Study Results
Results pending
The study team has not published outcome measurements, participant flow, or safety data for this trial yet. Check back later for updates.
Basic Information
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Recruitment Status
COMPLETED
Total Enrollment
30 participants
Study Classification
OBSERVATIONAL
Study Start Date
2013-06-30
Study Completion Date
2017-09-01
Brief Summary
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This is an observational pilot study to quantify the amount of vibration, noise, physiological and biochemical instability that premature babies are exposed to during inter-hospital transport.
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Detailed Description
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Neonatal intensive care has advanced significantly in recent years resulting in a marked decrease in mortality, especially in the extremely low birth weight (ELBW) infants (\<1000g). However, we have not observed a parallel improvement in long term outcomes such as neurological disability as observed with the EPICure and EPICure 2 data.
There is a need to explore new avenues in neonatal care that can reduce the long term neurodevelopment complications of extremely preterm birth. One area that has received little attention is that of inter-hospital transfer of these preterm babies. In the UK, like other countries such as USA and Australia, the centralisation of neonatal intensive care in large tertiary units (NICU's) has resulted in reduced mortality but not significant morbidity. Data from Australia suggests there is 4-fold increase in death for those ELBW infants transferred between tertiary neonatal units within the same city (Melbourne). Furthermore, data from the USA, where 69,000 neonatal transports occur each year, have demonstrated a significant increase in severe intraventricular haemorrhages (IVH) in transported infants. Severe IVH is associated with a poor neurological outcome including cerebral palsy. Many of the ELBW infants are transferred within a few hours of life in order to receive specialist care and services. However, it is the first few days of life that represent the greatest risk of developing an IVH with up to 50% developing IVH before 3 days and if severe 75% could go on to develop cerebral palsy.
No causation has been identified for the associated significant increase in risk of IVH and it is likely to be multifactorial. Such factors could include resuscitation at birth and early care on the NICU. However, in developed countries some of these factors are likely to be less important with the establishment of neonatal networks (sharing common practice and guidelines) and international and national guidelines/training programmes for newborn resuscitation. This raises the actual transfer of the preterm infant which could represent a significant stress to the infant. Inter-hospital transfer, usually many miles away from the birth hospital, is at a time during early life when transition from fetus to newborn is still occurring and there is often cardiorespiratory instability. The combination of these factors can increase the risk of neurological injury to the immature developing brain, especially during the period of greatest risk of IVH. Although IVH is easy to identify and define as a risk to the long term neurodevelopment of the baby there is also the possibility that more subtle neurological injury can occur. Such injury may not be detectable from ultrasound imaging alone but may require novel biochemical markers that can be detected in the bodily fluids (blood, urine) or by more detailed imaging techniques (magnetic resonance imaging - MRI). A recent study has highlighted this with early markers of stress correlating with poor neurological predictors, such as regional alterations in brain volume (on MRI) and functional motor deficits, in ex-preterm infants at term corrected gestation.
As more ELBW infants are reaching school age, there are growing concerns surrounding the increased in incidence of neurodevelopmental problems in these children. Many predict that such problems may stem from early life exposure to environmental stressors which could potentially have adverse effects on the infant's physiological and neurological stability. The presence of these stressors is very much evident during inter-hospital transportation and on neonatal units where preterm infants are exposed to noise and mechanical vibration.
On all neonatal units, the characteristic loud noises contributed by alarms, ventilators, phones and even conversations often exceed the recommended hourly level of 45 decibels on an A-weighted scale. Excessive noise levels have been shown to increase heart rate in both preterm and term infants. A maturing biphasic pattern with initial cardiac acceleration and rebound deceleration has been observed in higher birth weight infants, this which was absent or milder in ELBW infants. Noise has also been shown to increase blood pressure, increase respiratory rates, and affect sleep cycles. Decreased autonomic and self-regulatory abilities make these ELBW infants vulnerable to high noise levels due to their inability to filter and process noxious stimuli. This could potentially hinder neurodevelopment during such a critical time.
During inter-hospital transfers, infants are continually exposed to prolonged, low-frequency, high amplitude mechanical vibration. This mechanical vibration has been shown to exceed the maximum recommended limit (0.31m/s) for adults. In adult humans and experimental animals this vibration was found to have adverse effects on the cardiovascular function, the nervous system, the thermoregulatory functions, metabolic and endocrine function, and gastrointestinal system. In animal models, short periods of vibration, similar to those experienced by transported infants, there is a deleterious effect on surfactant and respiratory function which is again often requiring support in the early part of a preterm infants life. The implications of vibration may be especially relevant when transporting ELBW infants as it could compromise the stability and observation of the infant in transport.
Whilst the focus on transport is to ensure the safety of the infant we must also explore interventions that can increase comfort, reduce physical stress and improve outcomes. No studies have detailed the combined physical, physiological and biochemical effects of inter-hospital transfer on these infants and their outcomes. Indeed, many studies have documented sound exposure and a limited number have documented vibration (albeit of the transport incubator rather than the baby). None of these studies have addressed this in a detailed and structured way that will allow us to plan interventional strategies aimed at reducing these stressors. Until such detailed data is available it is not possible to undertake trials aimed at reducing the impact of inter-hospital transfer with the aim of improving outcomes.
The present study will be the first to examine the physical forces the baby is exposed to during transfer. We will also combine this with measures of physiological stability (i.e. monitor vital signs and correlate these with physical stressors) as well as measure key biochemical markers in the newborn. These biochemical markers include cortisol (a well described marker of short-term stress)32, copeptin (a marker of newborn stress) and s100b protein in the urine (a marker of neurological injury). Outcome data will also be analysed.
STUDY OBJECTIVES AND PURPOSE Hypothesis Inter-hospital transfer of the ELBW infant in the first days of life will adversely impact on measures of neonatal stress in the short-term.
Aims
The Primary aim is to quantify:
(i) physical stresses experienced by preterm infants during inter-hospital transfer in early life,
Secondary aims are to quantify:
(ii) the physiological and biochemical disruption caused by transfer, (iii) central nervous system dynamics using advanced computational modelling to ascertain the potential impact on brain injury.
STUDY DESIGN This is an observational study that will provide feasibility data for a larger interventional trial with appropriate sample size.
The study has 3 elements:
Study A. Using infant mannequins we will undertake standard inter-hospital journeys similar to those currently undertaken by neonatal transport teams. The mannequin will be equipped with motion detection equipment (accelerometers), positioning devices (GPS) and noise meters. We will examine a number of interventions aimed at reducing transport associated motion. This work will allow us to plan future trials aimed at improving transport comfort, safety and practicality in preterm infants.
Study B. Establish the motion experienced by neonatal patients during current transport methods. This element of the study will quantify multi-directional forces experienced by babies during their transfer. Whilst data is available on vibration of the transport incubator, no study has quantified the actual effects on the baby and the response of key physiological observations (e.g. heart rate and oxygen saturation). Data from this element will capture a range of clinical variables such as gestation, weight and level of support. This data, along with that gathered in Study C, will allow us to develop a computational model of the physical stresses experienced and design better transport systems.
Study C. To quantify, correlate and assess the physiological and biochemical disturbance experienced by preterm infants undergoing inter-hospital transfer. Preterm infants undergoing inter-hospital transfer will be included in this element.
There is a need to explore new avenues in neonatal care that can reduce the long term neurodevelopment complications of extremely preterm birth. One area that has received little attention is that of inter-hospital transfer of these preterm babies. In the UK, like other countries such as USA and Australia, the centralisation of neonatal intensive care in large tertiary units (NICU's) has resulted in reduced mortality but not significant morbidity. Data from Australia suggests there is 4-fold increase in death for those ELBW infants transferred between tertiary neonatal units within the same city (Melbourne). Furthermore, data from the USA, where 69,000 neonatal transports occur each year, have demonstrated a significant increase in severe intraventricular haemorrhages (IVH) in transported infants. Severe IVH is associated with a poor neurological outcome including cerebral palsy. Many of the ELBW infants are transferred within a few hours of life in order to receive specialist care and services. However, it is the first few days of life that represent the greatest risk of developing an IVH with up to 50% developing IVH before 3 days and if severe 75% could go on to develop cerebral palsy.
No causation has been identified for the associated significant increase in risk of IVH and it is likely to be multifactorial. Such factors could include resuscitation at birth and early care on the NICU. However, in developed countries some of these factors are likely to be less important with the establishment of neonatal networks (sharing common practice and guidelines) and international and national guidelines/training programmes for newborn resuscitation. This raises the actual transfer of the preterm infant which could represent a significant stress to the infant. Inter-hospital transfer, usually many miles away from the birth hospital, is at a time during early life when transition from fetus to newborn is still occurring and there is often cardiorespiratory instability. The combination of these factors can increase the risk of neurological injury to the immature developing brain, especially during the period of greatest risk of IVH. Although IVH is easy to identify and define as a risk to the long term neurodevelopment of the baby there is also the possibility that more subtle neurological injury can occur. Such injury may not be detectable from ultrasound imaging alone but may require novel biochemical markers that can be detected in the bodily fluids (blood, urine) or by more detailed imaging techniques (magnetic resonance imaging - MRI). A recent study has highlighted this with early markers of stress correlating with poor neurological predictors, such as regional alterations in brain volume (on MRI) and functional motor deficits, in ex-preterm infants at term corrected gestation.
As more ELBW infants are reaching school age, there are growing concerns surrounding the increased in incidence of neurodevelopmental problems in these children. Many predict that such problems may stem from early life exposure to environmental stressors which could potentially have adverse effects on the infant's physiological and neurological stability. The presence of these stressors is very much evident during inter-hospital transportation and on neonatal units where preterm infants are exposed to noise and mechanical vibration.
On all neonatal units, the characteristic loud noises contributed by alarms, ventilators, phones and even conversations often exceed the recommended hourly level of 45 decibels on an A-weighted scale. Excessive noise levels have been shown to increase heart rate in both preterm and term infants. A maturing biphasic pattern with initial cardiac acceleration and rebound deceleration has been observed in higher birth weight infants, this which was absent or milder in ELBW infants. Noise has also been shown to increase blood pressure, increase respiratory rates, and affect sleep cycles. Decreased autonomic and self-regulatory abilities make these ELBW infants vulnerable to high noise levels due to their inability to filter and process noxious stimuli. This could potentially hinder neurodevelopment during such a critical time.
During inter-hospital transfers, infants are continually exposed to prolonged, low-frequency, high amplitude mechanical vibration. This mechanical vibration has been shown to exceed the maximum recommended limit (0.31m/s) for adults. In adult humans and experimental animals this vibration was found to have adverse effects on the cardiovascular function, the nervous system, the thermoregulatory functions, metabolic and endocrine function, and gastrointestinal system. In animal models, short periods of vibration, similar to those experienced by transported infants, there is a deleterious effect on surfactant and respiratory function which is again often requiring support in the early part of a preterm infants life. The implications of vibration may be especially relevant when transporting ELBW infants as it could compromise the stability and observation of the infant in transport.
Whilst the focus on transport is to ensure the safety of the infant we must also explore interventions that can increase comfort, reduce physical stress and improve outcomes. No studies have detailed the combined physical, physiological and biochemical effects of inter-hospital transfer on these infants and their outcomes. Indeed, many studies have documented sound exposure and a limited number have documented vibration (albeit of the transport incubator rather than the baby). None of these studies have addressed this in a detailed and structured way that will allow us to plan interventional strategies aimed at reducing these stressors. Until such detailed data is available it is not possible to undertake trials aimed at reducing the impact of inter-hospital transfer with the aim of improving outcomes.
The present study will be the first to examine the physical forces the baby is exposed to during transfer. We will also combine this with measures of physiological stability (i.e. monitor vital signs and correlate these with physical stressors) as well as measure key biochemical markers in the newborn. These biochemical markers include cortisol (a well described marker of short-term stress)32, copeptin (a marker of newborn stress) and s100b protein in the urine (a marker of neurological injury). Outcome data will also be analysed.
STUDY OBJECTIVES AND PURPOSE Hypothesis Inter-hospital transfer of the ELBW infant in the first days of life will adversely impact on measures of neonatal stress in the short-term.
Aims
The Primary aim is to quantify:
(i) physical stresses experienced by preterm infants during inter-hospital transfer in early life,
Secondary aims are to quantify:
(ii) the physiological and biochemical disruption caused by transfer, (iii) central nervous system dynamics using advanced computational modelling to ascertain the potential impact on brain injury.
STUDY DESIGN This is an observational study that will provide feasibility data for a larger interventional trial with appropriate sample size.
The study has 3 elements:
Study A. Using infant mannequins we will undertake standard inter-hospital journeys similar to those currently undertaken by neonatal transport teams. The mannequin will be equipped with motion detection equipment (accelerometers), positioning devices (GPS) and noise meters. We will examine a number of interventions aimed at reducing transport associated motion. This work will allow us to plan future trials aimed at improving transport comfort, safety and practicality in preterm infants.
Study B. Establish the motion experienced by neonatal patients during current transport methods. This element of the study will quantify multi-directional forces experienced by babies during their transfer. Whilst data is available on vibration of the transport incubator, no study has quantified the actual effects on the baby and the response of key physiological observations (e.g. heart rate and oxygen saturation). Data from this element will capture a range of clinical variables such as gestation, weight and level of support. This data, along with that gathered in Study C, will allow us to develop a computational model of the physical stresses experienced and design better transport systems.
Study C. To quantify, correlate and assess the physiological and biochemical disturbance experienced by preterm infants undergoing inter-hospital transfer. Preterm infants undergoing inter-hospital transfer will be included in this element.
Conditions
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Preterm Birth
Study Design
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Observational Model Type
CASE_CONTROL
Study Time Perspective
PROSPECTIVE
Study Groups
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Preterm inter-hospital transfers
preterm infants \<31 weeks gestation and \<=day 3 of life
No interventions assigned to this group
Preterm infants inborn
Preterm infants \<31 weeks gestation and \<=3 days old born and remaining at same hospital.
No interventions assigned to this group
Ex-preterm infants back transfered
Mature ex-preterm infants transferred back to referring hospital
No interventions assigned to this group
Eligibility Criteria
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Inclusion Criteria
* \<31 weeks gestation
* \<= 3 days old
* \<= 3 days old
Exclusion Criteria
* major congenital abnormality
* survival unlikely
* survival unlikely
Minimum Eligible Age
30 Minutes
Maximum Eligible Age
3 Months
Eligible Sex
ALL
Accepts Healthy Volunteers
No
Sponsors
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University of Nottingham
OTHER
Sponsor Role
lead
Responsible Party
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Responsibility Role
SPONSOR
Principal Investigators
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Don Sharkey, PhD
Role: PRINCIPAL_INVESTIGATOR
University of Nottingham
Locations
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Nottingham University Hospitals NHS Trust
Nottingham, , United Kingdom
Site Status
Countries
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United Kingdom
Other Identifiers
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12063
Identifier Type: -
Identifier Source: org_study_id
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