Attention capture by own name decreases with speech compression.

Auditory stimuli that are relevant to a listener have the potential to capture focal attention even when unattended, the listener's own name being a particularly effective stimulus. We report two experiments to test the attention-capturing potential of the listener's own name in normal speech and time-compressed speech. In Experiment 1, 39 participants were tested with a visual word categorization task with uncompressed spoken names as background auditory distractors. Participants' word categorization performance was slower when hearing their own name rather than other names, and in a final test, they were faster at detecting their own name than other names. Experiment 2 used the same task paradigm, but the auditory distractors were time-compressed names. Three compression levels were tested with 25 participants in each condition. Participants' word categorization performance was again slower when hearing their own name than when hearing other names; the slowing was strongest with slight compression and weakest with intense compression. Personally relevant time-compressed speech has the potential to capture attention, but the degree of capture depends on the level of compression. Attention capture by time-compressed speech has practical significance and provides partial evidence for the duplex-mechanism account of auditory distraction.

Effects of Augmented Reality-Based Remote Mentoring on Task Performance and Communication: A Simulation Study in the Context of Emergency Medical Services.

Background: Augmented reality head-worn displays (HWDs) may enable efficient remote support in the prehospital environment due to their hand-free operability, their "see-what-I-see" features, and their ability to superimpose digital content over the environment. Methods: In this simulation-based randomized controlled study, a remote mentor used either a phone or HWD to instruct 23 physicians on how to insert a Multi-Lumen Access Catheter into a mannequin. In the phone condition, information could be exchanged only verbally. In the HWD condition, the mentor could additionally see the participant's first-person view and show reference images. We hypothesized that participants who received instructions via the HWD would achieve better procedural performance (lower task completion times, fewer errors advancing the catheter) and exhibit different communication patterns than participants who received instructions via phone. Results: The HWD did not significantly reduce task completion times or errors during catheter advancement. However, by analyzing the frequency of communication events with a Poisson regression, we could demonstrate that with the HWD, the mentor had to request situation reports less often (p < 0.001) but provided more instructions (p = 0.004) and more feedback (p = 0.008). As a possible consequence, participants in the HWD condition rated their workload as lower than participants who used a phone to communicate (p = 0.45). Conclusion: The study demonstrates that HWD-based telemedicine systems can be rated positively by physicians, can benefit communication, and can provide more opportunities for the detection of clinical errors.

Exploring the Effect of Head-Worn Displays on Prehospital Teamwork Using Online Simulation: A Crossover Randomized Controlled Trial.

INTRODUCTION: Prehospital teamwork occurs in dynamic environments where paramedics work together using technologies to care for patients. Despite increasing interest in using head-worn displays (HWDs) to support prehospital workers, little is known about how HWDs affect teamwork. METHODS: We tested the effect of HWDs on the team processes and patient care of paramedic trainee teams in a laboratory study using an online prehospital simulation environment, SPECTRa. In a randomized crossover design, 20 two-person teams worked in the SPECTRa laptop environment from separate physical rooms to assess and treat 2 simulated patients in 3 prehospital patient care scenarios. In each scenario, each trainee used either an HWD, a tablet computer (TAB), or no mobile device (CON) to help them monitor the vital signs of both patients. We measured team processes based around 3 themes of mutual understanding, team performance, and administered an 18-item questionnaire about teamwork and use of the devices. RESULTS: The mean number (HWD = 11; TAB = 7; P = 0.061) and duration (HWD = 1746 milliseconds; TAB = 1563 milliseconds; P = 0.504) of attention switches that teams made toward the mobile device did not differ with HWDs or TABs. However, teams switched attention between patients less with HWDs than with TABs (P = 0.026) or CON (P = 0.007) (medians: HWD = 5; TAB = 8; CON = 8). Teams communicated less when using HWDs than TABs (P = 0.017) (medians: HWD = 76; TAB = 96; CON = 83), but there were other mixed effects on communication. Team performance did not differ across device conditions on the timeliness to notice critical patient changes (P = 0.387) (medians: HWD = 244 seconds; TAB = 246 seconds; CON = 168 seconds) or to complete the scenarios (P = 0.212) (medians: HWD = 800 seconds; TAB = 913 seconds; CON = 835 seconds). Questionnaire results revealed some perceived benefits of the HWD. CONCLUSIONS: Head-worn displays may let prehospital teams monitor each other's performance more efficiently than TABs or CON, requiring less communication to maintain patient care performance with lower workload than with TABs. However, improvements in mutual understanding with HWDs compared with CON were more evident in teams' preferences than in actual behavior. Further research is needed to confirm and extend these results.

Effects of multitasking on interpreting a spearcon sequence display for monitoring multiple patients.

Spearcons are time-compressed speech phrases. When arranged in a sequence representing vital signs of multiple patients, spearcons may be more informative than conventional auditory alarms. However, multiple resource theory suggests that certain timeshared tasks might interfere with listeners' ability to understand spearcons. We tested the relative interference with spearcon identification from the following ongoing tasks: (1) manual tracking, (2) linguistic detection of spoken target words, (3) arithmetic true-false judgments, or (4) an ignored background speech control. Participants were 80 non-clinicians. The linguistic task worsened spearcon identification more than the tracking task, p < .001, and more than ignored background speech, p = .012. The arithmetic task worsened spearcon identification more than the tracking task, p < .001. The linguistic task and arithmetic task both worsened performance, p = .674. However, no ongoing task affected participants' ability to detect which patient(s) in a sequence had abnormal vital signs. Future research could investigate whether timeshared tasks affect non-speech auditory alerts.

Interruptions in healthcare: Modeling dynamic processes and effects at a team level.

Interruptions are associated with increases in medical errors amongst healthcare professionals, yet interventions to reduce interruptions have not been widely successful. While interruptions can be problematic for the interruptee, they may be necessary for the interrupter to maintain patient safety. To understand the emergent effects of interruptions within a dynamic environment, we develop a computational model that describes how nurses make decisions about interruptions and the effects those decisions have at a team level. Simulations reveal the dynamic interplay between urgency, task importance, the cost of being interrupted and team efficiency, depending on the consequences of clinical or procedural error, and shed light on the ways that the risks from interruptions can be better managed.

Evaluating enhanced pulse oximetry auditory displays for neonatal oxygen targeting: A randomized laboratory trial with clinicians and non-clinicians.

Standard pulse oximeter auditory tones do not clearly indicate departures from the target range of oxygen saturation (SpO2) of 90%-95% in preterm neonates. We tested whether acoustically enhanced tones would improve participants' ability to identify SpO2 range. Twenty-one clinicians and 23 non-clinicians used (1) standard pulse oximetry variable-pitch tones plus alarms; (2) beacon-enhanced tones without alarms in which reference tones were inserted before standard pulse tones when SpO2 was outside target range; and (3) tremolo-enhanced tones without alarms in which pulse tones were modified with tremolo when SpO2 was outside target range. For clinicians, range identification accuracies (mean (SD)) in the standard, beacon, and tremolo conditions were 52% (16%), 73% (14%) and 76% (13%) respectively, and for non-clinicians 49% (16%), 76% (13%) and 72% (14%) respectively, with enhanced conditions always significantly more accurate than standard. Acoustic enhancements to pulse oximetry clearly indicate departures from preterm neonates' target SpO2 range.

Enhanced Neonatal Pulse Oximetry Sounds for the First Minutes of Life: A Laboratory Trial.

OBJECTIVE: Auditory enhancements to the pulse oximetry tone may help clinicians detect deviations from target ranges for oxygen saturation (SpO2) and heart rate (HR). BACKGROUND: Clinical guidelines recommend target ranges for SpO2 and HR during neonatal resuscitation in the first 10 minutes after birth. The pulse oximeter currently maps HR to tone rate, and SpO2 to tone pitch. However, deviations from target ranges for SpO2 and HR are not easy to detect. METHOD: Forty-one participants were presented with 30-second simulated scenarios of an infant's SpO2 and HR levels in the first minutes after birth. Tremolo marked distinct HR ranges and formants marked distinct SpO2 ranges. Participants were randomly allocated to conditions: (a) No Enhancement control, (b) Enhanced HR Only, (c) Enhanced SpO2 Only, and (d) Enhanced Both. RESULTS: Participants in the Enhanced HR Only and Enhanced SpO2 Only conditions identified HR and SpO2 ranges, respectively, more accurately than participants in the No Enhancement condition, ps < 0.001. In the Enhanced Both condition, the tremolo enhancement of HR did not affect participants' ability to identify SpO2 range, but the formants enhancement of SpO2 may have attenuated participants' ability to identify tremolo-enhanced HR range. CONCLUSION: Tremolo and formant enhancements improve range identification for HR and SpO2, respectively, and could improve clinicians' ability to identify SpO2 and HR ranges in the first minutes after birth. APPLICATION: Enhancements to the pulse oximeter tone to indicate clinically important ranges could improve the management of oxygen delivery to the neonate during resuscitation in the first 10 minutes after birth.

Auditory Sequences Presented With Spearcons Support Better Multiple Patient Monitoring Than Single-Patient Alarms: A Preclinical Simulation.

OBJECTIVE: A study of auditory displays for simulated patient monitoring compared the effectiveness of two sound categories (alarm sounds indicating general risk categories from international alarm standard IEC 60601-1-8 versus event-specific sounds according to the type of nursing unit) and two configurations (single-patient alarms versus multi-patient sequences). BACKGROUND: Fieldwork in speciality-focused high dependency units (HDU) indicated that auditory alarms are ambiguous and do not identify which patient has a problem. We tested whether participants perform better using auditory displays that identify the relevant patient and problem. METHOD: During simulated patient monitoring of four patients in a respiratory HDU, 60 non-clinicians heard either (a) IEC risk categories as single-patient alarm sounds, (b) event-specific categories as single-patient alarm sounds, (c) IEC risk categories in multi-patient sequences or (d) event-specific categories in multi-patient sequences. Participants performed a perceptual-motor task while monitoring patients; after detecting abnormal events, they identified the patient and the event. RESULTS: Participants hearing multi-patient sequences made fewer wrong patient identifications than participants hearing single-patient alarms. Advantages of event-specific categories emerged when IEC risk category sounds indicated more than one potential event. Even when IEC and event-specific sounds indicated the same unique event, spearcons supported better event identification than did auditory icon sounds. CONCLUSION: Auditory displays that unambiguously convey which patient is having what problem dramatically improve monitoring performance in a preclinical HDU simulation. APPLICATION: Time-compressed speech assists development of detailed risk categories needed in specific HDU contexts, and multi-patient sound sequences allow multiple patient wellbeing to be monitored.

Similarity of expert clinicians' rank order of differential diagnoses in a newborn resuscitation context.

Background: We tested principles that could lead to a future cognitive aid that offers an interpretation of the newborn's physiological state during resuscitation after birth. Using concordance among experts' interpretations of newborn vital sign patterns as an approximation for an algorithm that could provide an interpretation of the newborn's state, we explored the reliability and generalisability of experts' interpretations. Methods: Twelve neonatal experts viewed eight pairs of graphical trajectories showing newborns' heart rate and oxygen saturation records supplemented with differential diagnoses elicited previously from other experts. Each pair of trajectories included one trajectory on which the original differential diagnoses had been based, and a similar but novel trajectory to which the original differential diagnoses were now generalised. For each trajectory, experts ranked the differential diagnoses according to their likelihood. We calculated how similar the new experts' ranking was to the original experts' ranking for both original and novel trajectories. We used descriptive categories to interpret the strength of the similarity. Results: For the original and novel trajectories, the experts' rank ordering of differential diagnoses was mostly moderately to substantially similar to the original rank ordering by the original participants. There were mostly small differences in similarity scores between the paired original and novel trajectories; fewer than 25% of the participants suggested an alternative differential diagnosis. Conclusions: The concordance of experts' interpretations could serve as an approximation of the newborn's physiological state, and the interpretations could be generalised. The results may justify pursuing an algorithm to underpin a cognitive aid.

Signaling Patient Oxygen Desaturation with Enhanced Pulse Oximetry Tones.

Manufacturers could improve the pulse tones emitted by pulse oximeters to support more accurate identification of a patient's peripheral oxygen saturation (SpO2) range. In this article, we outline the strengths and limitations of the variable-pitch tone that represents SpO2 of each detected pulse, and we argue that enhancements to the tone to demarcate clinically relevant ranges are feasible and desirable. The variable-pitch tone is an appreciated and trusted feature of the pulse oximeter's user interface. However, studies show that it supports relative judgments of SpO2 trends over time and is less effective at supporting absolute judgments about the SpO2 number or conveying when SpO2 moves into clinically important ranges. We outline recent studies that tested whether acoustic enhancements to the current tone could convey clinically important ranges more directly, without necessarily using auditory alarms. The studies cover the use of enhanced variable-pitch pulse oximeter tones for neonatal and adult use. Compared with current tones, the characteristics of the enhanced tones represent improvements that are both clinically relevant and statistically significant. We outline the benefits of enhanced tones, as well as discuss constraints of which developers of enhanced tones should be aware if enhancements are to be successful.

Attention to Changes on a Head-Worn Display: Two Preclinical Studies with Healthcare Scenarios.

OBJECTIVE: In two experiments, we examined how quickly different visual alerts on a head-worn display (HWD) would capture participants' attention to a matrix of patient vital sign values, while multitasking. BACKGROUND: An HWD could help clinicians monitor multiple patients, regardless of where the clinician is located. We sought effective ways for HWDs to alert multitasking wearers to important events. METHODS: In two preclinical experiments, university student participants performed a visuomotor tracking task while simultaneously monitoring simulated patient vital signs on an HWD to detect abnormal values. Methods to attract attention to abnormal values included highlighting abnormal vital signs and imposing a white flash over the entire display. RESULTS: Experiment 1 found that participants detected abnormal values faster with high contrast than low contrast greyscale highlights, even while performing difficult tracking. In Experiment 2, a white flash of the entire screen quickly and reliably captured attention to vital signs, but less so on an HWD than on a conventional screen. CONCLUSION: Visual alerts on HWDs can direct users' attention to patient transition events (PTEs) even under high visual-perceptual load, but not as quickly as visual alerts on fixed displays. Aspects of the results have since been tested in a healthcare context. APPLICATION: Potential applications include informing the design of HWD interfaces for monitoring multiple processes and informing future research on capturing attention to HWDs.

SPECTRa: An Online Tool for Simulating Prehospital Patient Care.

OBJECTIVES: To (1) develop a simulation software environment to conduct prehospital research during the COVID-19 pandemic on paramedics' teamwork and use of mobile computing devices, and (2) establish its feasibility for use as a research and training tool. BACKGROUND: Simulation-based research and training for prehospital environments has typically used live simulation, with highly realistic equipment and technology-enhanced manikins. However, such simulations are expensive, difficult to replicate, and require facilitators and participants to be at the same location. Although virtual simulation tools exist for prehospital care, it is unclear how best to use them for research and training. METHODS: We present SPECTRa-Simulated Prehospital Emergency Care for Team Research-an online simulated prehospital environment that lets participants care concurrently for single or multiple patients remotely. Patient scenarios are designed using Laerdal's SimDesigner. SPECTRa records data about scenario states and participants' virtual interaction with the simulated patients. SPECTRa's supporting environment records participants' verbal communication and their visual and physical interactions with their interface and devices using Zoom conferencing and audiovisual recording. We discuss a pilot research implementation to assess SPECTRa's feasibility. RESULTS: SPECTRa allows researchers to systematically test small-team interaction in single- or multipatient care scenarios and assess the impact of mobile devices on participants' assessment and care of patients. SPECTRa also supports pedagogical features that could allow prehospital educators to provide individual trainees or teams with online simulation training and evaluation. CONCLUSIONS: SPECTRa, an online tool for simulating prehospital patient care, shows potential for remote healthcare research and training.

Examining the efficacy of vibrotactile displays for monitoring patient vital signs: Six laboratory studies of change detection and state identification.

Healthcare workers often monitor patients while moving between different locations and tasks, and away from conventional monitoring displays. Vibrotactile displays can provide patient information in vibrotactile patterns that are felt regardless of the worker's location. We examined how effectively participants could identify changes in vibrotactile representations of patient heart rate (HR) and oxygen saturation (SpO2). In Experiment 1, participants identified changes in HR and SpO2 with greater than 90% accuracy while using vibrotactile displays configured in either an integrated or a separated format. In Experiment 2, incidental auditory and visual cues were removed and performance was still greater than 90% for the integrated display. In Experiments 3 and 4, ongoing tasks with low or high task load were introduced; high load worsened participants' response accuracy and speed at identifying vital signs. In Experiments 5 and 6, alternative designs were tested, including a design with a seemingly more natural mapping of HR to vibrotactile stimulation. However, no design supported more accurate performance than the integrated display. Results are interpreted with respect to multiple resource theory, and constraints on conforming to design guidelines are noted. Vibrotactile displays appear to be viable and therefore potentially suitable for use in healthcare and other contexts. (PsycInfo Database Record (c) 2022 APA, all rights reserved).

A review of the effects of head-worn displays on teamwork for emergency response.

Head-Worn Displays (HWD) can potentially support the mobile work of emergency responders, but it remains unclear whether teamwork is affected when emergency responders use HWDs. We reviewed studies that examined HWDs in emergency response contexts to evaluate the impact of HWDs on team performance and on team processes of situation awareness, communication, and coordination. Sixteen studies were identified through manual and systematic literature searches. HWDs appeared to improve the quality of team performance but they increased time to perform under some conditions; effects on team processes were mixed. We identify five challenges to explain the mixed results. We discuss four theoretical perspectives that might address the challenges and guide research needs-joint cognitive systems, distributed cognition, common ground, and dynamical systems. Researchers and designers should use process-based measures and apply greater theoretical guidance to uncover mechanisms by which HWDs shape team processes, and to understand the impact on team performance. Practitioner Summary: This review examines the effects of head-worn displays on teamwork performance and team processes for emergency response. Results are mixed, but study diversity challenges the search for underlying mechanisms. Guidance from perspectives such as joint cognitive systems, distributed cognition, common ground, and dynamical systems may advance knowledge in the area. Abbreviations: HWD: head-worn display; RC: remote collaboration; DD: data display; ARC: augmented remote collaboration; ACC: augmented collocated collaboration; SA: situation awareness; TSA: team situation awareness; CPR: cardiopulmonary resuscitation; SAGAT: situation awareness global assessment technique; SART: situation awareness rating technique.

Concordance of expert clinicians' interpretations of the newborn's true physiological state.

BACKGROUND: Many physiological aspects of the neonatal transition after birth are unobservable because relevant sensors do not yet exist, compromising clinicians' understanding of a neonate's physiological status. Given that a neonate's true physiological state is currently unavailable, we explored the feasibility of using clinicians' degree of concordance as an approximation of the true physiological state. METHODS: Two phases of structured interviews were conducted. In Phase 1 (N = 8) and Phase 2 (N = 12), we presented neonatal experts with eight graphical trajectories of real newborns' heart rate and oxygen saturation values in the first 10-15 min after birth. We elicited the participants' interpretations of potential underlying physiological conditions that could explain the vital sign patterns. RESULTS: The global differential diagnosis data for each phase produced the same pattern of results: (1) four trajectories produced a substantial degree of concordance among clinicians (61-80%) and (2) four trajectories produced a strong degree of concordance among clinicians (81-100%). CONCLUSIONS: It is possible to achieve a strong degree of concordance among neonatal experts' interpretations of newborn trajectories. Thus, using the degree of concordance as an approximation of the neonate's true physiological state in resuscitation after birth may be a promising direction to explore for cognitive aid design. IMPACT: Differential diagnoses with a good degree of concordance among expert neonatal clinicians could potentially substitute in part for the direct measurement of key physiological and anatomical variables of the neonatal transition, which is currently unavailable. The concordance of clinicians' judgements or inferences with regards to the true physiological state of the newborn during resuscitation after birth has never been explored. The findings provide a crucial first step toward using consensus of neonatal experts' judgements in the design of a cognitive aid to support clinicians' management of the newborns who require resuscitation after birth.

Need for a new paradigm in the design of alarms for patient monitors and medical devices.

Modern computerised medical devices emit large numbers of tone-based alerts and alarms. Notifications that comprise auditory icons or natural human speech substantially increase the psychological salience of alerts and alarms and may allow a larger set of notifications to be used, as they do not require memorisation of arbitrary sounds.

Nurses' use of auditory alarms and alerts in high dependency units: A field study.

A fieldwork study conducted in six units of a major metropolitan Australian hospital revealed that nurses' attitudes towards alarms are influenced by each unit's physical layout and caseload. Additionally, nurses relied heavily on both non-actionable and actionable alarms to maintain their awareness of the status of their patients' wellbeing, and used auditory alarms beyond the scope of their intended design. Results suggest that before reducing or removing auditory alarms from the clinical environment to improve patient safety, it is important to understand how nurses in different clinical contexts use current alarm systems to extract meaningful information. Such an understanding could guide appropriate alarm reduction strategies and guide alternative design solutions to support nurses' situation awareness during monitoring.

The Use of Head-Worn Displays for Vital Sign Monitoring in Critical and Acute Care: Systematic Review.

BACKGROUND: Continuous monitoring of patient vital signs may improve patient outcomes. Head-worn displays (HWDs) can provide hands-free access to continuous vital sign information of patients in critical and acute care contexts and thus may reduce instances of unrecognized patient deterioration. OBJECTIVE: The purpose of the study is to conduct a systematic review of the literature to evaluate clinical, surrogate, and process outcomes when clinicians use HWDs for continuous patient vital sign monitoring. METHODS: The review was registered with PROSPERO (CRD42019119875) and followed the PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-analyses) guidelines. A literature search was conducted for articles published between January 1995 and June 2020 using the following databases: PubMed, Embase, CINAHL, PsycINFO, and Web of Science. Overall, 2 reviewers independently screened titles and abstracts and then assessed the full text of the articles. Original research articles that evaluated the clinical, surrogate, or process outcomes of head-mounted displays for continuous vital sign monitoring in critical care or acute care contexts were included. RESULTS: Of the 214 records obtained, 15 (7%) articles met the predefined criteria and were included in this review. Of the 15 studies, 7 (47%) took place in a clinical context, whereas the remainder took place in a simulation environment. In 100% (7/7) of the studies that evaluated gaze behavior, changes were found in gaze direction with HWDs. Change detection improvements were found in 67% (2/3) of the studies evaluating changes in the participants' ability to detect changes in vital signs. Of the 10 studies assessing the ease of use of the HWD, most participants of 7 (70%) studies reported that the HWD was easy to use. In all 6 studies in which participants were asked if they would consider using the HWD in their practice, most participants responded positively, but they often suggested improvements on the HWD hardware or display design. Of the 7 studies conducted in clinical contexts, none reported any clinical outcomes. CONCLUSIONS: Although there is limited and sometimes conflicting evidence about the benefits of HWDs from certain surrogate and process outcomes, evidence for clinical outcomes is lacking. Recommendations are to employ user-centered design when developing HWDs, perform longitudinal studies, and seek clinical outcomes. TRIAL REGISTRATION: PROSPERO International Prospective Register of Systematic Reviews CRD42019119875; https://www.crd.york.ac.uk/prospero/display_record.php?RecordID=119875.

Interruptions to Intensive Care Nurses and Clinical Errors and Procedural Failures: A Controlled Study of Causal Connection.

OBJECTIVES: Interruptions occur frequently in the intensive care unit (ICU) and are associated with errors. To date, no causal connection has been established between interruptions and errors in healthcare. It is important to know whether interruptions directly cause errors before implementing interventions designed to reduce interruptions in ICUs. The aim of the study was to investigate whether ICU nurses who receive a higher number of workplace interruptions commit more clinical errors and procedural failures than those who receive a lower number of interruptions. METHODS: We conducted a prospective controlled trial in a high-fidelity ICU simulator. A volunteer sample of ICU nurses from a single unit prepared and administered intravenous medications for a patient manikin. Nurses received either 3 (n = 35) or 12 (n = 35) scenario-relevant interruptions and were allocated to either condition in an alternating fashion. Primary outcomes were the number of clinical errors and procedural failures committed by each nurse. RESULTS: The rate ratio of clinical errors committed by nurses who received 12 interruptions compared with nurses who received 3 interruptions was 2.0 (95% confidence interval = 1.41-2.83, P < 0.001). The rate ratio of procedural failures committed by nurses who received 12 interruptions compared with nurses who were interrupted 3 times was 1.2 (95% confidence interval = 1.05-1.37, P = 0.006). CONCLUSIONS: More workplace interruptions during medication preparation and administration lead to more clinical errors and procedural failures. Reducing the frequency of interruptions may reduce the number of errors committed; however, this should be balanced against important information that interruptions communicate.