Neonatal and Infant Intravenous Fluid Management (2025)

Introduction

Patients admitted to the Butterfly ward (Neonatal Intensive Care Unit) are at times unable to receive the required volume of enteral feeds to promote and sustain nutrition and growth. This includes patients who are critically unwell, require respiratory support, surgical intervention, ongoing investigations or are not tolerating enteral feeds. At these times, supplementation with IV fluids may be required to maintain optimal hydration and nutrition.

Effective fluid and electrolyte management of neonates and infants in NICU requires;
- A physical assessment
- Assessment of fluid status
- Haemodynamic monitoring of fluid balance (including any losses)
- Administration of the appropriate fluids and electrolytes.
- Assessment of risk factors for complications (such as critically unwell, preterm, or patients with gastrointestinal disorders).

Inadequate management can lead to complications such as dehydration, fluid overload and hyponatremia.

Aim

To provide guidance on the assessment and management of adequate hydration and fluid balance in neonates and infants admitted to the Butterfly Ward. To guide clinicians caring for unwell neonates and infants to appropriately assess and recognise signs and symptoms of fluid imbalances (such as dehydration or fluid overload) ensuring prompt escalation and management.

This guideline focuses on the fluid assessment and management of Butterfly inpatients, which ranges from preterm and term newborns right through to older infants who are also managed within the Butterfly ward. Nursing staff caring for neonates and young infants admitted to other areas of RCH can utilise this guideline but should also refer to local guidelines.

Definition of Terms

Acute Kidney Injury (AKI)	An abrupt decrease in glomerular filtration. Staged according to serum creatinine and urine output.
Chronic Lung Disease (CLD)	Oxygen dependency at 36 weeks corrected age”. A form of chronic injury to the lungs. (Definition by Safer Care Victoria)
Corrected age	Gestational age at birth plus chronological age
Extreme Preterm	Defined by World Health Organisation as less than 28 weeks gestation.
Fluid balance	Fluid balance is a function of the distribution of water in the body, water intake and water losses
Gestational Age	The number of completed weeks and days of gestation at birth
Glucose Infusion Rate (GIR)	GIR is the total amount of glucose the patient is receiving. It is calculated by considering fluids at different rates to ensure a patient is receiving enough glucose for metabolic use.
Hypoxic Ischemic Encephalopathy (HIE)	Diminished blood perfusion to the brain resulting in lack of sufficient oxygen delivery. This leads to suppression off electrical activity and cortical depression.
Insensible water loss	The water loss that occurs via the skin and mucous membrane (contributing to two thirds of the daily amount) and respiratory tract (contributing to one third of the daily amount).
Necrotising Enterocolitis (NEC)	A gastrointestinal condition that mostly impacts preterm infants that causes inflammation.
Neonate	An infant aged less than 28 days.
Order, Infusion, Lines, Securement Procedure (OILS)	Procedure for checking the pump programming for continuous IV medications, fluids and blood products administered at RCH. The nurse caring for the patient is accountable for the connection and the safe administration of the intravenous infusion(s)
Patent Ductus Arteriosus (PDA)	The persistent patency (failure to close) of the ductus arteriosus. This can lead to an increase in blood flow to the lungs and diversion of blood (steal) from the systemic circulation.
Preterm	A neonate born before 37 weeks of completed gestation.
Specific Gravity (SG)	Part of urinalysis test which compares the density of urine and water.
Total Body Water (TBW)	The percentage of water in the body.
Total fluid Intake (TFI)	Patients will have a set total fluid intake, per their weight, to calculate an hourly fluid volume.

Overview of fluid relatedadaptation in newborns (term and preterm)

Disorders of fluid and electrolyte imbalance are amongst the most common disorders encountered in unwell neonates (both term and preterm). The fluid and electrolyte requirements of the neonate are unique due to fluids shifts within the first few days and weeks of life. At birth, there is an excess of extracellular fluid which decreases over the first few days of life; extracellular fluid volumes and insensible water losses increase as weight and gestational age decrease.

Therefore, appropriate management of fluid and electrolytes must take into consideration:

Birth weight
Gestational age and corrected age.
Unwell term or preterm neonate
Disease pathophysiology

All of these factors may significantly influence fluid and electrolyte requirements. Fluid management in the preterm neonate is specific and challenging due to increases in insensible water loss, reduced renal function and low birth weight.

Total BodyWater (TBW)

In neonates, TBW distribution gradually changes with increasing gestational age, from the extreme preterm with TBW constituting 90% of body weight, to the term neonate with 75%. In addition to this gradual reduction with gestational age is a more abrupt reduction of TBW that occurs approximately 48 to 72 hours after birth which is closely related to cardiopulmonary adaption.

Fetal urine flow steadily increases with gestational age reaching 25 to 50 mL/hr at term and dropping to 8 – 16mL/hr (1-3mL/kg/hr) at birth reflecting the large exchange of TBW during fetal life and the abrupt change occurring with cardiopulmonary adaption after birth. Additionally, glomerular filtration rates (GFR) are low in utero remaining low at birth and gradually increasing in the neonatal period. With a changing GFR and variable urine concentration, all newborns undergo a diuresis in the days following birth resulting in a reduction of TBW.

Contraction/ the reduction of TBW accounts for early postnatal weight loss. This results in a 10-15% weight loss in those born preterm and 5-10% weight loss in term babies.

Assessment

Indications for IV Fluids:

Dehydration
Hypoglycaemia
Nil by Mouth
Feed Intolerance
Gastric losses replacement

Monitoring:

Continuous oxygen saturation and cardiorespiratory monitoring is required for Butterfly ward patients requiring administration of IV fluids. Patients should be assessed and monitored hourly.
Target observations should be established during ward rounds and vital signs breaching normal ViCTOR chart ranges must be escalated and discussed with the senior nursing team (TSN, ANUM) and medical team (Registrar/ Fellow/ Consultant).
Refer to RCH Nursing Guideline: Observation and Continuous Monitoringfor the requirement of monitoring of RCH ward inpatients.

Physical Examination

It is important to complete a full head-to-toe assessment, using a systematic approach. This should be performed at the commencement of each nursing shift and more frequently if there any concerns or changes. Any changes to activity level or may be a sign of fluid depletion and dehydration and should be escalated promptly, following a thorough assessment.

Physical assessment of hydration status includes the assessment of:

Weight on alternate days (for patients with renal or cardiac conditions see chart below)
Presence and severity of oedema
Skin turgor and colour, including capillary refill time
Mucous membranes
Periorbital tissue
Anterior fontanelle
Altered conscious state
Gastric losses (NGT, Stoma, Vomiting, diarrhoea, stoma)
Urine output

Physical signs can be used in the assessment of fluid status however may at times be unreliable and therefore must be observed within the context of

Body weight
Haemodynamic monitoring
Haematocrit
Serum biochemistry
Acid-base status
Urine output.

Refer to RCH Nursing Assessment Guideline for more details.

Table 1- Patient Examination in Assessment of fluid status:

Assessment component		Consideration for fluid depletion, dehydration or overload
General Appearance	Behaviour	Restless or irritable in mild to moderate dehydration. Lethargy or reduced conscious state in severe dehydration.
	Skin colour (Central and peripheral)	Jaundice, mottling, pallor, cyanosis may be indicative of dehydration.
	Oedema	Can be generalised or in local area (such as facial, genital/ nappy, peripheries) and part of assessment for fluid overload. Ensure to check for dependent oedema (back of head/ torso/ legs). Consider review of pressure area care plan.
Vital Signs (refer to VICTOR charts)	Heart rate (including cardiac rhythm)	An indicator of cardiac compromise or compensation. Tachycardia can be an indication of dehydration.
	Blood pressure	An indicator of intravascular volume. Presence of hypotension may indicate dehydration or shock. However, hypotension is usually a late sign of intravascular volume depletion.
	Respiratory rate	Tachypnoea may be an early sign of metabolic acidosis as a result of intravascular volume depletion.
Hydration status	Capillary Refill Time (CRT)	CRT >3 seconds may indicate a decreased intravascular volume or poor tissue perfusion. A more prolonged refill time or cool peripheries may be present in dehydration.
	Fontanelle tension	Sunken fontanelles may be a sign of dehydration.
	Moistness of mucous membranes	Slightly dry in mild dehydration and dry in moderate to severe dehydration. A very dehydrated baby may not produce tears.
	Pulses: Brachial, femoral, radial, dorsalis pedis Palpate pulses and note strength	Pulse can be rapid or weak in moderate to severe dehydration. Pulses in the lower limbs may be weak. Feet and hands might be cooler in comparison to the rest of the body.
	Skin turgor	Can be decreased in moderate dehydration. Tenting can occur in severe dehydration.
	Record accurate fluid balance (refer to urine output section below)	Fluid balance trends should be reviewed and discussed on ward round and the trend of previous days considered. Alert ANUM and medical team if patient in a significant positive or negative fluid balance.
Urine Output	All nappies should be weighed and documented whilst receiving IV fluids. Measure and document urine catheter chamber hourly.	See urine output section of guideline for more details.
Urinalysis	Order as a Point of Care test within EMR orders and complete daily for patients receiving IV fluids.	Urine electrolytes and osmolality offer additional information about a neonate’s ability to concentrate urine. These can be difficult to interpret in preterm neonates.
Weight	Allpatients should have a baseline weight completed prior to commencement of IV Fluids (i.e. birth weight and/or admission weight) Patientsshould be weighed on alternate days. (On Butterfly Sunday, Wednesday and Fridays have been chosen to facilitate the ordering of IV nutrition)	Weight loss may indicate of dehydration. Patients with renal or cardiac conditions, ongoing positive or negative fluid balances, persistent oedema or signs of dehydration may require more frequent weight monitoring (increased to twice daily or daily).
Losses	Stools Stoma and NG losses	High stoma losses can lead to dehydration and must be closely monitored. Please refer to separate guideline for further information on how to assess and manage such patients. RCH Departmental Guideline:Butterfly Replacement of Neonatal Gastrointestinal Losses Guideline. A changing stool pattern, loose or watery stools may lead to dehydration and so should be observed closely.

Table created by RCH Butterfly Nurse Educator, Nov 2024.

Urine Output

It is important to assess, calculate and document urine output and review the trend (from previous days). Not only does this indicate fluid intake but also renal perfusion.
Calculate urine output mL/kg/hr (see examples below).
Correct administration of maintenance fluids should aim to produce a urine output of
>1mL/Kg/hour in most circumstances.
If urine output is <1mL/Kg/hour, repeated reassessment of clinical condition and hydration status should be made and acted upon.
Urine output can vary, and targets should be discussed with the treating medical team.
Any concerns of reduced urine output should be appropriately escalated through nursing and medical pathways.
Clinical review is required for patients with a urine output above 6 mL/hr. A urine output above 8 mL/hr may require replacement fluid of urine losses to avoid dehydration but will require consideration of individual patient circumstances by Neonatologist.
Please refer to below guideline Butterfly Replacement of RenalLosses Guideline for further information.

To calculateurine output:

Urine volume ÷ patient weight ÷ number of hours from 0600

Urine volume ÷ patient weight ÷ number of hours since last nappy change / IDC chamber empty

Volume of urine divided by patient weight divided by number of hours from 0600 OR Urine volume divided by patient weight divided by number of hours since last nappy change/IDC chamber empty (e.g. 2 or 4 hours).

Example Urine output calculation:

Baby B weighs 3 kg and has passed 27 mL of urine over a 6-hour timeframe.

To calculate urine output for Baby B:

27 mL (total urine) divided by 3 kg (weight) divided by 6 (hours) equals1.5 mL/kg/hr

It is important to also consider changes in urine output trends, whichmay mean calculating urine output over different time frames. If theexpectation for Baby B was the production of 1mL/kg/hr urine and a urinarycatheter was in situ, then Baby B would need to produce 3 mL of urine in thechamber each time it was measured and emptied.

3 ml/ hr divided by 3 (kg) = 1mL/kg/hr

Examplecalculating over longer time frame

It is now 1800 and Baby B's urine output is 72mL in total.

Urine output divided by time in hours since 0600 divided by weight

72mL divided by 12 (hrs) divided by 3 (kg) = Urine output of 2mL/kg/hr

Other Investigations and Monitoring

SerumBiochemistry

All Butterfly patients receiving IV Fluids for acute conditions:

Check serum electrolytes and glucose before commencing the infusion (where possible).
Repeat bloods in 24 hours or sooner if clinically indicated.
Serum electrolytes and glucose should be checked at a minimum every 24 – 48 hours thereafter.

Changes in serum sodium concentration should be assessed in the context of total body weight hydration status and any recent increase or decrease in weight. The requirement of both sodium (Na+) and potassium (K+) is 2 – 4 mmoL/kg/24 hours.

Acid base status

Along with serum electrolyte and glucose monitoring, patients receiving IV fluids will also require blood gases to assist with assessing fluid and hydration status.

Variations in the metabolic components of the blood gas (bicarbonate, base excess and anion gap) can be indications of fluid status imbalance.

A metabolic acidosis can be suggestive of decreased intravascular volume and hyperosmolarity.

A decreasing Base Excess (BE) (increasing base deficit) in the context of decreased urine output, decreased mean arterial pressure and a prolonged CRT is suggestive of dehydration.
- Normal base excess (BE) =-3 to +3 mEq/L

A wideninganion gapis reflective of dehydration with a deceased intravascular volume as lactic acidosis follows poor tissue perfusion.
- Normal anion gap=8 – 16 mEq/L

Haematocrit

The haematocrit is a measure of the proportion of blood that is made up of cells, expressed as a fraction. In the neonatal period, a physiologic increase in haematocrit occurs due to a fluid shift away from the intravascular compartment. An increase in haematocrit can also occur because of dehydration due to a decrease in plasma volume.

Table 2- Haematocrit Level Ranges for NICU Patients

Normal Haematocrit (Term Newborn)	0.44 – 0.64
Normal Haematocrit (3 months)	0.32 – 0.44
RCH Laboratory Range	0.31 – 0.55

Total Fluid Intake (TFI)

If aneonate weighs less than their birth weight, use the birth weight as the working weight in a fluid calculation, unless specified by the medical team. A TFI will be discussed and determined on the ward round and should account for all requirements and possible risk factors. The TFI will be documented within the MAR fluid order and progress notes.

The TFI can be divided into sections to account for any feeds, TPN, IV fluids and medication infusions. The TFI should be calculated at the commencement of each nursing shift and following any changes, such as infusion rates or upgrading feeds.

Example 1

Baby A weighs 3.5 kg and a TFIof 100 mL/kg has been set. She is NBM and has no infusions. This weight will beused to calculate the rate of her maintenance fluid of 10% dextrose withadditives.

100 (mL/kg/day) x 3.5 (kg) = 350mL/day

To calculate the hourly rate:

350 (mL/day) divided by 24(hours) = 14.58 mL/hr

This can be rounded to 14.6 mL/hr

The TFI can be divided furtherinto portions to account for any feeds, TPN and medication infusions.

Example 2

Baby B has commenced feeds at 15 mL/kg/day (2 hrly). He has a current TPN N2 infusion at 100 mL/kg/dayand has a morphine infusion running at 10 mcg/kg/hr at 0.5 mL/hr. He weighs 2.4kg. TFI handed over at change of shift =120 mL/kg/day.

Feeds

15 (mL/kg/day) x 2.4 (kg) = 36 mL/day

To achieve the feed bolus:

36 (mL/day) divided by 12 feeds = 3 (mL/ feed)every 2 hours.

100 (mL/kg/day) x 2.4 (kg) = 240 (mL/day)

240 (mL/day) divided by 24 (hours) =10 (mL/hr)

Morphine (calculate volume for TFI volume only)

0.5 (mL/hr) x 24 (hours)= 12 (mL/day)

12 (mL/day) divided by 2.4 (kg) = 5 (mL/ kg/day)

Therefore TFI:

15 mL/kg/day (feeds) + 100 mL/kg/day (n2) + 5 mL/kg(infusion) = 120 mL/kg/day.

Management

The fluid choice and volume required should be discussed and clearly communicated on the ward round and documented in the patient’s EMR notes. The fluid requirement and TFI needs to consider risk factors for overload, renal impairment, current venous access and other infusions and medications required or being administered as well as the projected time that intravenous fluids may be expected to be required.

Standard Intravenous Fluid

As previously described, neonates undergo a diuresis within the first 24 hours of life and therefore electrolyte additives are not required during this time, unless clinically indicated. Glucose is the main source of energy for the brain. Glucose homeostasis reduces the risk, and associated complications, of hypoglycaemia.

Table 3-Standard IV Fluids used in NICU, RCH

Age

Standard Fluid

Fluid Bag available in Imprest

First 24 hours of age

10% Glucose

500 mL

More than 24 hours of age (and adequate urine output)

10% Glucose

+ 10 mmol Potassium Chloride

+ 0.225% Sodium Chloride

500 mL

Total Parenteral Nutrition (TPN)

TPN is usually commenced if a patient on Butterfly Ward is not likely to be fed enterally for longer than 3 days. It is prescribed by the Medical Staff in conjunction with the Pharmacist and Clinical Nutrition team.

Refer to RCH Departmental Guideline:Parenteral nutrition in NICU

Table 4- TPN Solutions most often prescribed for NICU Patients

Total Parenteral Nutrition (TPN)	Amino acids (g/L)	Glucose (g/L)	Central access requirement
N1	25	100	Can be administered peripherally or centrally
N2	30	125	Desirable
N3	50	200	Yes

All TPNsolutions are hyperosmolar and careful observation of infusion sites must occurif administered peripherally.

Table 5- Intravenous Fluid and Parenteral Requirement (ml/kg/day)

Day of Life	Maximum Total Fluid Intake	Day of Treatment	N1 (mL/kg/day)	N2 (mL/kg/day)	N3 (mL/kg/day)
1	60	1	60	50	30
2	80	2	80	70	40
3	100	3	100	80	50
4	120	4	120	100	60
5	120	5	120	120	70

Glucose Infusion Rate (GIR)

The neonatal liver normally produces 6 – 8mg/kg/min of glucose, which is the approximate basal requirement of a newborn neonate. The GIR is a measurement of how much glucose (as mg/kg/min) a neonate is receiving. When a neonate has hypoglycaemia or is fluid restricted, their GIR should be calculated to make sure they are receiving an adequate amount of glucose.

Initially these ranges can be used as a guide:

Term Neonates: 4-6mg/kg/min

Premature Neonates: 6-8mg/kg/min

The Glucose Delivery Calculator (NICU Tools) allows you to calculate the GIR of the neonate – including IV and enteral intake.

Line Selection for Intravenous Infusion

Theconcentration of glucose and/or amino acids in any intravenous fluid and the use of inotropes must be consideredin determining the appropriate site for infusion: central or peripheral.
Refer to RCH Policies and Procedures: Insertion, Management and removal of central venus access devices for more information on maintenance of CVAD devices, including standard procedures, blood sampling and troubleshooting.
Refer to RCH Departmental Guideline:Vasoactive Drug InfusionManagement NICU and RCH Departmental Guideline:Butterfly Common Infusions resources for more details.
Compatibilities of multiple infusions can be checked via Paediatric Injectable Guidelines, Lexicomp,
Inform the medical team if additional intravenous access is required to ensure compatible fluids are separated appropriately.

Table 6- Infusions that Require a CVAD

Type of Infusion	Required Access
Glucose concentrations > 12.5 %	Central Venous Access
TPN N3 (Amino acid concentrations ≥ 50g/L)	Central Venous Access
Vasoactive medications	Central Venous Access Diluted Adrenaline and Noradrenaline may run peripherally in emergency (refer to separate protocols for more details)

Checking Procedure

IV fluids are to be checked by two RNs at the commencement of therapy, with rate and bag changes, and at handover timers as per the OILs RCH Policies and Procedures: Standarised Checking for Infusion Pump Programming.

An hourly volume to be infused (VTBI) must be set. This ensures the appropriate hourly volume has been infused and is a prompt to complete the hourly site assessment and EMR LDA flowsheet documentation. Every hour the volume infused (VI) is to be cleared from the pump, documented in the EMR flowsheets and a new volume to be infused (VTBI) must be set.

Administration

On Butterfly ward, TPN bag, line and filter; SMOF syringe and line; and IV fluids with additives prepared on the ward (bags and syringes), should be changed every 24 hours.
Pre-prepared fluid bags can remain hanging for up to a maximum of 7 days. Please refer to RCH Policy and Procedure: Central Venous Access Device for further information.

Labelling

All patients with intravenous fluids require labels on the fluid bag, the syringe and the IV line (closest to the patient). Refer to RCH Policies and Procedures:User Applied Labelling of Injectable Medicines, Fluids and Linesexcluding Perioperative Environments.

Documentation

PhysicalAssessment:Initial and ongoing physical assessments should be documented in the primary assessment and focused assessment flowsheets within EMR.
Observations:Observations should be documented within the observation flowsheet. Observations breaching normal ViCTOR chart ranges must be escalated and discussed with ANUM and medical teams. Document this discussion in the progress notes, including reason for escalation, and any planed changes in care.
Fluidorders:Fluids are ordered within the MAR. The associated TFI, along with any alterations to standard regimes should be clearly documented in the progress notes.
Fluid Balance:The 24-hour fluid balance period begins at 0600. This provides a full 24-hour fluid balance to be reviewed on morning ward round and to enhance decision making. In some situations, formal review may be required more frequently, such as at a 12 hourly timeframe.

Escalation of Care

It is vital that any concerns with patient care (such as signs of dehydration, fluid overload, tachypnoea, increased or reduced urine output) are addressed and appropriately escalated through nursing and medical pathways to ensure that patients are assessed in a timely manner and provided appropriate management.

RCH has developed oneTEAM as a tool for parents, carers and staff to seek support for patients if they are concerned at any point.

Special Considerations

Inadequate/Inappropriate fluid management can lead to complications such as dehydration, fluid overload and hyponatremia.

InsensibleWater Loss (IWL)

Prematurity:An important variable influencing IWL is the maturity of neonatal skin, with greater IWL occurs in preterm babies resulting from evaporation through the immature epithelial layer and the greater surface area of the skin in relation to weight.

Phototherapy:Phototherapy may increase IWL and therefore fluid intake may need to be increased by 10 – 20 mL/kg/day. Refer to RCH Nursing Guideline: Phototherapy for Neonatal Jaundice and RCH Nursing Guideline:EnvironmentalHumidity for Premature Neonates.

FluidRestriction:In some cases, such as in the immediate post-operative period, patients with HIE or patients with a PDA, fluid restriction may be an appropriate strategy to avoid fluid overload.

OtherConsiderations

It may be necessary to provide haemodynamic support to ensure adequate cardiac output in neonates and infants following extensive surgery.
The administration of vasoactive medications may contribute to tachycardia and should be taken into consideration and discussed with the neonatologist.
Pain may also result in tachycardia and not be an indicator of fluid volume depletion.
Careful assessment of the patient in the event of hypovolaemia is necessary to ensure the adequate and appropriateness of fluid boluses.
Refer to Butterfly cardiovascularguideline for more details on the management of neonatal patients with cardiovascular compromise.

Albumin replacement

Routine screening for hypoalbuminemia may be required for critically unwell neonates, particularly those who are at risk of fluid overload. Occasionally 20% albumin replacement is administered as part of the management of a patient with hypoalbuminemia and fluid overload. Targets for albumin levels and necessity for administration of 20% albumin replacement will be determined by neonatologist on ward round. It is important to remember that albumin is a blood product and should be used sparingly and only when necessary.

Further details can be found at RCHAlbumin Administration- Paediatric Albumin Guidance.

Electrolyteimbalances

The administration of electrolyte corrections may be required for critically unwell neonates who experience electrolyte imbalances. The decision to correct electrolytes will be made by the neonatologist on a risk vs benefit basis while considering the patients intravenous access, other infusions.

Central access is likely to be required and all sourcesof intravenous potassium must be included when calculating replacement doses and infusion rates. To ensure the safe administration of any electrolyte corrections on Butterfly ward, refer to specific electrolyte replacementguidelines.

GastrointestinalLosses

Gastrointestinal losses (e.g. nasogastric losses, faecal stoma losses) 20 mL/kg and above require mL for mL replacement. Standard Replacement Fluid is 0.9% Sodium Chloride (500 mL) + 10 mmoL Potassium Chloride. Refer to Replacement of neonatalgastrointestinal losses.

Clinicalperformed ultrasound

On Butterfly, on some occasions ultrasounds have been performed to assess a patient’s intravascular volume and cardiac output, further supporting management goals. The need for this will be determined by the Neonatologist.

Renal Impairment

In neonates with renal impairment, special consideration needs to be given to fluid management. Fluid restriction will often be required as will replacement of urinary losses in the neonate with polyuria. These patients also require a strict fluid balance record, regular urea and electrolytes and frequent weighs (as often as twice daily).

Urine output (ml/kg/hour)	Condition	Intervention
<1	Dysuria / Oliguria	Clinical assessment is advised and escalation via nursing and medical pathways
1 – 5	Normouria	Continue to observe
>6	Mild to moderate polyuria	Clinical assessment is advised and escalation via nursing and medical pathways
>8	Severe polyuria	Urinary replacement is indicated Intravenous urinary replacement is indicated: 0.45% Sodium Chloride (75mmol/l) or 0.22% saline (37mmol/l) Depends on relative fluid versus salt depletion, the serum and urinary sodium, and may require added NaHCO310-20mmol/l.

Refer toReplacement of Renal Losses inNICU

Some patient groups may be at risk of developing AKI which will impact assessment and management, particularly in relation to their fluid management. Neonates and infants with congenital heart disease, HIE, NEC and those exposed to nephrotoxic medications are examples of patient groups who may be at risk. Patients with AKI may require more frequent weights and assessments of fluid status and electrolytes. It may be necessary to monitor urine output more closely with insertion of a urinary catheter.

Fluid Resuscitation

If fluid resuscitation is required for Butterfly patients:

To be given as rapidly as possible
May be repeated as necessary

Common intravenous fluid for resuscitation:

Type of Intravenous Fluid	Dose (ml/kg)
0.9% Sodium Chloride	10 – 20 ml/kg
Plasma-Lyte 148 (withOUT Glucose)	10 – 20 ml/kg
Alburex (albumin) 5% [ Refer to RCH Departmental Guideline:Albumin Administration]	12.5 – 25ml/kg

Family Considerations

It is the responsibility of the clinician caring for the neonate or infant to ensure that the family understands the rationale for the administration of IV fluids. Discuss any concerns they may have and update them of any changes.

Ensure parents or caregivers are aware of the oneTEAM process and how it may be utilised on Butterfly if they have any ongoing concerns.

Companion Documents

RCH Clinical Practice Guidelines

Dehydration
Intravenous fluids
Intravenous access - Peripheral

RCH Departmental Guidelines

Albumin Administration
Butterfly Replacement of Neonatal Gastrointestinal Losses Guideline
PICC and CVAD lines
Vasoactive Drug Infusion Management NICU

RCH Nursing Guidelines

Therapeutic Hypothermia in the Neonate
Observation and continuous monitoring
Ward Management of a neonate

RCH Policies and Procedures

Other RCH resources

OneTEAM

Evidence Table

Reference	Source of Evidence	Key findings and considerations
Ashford and St Peter’s Hospitals NHS Foundation Trust, Updated October 2021,IV fluid and electrolyte management in neonates https://ashfordstpeters.net/Guidelines_Neonatal/Fluid%20Balance%20Oct%202021.pdf	Clinical Guideline	Assessment of fluid status: tachypnoea, heart rate, perfusion (CRT), urine output, anterior fontanelle, mucous membranes, presence and severity of oedema. Preterm or infants requiring intensive care should be weighed daily The highest weight should usually be used to calculate total fluid requirement. (Exception suspected/confirmed hydrops or significant oedema). Sodium deficits and management explained AKI defined as sudden and severe reduction in glomerular filtration rate result in anuria / oliguria ( <1ml/kg/hr). Common causes in neonates include sepsis, perinatal asphyxia, hypovolaemia, NEC, drugs, renal artery thrombosis or congenital renal anomalies. AKI management (monitor electrolytes, treat hypertension, fluid restrict, consider need to insert catheter, consider renal dose of dopamine of 5mcg/kg/min, consider need for echo.
Ambalavavanan.N, Nimvat.D.J, October 2024, Fluid, Electrolyte, and Nutrition Management of the Newborn, Medscape, Pediatrics: Cardiac Disease and Critical Care medicine	Literature review	Infants with RDS need appropriate fluid replacement. Administration of excessive fluid, however, can lead to hyponatremia and volume overload, worsening the pulmonary condition and increasing the risk that BPD will develop. Inadequate fluid administration leads to hypernatremia and dehydration. When calculating fluid, electrolyte and nutrition requirements, most practitioner use an infant’s birth weight until the infant has regained the birth weight. Thereafter, daily weight is used in calculations. Tachycardia may be a reflection of decreased intravascular volume, decreased stroke volume or ineffective cardiac output. With severe hypovolemia, hypotension is almost invariably present. Urine electrolyte levels and specific gravity may be assessed. If the infant is being treated with diuretics results of these are difficult to interpret.
Arya, V., Kavitha, M., Mittal, K., & Gehlawat, V. K. (2021). Plasmalyte versus normal saline as resuscitation fluid in children: a randomized controlled trial. Journal of Pediatric Critical Care, 8(3), 134-138.	Randomised controlled trial	Plasmalyte was superior to Normal saline when used as a resuscitation fluid in children with shock, in terms of better improvement of acid-base balance after fluid bolus therapy A lower rise in serum chloride level at 6 h from baseline, shorter hospital stays, lesser need for vasoactive drugs and lower mortality.
Bethell G, Kenny S, Corbett H. Enterostomy-related complications and growth following reversal in infants. Arch Dis Child – Fetal Neonatal. 2017;102:230-4.	Retrospective review	58 Infants who underwent enterostomy formation and reversal during a 6 year period. Complications documented in 41 %. Infants of low birth weight and low gestational age were significantly more likely to have an enterostomy related complication. High output challenging.
Bell, E. F., & Acarregui, M. J. (2014). Restricted versus liberal water intake for preventing morbidityand mortality in preterm infants. Cochrane database of systematic reviews, (12).	Systematic Review	Cochrane review on fluid restriction in the preterm neonate. Overall author’s consensus of careful restriction that meets physiological need whilst avoiding significant dehydration.
Bengtsson, Bengt-Ola S. and van Houten, John P.. "Central edema in critically ill neonates" Case Reports in Perinatal Medicine, vol. 8, no. 2, 2019, pp.Direct link	Retrospective chart review	Terms to describe oedema: pitting, primary, dependent, generalised, by location (genital, pubic, penile, peno-scrotal, facial, scalp, nuchal, pedal). Fluid restriction, corticosteroids, use of 25% albumin and loop diuretics to mobilise interstitial edema.
Bhatia, J. (2006). Fluid and electrolyte management in the very low birth weight neonate. Journal of perinatology, 26(1), S19-S21.	Expert opinion	Discussion of the importance of appropriate fluid and electrolyte management in the very low birth weight neonate with emphasis on the importance of insensible water losses in the physiology of preterm neonates. Provides some brief management guidelines.
Bolisetty, S., Osborn, D., Sinn, J., Lui, K., & Australasian Neonatal Parenteral Nutrition Consensus Group. (2014). Standardised neonatal parenteral nutrition formulations–an Australasian group consensus 2012. BMC pediatrics, 14, 1-11.	Expert opinion	Identifies an Australian group consensus on standardization of total parenteral nutrition formulations and as such improvements in nutritional intakes, quality control and reduced errors.
Butterfly Neonatal Assessment learning packageUpdated 2020	Learning package	Breakdown and guide to assess neonatal fluid status
Corrales. A.Y, Starr. M, 2010, Assessment of the unwell Child, Focus Childhood emergencies. https://www.racgp.org.au/getattachment/39cf1eee-f463-4aa8-bce6-d52bb9330b2b/Assessment-of-the-unwell-child.aspx	Education resource	Assessment of circulation including pulse rate, volume, CRT. Ranges for normal heart rate, resp rate and blood pressure for infants. Paediatric Glasgow coma scale explained in detail
Gardner, S., Carter, B., Enzam-Hines, M., & Hernandez, J. (2021). Merenstein & Gardner’s handbook of neonatal intensive care (9th Edition). Elsevier: St Louis, Missouri	Textbook	Neonatology textbook – Unit 3: (Chapter 14 – Fluid & Electrolyte Management) & (Chapter 16 – Total Parenteral Nutrition) Discussion of the physiology of neonatal fluid and electrolyte management including the first few days of life and the aetiology and prevention of common neonatal fluid and electrolyte disturbances.
Gomella, T., Eyal, F. G., Bany-mohammed, F. & (2020). Fluid and Electrolytes \| Gomella's Neonatology: Management, Procedures, On-call Problems, Diseases, and Drugs, 8e. https://accesspediatrics.mhmedical.com/content.aspx?bookid=2762§ionid=234451192	Textbook	Neonatology textbook – Chapter 10: Fluid & Electrolytes A step by step guide to fluid and electrolyte balance in the first few days of life and neonatal period, fluid therapy including goals of treatment, fluid calculations and determinants of alterations in fluid and electrolyte requirements.
Government of Western Australia Child and Adolescent Health Service, Neonatology, Fluid Balance and Elimination, May 2024	Clinical Guideline	Assessment of fluid status: Weight (daily for first 7 days) Urine output 12-24 hrs 0.5ml/kg/hr and 1-5 mls/kg after Cardiovascular signs (heart rate, capillary refill time and blood pressure Physical exam (turgor/ oedema) Urinalysis Bloods Ultrasound Urinalysis- Normal SG varies with gestational and postnatal age, but is usually 1.008-1.020. Table for normal urine and renal values. Can be increased if the infant is receiving insufficient fluid. Fluid overload in neonates associated with increased mortality Clinical performed functional ultrasound can be used to assess intravascular volume and cardiac output.
Iowa Health Care, Stead Family Children’s Hospital, Fluid Management: NICU Handbook, May 2022.https://uihc.org/childrens/educational-resources/fluid-management-nicu-handbook	Clinical Guideline	Body composition/ surface area/ physiology of the newborn in relation to fluid and electrolyte management Renal haemodynamics and sodium homeostasis Monitoring Na for infants <1000g should be 6-8 hrly and every 12 hours for infants 100-1500g Increase fluids for urine output <0.5 mls/kg/hr
Mansout, F, Peterson, D, De Coppi, P and Eaton, S. (2014) Effect of sodium deficiency on growth of surgical infants: a retrospective observational study. Pediatric Surgery International. 30; 1279 – 1284.	Observational Study	Infants who have an ileostomy may suffer from growth faltering, as sodium losses from stomas may be excessive. Observational study to see if there is a relationship between urinary sodium and growth in infants undergoing ileostomy, colostomy and cystostomy. Of the patients studied, only ileostomy patients developed severe malnourishment, whereas patients with colostomy displayed both normal growth and moderate malnutrition.
Nada A, Askenazi D, Kupferman JC, Mhanna M, Mahan JD, Boohaker L, Li L, Griffin RL; AWAKEN Collaborative. Low albumin levels are independently associated with neonatal acute kidney injury: a report from AWAKEN Study Group. Pediatr Nephrol. 2022 Jul;37(7):1675-1686. doi: 10.1007/s00467-021-05295-2. Epub 2021 Oct 18. Erratum in: Pediatr Nephrol. 2022 Jul;37(7):1699-1700.	Retrospective observational cohort study	Evaluated association of albumin with early and late AKI for 531 neonates. Low albumin levels were associated with increased odd of neonatal AKI. Albumin could be a potential preventable risk factor for neonatal AKI.
McNab, S., Duke, T., South, M., Babl, F. E., Lee, K. J., Arnup, S. J., ... & Davidson, A. (2015). 140 mmol/L of sodium versus 77 mmol/L of sodium in maintenance intravenous fluid therapy for children in hospital (PIMS): a randomised controlled double-blind trial. The Lancet, 385(9974), 1190-1197.	Randomised double blind trial	Randomised double blind trial at RCH who needed IV maintenance for 6 hrs or longer (randomly assigned to receive either isotonic fluids containing 140 mmol/L sodium or hypotonic fluid containing77 mmol/L of sodium. Fewer patients who received Na 140 developed hyponatraemia. One patient in Na 140 group had seizures compared with seven who received Na 77. Plasma-lyte 148 co solution with 5% glucose fluid composition broken down Isotonic fluid is protective against hyponatraemia when compared with hypotonic fluid. These findings were consistent across all children assessed, medical and surgical.
Medsafe Plasmalyte 148 data sheet, Baxter health care July 2019https://www.medsafe.govt.nz/profs/datasheet/p/plasmalytesol.pdf	Pharmacy data sheet	Plasmalyte 148 ph 7.4 infusion solution has similar concentration as plasma Sodium 140 mmol, Chloride 98 mmol, Acetate 27 mmol, Gluconate 23 mmol, potassium5 mmol, magnesium 1.5 mmol.
O'Brien, F., & Walker, I. A. (2014). Fluid homeostasis in the neonate. Pediatric Anesthesia, 24(1), 49-59.	Expert opinion	Thorough academic piece on fluid homeostasis in the neonate with supportive evidence from various research including randomised controlled trials. Discusses the importance of understanding fluid physiology within the first few days of life during transition from intrauterine life.
Royal Children’s Hospital- CPGRCH CPG Neonatal Intravenous Fluids	Clinical Guideline	Assess general appearance and hydration status Signs of fluid overload- eg periorbital, genital, sacral or peripheral oedema Check total fluid balance Weigh- up to 10% loss in a health term neonate in week one of life is considered normal Red flags- abnormal sodium <135 mmol/L or>145 mmol/L, short gut or other significant gastrointestinal pathology, polyuria (>6ml/kg/hr) Overview of maintenance fluids (special care nurseries, ED and Wards) Administration via CVAD for Glucose concentration above 12.5%
Royal Children’s Hospital- CPGRCH Dehydration CPG	Clinical Guideline	Chart for assessing severity of dehydration (mild, moderate or shock) Asses conscious state, heart rate, breathing, blood pressure, skin colour, extremities, peripheral pulses, eye and Fontenelle, mucous membranes, skin turgor, central refill time. Management of dehydration in children
Rutledge. A, Murphy.H, Harer. M.W, Jetton.J.G, 2021, Fluid Balance in the Critically Ill Child Section: “How Bad is Fluid in Neonates?”, Front Pediatr April 20:9.	Systematic Review	Neonatal fluid balance is impacted by multiple factors including functional renal immaturity in the newborn period, physiologic postnatal diuresis and weight loss and pathologies that require fluid administration. Treatment options for fluid overload. Cardiac surgery risk factor for fluid overload. Fluid restriction reduced duration of respiratory support for severe TTN.Diuretics for fluid overload frequently used for pulmonary oedema or congestive heart failure
Safer Care Victoria, Chronic Lung Disease of prematurity, updated 2018.https://www.safercare.vic.gov.au/best-practice-improvement/clinical-guidance/neonatal/chronic-lung-disease-of-prematurity	State Guidelines	Chronic lung disease is defined as oxygen dependency at 36 weeks corrected gestational age Risk Factors: prematurity, peripartum inflammation/ infection associated with preterm labour, postnatal lung injury due to volutrauma, barotrauma, oxygen toxicity, hypocarbia or infection.
Segar JL. A physiological approach to fluid and electrolyte management of the preterm infant: Review. Journal of Neonatal-perinatal Medicine. 2020 ;13 (1):11-19. DOI: 10.3233/npm-190309. PMID: 31594261.	Literature Review	Infants who are critically ill or born prematurely cannot regulate their own intake of fluid and nutrients, and often display relative kidney dysfunction related to perinatal insults or organ immaturity. Fluid overload dysnatremia and acute kidney injury are independent associated with increased neonatal morbidity and mortality. Target driven fluid management that focuses on percentage of change in weight from birth, careful assessment of IWL, urine output and serum electrolytes and consideration of nutritional goals is suggested.
Slagle. C, Gist.K.M, Starr. M.C, Hemmegarn. T.S, Goldsdtein. S.L, Kent. A.L, March 2022, Fluid Homeostasis and diuretic Therapy in the Neonate, NeoReviews, Vol 23 (3).	Systematic Review	Minimal intravascular changes in albumin can greatly affect water balance between compartments. Use of controlled evaluated daily fluid management goals was associated with lower incidence of PDA and NEC. Pathologic fluid accumulation is associated with increased morbidity in neonates. Individualised approach with meticulous monitoring of net fluid balance and provision of fluid (nutrition, medications etc.) to avoid fluid overload. Daily weightsDaily serum creatinineRoutine screening for hypoalbuminemia and AKIMonitoring for electrolyte imbalances Consultation with nephrology if stage 2 AKI and/ or >10% fluid accumulation.
South Eastern Sydney Local Health District, The Royal Hospital for Women, Neonatal Services Division, Gastrointestinal aspirate replacement, 2020	Clinical Guideline	Measure volumes every 4 hours Initiate intravenous replacement after observing the total volume of aspirates for 12 hrs. Replace losses if the volume equates to ≥ 10 mls/kg/day Calculate the volume of aspirates in the previous 4 hours Replace entire losses ml for ml over next 4 hours.
Starship Hospital- Clinical Guidelines, Fluid requirements and age-appropriate formula for infants, children and young people, Published March 2022 https://starship.org.nz/guidelines/fluid-requirements-and-age-appropriate-formula-for-infants-and-children/	Clinical Guideline	Guideline with an overview of nutrition and enteral requirements for children
Starship Hospital- Clinical Guideline: Intravenous Fluids, published July 2024https://starship.org.nz/guidelines/intravenous-fluids/	Clinical Guideline	Resuscitation bolus 10-20 mL/kg sodium chloride 0.9% (or Plasma-Lyte 148 under specialist advice) Overview of maintenance fluids: < 4 weeks corrected age (glucose 10% + sodium chloride + 20 mmol/L potassium chloride) ≥4 weeks corrected Glucose 5 % + sodium chloride + 20 mmol/L potassium chloride All children who require IV fluids also require: Serum electrolytes (immediately prior to administering and daily) Glucose (immediately prior) Accurate fluid balance Daily weight where feasible Replacement of ongoing losses- fluids used to replace should roughly match the electrolyte composition of the fluid being lost. Gastrointestinal losses should be replaced in the first instance with sodium chloride 0.9% + 20 mmol/L potassium chloride.
Starship Hospital- Clinical Guideline: Practice recommendations for weight loss, dehydration and hypernatraemic dehydration in the Neonate, Published 2019.https://starship.org.nz/guidelines/practice-recommendations-for-weight-loss-dehydration-and-hypernatraemic/	Clinical Guideline	Dehydration occurs when fluid intake is inadequate to account for fluid losses. Extent of dehydration can be quantified by weight loss. Assess for signs of intracellular dehydration and neurological dysfunction Lethargy Irritability A dough feel to skill Ataxia, tremor, hyper-reflexia, seizures, reduced GCS Signs of good perfusion in neonates: Good skin colour and perfusion, alert, responsive, settles well, pale urine and soaked nappy.
The Royal Hospital for Women, Neonatal Services Division, May 2020, Gastrointestinal Aspirate Replacement, Local Operating Procedure	Clinical Guideline	High risk infants (post-op surgical, bowel obstruction) Inadequate replacement can lead to electrolyte and nutrient deficiencies Aim to replace losses as well as avoid overload. Measure 4 hrly Strict fluid balance Replace losses if the volume equates to ≥10 mL/kg/day
Weaver.L.J, Travers.C.P, Ambalavanan.N, Askenazi.D, January 2023, Neonatal Fluid Overload- ignorance is no longer bliss, Pediatr Nephrol 38 (1).	Author manuscript	Typically full term neonates should not lose more than 10% of their birth weight in the first postnatal week, whereas between 10-20% weight loss may be beneficial among extremely preterm neonates. Too much fluid administration affects postnatal cardiac and pulmonary adaptation. Increased fluid provision can impact cardiovascular function and prevent appropriate adaptation from uterine environment. A weight based fluid balance formula has been shown in multiple studies to calculate fluid status and determine fluid overload. Typical practice includes treatment of moderate hypoalbuminemia ( <2.5mg/dL) with 1 g/kg of 20% albumin or 2g/kg of 20% albumin to treat severe hypoalbumnemia (<2.0mg/dL).
Zarraga. C.M, Borowitz. S.M, 2021, Growth failure and metabolic acidosis due to a total body sodium depletion in an infant with an ileostomy, BMJ Case Report 2021, 14.	Case report	Sodium is an essential nutrient and inadequate sodium intake and/ or excessive sodium losses can result in suboptimal growth. Chronic sodium depletion can also limit the kidney’s ability to excrete hydrogen and potassium ions, mimicking electrolyte abnormalities found in type 4 renal tubular acidosis.

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The development of this nursing guideline was coordinated by Narelle Miller, CNC Neonatal Nursing, Alison Kendrick, CNE Neonatal Nursing and Lau Dan Wong, RN Neonatal Nursing, and approved by the Nursing Clinical Effectiveness Committee. Updated March 2025.