Speech recognition for the anaesthesia record during crisis scenarios

INTRODUCTION This article describes the evaluation of a prototype speech-input interface to an anaesthesia patient record, conducted in a full-scale anaesthesia simulator involving six doctor-nurse anaesthetist teams. OBJECTIVE The aims of the experiment were, first, to assess the potential advantages and disadvantages of a vocal interface compared to the traditional touch-screen and keyboard interface to an electronic anaesthesia record during crisis situations; second, to assess the usability in a realistic work environment of some speech input strategies (hands-free vocal interface activated by a keyword; combination of command and free text modes); finally, to quantify some of the gains that could be provided by the speech input modality. METHODS Six anaesthesia teams composed of one doctor and one nurse were each confronted with two crisis scenarios in a full-scale anaesthesia simulator. Each team would fill in the anaesthesia record, in one session using only the traditional touch-screen and keyboard interface while in the other session they could also use the speech input interface. Audio-video recordings of the sessions were subsequently analysed and additional subjective data were gathered from a questionnaire. Analysis of data was made by a method inspired by queuing theory in order to compare the delays associated to the two interfaces and to quantify the workload inherent to the memorization of items to be entered into the anaesthesia record. RESULTS The experiment showed on the one hand that the traditional touch-screen and keyboard interface imposes a steadily increasing mental workload in terms of items to keep in memory until there is time to update the anaesthesia record, and on the other hand that the speech input interface will allow anaesthetists to enter medications and observations almost simultaneously when they are given or made. The tested speech input strategies were successful, even with the ambient noise. Speaking to the system while working appeared feasible, although improvements in speech recognition rates are needed. CONCLUSION A vocal interface leads to shorter time between the events to be registered and the actual registration in the electronic anaesthesia record; therefore, this type of interface would likely lead to greater accuracy of items recorded and a reduction of mental workload associated with memorization of events to be registered, especially during time constrained situations. At the same time, current speech recognition technology and speech interfaces require user training and user dedication if a speech interface is to be used successfully.

[1]  Clare-Marie Karat,et al.  Hands-Free, Speech-Based Navigation During Dictation: Difficulties, Consequences, and Solutions , 2003, Hum. Comput. Interact..

[2]  Alexandre Alapetite Impact of noise and other factors on speech recognition in anaesthesia , 2008, Int. J. Medical Informatics.

[3]  Alexandre Alapetite,et al.  Introducing vocal modality into electronic anaesthesia record systems: possible effects on work practices in the operating room , 2005 .

[4]  C B DeVos,et al.  An evaluation of an automated anesthesia record keeping system. , 1991, Biomedical sciences instrumentation.

[5]  Lawrence M. Fagan,et al.  Research Paper: A Continuous-speech Interface to a Decision Support System: II. An Evaluation Using a Wizard-of-Oz Experimental Paradigm , 1995, J. Am. Medical Informatics Assoc..

[6]  J Sauer,et al.  Prospective memory: a secondary task with promise. , 2000, Applied ergonomics.

[7]  Lawrence M. Fagan,et al.  A continuous-speech interface to a decision support system: I. Techniques to accommodate for misrecognized input. , 1995, Journal of the American Medical Informatics Association : JAMIA.

[8]  Yoshimitsu Sanjo,et al.  Ergonomic Automated Anesthesia Recordkeeper using a Mobile Touch Screen with Voice Navigation , 2004, Journal of Clinical Monitoring and Computing.

[9]  Anita Burgun-Parenthoine,et al.  Automatic concept extraction from spoken medical reports , 2003, Int. J. Medical Informatics.

[10]  Yili Liu,et al.  Queueing network modeling of human performance of concurrent spatial and verbal tasks , 1994, IEEE Trans. Syst. Man Cybern. Part A.

[11]  Günter Rau,et al.  A Case Study in Designing Speech Interaction with a Patient Monitor , 2004, Journal of Clinical Monitoring and Computing.

[12]  Doris Ostergaard National Medical Simulation training program in Denmark. , 2004, Critical care medicine.

[13]  Igor Kozine Simulation of human performance in time-pressured scenarios , 2007 .

[14]  Vimla L. Patel,et al.  Cognitive and usability engineering methods for the evaluation of clinical information systems , 2004, J. Biomed. Informatics.

[15]  Christian Lovis,et al.  Power of expression in the electronic patient record: structured data or narrative text? , 2000, Int. J. Medical Informatics.

[16]  N. Cowan The magical number 4 in short-term memory: A reconsideration of mental storage capacity , 2001, Behavioral and Brain Sciences.

[17]  D. Gaba,et al.  A comprehensive anesthesia simulation environment: re-creating the operating room for research and training. , 1988, Anesthesiology.