REPRO: Pharmacology of the Uterus

Question 1

Briefly, describe the muscular structure of the uterus.

Answer 1

• outer longitudinal fibres
• middle figure-eight fibres
• inner circular fibres

Question 2

What are some mechanical properties of the myometrium?

Answer 2

• contractions mean an increase in uterine pressure, forcing content towards the cervix and acts as a natural ligature to prevent blood loss
• it’s spontaneously active (myogenic): it produces regular contractions without neural or hormonal input
• highly sensitive to neurotransmitter and hormones
• rhythmic contractions for parturition

Question 3

How is synchronous contraction achieved?

Answer 3

There are pacemaker cells in the myometrium called the interstitial cells of Cajal (ICCs), which initiate and coordinate contractions.
There is electrical communication via gap junctions made of connection proteins. These gap junctions are found:
- between ICCs
- between ICCs and smooth muscle cells
- between smooth muscle cells

They function as a syncytium.

Question 4

Briefly, what is the contractility mechanism of smooth muscle in the uterus?

Answer 4

We get:

• ICC periodic activation of inward currents
• depolarisations
• Ca2+ entry through VGCCs
• an increase in [Ca2+]i
• contraction

This works through the Gα q/11 subunit mechanism.

Question 5

What effect does increasing calcium levels have on these SMCs?

Answer 5

An increase in [Ca2+]i will lead to contraction. This is a graded response; incremental increases in [Ca2+]i will lead to incremental increases in the force of contraction.

Question 6

Describe the effect of gradually increasing calcium levels on these SMCs.

Answer 6

• at low concentrations of stimulants on ICCs:
  
  • there is an increased slow wave frequency, producing an increased frequency of contractions
• at higher concentrations:
  
  • there is an increased frequency of action potentials on top of those slow waves
  • ie. increased peak of [Ca2+]i, producing both increased frequency and increased force of contractions
• at higher concentrations still:
  
  • there is an increased plateau of slow wave, producing prolonged sustained contractions

Question 7

What will the effects of large concentrations of stimulants on ICCs indicate?

Answer 7

• the cells will be hypertonus (there is incomplete relaxation)
• the Ca2+ extrusion processes are not effective
• important: it interferes with blood flow, which can cause foetal distress

Question 8

Describe the innervation of the uterus, and how it is regulated by neurotransmitters.

Answer 8

The myometrium is sympathetically (not parasympathetically) innervated. This means that there is the expression of α and β adrenoreceptors.

An α adrenoreceptor agonist will cause contraction.
A β adrenoreceptor agonist will cause relaxation.

Question 9

Describe how the uterus is regulated by sex hormones.

Answer 9

Progesterone inhibits contractions.

Oestrogen increases contractions.

Question 10

Describe the contractions in a pregnant and nonpregnant uterus.

Answer 10

NON-PREGNANT UTERUS:

• weak contractions early on in the cycle
• strong contractions during menstruation (decreased progesterone, increased prostaglandins)

PREGNANT UTERUS:

• weak and uncoordinated contractions in early pregnancy (high progesterone)
• strong and coordinated contractions at parturition (increased oestrogen)

Question 11

How do sex steroids directly affect ICCs?

Answer 11

Oestrogen/progesterone receptors are found on ICCs.

During parturition, the oestrogen:progesterone ratio increases. Oestrogen increases, while progesterone decreases the expression of gap junctions in the myometrium.

Question 12

Describe how the uterus is regulated by prostaglandins.

Answer 12

The myometrium and endometrium synthesise PGE2 and PGF2α - this is promoted by oestrogens. Both these prostaglandins induce myometrial contraction.

The prostaglandins act together to:

• coordinate an increased frequecy/force of contractions
• increase the gap junctions
• soften the cervix

They play a role in dysmenorrhoea (severe menstrual pain), menorrhagia (severe menstrual blood loss) and pain after parturition. Thus, NSAIDS are effective, as they can reduce contractions and pain.

Prostaglandins are effective in early and mid-pregnancy.

Question 13

List some examples of prostaglandin analogues.

Answer 13

EXAMPLES: dinoprostone (PGE2), carboprost (PGF2α), misoprotol (PGE1) analogues

Question 14

What are the uses and concerns of using prostaglandin analogues?

Answer 14

USES:

• induction of labour before term
• induction of abortion
• pospartum bleeding
• softening the cervix

CONCERNS:

• dinoprostone can cause systemic vasodilation
• they have the potential for cardiovascular collapse (if given as cervical.vaginal insert)
• PGs can make the uterus hypertonus and cause the foetus distress

Question 15

Describe the regulation of the uterus by oxytocins.

Answer 15

Oxytocin is a non-peptide hormone synthesised in the hypothalamus and released from the posterior pituitary gland. It is released in response to suckling and cervical dilation.

Oestrogen (released at later stages of parturition) produces:

• increased oxytocin release
• increased oxytocin receptors
• increased gap junctions

Oxytocin also increases the synthesis of prostaglandins.

Question 16

Why can we not use oxytocin interchangeably with prostaglandins?

Answer 16

Oxytocin receptors are not expressed much (if at all) pre-term; they’re particularly expressed at term, so there wouldn’t be that big of an effect.

Effects of oxytocin require oestrogen-induced oxytocin receptor expression).

Question 17

List some examples of oxytocin analogues and describe the pharmacological actions.

Answer 17

EXAMPLES: syntocinon and pitocin are synthetic versions of oxytcin
Syntometrine is a combination of oxytocin (causing rapid contractions) and ergot (causing prolonged contractions).

PHARMACOLOGICAL ACTIONS:

• low concentrations of oxytocin analogues can increase the frequency/force of contractions
• high concentrations cause hypertonus (foetal distress)

Question 18

What are the uses of using oxytocin analogues?

Answer 18

USES:

• induction of labour at term (doesn’t soften cervix)
• treat/prevent post-partum haemorrhage

Question 19

What is ergot?

Answer 19

Ergot is a fungus that grows on some cereals (eg. rye) and grasses.
It contains an array of potent agents, including ergot alkalois (eg. ergometrine, ergotamine; both based on LSD moiety), histamine, tyramine and acetylcholine.

When ingested, it causes ergotism, gangrene, convulsions and induces abortions.

Question 20

Describe the mechanism of actions, the actions and the uses of ergot.

Answer 20

ACTION:
- powerful and prolonged uterine contractions, but only when the myometrium is relaxed

MECHANISM:
- stimulation of α adrenoreceptors, 5HT receptors?

USES:
- post-partum bleeding (not induction)

Question 21

When would myometrial relaxants be used?

Answer 21

Relaxants may be used in premature labour.
It would be to delay the delivery by up to 48 hours, so that the mother can be transferred to a specaialist unit, and given antenatal corticosteroids to aid foetal lung maturation and increase the chances of survival.

Question 22

List some examples of myometrial relaxants and explain the implications.

Answer 22

β2 adrenoreceptor stimulants (eg. salbutamol):

• relax uterine contractions by a direct action on the myometrium
• used to reduce the strengths of contractions in premature labour
• may occur as a side effect of the drug used in asthma

Ca2+ channel antagonists (eg. nifedipine):
- used in hypertension

Oxytocin receptor antagonists (eg. retosiban)

COX inhibitors (eg. NSAIDs):

• decrease prostaglandins
• useful to treat dysmenorrhoea and menorrhagia
• may cause foetal renal dysfunction

Question 23

How can we measure uterine contractions?

Answer 23

We can use isomertic tension recording.
This is when you measure the tension genrated with the diameter of the mucle ring remaining constant.

You can use large organ baths, examples being the aortic ring experiments we did in Year 1.

These are widely used techniques to investigate the functional proterties of uterine, vascular, airway and bladder smooth muscle segments.