TADAA: Towards Automated Detection of Anaesthetic Activity

B. R. Houliston; D. T. Parry; A. F. Merry

doi:10.3414/ME11-02-0001

Methods of Information in Medicine, Inhaltsverzeichnis

Methods Inf Med 2011; 50(05): 464-471
DOI: 10.3414/ME11-02-0001

Special Topic – Original Articles

Schattauer GmbH

TADAA: Towards Automated Detection of Anaesthetic Activity

B. R. Houliston

¹AURA Laboratory, School of Computing & Mathematical Sciences, Auckland University of Technology, Auckland, New Zealand

,

D. T. Parry

¹AURA Laboratory, School of Computing & Mathematical Sciences, Auckland University of Technology, Auckland, New Zealand

,

A. F. Merry

²Department of Anaesthesiology, Faculty of Medicine, University of Auckland, Auckland, New Zealand

› Institutsangaben

Abstract

Summary

Background: Task analysis is a valuable research method for better understanding the activity of anaesthetists in the operating room (OR), providing evidence for designing and evaluating improvements to systems and processes. It may also assist in identifying potential error paths to adverse events, ultimately improving patient safety. Human observers are the current ‘gold standard’ for capturing task data, but they are expensive and have cognitive limitations.

Objectives: Towards Automated Detection of Anaesthetic Activity (TADAA) – aims to produce an automated task analysis system, employing Radio Frequency Identification (RFID) technology to capture anaesthetists’ location, orientation and stance (LOS). This is the first stage in a scheme for automatic detection of activity.

Methods: Active RFID tags were attached to anaesthetists and various objects in a high fidelity OR simulator, and anesthetic procedures performed. The anaesthetists’ LOSs were calculated using received signal strength (RSS) measurements combined with machine learning tools including Self-Organizing Maps (SOMs). These LOSs were compared to those derived from video recordings.

Results: SOM clustering was effective at determining anaesthetists’ LOS from RSS data for each procedure. However cross-procedure comparison was less reliable, probably because of changes in the environment.

Conclusions: Active RFID tags provide potentially useful information on LOS at a low cost and with minimal impact on the work environment. Machine learning techniques may be employed to handle the variable nature of RFID’s radio signals. Work on mapping LOS data to activities will involve integration with other sensors and task analysis techniques.

Keywords

Anesthesiology - task performance and analysis - automated pattern recognition - radio frequency identification device

Volltext

Referenzen

References
1 Reason J. Human error: models and management. BMJ 2000; 320 7237 768-770.
2 Sexton JB, Thomas EJ, Helmreich RL. Error, stress, and teamwork in medicine and aviation: cross sectional surveys. BMJ 2000; 320 7237 745-749.
3 Cooper JB, Newbower RS, Long CD, McPeek B. Preventable anesthesia mishaps: a study of human factors*. Quality and Safety in Health Care 2002; 11 (03) 277-282.
4 Davis P, Lay-Yee R, Briant R, Ali W, Scott A, Schug S. Adverse events in New Zealand public hospitals II: preventability and clinical context. New Zealand Medical Journal 2003 116 (1183)
5 Weinger MB, Herndon OW, Zornow MH, Paulus MP, Gaba DM, Dallen LT. An Objective Methodology for Task Analysis and Workload Assessment in Anaesthesia Providers. Anesthesiology 1994; 80 (01) 77-92.
6 Shojania KG, Duncan BW, McDonald KM, Wachter RM. Safe but Sound: Patient Safety Meets Evidence-Based Medicine. JAMA 2002; 288 (04) 508-513.
7 Aitkenhead AR, Smith G, Rowbotham DJ. Textbook of Anaesthesia. Fifth ed. Elsevier Limited; 2007
8 Manser T, Dieckmann P, Wehner T, Rall M. Comparison of anaesthetists’ activity patterns in the operating room and during simulation. Ergonomics 2007; 50 (02) 246-260.
9 Slagle J, Weinger MB, Dinh MTT, Brumer VV, Williams K. Assessment of the Intrarater and Interrater Reliability of an Established Clinical Task Analysis Methodology. Anesthesiology 2002; 96 (05) 1129-1139.
10 Weinger MB, Gonzales DC, Slagle J, Syeed M. Video capture of clinical care to enhance patient safety. Quality and Safety in Health Care 2004; 13 (02) 136-144.
11 Phipps D, Meakin GH, Beatty PCW, Nsoedo C, Parker D. Human factors in anaesthetic practice: insights from a task analysis. British Journal of Anaesthesia 2008; 100 (03) 333-343.
12 Lane R, Stanton NA, Harrison D. Applying hierarchical task analysis to medication administration errors. Applied Ergonomics 2006; 37 (05) 669-679.
13 Alapetite A. Speech recognition for the anaesthesia record during crisis scenarios. Int J Med Inform 2008; 77: 448-460.
14 Fishkin KP, Consolvo S, Rode J, Ross B, Smith I, Souter K. editors. Ubiquitous Computing Support for Skills Assessment in Medical School. International Workshop on Ubiquitous Computing for Pervasive Healthcare Applications 2004. Nottingham, England: ACM Press; 2004
15 Reicher J, Reicher D, Reicher M. Use of Radio Frequency Identification (RFID) Tags in Bedside Monitoring of Endotracheal Tube Position. Journal of Clinical Monitoring and Computing 2007; 21 (03) 155-158.
16 Agarwal S, Joshi A, Finin T, Yesha Y, Ganous T. A Pervasive Computing System for the Operating Room of the Future. Mobile Networks and Applications 2007; 12: 215-228.
17 Merry A, Webster C, Mathew D. A New, Safety-Oriented, Integrated Drug Administration and Automated Anesthesia Record System. Anesthesia & Analgesia 2001; 93: 385-390.
18 Bacheldor B. Rehab Center Monitors With Ultra-wide Band. 2008 (cited September 1, 2008). Available from: www.rfidjournal.com
19 Boginski V, Mun IK, Wu Y, Mason KP, Zhang C. Simulation and Analysis of Hospital Operations and Resource Utilization Using RFID Data. International Conference on RFID; Grapevine, Texas: IEEE; 2007
20 Bravo J, Hervas R, Fuentes C, Chavira G, Nava SW. Tagging for Nursing Care. Second International Conference on Pervasive Computing Technologies for Healthcare; Tampere, Finland: IEEE; 2008
21 Mackenzie CF, Xiao Y. Video techniques and data compared with observation in emergency trauma care. Journal of Quality and Safety in Health Care 2003; 12: 51-57.
22 Ince NF, Min C-H, Tewfik AH. A Feature Combination Approach for the Detection of Early Morning Bathroom Activities with Wireless Sensors. First International Workshop on Systems and Networking Support for Healthcare and Assisted Living Environments; San Juan, Puerto Rico, June 11, 2007. ACM; 2007
23 Khoussainova N, Balazinska M, Suciu D. Probabilistic RFID Data Management:. University of Washington; Seattle;: 2007
24 Logan B, Healey J, Philipose M, Tapia EM, Intille S. editors. A Long-Term Evaluation of Sensing Modalities for Activity Recognition. Ninth International Conference on Ubiquitous Computing;; Innsbruck, Austria, 2007
25 Neild I, Bowman P, Heatley D. Sensor Networks in Telecare. Fourth Workshop on Embedded Networked Sensors; Cork, Ireland, June 25-26, 2007. : ACM Press; 2007
26 Wu J, Osuntogun A, Choudhury T, Philipose M, Rehg JM. A Scalable Approach to Activity Recognition based on Object Use. IEEE 11th International Conference on Computer Vision. Rio de Janeiro, Brazil: IEEE; 2007
27 Francis Q, Roger E, Thurmon L. As go the feet...: on the estimation of attentional focus from stance. Proceedings of the 10th international conference on Multimodal interfaces. Chania, Crete, Greece: ACM; 2008
28 Want R. An Introduction to RFID Technology. IEEE Pervasive Computing 2006; 5 (01) 25-33.
29 Greengard S. A Healthy Dose of RFID. (Cited September 8, 2004). Available from: www.rfidjournal.com
30 Sheng QZ, Li X, Zeadally S. Enabling Next-Generation RFID Applications: Solutions and Challenges. IEEE Computer 2008; 41 (09) 21-28.
31 van der Togt R, van Lieshout EJ, Hensbroek R, Beinat E, Binnekade JM, Bakker PJM. Electromagnetic Interference From Radio Frequency Identification Inducing Potentially Hazardous Incidents in Critical Care Medical Equipment. JAMA 2008; 299 (24) 2884-2890.
32 Houliston B, Parry D, Merry A, Webster C. Interference in the operation of medical devices from the use of radio frequency identification technology. New Zealand Medical Journal 2009; 122 1297 9-16.
33 Seidman SJ, Brockman R, Lewis BM, Guag J, Shein MJ, Clement WJ. et al. In vitro tests reveal sample radiofrequency identification readers inducing clinically significant electromagnetic interference to implantable pacemakers and implantable cardioverterdefibrillators. HeartRhythm 2010; 7 (01) 99-107.
34 Houliston B. Integrating RFID Technology into a Drug Administration System. Bulletin of Applied Computing and Information Technology 2005; 3 (1). ISSN 1176-4120. Retrieved July 26, 2011 from http://www.naccq.ac.nz/bacit/0301/2005Houliston_RFID.htm
35 Bacheldor B. RFID Tag Built To Survive Gamma Rays. 2006 (cited September 1, 2008). Available from: www.rfidjournal.com
36 Sokol B, Shah S. RFID in Healthcare. 2004 (cited Oct. 30, 2004). Available from: www.rfidjournal.com
37 Swedberg C. Tough RFID Tag Strikes Oil. 2008 (cited September 1, 2008). Available from: www.rfidjournal.com
38 Bensky A. Radio Propagation. In: Fette BA, Aiello R, Chandra P, Dobkin DM, Bensky A, Miron D. et al., editors. RF & Wireless Technologies. Elsevier;; 2008
39 Maarten W, Martin K, Widyawan W. Adaptive motion model for a smart phone based opportunistic localization system. Proceedings of the 2nd international conference on Mobile entity localization and tracking in GPS-less environments. Orlando, FL, USA: Springer-Verlag; 2009
40 Hightower J, Borriello G, Want R. SpotON: An Indoor 3D Location Sensing Technology Based on RF Signal Strength. University of Washington, Computer Science and Engineering 2000 Contract No.: Technical Report #2000-02-02
41 Ni LM, Liu Y, Lau YC, Patil AP. LANDMARC: Indoor Location Sensing Using Active RFID. Wireless Networks 2004; 10 (06) 701-710.
42 Kohonen T. The self-organizing map. Proceedings of the IEEE 1990; 78 (09) 1464-1480.
43 Kohonen T. Data Management by Self-Organising Maps. IEEE World Conference on Computational Intelligence; Hong Kong, June 1-6, 2008. IEEE; 2008
44 Kennedy PJ, Feingold A, Wiener EL, Hosek RS. Analysis of Tasks and Human Factors in Anesthesia for Coronary-Artery Bypass. Anesthesia and Analgesia 1976; 55 (03) 374-377.
45 Rabiner LR, Juang BH. An Introduction to Hidden Markov Models. IEEE ASSP Magazine 1986; 3 (01) 4-16.