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Trial registered on ANZCTR

Registration number

ACTRN12620000324910

Ethics application status

Approved

Date submitted

20/02/2020

Date registered

9/03/2020

Date last updated

20/09/2021

Date data sharing statement initially provided

9/03/2020

Type of registration

Prospectively registered

Titles & IDs

Public title

Early versus late parenteral nutrition in term and late preterm infants: A Randomized Controlled Trial

Scientific title

Early versus late parenteral nutrition in term and late preterm infants: A Randomized Controlled Trial

Secondary ID [1]

Nil known

Universal Trial Number (UTN)

Trial acronym

Linked study record

Health condition

Health condition(s) or problem(s) studied:

critical illness

Condition category

Condition code

Diet and Nutrition

Other diet and nutrition disorders

Reproductive Health and Childbirth

Complications of newborn

Intervention/exposure

Study type

Interventional

Description of intervention(s) / exposure

‘Late Parenteral Nutrition (PN)’
Infants randomised to ‘Late PN’ will commence PN only after the completion of Day 5 (i.e.120 hours) of NICU admission.
If an infant randomised to ‘late PN’ does not require PN after Day 5, the infant will still be included as being in the ‘Late PN’ group and analysed as such.

PN will be defined as the administration of any amount of intravenous amino acids and/or lipid emulsion. Administration of PN is either via peripheral intravenous cannula or central venous access device. Prescription of PN (including type of PN, dosage and rate of administration) will be determined by the treating clinician on a daily basis, depending on the infant’s clinical progress and according to the KEMH/PCH Neonatology Guidelines (Nutrition: Volume and Nutritional Requirements AND Parenteral Nutrition.
All PN formulations will be prepared by the Pharmacy Department at PCH or an external compounding provider. PN may be ‘Standard PN’ or ‘Non- standard PN’. ‘Standard PN’ consists of predetermined amounts of glucose, amino acids and standard concentrations of electrolytes, trace elements, vitamins and heparin. If clinically indicated, ‘Non-standard PN’ may be ordered by the treating clinician to allow modifications. SMOF 17% consisting of soya oil (30%), medium chain triglyceride (30%), refined olive oil (25%) and fish oil (15%) will be used as the source of parenteral lipids. Both fat soluble (Soluvit N®) and water soluble vitamins (Vitalipid N®) will be added to the lipid emulsion (SMOF®).
Infants randomised to the ‘early PN’ group will receive PN formulation as prescribed by the treating doctor within the 48 hours of admission to NICU.
Infants randomised to the ‘late PN’ group, will receive glucose and sodium chloride solutions at a rate, as per infant’s needs up to Day 5 and then commence PN from Day 6 of admission to NICU.
PN will be prescribed by NICU registrar/senior registrar/consultant and administered by NICU nursing staff according to the KEMH/PCH Neonatology Guidelines: Volume and Nutritional Requirements. Administration of PN and glucose, sodium and other electrolytes will be titrated according to routine biochemical results (examples: blood glucose, serum sodium, potassium, magnesium, calcium) by the treating clinician.
All PN charts will be reviewed daily by the research team to ensure each prescription is ordered, prepared and administered correctly.

Intervention code [1]

Treatment: Other

Comparator / control treatment

‘Early Parenteral Nutrition (PN)’
Infants randomised to ‘Early PN’ will be commenced PN within Day 2 (i.e. 48 hours) of admission to NICU.

Control group

Active

Outcomes

Primary outcome [1]

Plasma phenylalanine levels
measured by performing amino acid analysis using ultra performance binary liquid chromatography

Timepoint [1]

Day 4 and Day 8 of admission

Primary outcome [2]

Plasma F2- isoprostanes levels
measured by GC coupled to electron-capture negative-mode chemical ionisation and MS (GC/MS)

Timepoint [2]

Day 4 and Day 8 of admission

Secondary outcome [1]

Total and individual plasma amino acid levels
composite endpoint
measured by performing amino acid analysis using ultra performance binary liquid chromatography

Timepoint [1]

Day 4 and Day 8 of admission

Secondary outcome [2]

Plasma fatty acid profiles
composite endpoint
measured by gas chromatography

Timepoint [2]

Day 4 and Day 8 of admission

Secondary outcome [3]

In-hospital all-cause mortality: defined as death from any cause during the initial hospital stay
measured by reviewing medical records.

Timepoint [3]

During hospital stay

Secondary outcome [4]

Healthcare-associated bloodstream infection (HABSI): defined as positive culture on a blood sample drawn 48 hours after admission to the ICU

Determined by reviewing medical records

Timepoint [4]

During hospital stay

Secondary outcome [5]

Length of hospital stay (days)
Length of hospital stay will be determined by reviewing medical records

Timepoint [5]

During hospital stay

Secondary outcome [6]

Weight at the time of discharge from the hospital (Z-scores)
Weight will be measured using a baby scale and then converted to Z-score by using Fenton 2013 growth charts (https://peditools.org/fenton2013/).

Timepoint [6]

At discharge

Secondary outcome [7]

Duration of respiratory support [defined as mechanical ventilation via endotracheal tube OR non-invasive positive-pressure ventilation (NIPPV) OR continuous positive airway pressure (CPAP) OR humidified high-flow nasal prong (HFNP) therapy in days]

Duration of respiratory support will be determined by reviewing medical records..

Timepoint [7]

During hospital stay

Secondary outcome [8]

Incidence of hypoglycaemia (plasma glucose < 45 mg/dL (2.6 mmol/L)

Determined by reviewing medical records.

Timepoint [8]

During hospital stay

Secondary outcome [9]

Liver function outcomes
Incidence of liver dysfunction [raised liver function tests including total bilirubin, alkaline phosphatase, gamma-glutamyltransferase , alanine transferase, and aspartate aminotransferase]
Determined by reviewing medical records.

Timepoint [9]

During hospital stay

Secondary outcome [10]

Highest blood urea nitrogen levels during hospital stay (Urea/2.14; mmol/L)
Determined by reviewing medical records.

Timepoint [10]

During hospital stay

Secondary outcome [11]

Highest C reactive protein (mg/L)
Determined by reviewing medical records

Timepoint [11]

During hospital stay

Secondary outcome [12]

Neonatal mortality (death in the first 28 days of birth from any cause)
Determined by reviewing medical records

Timepoint [12]

28 days from birth

Secondary outcome [13]

Incidence of hyperglycaemia (plasma glucose > 150 mg/dL (8.3 mmol/L)
determined by reviewing medical records

Timepoint [13]

during hospital stay

Secondary outcome [14]

Other types of hospital-acquired infection [e.g. ventilator-associated pneumonia, cerebrospinal fluid (CSF) infection, urinary tract infection (UTI), surgical site infection and fungal infection]: defined as positive growth on blood culture or CSF or sterile urine or wound swabs)
Determined by reviewing medical records.

Timepoint [14]

during hospital stay

Secondary outcome [15]

Duration of NICU stay (days)
Duration of NICU will be determined by reviewing medical records.

Timepoint [15]

during hospital stay

Secondary outcome [16]

Length at the time of discharge from the hospital (Z-scores)
Length will be measured by using a baby scale and then converted to Z-score by using Fenton 2013 growth charts (https://peditools.org/fenton2013/).

Timepoint [16]

At discharge

Secondary outcome [17]

Head circumference at the time of discharge from the hospital (Z-scores)
Head circumference will be measured by using a tape measure and then converted to Z-score by using Fenton 2013 growth charts (https://peditools.org/fenton2013/).

Timepoint [17]

At discharge

Secondary outcome [18]

Changes in length from baseline at discharge (Changes in Z scores)
Length will be measured by using a baby scale and then converted to Z-score by using Fenton 2013 growth charts (https://peditools.org/fenton2013/).

Timepoint [18]

At discharge

Secondary outcome [19]

Changes in head circumference from baseline at discharge (Changes in Z scores)
Head circumference will be measured by using a tape measure and then converted to Z-score by using Fenton 2013 growth charts (https://peditools.org/fenton2013/).

Timepoint [19]

On admission and at discharge

Secondary outcome [20]

Changes in weight from baseline at discharge (Changes in Z scores)
Weight will be measured by using a baby scale and then converted to Z-score by using Fenton 2013 growth charts (https://peditools.org/fenton2013/).

Timepoint [20]

During hospital stay

Secondary outcome [21]

Highest blood glucose level (mmol/L)
Determined by reviewing medical records.

Timepoint [21]

During admission

Secondary outcome [22]

Lowest blood glucose level (mmol/L)
Determined by reviewing medical records.

Timepoint [22]

During hospital stay

Secondary outcome [23]

Incidence of cholestasis: defined as serum level of direct bilirubin>20% of total serum bilirubin or serum level of direct bilirubin > 34 mmol/L
Determined by reviewing medical records.

Timepoint [23]

During hospital stay

Secondary outcome [24]

Highest plasma level of total bilirubin during hospital stay (mmol/L)
Determined by reviewing medical records.

Timepoint [24]

During hospital stay

Secondary outcome [25]

Highest plasma level of alkaline phosphatase during hospital stay (IU/L)
Determined by reviewing medical records,

Timepoint [25]

During hospital stay

Secondary outcome [26]

Highest plasma level of gamma-glutamyl-transferase during hospital stay (IU/L)
Determined by reviewing medical records.

Timepoint [26]

During hospital stay

Secondary outcome [27]

Highest plasma level of alanine transferase (IU/L)
Determined by reviewing medical records.

Timepoint [27]

During hospital stay

Secondary outcome [28]

Highest plasma level of aspartate aminotransferase (IU/L)
Determined by reviewing medical records.

Timepoint [28]

During hospital stay

Secondary outcome [29]

Duration of ventilation (days): defined as mechanical ventilation via endotracheal tube or NIPPIV
Duration of ventilation will be determined by reviewing medical records.

Timepoint [29]

During hospital stay

Secondary outcome [30]

Duration of inhaled nitric oxide therapy (hours)
Duration of inhaled nitric oxide therapy will be determined by reviewing medical records.

Timepoint [30]

During hospital stay

Secondary outcome [31]

Duration of inotrope support (hours)
Duration of inotrope support will be determined by reviewing medical records.

Timepoint [31]

During hospital stay

Secondary outcome [32]

Incidence of metabolic acidosis (pH< 7.25 or base excess <-5)
Incidence of metabolic acidosis will be determined by reviewing medical records.

Timepoint [32]

During hospital stay

Secondary outcome [33]

Red cell fatty acid profiles
Red cell fatty acid profiles will be measured by gas chromatography

Timepoint [33]

Day 4 and Day 8 of admission

Eligibility

Key inclusion criteria

Infants will be eligible for study inclusion it they meet all of the following inclusion criteria: (1) All term or late preterm infants, born >=34 weeks of gestation at birth until day 28 of life admitted to NICU who have high likelihood of being unable to tolerate full enteral feeds for at least three to five days and hence require parenteral nutrition (PN) (2) Informed parental/legal guardian consent

Minimum age

0 Days

Maximum age

28 Days

Sex

Both males and females

Can healthy volunteers participate?

Key exclusion criteria

Infants will be excluded from participation in the trial if they meet any one or more of the following exclusion criteria: (1) Infants > 28 days of life; (2) Preterm infants (born at <34 weeks of gestation); (3) Infants who received PN from a referring hospital; (4) Infants with suspected inborn error of metabolism.

Study design

Purpose of the study

Treatment

Allocation to intervention

Randomised controlled trial

Procedure for enrolling a subject and allocating the treatment (allocation concealment procedures)

Allocation concealment will be achieved by using opaque sealed envelopes. Once consent is provided, the CPI will open the next opaque sealed envelope to allocate the infant to either ‘Early PN’ or ‘Late PN’ group.

Methods used to generate the sequence in which subjects will be randomised (sequence generation)

Group assignment will be allocated by the Clinical Trial Pharmacist at Perth Children's Hospital using a computer-generated randomisation sequence in a 1:1 ratio in block sizes of 2 and 4 and stratified according to the primary diagnostic category (medical or surgical) in order to minimise selection bias.

Masking / blinding

Open (masking not used)

Who is / are masked / blinded?

Intervention assignment

Parallel

Other design features

Phase

Not Applicable

Type of endpoint/s

Safety/efficacy

Statistical methods / analysis

Data will be analysed by the trial biostatistician. The primary ANCOVA analyses will assess differences between the two PN groups in log-transformed F2 isoprostane and phenylalanine levels at Days 4 and 8. Covariate adjustment will be made for baseline F2 isoprostane/phenylalanine, sex, gestational age, medical/surgical group, term/late term group, daily PN doses, and severity of illness scores (SNAPPE-II).
Linear regression will be used for analysis of the secondary continuous outcomes (amino acid and fatty acid profiles; growth outcomes; highest BUN/CRP/ LFTs/blood glucose). Trajectories of F2 isoprostane, plasma amino acids and fatty acids will be examined within a mixed effects regression framework to take account of the multiple measures per child. Logistic regression will be used to derive odds ratios for binary outcomes (mortality, incidence of infection/elevated LFTs/metabolic acidosis). Morbidity and respiratory outcomes (duration of hospital/NICU stay, duration of respiratory support/mechanical ventilation) will be analysed as time-to-event data using Cox regression, with data censored at 90 days for non-survivors and survivors not reaching the endpoint within that time. Regression analyses will assess PN group differences in an uncorrected manner, as well as (jointly) adjusted for risk factors including sex, gestational age, medical/surgical group, term/late term group, daily PN doses, and severity of illness scores (SNAPPE-II). Associations of the biochemical markers (F2 isoprostane, plasma amino acids and fatty acids) with the main clinical outcomes will also be explored by appropriate regression analyses.
Summary statistics for main outcome measures will include 95% confidence intervals, and for all endpoints differences between PN groups will be considered statistically significant whenever the p-value is lower than 0.05 without correction for multiple testing. Baseline characteristics of study participants will be reported as percentages for categorical outcomes, and mean (standard deviation) for normally distributed continuous outcomes or median (interquartile range) for skewed continuous outcomes.

Cost analysis

The results of this RCT will be used to perform a cost analysis from an Australian public hospital perspective. We will estimate and compare the total direct medical costs associated with early versus late PN by using a micro-costing method. Medical cost types will include 1) NICU hospitalisation; 2) Total duration of hospitalisation; 3) Mechanical ventilation support; 4) Respiratory support; 5) Renal replacement therapy; 6) Haemodynamic support; 7) Surgery; 8) Medications; 9) PN; 10) Consultations from another specialist; 11) HABSI. The primary endpoint is the difference in total direct medical costs between early and late PN. Actual medical costs will be calculated by multiplying the volumes of health care use with the corresponding unit prices, obtained from a Senior Data Analyst of the Business Intelligence Unit, Child Adolescent Health Service. We will perform subgroup analysis for medical and surgical infants and for each major condition within the subgroups.
The cost analyses will be based on the Australian guidelines for performing economic evaluations79. Consolidated Health Economic Reporting Standards (CHEERS) statements will be followed for reporting the results in a peer reviewed journal.

Recruitment

Recruitment status

Recruiting

Date of first participant enrolment

Anticipated

13/04/2020

Actual

21/06/2020

Date of last participant enrolment

Anticipated

31/10/2021

Actual

Date of last data collection

Anticipated

31/12/2021

Actual

Sample size

Target

Accrual to date

Final

Recruitment in Australia

Recruitment state(s)

Recruitment hospital [1]

Perth Children's Hospital - Nedlands

Recruitment postcode(s) [1]

6009 - Nedlands

Funding & Sponsors

Funding source category [1]

University

Name [1]

University of Western Australia

Address [1]

35 Stirling Hwy, Crawley, Western Australia, 6009

Country [1]

Australia

Funding source category [2]

Hospital

Name [2]

Perth Children's Hopsital

Address [2]

15 Hospital Ave, Nedlands, WA, 6009

Country [2]

Australia

Primary sponsor type

Hospital

Name

Perth Children's Hospital

Address

15 Hospital Ave, Nedlands, 6009

Country

Australia

Secondary sponsor category [1]

University

Name [1]

University of Western Australia

Address [1]

35 Stirling Hwy, Crawley, WA, 6009

Country [1]

Australia

Ethics approval

Ethics application status

Approved

Ethics committee name [1]

Child and Adolescent Health Service HREC

Ethics committee address [1]

15 Hospital Ave, Nedlands, WA, 6009

Ethics committee country [1]

Australia

Date submitted for ethics approval [1]

17/09/2019

Approval date [1]

01/11/2019

Ethics approval number [1]

RGS3537

Summary

Brief summary

During periods of acute illness in term (= 37 weeks’ gestation) and late preterm infants (between 34 to 37 weeks’ gestation), provision of sufficient enteral nutrition is unachievable, which necessitates the use of parenteral nutrition (PN). PN involves the administration of glucose, amino acids, lipids and various micronutrients. More than 200 babies receive PN in the Neonatal Intensive Care Unit (NICU) at Perth Children’s Hospital (PCH) each year, accounting for up to 1400 PNs annually. 
In very preterm infants (< 32 weeks’ gestation), nutrition has been extensively researched and hence there is adequate evidence recommending early commencement of PN. However, there is a lack of evidence regarding the optimal time to commence PN therapy in term and late preterm infants. Hence, there are no clinical guidelines for this population. Moreover, nutritional reserve, requirements and morbidity of very preterm infants are different to that of term and late preterm infants. Therefore, it is inappropriate to extrapolate the nutritional recommendations of very preterm infants to term and late preterm infants. 
The potential benefits of early amino acids include the prevention of catabolism, reduction in hypoglycaemia, improved growth and neurodevelopmental outcomes. Potential harms associated with early amino acids include hyperammonaemia, azotaemia, and metabolic acidosis. 
The potential benefits of early lipids include the prevention of essential fatty acid (EFA) deficiency, improve nutrition, increase long chain polyunsaturated fatty acids (LCPUFA) and improved neurodevelopmental outcomes.  Potential harms associated with early lipids include increased risk of sepsis, worsening of pulmonary hypertension and respiratory function.
Therefore, we plan to conduct a randomised controlled trial (RCT) that evaluates the benefits and risks of early versus late PN in term and late preterm infants by comparing relevant biochemical and clinical outcomes. We will also conduct a cost analysis of early versus late PN from a Western Australian (WA) public hospital perspective.

Trial website

Trial related presentations / publications

Public notes

Contacts

Principal investigator

Name

Ms Kwi Moon

Address

Pharmacy Department
Perth Children's Hospital
15 Hospital Ave, Nedlands, WA, 6009

Country

Australia

Phone

+61 8 6456 2222

Fax

[email protected]

Contact person for public queries

Name

Kwi Moon

Address

Pharmacy Department
Perth Children's Hospital
15 Hospital Ave, Nedlands, WA, 6009

Country

Australia

Phone

+61 8 6456 2222

Fax

[email protected]

Contact person for scientific queries

Name

Kwi Moon

Address

Pharmacy Department
Perth Children's Hospital
15 Hospital Ave, Nedlands, WA, 6009

Country

Australia

Phone

+61 8 6456 2222

Fax

[email protected]

Data sharing statement

Will individual participant data (IPD) for this trial be available (including data dictionaries)?

No/undecided IPD sharing reason/comment

What supporting documents are/will be available?

No Supporting Document Provided

Results publications and other study-related documents

Documents added manually

No documents have been uploaded by study researchers.

Documents added automatically

Source	Title	Year of Publication	DOI
Embase	Early versus late parenteral nutrition in term and late preterm infants: study protocol for a randomised controlled trial.	2022	https://dx.doi.org/10.1186/s12887-022-03569-8

N.B. These documents automatically identified may not have been verified by the study sponsor.

Trial Review

Documents added manually

Documents added automatically