A practical algorithm to reduce false critical ECG alarms using arterial blood pressure and/or photoplethysmogram waveforms

There has been a high rate of false alarms for the critical electrocardiogram (ECG) arrhythmia events in intensive care units (ICUs), from which the ‘crying-wolf’ syndrome may be resulted and patient safety may be jeopardized. This article presents an algorithm to reduce false critical arrhythmia alarms using arterial blood pressure (ABP) and/or photoplethysmogram (PPG) waveform features. We established long duration reference alarm datasets which consist of 573 ICU waveform-alarm records (283 for development set and 290 for test set) with total length of 551 patent days. Each record has continuous recordings of ECGs, ABP and/or PPG signals and contains one or multiple critical ECG alarms. The average length of a record is 23 h. There are totally 2408 critical ECG alarms (1414 in the development set and 994 in the test set), each of which was manually annotated by experts. The algorithm extracts ABP/PPG pulse features on a beat-by-beat basis. For each pulse, five event feature indicators (EFIs), which correspond to the five critical ECG alarms, are generated. At the time of a critical ECG alarm, the corresponding EFI values of those ABP/PPG pulses around the alarm time are checked for adjudicating (accept/reject) this alarm. The algorithm retains all (100%) the true alarms and significantly reduces the false alarms. Our results suggest that the algorithm is effective and practical on account of its real-time dynamic processing mechanism and computational efficiency.

[1]  Wei Zong,et al.  Reduction of false critical ECG alarms using waveform features of arterial blood pressure and/or photoplethysmogram signals , 2015, 2015 Computing in Cardiology Conference (CinC).

[2]  Qiao Li,et al.  The PhysioNet/Computing in Cardiology Challenge 2015: Reducing false arrhythmia alarms in the ICU , 2015, 2015 Computing in Cardiology Conference (CinC).

[3]  B. Drew,et al.  Insights into the Problem of Alarm Fatigue with Physiologic Monitor Devices: A Comprehensive Observational Study of Consecutive Intensive Care Unit Patients , 2014, PloS one.

[4]  Deborah Whalen,et al.  Novel Approach to Cardiac Alarm Management on Telemetry Units , 2014, The Journal of cardiovascular nursing.

[5]  T. H. Kyaw,et al.  Multiparameter Intelligent Monitoring in Intensive Care II: A public-access intensive care unit database* , 2011, Critical care medicine.

[6]  Laura Wallis,et al.  Alarm Fatigue Linked to Patient's Death , 2010 .

[7]  Mohammed Saeed,et al.  Reducing false alarm rates for critical arrhythmias using the arterial blood pressure waveform , 2008, J. Biomed. Informatics.

[8]  R.G. Mark,et al.  A signal abnormality index for arterial blood pressure waveforms , 2006, 2006 Computers in Cardiology.

[9]  M. Imhoff,et al.  Alarm Algorithms in Critical Care Monitoring , 2006, Anesthesia and analgesia.

[10]  R. G. Mark,et al.  Reduction of false arterial blood pressure alarms using signal quality assessement and relationships between the electrocardiogram and arterial blood pressure , 2004, Medical and Biological Engineering and Computing.

[11]  M. Chambrin,et al.  Multicentric study of monitoring alarms in the adult intensive care unit (ICU): a descriptive analysis , 1999, Intensive Care Medicine.

[12]  C. Tsien,et al.  Poor prognosis for existing monitors in the intensive care unit. , 1997, Critical care medicine.

[13]  S. Lawless Crying wolf: False alarms in a pediatric intensive care unit , 1994, Critical care medicine.

[14]  Julie Scott,et al.  Simple Solutions for Improving Patient Safety In Cardiac Monitoring — Eight Critical Elements to Monitor Alarm Competency FOUNDATION HTSI , 2014 .

[15]  K. Graham,et al.  Monitor alarm fatigue: standardizing use of physiological monitors and decreasing nuisance alarms. , 2010, American journal of critical care : an official publication, American Association of Critical-Care Nurses.

[16]  Yadin David,et al.  A national online survey on the effectiveness of clinical alarms. , 2008, American journal of critical care : an official publication, American Association of Critical-Care Nurses.

[17]  Bjug Borgundvaag,et al.  ALARMED: adverse events in low-risk patients with chest pain receiving continuous electrocardiographic monitoring in the emergency department. A pilot study. , 2006, The American journal of emergency medicine.

[18]  Roger G. Mark,et al.  An open-source algorithm to detect onset of arterial blood pressure pulses , 2003, Computers in Cardiology, 2003.

[19]  R G Mark,et al.  MIMIC II: a massive temporal ICU patient database to support research in intelligent patient monitoring , 2002, Computers in Cardiology.

[20]  Jeffrey M. Hausdorff,et al.  Physionet: Components of a New Research Resource for Complex Physiologic Signals". Circu-lation Vol , 2000 .

[21]  C. Goodman Association for the Advancement of Medical Instrumentation , 1988 .