STOP-BANG Score Calculator

Screens for obstructive sleep apnoea risk using eight yes/no items covering Snoring, Tiredness, Observed apnoeas, blood Pressure, BMI, Age, Neck circumference, and Gender. Widely used in preoperative anaesthetic assessment and sleep medicine clinics.

Clinical Tool· Anaesthesia· Sleep Medicine· Primary Care

Calculate STOP-BANG Score

Answer all eight questions below. Each “Yes” scores 1 point. The total score ranges from 0 to 8 and stratifies risk into low, intermediate, and high categories for obstructive sleep apnoea (OSA).

STOP — Subjective & Clinical

S — Snoring Do you snore loudly (louder than talking, or loud enough to be heard through closed doors)?

T — Tired Do you often feel tired, fatigued, or sleepy during the daytime?

O — Observed Apnoeas Has anyone observed you stop breathing or choke/gasp during sleep?

P — Blood Pressure Do you have or are you being treated for high blood pressure?

BANG — Objective & Anthropometric

B — BMI > 35 kg/m² Body Mass Index greater than 35 kg/m²

A — Age > 50 Patient age over 50 years

N — Neck Circumference Neck circumference > 40 cm (≈ 16 inches)

G — Gender Biological sex at birth

Low (0–2) Intermediate (3–4) High (5–8)

Important

The STOP-BANG questionnaire is a screening tool for obstructive sleep apnoea — it does not establish a diagnosis. A positive screen suggests the need for further evaluation, typically with polysomnography or home sleep apnoea testing. Clinical context, including symptom burden and perioperative risk, should guide the urgency of formal testing.

Understanding the STOP-BANG Score

The STOP-BANG questionnaire was developed by Dr Frances Chung and colleagues at the University of Toronto in 2008. It was originally designed as a concise, easy-to-administer screening tool for obstructive sleep apnoea (OSA) in the preoperative setting. The acronym combines four subjective symptom questions (STOP) with four objective or demographic criteria (BANG).

OSA affects an estimated 10–30% of adults worldwide, yet a large proportion of cases remain undiagnosed. Unrecognised OSA carries significant perioperative risk — including difficult intubation, postoperative respiratory complications, and sensitivity to opioids and sedatives. Beyond the perioperative context, untreated OSA is independently associated with hypertension, cardiovascular disease, stroke, metabolic syndrome, and motor vehicle accidents.

The STOP-BANG Mnemonic

S — Snoring (loud)

T — Tired (daytime sleepiness)

O — Observed apnoeas

P — Pressure (hypertension)

B — BMI > 35 kg/m²

A — Age > 50 years

N — Neck > 40 cm

G — Gender (male)

Scoring

Each “Yes” = 1 point. Total range: 0–8.

The score is additive — there are no weighted components. The simplicity of binary yes/no answers and the use of easily measurable parameters (BMI, neck circumference, age, sex) make it feasible for bedside administration, pre-admission clinic questionnaires, and primary care screening.

Administration typically takes less than 2 minutes and requires no specialised equipment beyond a tape measure for neck circumference.

Key distinction: The STOP-BANG questionnaire is a screening tool with high sensitivity — it is designed to minimise missed cases of OSA. This means it intentionally accepts a higher false-positive rate. A high score warrants confirmatory testing with polysomnography, not immediate treatment initiation.

Interpretation & Risk Categories

Risk categories are based on the original validation data and subsequent large-scale studies. Higher scores correlate with increasing probability and severity of OSA as measured by the apnoea-hypopnoea index (AHI) on polysomnography.

Score	Risk Category	OSA Probability	Suggested Action
0–2	Low Risk	Low probability of moderate-to-severe OSA	Reassurance; no routine sleep study unless symptoms warrant
3–4	Intermediate Risk	Increased probability of OSA	Consider sleep study; apply perioperative precautions if surgical patient
5–8	High Risk	High probability of moderate-to-severe OSA	Strongly recommend polysomnography; perioperative OSA precautions essential

Predicting OSA Severity

Beyond the three-tier classification, the STOP-BANG score correlates with OSA severity as defined by the AHI:

Score 0–2: Sensitivity for detecting any OSA (AHI ≥ 5) is limited in this range. However, the negative predictive value is high — a score of 0–2 is useful for ruling out moderate-to-severe OSA with reasonable confidence.

Score 3–4: Intermediate zone. Sensitivity for moderate OSA (AHI ≥ 15) ranges from approximately 74–93% depending on the study population. Further risk stratification can be achieved by examining which specific BANG criteria are positive (see below).

Score 5–8: Sensitivity for moderate-to-severe OSA (AHI ≥ 15) exceeds 90% in most validation studies. A score of 5–8 is associated with an approximately 60% probability of having moderate-to-severe OSA on polysomnography.

Clinical Pearl

For patients with intermediate scores (3–4), further stratification is possible: if ≥ 2 of the four BANG criteria are positive (BMI > 35, Age > 50, Neck > 40 cm, male Gender), the probability of moderate-to-severe OSA increases substantially — approaching that of the high-risk group. This “STOP-BANG with BANG refinement” can guide the urgency of referral.

Clinical Details & Perioperative Implications

Obstructive sleep apnoea has far-reaching clinical consequences beyond daytime sleepiness. The STOP-BANG score is most commonly applied in two settings: preoperative anaesthetic assessment and primary care or sleep medicine screening. The following sections detail key clinical considerations.

Perioperative Risk in Undiagnosed OSA

Patients with undiagnosed or untreated OSA face a significantly increased risk of perioperative complications. The collapsible upper airway that characterises OSA makes these patients vulnerable at multiple points during the surgical journey.

Airway management: OSA is associated with difficult mask ventilation and difficult intubation. Anatomical features contributing to OSA (retrognathia, large tongue base, short thyromental distance, increased neck circumference) overlap with predictors of difficult airway management.
Opioid sensitivity: OSA patients have heightened sensitivity to opioid-induced respiratory depression. Even standard doses of postoperative opioids can precipitate prolonged apnoeas and desaturation.
Postoperative respiratory events: Oxygen desaturation, re-intubation, ICU transfer, and cardiac arrhythmias are all more frequent in OSA patients, particularly after upper abdominal and airway surgery.
Postoperative monitoring: High-risk patients may require continuous pulse oximetry, supplemental oxygen, CPAP continuation, and avoidance of supine positioning postoperatively.

Society of Anesthesia and Sleep Medicine (SASM) guidelines recommend screening all surgical patients with STOP-BANG and implementing OSA-specific perioperative protocols for those who screen positive.

Cardiovascular Consequences of OSA

OSA is an independent risk factor for several cardiovascular conditions. The intermittent hypoxia, intrathoracic pressure swings, and sympathetic surges associated with repetitive apnoeic episodes drive a cascade of pathophysiological changes including endothelial dysfunction, systemic inflammation, and oxidative stress.

Hypertension: OSA is the most common identifiable cause of secondary or resistant hypertension. Treatment with CPAP has been shown to modestly reduce blood pressure, particularly in patients with severe OSA and good CPAP adherence.
Atrial fibrillation: OSA is associated with a 2–4 fold increased risk of AF and higher recurrence rates after cardioversion or ablation. Screening for OSA is recommended in AF management guidelines.
Heart failure: Both OSA and central sleep apnoea are prevalent in patients with heart failure. OSA may worsen cardiac function through increased afterload and sympathetic activation.
Stroke: Moderate-to-severe OSA approximately doubles stroke risk, and OSA is highly prevalent (60–80%) among stroke survivors.

These associations underscore the importance of screening beyond the perioperative setting — STOP-BANG can be applied in cardiology, hypertension, and stroke clinics.

Confirmatory Diagnosis — Polysomnography & HSAT

A positive STOP-BANG screen should be followed by objective testing to confirm and grade OSA severity. Two main testing modalities are available:

In-laboratory polysomnography (PSG): The reference standard. Records EEG, EOG, EMG, airflow, respiratory effort, oxygen saturation, ECG, body position, and limb movements. Provides the AHI, respiratory disturbance index (RDI), and data on sleep architecture. Recommended when there is suspicion of comorbid sleep disorders (central sleep apnoea, periodic limb movement disorder, narcolepsy) or when HSAT is inconclusive.
Home sleep apnoea testing (HSAT): A simplified, portable test typically measuring airflow, respiratory effort, and oxygen saturation. Appropriate for patients with a high pretest probability of moderate-to-severe OSA (i.e., STOP-BANG ≥ 5) without significant comorbidities. HSAT may underestimate severity because total sleep time is estimated rather than measured, and it cannot identify central apnoeas reliably.

OSA severity is graded by the AHI: mild (5–14 events/hour), moderate (15–29 events/hour), and severe (≥ 30 events/hour). Treatment decisions incorporate both AHI and symptom burden.

Treatment Overview — CPAP, Oral Appliances & Beyond

Treatment of OSA is guided by severity, symptom burden, patient preference, and comorbidities. CPAP (continuous positive airway pressure) remains the first-line treatment for moderate-to-severe OSA and is the standard of care in the perioperative setting for known OSA patients.

CPAP: Delivers positive pressure via a nasal or full-face mask, acting as a pneumatic splint for the upper airway. Highly effective when used consistently. Adherence remains the primary challenge — approximately 50% of patients discontinue CPAP within 1–3 years.
Mandibular advancement devices (MAD): Custom-fitted oral appliances that protrude the mandible forward, increasing the retroglossal airway space. Recommended for mild-to-moderate OSA or for patients who cannot tolerate CPAP. Less effective than CPAP for severe disease.
Positional therapy: Effective in patients with predominantly supine-dependent OSA. Devices or techniques to maintain lateral sleeping position can reduce AHI significantly in selected patients.
Surgical options: Uvulopalatopharyngoplasty (UPPP), maxillomandibular advancement, and hypoglossal nerve stimulation are options for selected patients who fail conservative therapy. Bariatric surgery may be considered when severe obesity is the primary driver of OSA.
Weight management: Weight loss of ≥ 10% can substantially reduce AHI and may resolve mild OSA entirely. This is a key adjunctive treatment in overweight and obese patients.

STOP-BANG vs Other Screening Tools

Several OSA screening questionnaires exist. The STOP-BANG has emerged as the most widely validated and recommended, but understanding alternatives helps contextualise its strengths and limitations.

STOP questionnaire: The four-question precursor to STOP-BANG (Snoring, Tiredness, Observed apnoeas, Pressure). Simpler to administer but substantially less sensitive than STOP-BANG, particularly for moderate-to-severe OSA.
Epworth Sleepiness Scale (ESS): An eight-item questionnaire assessing daytime sleepiness (not OSA specifically). The ESS measures symptom burden but has poor sensitivity and specificity for predicting OSA on polysomnography. It is complementary to STOP-BANG — a high STOP-BANG with a high ESS suggests both high OSA probability and significant symptom impact.
Berlin Questionnaire: A 10-item questionnaire categorising patients by snoring behaviour, daytime somnolence, and hypertension/obesity. More complex to administer and score than STOP-BANG. Comparable sensitivity but lower specificity in most head-to-head comparisons.
NoSAS Score: A newer scoring system (Neck circumference, Obesity, Snoring, Age, Sex) that uses weighted components. Shows promising discrimination in some populations but has less validation data than STOP-BANG, particularly in the perioperative setting.

Current SASM and ASA guidelines endorse STOP-BANG as the preferred screening tool for the perioperative context due to its combination of high sensitivity, ease of administration, and extensive validation.

Bedside Approach

In the pre-admission clinic, administer STOP-BANG to every surgical patient. For those scoring ≥ 3, assess whether formal sleep study is feasible before surgery. If surgery cannot be delayed, implement perioperative OSA precautions: minimise opioids, use multimodal analgesia, consider regional anaesthesia, ensure postoperative monitoring, and apply CPAP if available.

Special Populations & Considerations

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Women & OSA

OSA is historically underdiagnosed in women. The STOP-BANG assigns 1 point for male sex, reflecting the higher population prevalence in men. However, postmenopausal women have OSA rates approaching those of men, and women may present with atypical symptoms — insomnia, morning headaches, mood disturbance, and fatigue rather than classic loud snoring and witnessed apnoeas. The tool may underestimate risk in women, particularly postmenopausal women.

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Paediatric Patients

The STOP-BANG questionnaire is validated only in adults (≥ 18 years) and should not be applied to children or adolescents. Paediatric OSA has a different pathophysiology (primarily adenotonsillar hypertrophy) and different risk factors. The Pediatric Sleep Questionnaire (PSQ) is the recommended screening tool for children. Diagnostic criteria and treatment thresholds also differ in the paediatric population.

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Asian Populations

Craniofacial anatomy influences OSA risk independently of BMI. Asian populations may develop clinically significant OSA at lower BMI thresholds due to differences in mandibular and midface anatomy. The BMI > 35 criterion in STOP-BANG may miss a substantial proportion of OSA cases in Asian patients. Some studies suggest lowering the BMI threshold to 30 kg/m² or incorporating additional craniofacial parameters for these populations.

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Elderly Patients

OSA prevalence increases with age, and the STOP-BANG assigns 1 point for age > 50. However, in elderly populations (≥ 70 years), most patients will score at least 2–3 points on demographic criteria alone (age, often hypertension, possibly male). This can reduce the discriminatory power of the tool. The clinical significance of mild OSA in the elderly is debated, and treatment decisions should weigh symptom burden and comorbidity rather than AHI alone.

Bariatric surgery patients: OSA prevalence in patients presenting for bariatric surgery ranges from 60–90%. Virtually all bariatric surgery candidates will score ≥ 3 on STOP-BANG, limiting the tool’s discriminatory value in this specific population. Most bariatric surgery centres require preoperative polysomnography regardless of screening score, and perioperative CPAP protocols are standard.

Common Pitfalls & Limitations

Treating the score as a diagnosis rather than a screen

The most common error is interpreting a high STOP-BANG score as equivalent to a diagnosis of OSA. STOP-BANG is a screening instrument with intentionally high sensitivity — it is designed to cast a wide net and minimise false negatives. The trade-off is a significant false-positive rate: a substantial proportion of patients scoring 3–4 will have a normal AHI on polysomnography.

A positive screen should prompt further evaluation (sleep study), not automatic labelling of the patient as having OSA. Conversely, in the perioperative setting, a positive screen can and should trigger precautionary measures even before formal diagnosis, because the consequences of unrecognised OSA during anaesthesia are potentially serious.

Low specificity in certain demographics

Because three of the eight criteria are demographic (age > 50, male sex, BMI > 35), certain patient groups will automatically score 2–3 points without any sleep-related symptoms. An overweight male patient over 50 with treated hypertension scores 4 by demographics alone — placing him in the intermediate-risk category regardless of whether he has any sleep-related symptoms.

This demographic loading reduces specificity in older, male, and obese populations. The BANG refinement (counting the number of positive BANG criteria in intermediate scorers) can help improve specificity. Additionally, clinicians should always weigh the STOP components (symptom-based) more heavily when making clinical decisions about referral urgency — a patient with witnessed apnoeas and excessive daytime sleepiness warrants more urgent evaluation than an asymptomatic patient scoring on demographics alone.

Self-reported symptoms may be unreliable

Four of the eight STOP-BANG items rely on patient self-report (snoring, tiredness, observed apnoeas, hypertension). Patients who sleep alone may be unaware of loud snoring or apnoeic episodes. Cultural factors, health literacy, and the tendency to minimise symptoms can all affect accuracy. Daytime tiredness is non-specific and overlaps with many other conditions including depression, anaemia, hypothyroidism, and poor sleep hygiene.

Where possible, corroborate the snoring and observed apnoea items with a bed partner or family member. If the patient sleeps alone and is unsure, the clinician should consider this an uncertain rather than negative response and exercise clinical judgement about the overall risk profile.

Not applying perioperative precautions despite a positive screen

A positive STOP-BANG score is only clinically useful if it changes management. Screening patients before surgery but failing to implement OSA-specific precautions negates the benefit of screening. Common failures include: not communicating the result to the anaesthetist, not adjusting the analgesic plan, not arranging postoperative monitoring, and not ensuring CPAP availability for patients with known OSA.

Perioperative OSA protocols should include: preoperative discussion of airway management strategy, use of multimodal analgesia to minimise opioids, regional or neuraxial anaesthesia where appropriate, extubation when fully awake, avoidance of supine positioning in recovery, continuous pulse oximetry for at least the first postoperative night, and CPAP application for patients with diagnosed OSA or high STOP-BANG scores.

Overlooking OSA in women and non-obese patients

The STOP-BANG score assigns points for male sex and BMI > 35, which can lead to lower scores in women and non-obese patients who nevertheless have clinically significant OSA. Approximately 6% of women and a significant proportion of lean individuals with unfavourable craniofacial anatomy have moderate-to-severe OSA that may be missed by the questionnaire.

Clinicians should maintain a low threshold for further evaluation when patients present with symptoms suggestive of OSA — particularly witnessed apnoeas, choking awakenings, or refractory hypertension — even if the STOP-BANG score falls in the low-risk range. No screening tool is perfect, and clinical suspicion should always take precedence over a numerical score.

Quick Reference Summary

0–8 Score Range (8 binary items)

>90% Sensitivity at Score ≥ 3 for Moderate-Severe OSA

10–30% Estimated Adult OSA Prevalence

< 2 min Typical Administration Time

Score	Risk	Clinical Action
0–2	Low	No routine sleep testing needed unless symptomatic; standard perioperative care
3–4	Intermediate	Consider sleep study referral; apply perioperative OSA precautions; refine risk with BANG criteria count
5–8	High	Strongly recommend polysomnography; full perioperative OSA protocol; opioid-sparing analgesia; postop monitoring

The Golden Rule

STOP-BANG is a screening tool — not a diagnostic test. A positive score identifies patients who need further evaluation with polysomnography and, in the perioperative setting, who need OSA-specific precautions now, even before formal diagnosis. Treat the score as a prompt for action, not a label.

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

Chung F, Yegneswaran B, Liao P, et al. STOP questionnaire: a tool to screen patients for obstructive sleep apnea. Anesthesiology. 2008;108(5):812–821. DOI: 10.1097/ALN.0b013e31816d83e4
Chung F, Subramanyam R, Liao P, et al. High STOP-Bang score indicates a high probability of obstructive sleep apnoea. Br J Anaesth. 2012;108(5):768–775. DOI: 10.1093/bja/aes022
Nagappa M, Liao P, Wong J, et al. Validation of the STOP-Bang questionnaire as a screening tool for obstructive sleep apnea among different populations: a systematic review and meta-analysis. PLoS One. 2015;10(12):e0143697. DOI: 10.1371/journal.pone.0143697
Chung F, Abdullah HR, Liao P. STOP-Bang Questionnaire: a practical approach to screening for obstructive sleep apnea. Chest. 2016;149(3):631–638. DOI: 10.1378/chest.15-0903
Chung F, Memtsoudis SG, Ramachandran SK, et al. Society of Anesthesia and Sleep Medicine guidelines on preoperative screening and assessment of adult patients with obstructive sleep apnea. Anesth Analg. 2016;123(2):452–473. DOI: 10.1213/ANE.0000000000001416
Benjafield AV, Ayas NT, Eastwood PR, et al. Estimation of the global prevalence and burden of obstructive sleep apnoea: a literature-based analysis. Lancet Respir Med. 2019;7(8):687–698. DOI: 10.1016/S2213-2600(19)30198-5
Kapur VK, Auckley DH, Chowdhuri S, et al. Clinical practice guideline for diagnostic testing for adult obstructive sleep apnea: an American Academy of Sleep Medicine clinical practice guideline. J Clin Sleep Med. 2017;13(3):479–504. DOI: 10.5664/jcsm.6506
Memtsoudis SG, Cozowicz C, Nagappa M, et al. Society of Anesthesia and Sleep Medicine guideline on intraoperative management of adult patients with obstructive sleep apnea. Anesth Analg. 2018;127(4):967–987. DOI: 10.1213/ANE.0000000000003434
Senaratna CV, Perret JL, Lodge CJ, et al. Prevalence of obstructive sleep apnea in the general population: a systematic review. Sleep Med Rev. 2017;34:70–81. DOI: 10.1016/j.smrv.2016.07.002