Deferred Umbilical Cord Clamping Clinical Trial
Official title:
Delivery Room and Postnatal Assessment of the Physiological Effects of Deferred Cord Clamping on the Newborn: A Feasibility Study
This is an observational study to see if at birth, flow of blood from a placenta to the baby can be estimated non-invasively using Doppler ultrasound and/or cutaneous perfusion measured using a novel PPG sensor.
Deferred cord clamping appears to confer short term benefits for both term and preterm
newborn babies. However, the optimal timing of cord clamping remains unclear, it is
increasingly being hypothesised that immediate cord clamping may be disrupting a
physiological process. Indeed, differences in the anatomy and physiology of the baby and
placenta may lead to functional differences potentially altering the blood flow to the
newborn. This may have implications for the baby if the cord is clamped too early or too
late. A method of estimating the best time to clamp the cord could offer both short and
long-term benefits especially in the preterm population.
Many studies have started measuring the short-term benefits of deferred cord clamping such as
reduced requirements for ventilation , red cell transfusions, improved perfusion and reduced
incidence of intraventricular haemorrhage. Studies are currently underway examining the
long-term benefits of deferred cord clamping. However, very little is known on the background
physiology of placental transfusion. Studies often use arbitrary times for clamping the cord
with little reference to a scientific basis. Many of the studies included in both Cochrane
reviews and meta-analysis use a variable definition of deferred cord clamping varying from 30
seconds to 5 minutes or when the cord had stopped pulsating.
There appears to be very few risks associated with deferred cord clamping. There are some
reports of an increased need for phototherapy to treat jaundice but this is not consistent.
Polycythaemia is also reported, however, this is known to be present in a proportion of term
deliveries regardless of the time of clamping and deferred cord clamping appears to confer no
greater clinical risk with no change in the incidence of hypoglycaemia or increased need for
exchange transfusion. In the preterm population once the baby has delivered there are issues
relating to resuscitation that also need to be addressed. For example, a baby born at 25
weeks gestation may benefit from deferred cord clamping but this will alter the timing and
approach of resuscitation. A better understanding of the physiology in these instances,
coupled with a reliable measure of when the majority of the placental transfusion has
occurred, may guide the optimal timing of cord clamping and the initiation of resuscitation.
Other methods of assessing placental transfusion have been tried and studies are currently
ongoing including weighing infants during transfusion to measure the volume and speed of
blood transfusion. However, it is difficult to transfer this method to the preterm population
due to concerns regarding thermoregulation and need for resuscitation.
Although a number of studies investigating the effects of deferred umbilical cord clamping
have been performed there is little research on the physiology behind placental transfusion.
One study has previously used Doppler to assess blood velocity in the umbilical arteries
although the methodology of this study is now outdated. This study was performed using sound
Doppler recordings, which were then played via tape into a continuous spectrograph analyser.
With the advancement of technology and the use of colour Doppler ultrasound it is possible to
more reliably and quickly quantify umbilical cord blood flow therefore eliminating the
methodological flaws of the above study. A few studies have examined the rate of placental
transfusion although there has been disagreement as to whether the transfusion is a steady
state or a rapid decrease over the first minutes after delivery. There is also little
discussion as to whether timings are individual for each foetal-placental unit.
As discussed, there seems to be a decreased requirement for red cell transfusion after
deferred cord clamping which confers that infants have a higher haemoglobin concentration.
Photoplethysmographic Sensors (PPG) can be used to monitor the haemodynamic status of a
patient including heart rate, oxygen saturations and perfusion. PPG works by emitting a light
source into tissue which is then reflected and measured, this fluctuates according to blood
flow. The amount of light reflected will therefore vary according to the blood volume and
hence give an assessment of haemodynamic status.
Assessing whether either Doppler or PPG provide a feasible method of measuring umbilical
blood flow and its cessation will help guide us in clinical practice. Both methods involve
equipment available for use in the delivery suite, they involve minimal handling of the
infant which is important especially in the context of preterm deliveries and they enable the
neonatal team to continue assessment and early management. The added advantage of PPG is that
it can also be used to monitor the heart rate of the baby during the first minutes of life.
This will provide valuable information relating to the stability of the baby during the
placental transfusion.
It has been shown that neonates who undergo deferred cord clamping have an increased
haemoglobin level and a lower requirement for inotropic support of their blood pressure. This
improved haemodynamic status may be sustained for a period of time. Important markers of
haemodynamic status include heart rate, blood pressure and capillary refill. Assessment of
these markers needs to be carried out in the first few days of life and correlated with skin
perfusion.
STUDY OBJECTIVES
Primary Objective:
To use Doppler ultrasound and/or PPG to improve knowledge on the physiology of deferred cord
clamping and assess their use in measuring when the majority of placental transfusion has
occurred. This may provide a quantitative method of guiding the optimal timing of cord
clamping and the initiation of resuscitation enabling it to extend studies to preterm infants
in whom this may be of greater benefit.
Secondary Objective:
To compare cardiovascular status of infants undergoing cord clamping at different ages after
birth. Measure central and peripheral capillary refill time using a PPG sensor and by the
investigators observation, measure non-invasive blood pressure, record heart rate by
auscultation, measure haemoglobin and haematocrit.
STUDY DESIGN This is an observational study that will provide feasibility data for a larger
trial with a preterm cohort.
The study will recruit babies born at or after 32 weeks with no antenatal or perinatal risk
factors that may necessitate the need for resuscitation beyond normal thermal management in
the delivery room.
The study has 2 elements:
Part I. Either, a Doppler probe will be applied to the umbilical cord to measure umbilical
blood flow or a PPG sensor placed on the baby to monitor cutaneous perfusion. In the case of
Doppler assessment the probe will be applied in a manner that does not affect blood flow.
Part II. To determine whether deferred cord clamping has an effect on cardiovascular status
after delivery we will compare the cohort with deferred cord clamping to an observational
control cohort and measuring indicators of cardiovascular status (blood pressure, capillary
refill time, haemoglobin count). We will be assessing the capillary refill time using
standardised pressure application with a PPG sensor placed centrally and peripherally on the
baby. Both pressures and lengths of blanching will be variable.
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