamic dopamine

Question 27

How long does risk to pituitary persist for after radiotherapy?

Answer 27

Up to 10 years, so annual assessment needed

Question 28

How does hypopituitarism present for FSH/LH? (4)

Answer 28

• reduced libido
• secondary amenorrhoea
• erectile dysfunction
• reduced pubic hair

Question 29

How does hypopituitarism present for ACTH?

Answer 29

• fatigue
• NB not a salt losing crises as aldosterone dependent on renin-angiotensin axis

Question 30

How does hypopituitarism present for TSH? (3)

Answer 30

• fatigue
• maybe weight gain
• bradycardia if extreme

Question 31

How does hypopituitarism present for GH?

Answer 31

• reduced QOL
• NB short stature only in children

Question 32

How does hypopituitarism present for prolactin?

Answer 32

Inability to breastfeed

Question 33

What is Sheehan’s syndrome?

Answer 33

• post-partum hypopituitarism secondary to hypotension (post-partum haemorrhage - PPH)
• PPH (blood loss) leads to pituitary infarction (loss of blood supply)
• more common in developing countries

Question 34

How does Sheehan’s syndrome occur?

Answer 34

• at the end of pregnancy, anterior pituitary is 2x normal size but blood supply has not increased
• this is normal but any blood loss means blood supply to pituitary too low
• blood supply not low enough for organ failure/death, but enough to infarct pituitary = cells die
• (PPG not affected as downgrowth of hypothalamus so neuronal not glandular)

Question 35

What are the symptoms of Sheehan’s syndrome?

Answer 35

• lethargy, anorexia, weight loss - TSH/ACTH/GH deficiency
• failure of lactation (cannot breastfeed) - prolactin deficiency
• failure to resume menses post-delivery
• posterior pituitary usually not affected

Question 36

How is Sheehan’s disease treated?

Answer 36

Lifelong supply of pituitary hormones

Question 37

What happens to anterior pituitary during pregnancy?

Answer 37

It enlarges (lactotroph hyperplasia)

Question 38

What is pituitary apoplexy?

Answer 38

• bleeding (haemorrhage) into the pituitary
• often dramatic presentation in patients with pre-existing pituitary tumours (adenomas)
• may be first presentation of pituitary adenoma

Question 39

What can the haemorrhage in pituitary apoplexy be precipitated by?

Answer 39

Anticoagulants

Question 40

What are the features of pituitary apoplexy?

Answer 40

• severe sudden onset headache (due to sudden increase in intracranial pressure)
• visual field defect - compressed optic chiasm (bitemporal hemianopia)
• if blood enters cavernous sinus it could compress nearby cranial nerves causing eye movement problems: diplopia - double vision (IV, VI), ptosis (III)

Question 41

What is important to keep in mind when measuring basal plasma hormone concentrations to diagnose hypopituitarism?

Answer 41

• cortisol - diurnal rhythm so time of day changes conc in blood
• T4 - circulating half life of 6 days so may be normal on day of presentation but low a week later
• FSH/LH - cyclical in women
• GH/ACTH - pulsatile

Question 42

What is a dynamic pituitary function test for ACTH & GH?

Answer 42

• ACTH & GH are stress hormones so we induce stress in patients by making them hypoglycaemic (<2.2mM) using insulin
• look for GH increase and ACTH release (cortisol measured since ACTH is hard to measure)
• if high levels, normal function

Question 43

What is a dynamic pituitary function test for TSH?

Answer 43

Could give TRH to see whether pituitary can make TSH

Question 44

What is a dynamic pituitary function test for FSH and LH?

Answer 44

Could give GnRH to see whether pituitary can make FSH and LH

Question 45

How would we make a radiological diagnosis of hypopituitarism?

Answer 45

• pituitary MRI - CT not so good at delineating pituitary gland
• may reveal specific pituitary pathology e.g. haemorrhage (apoplexy), adenoma
• would see an empty sella - thin rim of pituitary tissue

Question 46

How do we treat GH deficiency?

Answer 46

• NICE guidance
• confirm GH deficiency on dynamic pituitary function test
• assess QoL using specific questionnaire
• daily injection (no oral option as peptide)
• measure response by improvement in QoL and plasma IGF-1

Question 47

How do we treat prolactin deficiency?

Answer 47

Cannot treat

Question 48

How do we treat TSH deficiency?

Answer 48

• replace with once daily levothyroxine
• in secondary hypothyroidism, TSH is low so you cannot use this to adjust dose as you do in primary hypothyroidism
• aim for a fT4 above the middle of the reference range

Question 49

How do we treat ACTH deficiency?

Answer 49

• replace cortisol rather than ACTH
• difficult to mimic diurnal variation of cortisol
• two main options in the UK using synthetic glucocorticoids

Question 50

What are the two main options in the UK to replace cortisol using synthetic glucocorticoids?

Answer 50

• Prednisolone - once daily AM e.g. 3mg
• Hydrocortisone - three times per day e.g. 10mg/5mg/5mg

Question 51

Who is at risk of adrenal crisis?

Answer 51

Those with primary adrenal failure (Addison’s) or secondary adrenal failure (ACTH deficiency) at risk of adrenal crisis triggered by intercurrent illness

Question 52

What are the features of an adrenal crisis? (5)

Answer 52

• dizziness
• hypotension
• vomiting
• weakness
• can result in collapse and death

Question 53

What are the sick day rules for patients with ACTH deficiency? (4)

Answer 53

• patients who take replacement steroid e.g. prednisolone, hydrocortisone must be told sick day rules
• steroid alert pendant/bracelet
• double steroid dose (glucocorticoid not mineralocorticoid) if fever/recurrent illness
• if unable to take tablets (e.g. vomiting), inject IM hydrocortisone or come to A&E

Question 54

How is FSH/LH deficiency treated in men when no fertility is required?

Answer 54

• replace testosterone - topical or intramuscular
• measure plasma testosterone
• replacing testosterone does not restore sperm production (FSH dependent)

Question 55

How is FSH/LH deficiency treated in men when fertility is required?

Answer 55

• induction of spermatogenesis by gonadotrophin injections
• best response if secondary hypogonadism has developed after puberty
• measure testosterone and semen analysis
• sperm production may take 6-12 months

Question 56

How is FSH/LH deficiency treated in women when no fertility is required?

Answer 56

• replace oestrogen
• oral or topical
• will need additional progestogen if intact uterus to prevent endometrial hyperplasia

Question 57

How is FSH/LH deficiency treated in women when fertility is required?

Answer 57

Can induce ovulation by carefully timed gonadotrophin injections (IVF)