BUN/Creatinine Ratio Calculator

Calculate the BUN/creatinine ratio from blood urea nitrogen and serum creatinine. Enter values in mg/dL, mmol/L, or μmol/L for prerenal vs intrinsic renal pattern interpretation and exportable results.

Enter your details — results appear below after you calculate.

Lab values

BUN units

Typical reference: 7–20 mg/dL (2.5–7.1 mmol/L urea)

Creatinine units

Typical reference: ~0.6–1.3 mg/dL (53–115 μmol/L)

How this BUN/creatinine ratio calculator works

This tool computes the BUN/creatinine ratio: BUN (mg/dL) ÷ creatinine (mg/dL). The typical adult reference range is approximately 10–20:1. Values above 20:1 suggest prerenal azotemia (dehydration, heart failure, GI bleed); below 10:1 favor intrinsic renal injury (ATN, glomerulonephritis).

Enter blood urea nitrogen (BUN) in mg/dL or mmol/L and serum creatinine in mg/dL or μmol/L exactly as shown on your lab report. The calculator converts units internally before dividing— never mix units manually without conversion.

Results include ratio category, individual BUN and creatinine reference status, health score, risk level, clinical interpretation, and recommendations when the ratio is abnormal. Pair with eGFR, urinalysis, and volume assessment for complete kidney evaluation.

This is an educational screening tool—not a diagnosis. Seek urgent care for oliguria, severe dehydration, confusion, or rapidly rising creatinine. Scroll below for detailed articles, worked examples, and FAQs.

BUN/Creatinine Ratio Calculator – Prerenal vs Intrinsic Renal Patterns

The BUN/creatinine ratio is a simple bedside calculation that compares blood urea nitrogen (BUN) to serum creatinine. When kidney function is abnormal, the ratio helps clinicians distinguish prerenal azotemia (decreased renal perfusion) from intrinsic renal disease (parenchymal injury). Our calculator accepts BUN in mg/dL or mmol/L and creatinine in mg/dL or μmol/L, converts values internally, and returns ratio category, individual lab status, clinical interpretation, and exportable results. Whether you are reviewing a routine metabolic panel, monitoring acute kidney injury (AKI), or learning renal physiology, this tool translates your lab numbers into actionable clinical context—always alongside professional medical judgment.

Why Calculate the BUN/Creatinine Ratio?

BUN and creatinine both rise when kidney filtration falls, but they do not rise equally in every situation. In prerenal states, BUN is reabsorbed more avidly in the proximal tubule while creatinine rises modestly—producing a ratio above 20:1. In acute tubular necrosis and other intrinsic injuries, both markers often rise together, yielding a ratio below 10:1. The ratio is one piece of the AKI puzzle alongside volume status, urinalysis, and trend data.

1Key Components of Ratio Interpretation

Laboratory Values

  • Blood urea nitrogen (BUN) — mg/dL or mmol/L
  • Serum creatinine — mg/dL or μmol/L
  • BUN/creatinine ratio (dimensionless)
  • Pair with eGFR, urinalysis, and electrolytes

Clinical Context

  • Volume status, blood pressure, heart failure
  • Medications: NSAIDs, ACEi/ARB, diuretics
  • GI bleeding, protein intake, liver function
  • Urine output and AKI staging when applicable

2How the Ratio Is Calculated

Formula

BUN/Creatinine Ratio = BUN (mg/dL) ÷ Creatinine (mg/dL)

Convert BUN and creatinine to mg/dL before dividing. This calculator performs unit conversion automatically when you enter mmol/L or μmol/L values from your lab report.

Unit conversions used

  • BUN mg/dL = mmol/L (urea) ÷ 0.357 (× 2.801)
  • Creatinine mg/dL = μmol/L ÷ 88.42

Example calculation

BUN 42 mg/dL, creatinine 1.4 mg/dL: Ratio = 42 ÷ 1.4 = 30:1 — markedly elevated, suggesting prerenal azotemia until proven otherwise. BUN 28 mg/dL, creatinine 3.5 mg/dL: Ratio = 28 ÷ 3.5 = 8:1 — low ratio favoring intrinsic renal injury.

Understanding BUN and Creatinine Separately

Before interpreting the ratio, it helps to understand what each marker measures. BUN and creatinine both reflect kidney function but originate from different metabolic pathways and respond differently to hydration, diet, muscle mass, and liver health.

Blood Urea Nitrogen (BUN)

BUN measures nitrogen content from urea, the end product of dietary and endogenous protein metabolism. The liver converts ammonia to urea; kidneys excrete it. BUN rises with high protein intake, GI bleeding, corticosteroids, tetracyclines, and decreased renal perfusion (enhanced proximal tubular reabsorption). It falls with severe liver disease, malnutrition, low protein diet, and overhydration.

  • Typical range: 7–20 mg/dL (2.5–7.1 mmol/L)
  • More variable than creatinine day-to-day
  • Sensitive to hydration and protein load
  • Elevated in upper GI bleed (digested blood protein)

Serum Creatinine

Creatinine is produced at a relatively constant rate from muscle creatine phosphate breakdown. It is freely filtered at the glomerulus with minimal tubular secretion. Because production correlates with muscle mass, reference ranges differ by sex and age. Creatinine is the backbone of eGFR equations (CKD-EPI, MDRD) and Cockcroft-Gault clearance estimates.

  • Typical range: ~0.6–1.3 mg/dL (53–115 μmol/L)
  • Higher in muscular individuals and males
  • Less affected by diet than BUN
  • Lags behind true GFR changes (especially in AKI)

Normal BUN and Creatinine Reference Ranges

Individual lab values matter independently of the ratio. Use your laboratory's printed reference interval when available—the ranges below are typical adult teaching values.

Testmg/dLSI unitsNotes
BUN7–202.5–7.1 mmol/L (urea)Rises with azotemia, protein load
Creatinine (men)0.7–1.362–115 μmol/LHigher with muscle mass
Creatinine (women)0.6–1.153–97 μmol/LLower average muscle mass
BUN/Cr ratio10–20:1 (approximate)Most useful when azotemic

BUN/Creatinine Ratio Reference Ranges

CategoryRatioClinical significance
Low< 10:1Intrinsic renal disease, liver disease, malnutrition
Normal10–20:1No strong directional pattern alone
Elevated20–30:1Possible prerenal azotemia
High> 30:1Likely prerenal azotemia; consider GI bleed

Prerenal, Intrinsic, and Postrenal Kidney Injury

Acute kidney injury is traditionally classified by anatomic level of dysfunction. The BUN/creatinine ratio is most helpful distinguishing prerenal from intrinsic causes when creatinine is acutely rising. Postrenal obstruction may present with variable ratios depending on timing and bilateral involvement.

Prerenal (High ratio)

Reduced renal blood flow with structurally normal kidneys. Often reversible with perfusion restoration.

  • Dehydration, vomiting, diarrhea
  • Heart failure, hepatorenal syndrome
  • Sepsis, anaphylaxis, hemorrhage
  • NSAIDs, ACEi/ARB with hypovolemia
  • Ratio often > 20:1, may exceed 30:1

Intrinsic Renal (Low ratio)

Parenchymal kidney damage. BUN and creatinine rise more proportionally; tubular injury impairs urea reabsorption.

  • Acute tubular necrosis (ischemia, toxins)
  • Glomerulonephritis, vasculitis
  • Acute interstitial nephritis (drugs)
  • Contrast nephropathy, rhabdomyolysis
  • Ratio often < 10:1

Postrenal (Variable)

Urinary tract obstruction. Early obstruction may raise creatinine with variable BUN; chronic obstruction can elevate both.

  • BPH, ureteral stones, tumors
  • Neurogenic bladder, anticholinergics
  • Pelvic mass, retroperitoneal fibrosis
  • Ultrasound: hydronephrosis
  • Ratio not reliable for diagnosis alone

FENa, Urinalysis, and Beyond the Ratio

The BUN/creatinine ratio is a screening clue—not a definitive test. Nephrologists combine it with urine studies when differentiating AKI etiologies. Fractional excretion of sodium (FENa) and urine microscopy add critical information the ratio alone cannot provide.

FENa (%) = (Urine Na × Plasma Cr) ÷ (Plasma Na × Urine Cr) × 100

FENa interpretation (without diuretics)

  • < 1% — favors prerenal azotemia
  • > 2% — favors intrinsic renal (ATN)
  • 1–2% — indeterminate; use clinical context

Urinalysis findings

  • Muddy brown casts — ATN
  • RBC casts — glomerulonephritis
  • WBC casts — pyelonephritis, AIN
  • Bland sediment — may support prerenal

Important: Diuretics invalidate FENa—use fractional excretion of urea (FEUrea < 35% favors prerenal) or compare sequential ratios after volume repletion instead.

Worked Examples: Putting Numbers in Context

Example 1 — Dehydration (prerenal)

A 68-year-old with vomiting and poor intake: BUN 56 mg/dL, creatinine 1.8 mg/dL. Ratio = 56 ÷ 1.8 = 31:1. Markedly elevated ratio with acute creatinine rise strongly suggests prerenal azotemia. After IV fluids, repeat labs often show falling BUN and creatinine with ratio normalizing toward 10–20:1.

Example 2 — ATN after sepsis (intrinsic)

Post-ICU patient with septic shock: BUN 48 mg/dL, creatinine 4.2 mg/dL. Ratio = 48 ÷ 4.2 = 11.4:1 — borderline normal despite significant azotemia. Low-normal ratio in setting of high creatinine favors intrinsic injury (ATN). Urine sediment with muddy brown casts would support this pattern.

Example 3 — GI bleeding (high BUN, modest Cr rise)

Patient with melena: BUN 85 mg/dL, creatinine 1.1 mg/dL. Ratio = 85 ÷ 1.1 = 77:1 — extreme elevation from blood protein digestion in the GI tract raising BUN disproportionately. Creatinine may remain near baseline unless hypovolemia causes prerenal injury concurrently. Always evaluate hemoglobin and stool for blood.

Example 4 — SI units (mmol/L and μmol/L)

Lab reports BUN 8.9 mmol/L (urea) and creatinine 106 μmol/L. Convert: BUN ≈ 8.9 ÷ 0.357 = 24.9 mg/dL; Cr = 106 ÷ 88.42 = 1.2 mg/dL. Ratio = 24.9 ÷ 1.2 = 20.8:1 — borderline elevated, suggesting possible prerenal component. This calculator performs these conversions automatically.

High vs Low Ratio: Clinical Patterns

High Ratio (> 20:1)

  • Dehydration and volume depletion
  • Heart failure with reduced renal perfusion
  • Shock, sepsis, renal artery stenosis
  • Upper GI bleeding (elevated BUN from protein digestion)
  • High protein intake or catabolic states

Low Ratio (< 10:1)

  • Acute tubular necrosis (ATN)
  • Glomerulonephritis and interstitial nephritis
  • Advanced liver disease (low urea synthesis)
  • Malnutrition and low protein diet
  • Rhabdomyolysis with high creatinine

Medications and Conditions That Alter the Ratio

Many drugs and systemic conditions shift BUN and creatinine independently, which changes the ratio even when kidney structure is normal. Always review the medication list and comorbidities before attributing an abnormal ratio to a single cause.

Raises BUN (may increase ratio)

  • Corticosteroids — increased protein catabolism
  • Tetracyclines — anti-anabolic effect on urea
  • High-dose protein supplements or enteral feeds
  • GI bleeding — absorbed blood protein
  • CHF, sepsis — enhanced proximal tubular reabsorption

Raises creatinine (may lower ratio)

  • Trimethoprim — blocks tubular creatinine secretion
  • Cimetidine — reduces creatinine secretion
  • Rhabdomyolysis — massive muscle breakdown
  • High meat intake — transient creatinine rise
  • Creatine supplements in athletes

Lowers BUN (may decrease ratio)

  • Severe hepatic failure — impaired urea synthesis
  • Malnutrition, alcoholism, anorexia
  • Very low protein diet
  • Pregnancy — hemodilution and increased GFR
  • SIADH — water retention dilutes BUN

Nephrotoxic drugs (intrinsic injury)

  • NSAIDs, aminoglycosides, amphotericin B
  • IV contrast (especially with dehydration)
  • ACE inhibitors/ARBs in bilateral RAS
  • Calcineurin inhibitors (tacrolimus, cyclosporine)
  • Chemotherapy agents (cisplatin, methotrexate)

Warning Signs When Azotemia Is Present

Azotemia means elevated nitrogenous waste in blood (high BUN and/or creatinine). Symptoms depend on severity, acuity, and underlying cause. Mild chronic elevation may be asymptomatic; acute severe AKI requires urgent evaluation.

Seek urgent care if you have

  • Minimal or no urine output (< 0.5 mL/kg/hr)
  • Severe dehydration, dizziness, or confusion
  • Shortness of breath or leg swelling (fluid overload)
  • Chest pain, palpitations, or syncope
  • Bloody or black tarry stools, vomiting blood
  • Rapidly rising creatinine on repeat labs

Chronic azotemia may cause

  • Fatigue, poor appetite, unintentional weight loss
  • Nausea, metallic taste, ammonia breath (uremia)
  • Itching, muscle cramps, restless legs
  • Peripheral edema, foamy urine (proteinuria)
  • Bone pain, fractures (renal osteodystrophy)

Limitations of the BUN/Creatinine Ratio

Despite decades of clinical use, the ratio has important limitations. Understanding when it misleads prevents overconfidence in a single number.

  • Chronic kidney disease — BUN and creatinine often rise together, keeping the ratio in the normal 10–20:1 range despite advanced disease.
  • Liver disease — Low BUN from impaired urea synthesis can produce falsely low ratios even with renal impairment.
  • Malnutrition and low protein intake — Suppresses BUN, lowering the ratio independent of kidney perfusion.
  • GI bleeding — Dramatically elevates BUN without intrinsic renal disease, producing very high ratios.
  • Rhabdomyolysis — Massive creatinine rise from muscle breakdown lowers the ratio even when kidneys are injured.
  • Diuretic use — Alters sodium handling and volume status, confounding FENa and ratio interpretation together.
  • Timing in AKI — Creatinine lags injury by 24–48 hours; early prerenal states may not yet show expected ratio elevation.

Common Mistakes to Avoid

1. Dividing without unit conversion

Never divide mmol/L BUN by μmol/L creatinine directly. Always convert both to mg/dL first—or use this calculator to avoid arithmetic errors.

2. Over-interpreting a normal ratio

CKD can produce a normal ratio when BUN and creatinine rise in parallel. Always assess absolute creatinine, eGFR, and trends over time.

3. Ignoring medications and volume status

Diuretics, NSAIDs, and ACE inhibitors/ARBs alter renal hemodynamics and can confound ratio interpretation. Clinical context is essential.

4. Self-treating dehydration with large fluid loads

Aggressive fluid resuscitation without medical assessment can worsen heart failure or pulmonary edema. Seek professional guidance for significant azotemia.

5. Using a single ratio snapshot without trends

One ratio at one time point can mislead. Serial BUN, creatinine, and ratio trends after intervention (e.g., fluids) are far more informative than any isolated calculation.

6. Forgetting muscle mass effects on creatinine

Elderly, frail, or amputee patients have lower baseline creatinine—a "normal" creatinine can mask significant GFR loss. Use eGFR equations that account for age and sex.

The Science Behind BUN and Creatinine

Urea is the end product of protein metabolism, synthesized in the liver via the urea cycle and excreted by the kidneys. Creatinine derives from muscle creatine phosphate breakdown at a relatively constant daily rate. Because creatinine production is stable and filtration-dependent, it is a reliable GFR marker. BUN is more variable—rising with high protein intake, GI bleeding, corticosteroids, and decreased renal perfusion with enhanced proximal tubular reabsorption. The ratio exploits these differential behaviors but has limitations in liver disease, malnutrition, and chronic stable CKD.

In prerenal states, angiotensin II and sympathetic activation increase sodium and urea reabsorption in the proximal tubule while glomerular filtration falls modestly—BUN climbs faster than creatinine. In ATN, tubular injury impairs both filtration and reabsorption, so creatinine rises sharply and the ratio falls. This physiologic basis has been taught for decades, though modern AKI workups increasingly integrate biomarkers (NGAL, KIM-1), renal ultrasound, and kidney biopsy when etiology remains unclear.

When to Order Additional Tests

  • Urinalysis with microscopy and protein
  • Renal ultrasound for obstruction or size
  • eGFR and electrolytes (K⁺, HCO₃⁻, phosphate)
  • CPK if rhabdomyolysis suspected
  • Hemoglobin if GI bleed suspected
  • Nephrology referral for persistent AKI

Who Benefits Most From Ratio Calculation

  • Hospitalized patients with new azotemia
  • Emergency department volume depletion workups
  • Post-operative fluid management monitoring
  • Students learning prerenal vs intrinsic patterns
  • Patients tracking labs between clinic visits

Frequently Asked Questions (FAQs)

Related Calculators

You might also be interested in these related health and wellness calculators:

Kidney Function (eGFR) Calculator

Kidney Function (eGFR) Calculator

Estimate your kidney function by calculating your glomerular filtration rate (eGFR) using serum creatinine, age, sex. Detect early signs of chronic kidney disease and monitor renal health.

Try Calculator →
Creatinine Clearance (Cockcroft-Gault) Calculator

Creatinine Clearance (Cockcroft-Gault) Calculator

Estimate creatinine clearance (CrCl) using the Cockcroft-Gault formula with age, sex, body weight, and serum creatinine. Medication dosing context, clearance categories, and PDF export.

Try Calculator →
Corrected Calcium Calculator

Corrected Calcium Calculator

Estimate albumin-corrected total calcium using the Payne formula. Enter serum calcium and albumin in mg/dL or mmol/L with hypocalcemia and hypercalcemia interpretation, PDF export.

Try Calculator →
Anion Gap Calculator

Anion Gap Calculator

Calculate serum anion gap from sodium, chloride, and bicarbonate. Optional albumin correction, delta gap analysis, HAGMA interpretation, and PDF export.

Try Calculator →
NLR (Neutrophil-to-Lymphocyte Ratio) Calculator

NLR (Neutrophil-to-Lymphocyte Ratio) Calculator

Calculate NLR from CBC absolute neutrophil and lymphocyte counts. Enter ×10³/µL, cells/µL, or WBC with differential % for inflammation screening, risk bands, and PDF export.

Try Calculator →
HbA1c ↔ Average Blood Glucose Calculator

HbA1c ↔ Average Blood Glucose Calculator

Convert HbA1c (%) to estimated average glucose (eAG) and back using the ADAG formula. ADA category bands, mg/dL and mmol/L units, PDF export.

Try Calculator →
Type 2 Diabetes Risk Assessment Calculator

Type 2 Diabetes Risk Assessment Calculator

Assess type 2 diabetes risk using the Indian Diabetes Risk Score (IDRS). Enter age, waist, family history, activity, and clinical history. Low to Very High risk with PDF export.

Try Calculator →
Blood Pressure Interpreter & Risk Calculator

Blood Pressure Interpreter & Risk Calculator

Interpret blood pressure with AHA/ACC 2017 categories, color-coded gauge, overall health risk (Low/Moderate/High/Urgent), lifestyle recommendations, and emergency alert for crisis readings.

Try Calculator →