8.3 - Normal CTG COPY Flashcards

1
Q

What causes normal variability?

A

interaction between sympathetic and parasympathetic systems- normal variability means the fetus is unlikely to be hypoxic

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2
Q

Fetal response to hypoxia

A

Aim of fetus: decrease myocardial workload by slowing FHR—–> Deceleration

If this is insufficient to maintain adequate oxygenation —> conserves non essential activity therefore stops moving —-> lack of accelerations

If intrapartum hypoxia continues:

—> Release of catecholamines to increase HR which increase oxygenation from placental bed and results in peripheral vasoconstriction to divert non essential blood flow from periphery to central organs. Also causes breakdown of glycogen to glucose for use in myocardium

***Compensated response *****–> Rise in baseline HR but normal variability

Still hypoxic:

*****DECOMPENSATION******

loss of variability due to myocardial hypoxia and acidosis —-> unstable baseline and a progressive stepwise reduction of the HR (preterminal)

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3
Q

What is the fetal response to a significant fall in available oxygen?

A

The chemoreceptors in carotid sinus, aortic arch and brainstem detect low partial pressure of oxygen, and stimulate the cardioregulatory centre in the medulla oblongata. This triggers the vagus nerve and ACH is secreted to act on the SA node to reduce HR, thus causing a deceleration.

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4
Q

What does normal variability demonstrate and why is this reassuring?

A

Sympathetic NS - adrenalin and noradrenalin act on SA node to increase HR and blood pressure
Parasympathetic NS - acetylcholine act on SA node to reduce HR and BP
Variability demonstrates normal development and good oxygenation of the CNS and ability to self-regulate HR and BP to respond and compensate for external pressures

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5
Q

What is the fetal response to a gradual fall in available oxygen?

A

The chemoreceptors in carotid sinus, aortic arch and brainstem detect low partial pressure of oxygen, and stimulate the cardioregulatory centre in the medulla oblongata. Increased sympathetic nerve firing stimulates the adrenals to release adrenalin (80%) and noradrenalin (20%). Adrenalin acts of beta-adrenergic receptors, and noradrenalin acts as neurotransmitter for sympathetic neurones.
They act to increase HR and increase peripheral vasoconstriction - both increasing BP (and O2 delivery) and directing blood flow away from peripheries in favour of perfusion key organs (heart, brain, adrenals).
This causes a high baseline rate and reduced variability as the sympathetic drive outweighs the parasympathetic.

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6
Q

Where are the baroreceptors located and what is their function?

A

Carotid sinus, aortic arch and brainstem.
They detect hypertension and hypotension.
Their mode of action is to increase vagal stimulation and ACH release (causing drop in HR and BP), or switch off vagal firing and ACH release (causing rise in HR and BP).

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7
Q

What happens during cord compression?

A

Chemoreceptors detect sudden and significant drop on O2 concentration of fetal blood. They stimulate vagus nerve and increase ACH release, which acts on SA node to cause a deceleration in HR.
As cord is released after contraction, the relative hypotension from low cardiac output and removal of downstream obstruction is detected by baroreceptors, and causes reduced vagal firing and ACH release, thus causing increase in HR and BP.
Overshoot is caused by increased sympathetic drive in response to hypoxia, as it is unopposed by parasympathetic innervation.

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8
Q

Cause of a fetal tachycardia?

A
  • maternal pyrexia / dehydration
  • infection
  • prematurity
  • hypoxia
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9
Q

How does the fetus compensate for acute versus chronic hypoxia?

A

Acute

  • sympathetic and parasympathetic effects on fetal HR to increase/reduce HR
  • redirecting blood flow from gut/peripheries in order to maintain constant perfusion to essential organs (brain/adrenals/heart)
  • minimising movements to reduce oxygen requirement

Chronic - (in addition to above) increase fetal Hb concentration to maximise oxygen carrying capacity.

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10
Q

What is the sympathetic response to hypoxia?

A

Release of catecholamines from adrenals

Purpose:

  • Increase HR to increase oxygemation from placental bed
  • Peripheral vasoconstriction to achieve effective redistribution of blood centrally
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11
Q

How is the parasympathetic nervous system mediated?

A

Baroreceptors
- Stretch receptors in carotid sinus and arch of aorta

Chemoreceptors
- Found on aortic and carotid bodies and in brain

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12
Q

How does the fetal response to head/cord compression manifest?

A

Baroreceptor driven

  • Stretch receptors in carotid sinus and arch of aorta
  • In labour, both fetal heart and umbilical cord may undergo compression
  • Compression = Increased peripheral resistance => increased blood pressure => stimulation of baroreceptors => parasympathetic NS triggered => vagus nerve triggers AV node to slow down HR
  • Baroreceptors also decrease sympathetic stimulation
  • Seen as a sudden decrease and rapid return when compression finishes- variable decels
  • In the absence of other abnormalities on CTG (e.g. rising BR) this shows mechanical stress and no further intervention other than observation is needed
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13
Q

Describe fetal response if chemoreceptors triggered?

A
  • On aortic and carotid bodies + in brain
  • Respond to changes blood- acidaemia and hypoxia
  • Stimulation of these chemoreceptors leads to PS stimulation and therefore drop in FHR
  • When stimulated, take longer to return to BR as oxygenated blood needs to return to maternal venous sinuses to remove the stimulus to chemoreceptors
  • Late onset and late recovery —> LATE decelerations
  • Often associated with fetal acidosis
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14
Q

Baseline CTG

A
  • Baseline heartrate - 110 - 160 (at time of rest and no movement or contractions) (sleep pattern may decrease)
  • Variability - 6- 25 bpm - normal variability
  • Accelerations - present - (well oxygenated fetus) min of two accelerations within a 20 minute period
  • Decelerations - no decleleration
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15
Q

Indication for CTG

A
  • RFM - reduced M
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16
Q

How does a rise in temperature affect a fetus’ ability to deal with hypoxia?

A

Can predispose fetus to neurological injury from hypoxia

17
Q

Cause of accelerations?

A

Fetal movement and somatic NS

Sign of fetal well being

18
Q

Impact of placental reserve on growth and wellbeing:

A
  • FGR– uteroplacental sinuses smaller
  • Diabetes — uteroplacental sinuses bigger but hyperplacentosis affects amount of placental pools available for gaseous exchange

If reserve low due to either of above:

  • fetus may restricted growth to supply oxygenated blood to vital organs
  • Labour- uterine contractions may cause rapid development of hypoxia and acidosis due to compression of branches of uterine artery
  • Oxytocin use- may increase strength/frequency contractions therefore perfusion of uteroplacental sinuses and subsequent hypoxia/metabolic acidosis
19
Q

Fetal adaptations to hypoxic intrauterine environment

A
  • High Hb 180-220
  • HbF increased affinity for O2
  • Rapidly releases O2 in hypoxic environments
  • Raised Hb also acts as buffer to metabolic acidosis to minimise neurological sequelae
20
Q

Fetal response to hypoxia

A

Aim of fetus: decrease myocardial workload by slowing FHR—–> Deceleration

If this is insufficient to maintain adequate oxygenation —> conserves non essential activity therefore stops moving —-> lack of accelerations

If intrapartum hypoxia continues:

—> Release of catecholamines to increase HR which increase oxygenation from placental bed and results in peripheral vasoconstriction to divert non essential blood flow from periphery to central organs. Also causes breakdown of glycogen to glucose for use in myocardium

***Compensated response *****–> Rise in baseline HR but normal variability

Still hypoxic:

*****DECOMPENSATION******

loss of variability due to myocardial hypoxia and acidosis —-> unstable baseline and a progressive stepwise reduction of the HR (preterminal)