Paediatric Dose Calculator

Calculates weight-based medication doses for paediatric patients. Enter any drug’s per-kilogram dose and the child’s weight to determine single-dose amount, daily total, and liquid volume — with automatic maximum-dose capping and safety checks.

Clinical Tool · Paediatrics · Pharmacology · Drug Dosing

Calculate Paediatric Dose

Enter the child’s weight and the prescribed dose in mg/kg (or mcg/kg). The calculator will determine the dose per administration, total daily dose, and — if you provide the drug concentration — the volume to administer. Set an optional maximum single dose to apply a safety cap. Use the common drugs reference below to look up standard paediatric dosing.

Patient & Drug

Body Weight kg · Use actual body weight

Body Weight lb · Use actual body weight

Dose per kg Amount per kg per dose (see unit below)

Dose Unit Unit of the per-kg dose

Frequency How often is the dose given?

Optional — Liquid Formulation & Dose Cap

Drug Concentration mg (or mcg/units/mEq) per mL

Maximum Single Dose Cap per dose (same unit as dose)

Safety Notice

This calculator performs a generic weight-based dose calculation. It does not validate that the entered mg/kg dose is correct for any specific drug, indication, or age group. Always verify the dose per kg against current prescribing information or a paediatric formulary (e.g., BNF for Children, Lexicomp, Harriet Lane) before prescribing. Double-check all high-risk medications with a second clinician or pharmacist.

Principles of Weight-Based Paediatric Dosing

Children are not simply “small adults.” Paediatric pharmacokinetics differ from adult pharmacokinetics in absorption, distribution, metabolism, and elimination — and these parameters change rapidly with growth and development. Weight-based dosing (mg/kg) is the foundation of paediatric prescribing because it adjusts for the large variation in body size across the paediatric age range, from a 3 kg neonate to a 70 kg adolescent.

The basic calculation is straightforward: multiply the per-kilogram dose by the child’s weight to obtain the actual dose. However, safe paediatric prescribing requires attention to several additional factors — maximum dose caps, age-specific dose ranges, formulation availability, and the practical challenge of measuring small liquid volumes accurately.

Basic Dose Calculation

Single dose:
Dose = Weight (kg) × Dose/kg

Daily dose:
Daily = Single dose × Frequency

Volume (liquid):
Volume (mL) = Dose / Concentration

Worked Example

Amoxicillin for a 15 kg child:
Dose: 25 mg/kg/dose, TDS (q8h)
Concentration: 250 mg / 5 mL = 50 mg/mL
Max single dose: 500 mg

Single dose: 15 × 25 = 375 mg
Volume: 375 / 50 = 7.5 mL
Daily: 375 × 3 = 1,125 mg/day

Key safety principle: The calculated weight-based dose must always be checked against the maximum recommended dose (which is typically the adult dose). A large adolescent dosed at mg/kg may exceed safe adult limits. If the calculated dose exceeds the maximum, cap at the maximum — never exceed the adult dose simply because the mg/kg calculation yields a higher number.

Common Paediatric Drug Doses

The table below provides commonly used paediatric doses for frequently prescribed medications. These are general reference values only — doses may vary by indication, severity, age, and local guidelines. Always verify against your institution’s formulary or a current paediatric reference.

Drug	Dose	Frequency	Max Single Dose	Common Concentration
Paracetamol (Acetaminophen)	15 mg/kg	q4–6h	1,000 mg	120 mg/5 mL, 250 mg/5 mL
Ibuprofen	5–10 mg/kg	q6–8h	400 mg	100 mg/5 mL
Amoxicillin (standard)	25 mg/kg	q8h (TDS)	500 mg	125 mg/5 mL, 250 mg/5 mL
Amoxicillin (high-dose AOM)	40–45 mg/kg	q12h (BD)	1,000 mg	400 mg/5 mL
Co-amoxiclav (Augmentin)	25 mg/kg (amox component)	q8h (TDS)	500 mg	125 mg/5 mL, 250 mg/5 mL
Azithromycin	10 mg/kg day 1, then 5 mg/kg	q24h	500 mg day 1, 250 mg	200 mg/5 mL
Cefalexin (Cephalexin)	12.5–25 mg/kg	q6–8h	500 mg	125 mg/5 mL, 250 mg/5 mL
Prednisolone (acute asthma)	1–2 mg/kg	q24h	40–60 mg	5 mg/5 mL, 15 mg/5 mL
Ondansetron (IV/PO)	0.15 mg/kg	q8h (max 3 doses)	4 mg	4 mg/5 mL
Oral Rehydration Salts	10 mL/kg per loose stool	PRN	200 mL/dose	Reconstituted as directed

Clinical Pearl

Concentration matters. Many paediatric liquid medications come in multiple concentrations (e.g., paracetamol infant drops at 100 mg/mL vs. paracetamol suspension at 120 mg/5 mL = 24 mg/mL). A fivefold concentration difference means a fivefold volume difference — and a potential fivefold overdose if the wrong formulation is assumed. Always verify the exact product concentration when calculating volume.

Dose Verification & Safety Checks

Paediatric medication errors are among the most common and most preventable causes of harm in hospital medicine. The unique vulnerability of children — narrow therapeutic windows, weight-dependent dosing, and concentration-dependent volume calculations — means that every paediatric prescription should undergo systematic safety checks.

Five-Point Dose Verification Checklist

Before dispensing or administering any paediatric dose, verify each of these five elements:

Correct weight: Has the child been weighed today (or recently)? Is the weight recorded in kilograms? Estimated weights are acceptable only in emergencies — always weigh the child as soon as feasible.
Correct dose per kg: Does the mg/kg dose match the formulary recommendation for this drug, this indication, and this age group? Higher or lower doses may apply to different infections or severity levels.
Dose within range: Is the calculated dose below the maximum single dose and below the maximum daily dose? Does it fall within the expected range for the child’s age?
Correct formulation: Is the concentration on the label the same concentration used in the calculation? Are you dispensing the correct product (suspension vs. drops vs. tablets)?
Measurable volume: Can the dose be practically measured with the available device (oral syringe, measuring cup)? Rounding to the nearest 0.1 mL (syringe) or 0.5 mL (cup) is acceptable for most drugs.

Tenfold Dose Error Prevention

Tenfold (10×) dose errors are one of the most dangerous and common types of paediatric medication errors. They typically occur due to decimal point misplacement, unit confusion (mg vs. mcg), or calculation errors when converting between concentrations.

Prevention strategies include: always using a leading zero before a decimal point (write 0.5 mg, not .5 mg), never using a trailing zero after a decimal point (write 5 mg, not 5.0 mg), using standardised concentration labels, double-checking calculations with a second person for all high-risk medications, and using electronic prescribing systems with built-in dose-range checking wherever available.

A practical sanity check: if the calculated volume seems unusually large or small for the child’s age, recalculate. A neonate requiring 10 mL of a suspension or an older child requiring 0.02 mL of anything should trigger a pause and recheck.

High-Risk Medication Categories

Certain drug classes carry elevated risk of harm from dosing errors in children and should always be independently double-checked before administration:

Opioids: Narrow therapeutic index, respiratory depression risk. Weight-based dosing is essential. Morphine, fentanyl, and codeine have age-specific contraindications.
Insulin: Unit-based dosing with potentially fatal hypoglycaemia from overdose. Use insulin-specific syringes only. Verify units vs. mL.
Anticonvulsants: Loading doses of phenytoin, phenobarbital, and levetiracetam are weight-based and given IV with cardiac monitoring. Calculation errors can cause cardiovascular collapse or inadequate seizure control.
Chemotherapy: BSA-based dosing (not weight-based) for most agents. Errors are catastrophic. Protocol-driven verification is mandatory.
Electrolytes (IV potassium, calcium): Concentration and rate errors can cause fatal arrhythmias. Always verify mEq dose, concentration, and infusion rate independently.
Digoxin: Mcg/kg dosing with a very narrow therapeutic window. Tenfold errors between mcg and mg are classic and potentially fatal.

Practical Rounding Guidance

Calculated doses are rarely perfectly round numbers. Appropriate rounding depends on the drug’s therapeutic index and the available measuring device.

Oral liquids (syringe): Round to the nearest 0.1 mL for volumes < 5 mL. Round to the nearest 0.5 mL for volumes ≥ 5 mL. Oral syringes are preferred over household teaspoons for accuracy.
Tablets/capsules: Round to the nearest available tablet fraction. Half-tablets are acceptable for scored tablets. Quarter-tablets are unreliable — use liquid formulations instead.
IV medications: Round to the nearest 0.1 mL for syringe-drawn doses. For infusions, round concentration-adjusted rates to practical pump settings.
Narrow therapeutic index drugs: Do not round. Use exact volumes and verify with a second calculator or pharmacist.

General principle: rounding should never change the dose by more than 10% from the calculated value. If it does, choose a different formulation or concentration.

Special Populations

Weight-based dosing is the starting point, but several paediatric subpopulations require additional considerations beyond simple mg/kg calculations.

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Neonates (< 28 days)

Neonatal drug metabolism is markedly immature. Hepatic enzyme systems (especially CYP450 and glucuronidation pathways) are not fully developed, and renal clearance is reduced. Many drugs require lower mg/kg doses and extended dosing intervals in neonates compared to older infants. Gestational age and postnatal age both affect dosing — always consult a neonatal formulary.

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Obese Children

Using actual body weight in an obese child may lead to supratherapeutic doses for hydrophilic drugs that distribute primarily into lean tissue. Conversely, lipophilic drugs may need actual-weight dosing. There is limited evidence to guide dose-weight selection in paediatric obesity — for most drugs, use actual weight but do not exceed the maximum adult dose. For aminoglycosides and similar drugs, consider adjusted body weight.

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Renal & Hepatic Impairment

Weight-based dosing does not account for impaired drug clearance. Children with renal impairment require dose reduction or interval extension for renally cleared drugs (aminoglycosides, vancomycin, aciclovir). Hepatic impairment affects drugs cleared by hepatic metabolism (paracetamol, midazolam, phenytoin). Consult specialist guidelines and monitor drug levels where available.

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Adolescents Nearing Adult Weight

Large adolescents (40–70+ kg) frequently calculate to doses that meet or exceed the adult maximum. Once the calculated dose reaches the adult dose, cap at the adult dose — do not continue to scale linearly with weight. Some institutions transition to adult dosing guidelines entirely once the child exceeds 40 kg or reaches a defined age (e.g., 12 years), depending on the drug.

Body surface area (BSA) dosing: Some medications — particularly chemotherapy agents and certain cardiac drugs — are dosed by BSA (mg/m²) rather than weight (mg/kg). BSA-based dosing accounts better for metabolic rate across the paediatric size range. This calculator uses weight-based dosing only. For BSA-based drugs, use a dedicated BSA calculator.

Common Pitfalls & Limitations

Confusing “per dose” and “per day” dosing

This is one of the most frequent sources of paediatric dosing errors. Some references list doses as mg/kg/dose (per administration), while others list mg/kg/day (total daily dose to be divided across multiple administrations). Confusing the two leads to either underdosing (if a per-day dose is given per administration without dividing) or overdosing (if a per-dose amount is multiplied as though it were per-day).

Example: Amoxicillin 75 mg/kg/day divided TDS = 25 mg/kg/dose three times daily. Misreading 75 mg/kg as per-dose gives a threefold overdose. Always verify whether the reference source quotes per-dose or per-day figures, and document the calculation clearly.

Using estimated weight instead of measured weight

Age-based weight estimates (e.g., APLS formula: weight = 2 × (age + 4)) are intended for emergency resuscitation only and have wide confidence intervals — up to ±30% from actual weight. Using an estimated weight for routine drug dosing introduces unnecessary and preventable error.

Every child should be weighed on admission and periodically during hospitalisation. The weight must be in kilograms — weighing in pounds and converting introduces additional calculation steps and opportunities for error. Electronic prescribing systems should pull the documented weight automatically. If a child cannot be weighed (e.g., critical care, immobilisation), use a Broselow tape or the best available estimate and document the method used.

Wrong concentration selected for liquid formulation

Many paediatric drugs come in multiple concentrations. Paracetamol is a classic example: infant drops (100 mg/mL), children’s suspension (120 mg/5 mL = 24 mg/mL), and adult suspension (250 mg/5 mL = 50 mg/mL). If the pharmacist dispenses one concentration but the prescriber calculated the volume based on another, the actual dose delivered can be dramatically wrong.

Prevention: always write the concentration on the prescription alongside the volume (e.g., “7.5 mL of paracetamol 120 mg/5 mL suspension”), verify the product label at the point of dispensing, and educate parents about which product they have at home. Automatic electronic dose calculators should be linked to the specific product, not just the drug name.

Exceeding the maximum dose in large children

A 50 kg adolescent prescribed paracetamol at 15 mg/kg calculates to 750 mg per dose. The adult maximum single dose is 1,000 mg — so 750 mg is safe. But a 80 kg teenager at 15 mg/kg calculates to 1,200 mg — exceeding the maximum. Without a dose cap, weight-based dosing in large children leads to supratherapeutic doses.

Every weight-based prescription should include an explicit maximum dose. This calculator allows you to enter a maximum single dose that automatically caps the result. In practice, many institutions transition to adult fixed dosing once a child exceeds a threshold weight (typically 40–50 kg) or age (12–16 years, depending on the drug).

Not accounting for indication-specific dose differences

Many drugs have different mg/kg doses depending on the indication. Amoxicillin is 25 mg/kg/dose TDS for standard infections but 40–45 mg/kg/dose BD for acute otitis media. Ibuprofen is 5–10 mg/kg for analgesia but different protocols exist for PDA closure in neonates (which uses a different drug form entirely). Prednisolone is 1 mg/kg for mild asthma exacerbations but 2 mg/kg for severe presentations.

A generic “dose of amoxicillin” is clinically meaningless without the indication. Always specify the indication when looking up paediatric doses, and ensure the mg/kg value entered into this calculator matches the intended clinical use.

Quick Reference Summary

mg/kg Standard paediatric
dosing unit

≤ Max Never exceed
adult maximum dose

2× Check Independent double-check
for high-risk drugs

kg Only Always weigh
in kilograms

Step	Action	Check
1. Weight	Weigh child in kg (not estimated)	Is the weight recent and documented?
2. Dose/kg	Look up correct mg/kg for indication	Per dose or per day? Correct indication?
3. Calculate	Weight × dose/kg = dose	Is the dose below the maximum?
4. Formulation	Select correct product concentration	Does the label match the calculation?
5. Volume	Dose / concentration = mL	Is the volume measurable and practical?
6. Verify	Independent double-check for high-risk drugs	Second person agrees with calculation?

The Golden Rule

Weigh in kilograms, dose in mg/kg, cap at the adult maximum, verify the concentration, and double-check the maths. Paediatric dosing errors are preventable. The five-point verification — correct weight, correct dose/kg, dose within range, correct formulation, measurable volume — should be applied to every prescription. When the calculated volume seems implausible for the child’s size, stop and recalculate before administering.

Disclaimer & References

Disclaimer

For Educational Purposes Only. This calculator and the accompanying clinical information are intended as educational tools for healthcare professionals. They do not replace clinical judgement. Results should be interpreted in the full clinical context. Lab reference ranges vary by institution — verify with your own laboratory. Drug dosages should be confirmed against current prescribing information.

References

Kearns GL, Abdel-Rahman SM, Alander SW, et al. Developmental pharmacology — drug disposition, action, and therapy in infants and children. N Engl J Med. 2003;349(12):1157–1167. DOI: 10.1056/NEJMra035092
Ghaleb MA, Barber N, Franklin BD, Wong ICK. The incidence and nature of prescribing and medication administration errors in paediatric inpatients. Arch Dis Child. 2010;95(2):113–118. DOI: 10.1136/adc.2009.158485
Stucky ER; American Academy of Pediatrics Committee on Drugs, Committee on Hospital Care. Prevention of medication errors in the pediatric inpatient setting. Pediatrics. 2003;112(2):431–436. DOI: 10.1542/peds.112.2.431
Wong ICK, Ghaleb MA, Franklin BD, Barber N. Incidence and nature of dosing errors in paediatric medications: a systematic review. Drug Saf. 2004;27(9):661–670. DOI: 10.2165/00002018-200427090-00004
British National Formulary for Children (BNFc). BMJ Group, Pharmaceutical Press, and RCPCH Publications. Available at: bnfc.nice.org.uk
Taketomo CK, Hodding JH, Kraus DM. Pediatric & Neonatal Dosage Handbook. Lexicomp. (Current edition).
Anderson BJ, Holford NHG. Understanding dosing: children are small adults, neonates are immature children. Arch Dis Child. 2013;98(9):737–744. DOI: 10.1136/archdischild-2013-303720
Kozer E, Scolnik D, Macpherson A, et al. Variables associated with medication errors in pediatric emergency medicine. Pediatrics. 2002;110(4):737–742. DOI: 10.1542/peds.110.4.737