Introduction
Excluding the noises made by human interventions in clinical environments, almost 80% of the noise in intensive care units is due to electronic alarms. Because of their physiological impact, alarms lead to alarm fatigue.1-3) Alarm fatigue is defined as incompetence at identifying or prioritizing alarms which, in turn, leads to inappropriate responses to alarms.4 There are two reasons for alarm fatigue: becoming desensitized to alarms due to emotional overload and indifference to responses and confusion caused by alarms which results in distrust in accuracy of alarms.5 Alarm fatigue not only increases emotional burden in healthcare personnel who are overexposed to alarms,6,7 but also causes considerable stress to patients and healthcare providers.8,9 Moreover, alarm fatigue can lead to delayed responses to alarms, readjustment of alarms to ranges which are unsafe for patients and eventually switching alarms silent or off.9 As a growing problem with dire consequences, alarm fatigue was ranked by Emergency Care Research Institute (ECRI) as the top hazard among the 10 threats of technology in healthcare in 2012.10 Alarm fatigue is a human error responsible for a large number of fatalities in hospitals. According to Food and Drug Administration, between 2002 and 2004, 237 deaths were caused by negligence of clinical alarms.11,12 In a survey conducted by Federal Drug Administration over 4 months in 2010, 73 alarm-related deaths were investigated 33 of which were attributed to physiologic monitors.13
The purpose of clinical alarms is to enhance patients' safety and alert doctors and nurses to aberrations in patients' conditions. Also, when a patient's condition gets worse or a machine fails to function properly, alarms alert doctors and nurses.12 It is a fact that nurses are the best monitors of patients and physiologic monitors are simply for further assurance of the doctors and nurses who use them; however, the issue of false positive alarms remains a serious unsolved problem with many grave consequences.14 False alarms are cry wolves which lead nurses to ignore alarms or respond to repetitive alarms with delay. Furthermore, alarms can prevent nurses from planning effectively and performing their tasks properly and distract them in other ways.14 Studies show that the majority of alarms are false.3,14 The results of 371 hours of monitoring in a study showed that 1762 alarms (99.4%) were false alarms.15 In their study, Graham and Cvach have recorded 942 alarms per day or 1 critical alarm every 92 seconds, while other researchers report 6 to 16 alarms per hour.16 Delay settings on SpO2 (peripheral capillary oxygen saturation) alarm systems up to 15 seconds or 19 seconds,17 can reduce the frequency of alarms to 50% or 70% respectively; thus, in the case of lack of oxygen saturation in short periods, the number of alarms is decreased.10 Setting alarm ranges according to each patient's condition can also reduce the frequency of alarms, thus decreasing alarm fatigue.17
Considering the results of studies regarding the consequences of alarm fatigue and given the fact that, so far, few studies have addressed alarm fatigue management, the present study is an attempt at exploring the effects of development and introduction of a manual for alarm management for intensive care unit nurses.
Methods
This study was approved by the Research Ethics Committee of Shiraz University of Medical Sciences located in Southwest of Iran (IR.SUMS.REC.1393.S7362), data were collected in 2017. The present study is a quasi-experimental work of research conducted in two stages: development of a manual for management of alarms from clinical equipment and introduction of the manual. Since a nurse's response to an alarm is an occurrence which may happen at any time in a hospital unit and is not considered a unique event, i.e. a nurse's response to an alarm is independent of the changes specific to a period, in the present study, considering the nature of the behavior under study, the researchers employed the methods of observation and time sampling.18 The sample consisted of 200 hours of observation in an intensive care unit-100 hours before the intervention and 100 hours after the intervention. Accordingly, the nurses' responses to alarms were observed during different days and shifts (morning, evening and night) for 6.5 hours per shift.
To perform the observation, two of the researchers who were completely familiar with intensive care units would randomly select a shift every day and record the nurses' responses to alarms. For one month, data were collected from morning, afternoon, and evening shifts by the two researchers using a checklist. The study population consisted of all the practicing nurses in the general intensive care unit of the largest hospital in the south of Iran. Sampling was based on the census method and the subjects who met the inclusion criteria of the study and filled out the informed consent form were included. The inclusion criteria were to be a permanent nursing staff member in the intensive care unit, to not have participated in a similar work of research, and to be willing to participate. The exclusion criterion was failing to attend one of the education sessions (none of the nurses were excluded).
Data Collection. The researchers developed the monitoring system alarms data collection form based on a literature review and the results of previous studies. The data collection form includes items about type of monitoring parameter, type of alarm, response time to alarm (the time lapse between the moment an alarm starts and the moment a response is made to it), type of response, personalization of alarm settings for each patient, the individual who responds to an alarm, and cause of alarm. Alarms were classified into three types: false, true, and technical. A false alarm is one which is detected and recorded by the monitoring system as a physiologic occurrence, while actually nothing has occurred. A true alarm is a correct detection of a deviation in parameter settings recorded by the monitoring system. A technical alarm is defined as an alarm which informs nurses of a problem in the functioning of a monitoring system, e.g. disconnection of a machine from the power supply and disconnection of the pipes and other gears attached to patients. The equipment dealt with in the present study were the entire vital signs monitoring systems, cardiac monitoring systems, ventilators and syringe pumps. To increase the validity of the findings, the data collected from the first 30 hours of observations were excluded and the data obtained during the following 200 hours of observations were analyzed. To test the reliability of a data collection form (in order to reduce the possibility of errors and increase consistency in the collection of data), the observers are required to be in the same environment and record the same event simultaneously. Accordingly, the two researchers who were responsible for data collection in the present study were placed in a simulated environment where they were shown the same video of patient monitoring systems and answered the questions on the form about the alarms. Subsequently, SPSS v. 21 was used to measure the consistency between the data collected on the two forms. The consistency was found to be 0.88.
The manual for alarm management in intensive care units was developed as a protocol by three intensive care specialists, an intensive care unit head nurse and two experienced staff members, and the research team during three two-hour focus group sessions. The manual includes sections on introduction to alarms, the consequences of alarms, and methods of controlling and preventing alarms. The manual was introduced to the ICU personnel over a six-session workshop (Table 1). Lasting for 4 hours, each session was directed by experienced professors in the field of intensive care. After the introduction of the manual for alarm management, the ICU personnel were asked to adjust themselves to the instructions they had received for two weeks. In the first week of the initiation, the personnel's inquiries were dealt with; in the second week, the personnel were allowed to use the manual on their own. Next, as of the fifteenth day, data were collected again in the intensive care unit using the monitoring system alarms data collection form.
Session | Goal | Content |
---|---|---|
1 | Introduction to alarms and their adverse effects | Discussing the role of alarms in the safety of patients |
1 | Introduction to alarms and their adverse effects | Discussing the methods of controlling and preventing alarms |
2 | Standardization of ECG monitoring systems | A review of the content of the previous session |
2 | Standardization of ECG monitoring systems | Empowerment of the personnel by educating them in how to properly prepare the skin for ECG electrodes, daily replacement of electrodes, and modification of alarm parameters and thresholds of ECG monitors, among others |
3 | Standardization of SpO2 and blood pressure monitoring systems | A review of the content of the previous session |
3 | Standardization of SpO2 and blood pressure monitoring systems | Modification of delay and threshold settings in SpO2 monitoring systems |
3 | Standardization of SpO2 and blood pressure monitoring systems | Modification of threshold settings in blood pressure monitoring systems |
4 | Empowerment and education of personnel in using ventilators | A review of the content of the previous session |
4 | Empowerment and education of personnel in using ventilators | Modification of settings of a ventilator, including respiratory rate, tidal volume, positive end-expiratory pressure, and respiratory tract pressure |
5 | Standardization of syringe pumps and infusion pumps | A review of the content of the previous session |
5 | Standardization of syringe pumps and infusion pumps | Modification of threshold settings in syringe pumps and infusion pumps |
5 | Standardization of syringe pumps and infusion pumps | Introduction to alarm types of syringe pumps and infusion pumps |
6 | Starting an inter-professional team | A review of the content of the previous session |
6 | Starting an inter-professional team | Creating an inter-professional team in the hospital which oversees alarm-related issues, including policy development and introduction of new methods |
Abbreviations: SPO2, Peripheral capillary oxygen saturation; ECG, Electrocardiography
Data Analysis. The collected data were analyzed using SPSS v. 21. The central indexes and the distribution of the data were measured using descriptive statistics, including mean, standard deviation, frequency, and percentage based on the type of variable (quantitative or qualitative). In order to assess the efficacy of the interventions, the researchers employed the statistical tests of paired sample t-test, independent t-test, and Chi-square. The assumption that the variables were normal was tested using Kolmogorov-Smirnov test; if the assumption was disproved, nonparametric tests, including Mann-Whitney test, Wilcoxon test, Fisher's exact test, McNemar test, and sign test would be used. The significance level for the tests was set at 0.05 and the confidence interval for the calculation of point estimations was 95%.
Results
In the present study, 60 nurses with the average age of 34.36±6.42 years and work experience of 9.69±7.44 years participated. 63.3% of the participants were female and 36.7% were male. 83.4% had a bachelor's degree and 16.6% had a master's degree. Also, 26.6% of the participants were permanent employees, 36.6% were fixed-term employees, 16.6% were contractual employees, and 20% were trainees. The results showed a significant reduction (53.8%) in the frequency of false alarms following the intervention. Also, the results of the Chi-square test showed a statistically significant difference between the pre- and post-intervention alarm types (p<0.001). As only one technical alarm was observed and because such alarms are in fact true alarms, the number of technical alarms was considered together with the true alarms and the tests were conducted between the two groups of false and true alarms (Table 2).
Type of alarm | Before | After | Percentage change |
Type of alarm | n (%) | n (%) | Percentage change |
False | 552 (79.5) | 255 (48.9) | -53.8 |
True* | 141 (20.4) | 262 (50.1) | 85.81 |
Technical | 1 (0.1) | 5 (1) | 4 |
Total | 694 | 522 | p<0.001 |
* Technical and true alarms were merged due to the small number of technical alarms, these alarms were combined with the true alarms in statistical calculations.
The results of Fisher's exact test showed a statistically significant difference between the pre- and post-intervention frequency distribution of monitoring parameters (p<0.001). The highest and lowest impacts of the introduction of the manual belonged to RR (Respiratory Rate) monitoring (with a 64.7% reduction in frequency of alarms) and NIBP monitoring (with a 19.8% reduction in frequency of alarms) respectively (overall p <0.05) (Table 3).
Type of parameter | Type of alarm | Before | After | p-value |
n (%) | n (%) | |||
SPO2 | False | 228 (32.85) | 110 (21.7) | <0.001 |
SPO2 | True | 37 (5.33) | 89 (17.4) | <0.001 |
NIBP | False | 51(7.34) | 29 (5.55) | 0.037 |
NIBP | True | 40 (5.76) | 44 (8.42) | 0.037 |
ECG | False | 140 (20.17) | 66 (12.64) | <0.001 |
ECG | True | 26 (3.74) | 58 (11.11) | <0.001 |
Ventilator | False | 14 (2.01) | 40 (7.66) | 0.005 |
Ventilator | True | 33 (4.75) | 31 (5.93) | 0.005 |
RR | False | 107 (15.41) | 6 (1.14) | <0.001 |
RR | True | 5 (0.72) | 27 (5.17) | <0.001 |
S.P | False | 12 (1.72) | 4 (0.76) | 0.01 |
S.P | True | 1 (0.14) | 5 (0.95) | 0.01 |
Total | False | 552 (79.5) | 255 (48.9) | <0.001 |
Total | True | 142 (20.5) | 267 (51.1) | <0.001 |
Abbreviations: SPO2, Peripheral capillary oxygen saturation; NIBP, Non Invasive Blood Pressure; ECG, Electrocardiography; RR, Respiratory Rate; S.P, Syringe pump
The results of Fisher's exact test showed that the difference between the pre- and post-intervention types of response to alarms was not statistically significant. The most and least effective responses to alarms after the intervention belonged to SpO2 (16.47%) and syringe pumps (0.5) was significant for the total of parameters. However, the percentage of effective interventions was significantly higher for all parameters after the intervention (46.9%) than before the intervention (38.9%) with a p-value of 0.005 (Table 4).
Type of parameter | Type of response | Before | After | p-value |
n (%) | n (%) | |||
SPO2 | Effective | 95 (13.68) | 86 (16.47) | 0.17 |
SPO2 | Ineffective | 170 (24.49) | 116 (22.22) | 0.17 |
NIBP | Effective | 53 (7.63) | 50 (9.58) | 0.24 |
NIBP | Ineffective | 40 (5.76) | 26 (26) | 0.24 |
ECG | Effective | 75 (10.8) | 68 (13.5) | 0.12 |
ECG | Ineffective | 91 (13.11) | 57 (10.92) | 0.12 |
Ventilator | Effective | 33 (4.75) | 30 (5.75) | 0.73 |
Ventilator | Ineffective | 13 (1.87) | 10 (1.91) | 0.73 |
RR | Effective | 9 (1.29) | 8 (1.55) | 0.44 |
RR | Ineffective | 102 (14.69) | 61 (11.7) | 0.44 |
S.P | Effective | 5 (0.72) | 3 (0.5) | 0.71 |
S.P | Ineffective | 8 (1.15) | 7 (1.35) | 0.71 |
Total | Effective | 270 (38.9) | 245 (46.93) | 0.005 |
Total | Ineffective | 424 (61.1) | 277 (53.07) | 0.005 |
Abbreviations: SPO2, Peripheral capillary oxygen saturation; NIBP, Non Invasive Blood Pressure; ECG, Electrocardiography; RR, Respiratory Rate; S.P, Syringe pump
Even though the results of Wilcoxon test indicated a statistically significant difference (p-value=0.001) between the pre- and post-intervention personalized monitoring system settings for each patient, the majority of the alarms and parameters (85.8%) remained without personalized settings. The greatest and smallest numbers of personalized settings for monitoring each patient as implemented by the nurses belonged to SpO2 monitoring and ventilators respectively (Table 5).
Type of parameter | Before | After | p-value |
---|---|---|---|
n (%) | n (%) | ||
SPO2 | 0 (0) | 26 (5) | <0.001 |
NIBP | 0 (0) | 23 (4.4) | <0.001 |
HR | 0 (0) | 13 (2.5) | <0.001 |
Ventilator | 0 (0) | 12 (2.3) | 0.001 |
None | 694 (100) | 448 (85.8) | <0.001 |
Total | 694 | 522 |
Abbreviations: SPO2, Peripheral capillary oxygen saturation; NIBP, Non Invasive Blood Pressure; HR, Heart Rate; S.P, Syringe pump
Based on the results of Fisher's exact test, there was a statistically difference between the pre- and post-intervention types of individual who responded to alarms. Before the intervention, the nurses responded to 43.1% of the alarms, while after the intervention, they responded to 62.1% of the alarms. In other words, in the post-intervention stage, the nurses were more responsive to the alarms from the patients' monitoring systems. Besides the nurses, the personnel consisted of the doctors, medical equipment technicians, and the cleaning staff. In the present study, the doctors were never seen to respond to an alarm in any way (Table 6).
Type of parameter | Type of alarm | Before | After | p-value |
---|---|---|---|---|
n (%) | n (%) | |||
SPO2 | Nurse | 110 (15.8) | 130 (24.9) | <0.001 |
SPO2 | Nursing assistant | 31 (4.4) | 11 (2.1) | <0.001 |
SPO2 | Others* | 21 (3) | 3 (0.5) | <0.001 |
SPO2 | No response | 103 (14.9) | 58 (11.1) | <0.001 |
NIBP | Nurse | 61 (7.8) | 63 (12) | 0.01 |
NIBP | Nursing assistant | 8 (1.2) | 1 (0.2) | 0.01 |
NIBP | Others | 4 (0.6) | 0 (0) | 0.01 |
NIBP | No response | 18 (2.6) | 12 (2.3) | 0.01 |
ECG | Nurse | 74 (10.7) | 78 (14.9) | 0.008 |
ECG | Nursing assistant | 24 (3.5) | 6 (1.1) | 0.008 |
ECG | Others | 1 (0.1) | 0 (0) | 0.008 |
ECG | No response | 67 (9.7) | 41 (7.9) | 0.008 |
Ventilator | Nurse | 34 (4.9) | 34 (6.5) | 0.15 |
Ventilator | Nursing assistant | 3 (0.4) | 1 (0.2) | 0.15 |
Ventilator | Others | 2 (0.3) | 0 (0) | 0.15 |
Ventilator | No response | 8 (1.2) | 5 (1) | 0.15 |
RR | Nurse | 10 (1.4) | 11 (2.1) | 0.15 |
RR | Nursing assistant | 2 (0.3) | 0 (0) | 0.15 |
RR | Others | 0 (0) | 0 (0) | 0.15 |
RR | No response | 100 (14.4) | 58 (11.1) | 0.15 |
S.P | Nurse | 10 (1.4) | 8 (1.5) | 0.86 |
S.P | Nursing assistant | 0 (0) | 0 (0) | 0.86 |
S.P | Others | 1 (0.1) | 1 (0.2) | 0.86 |
S.P | No response | 2 (0.3) | 1 (0.2) | 0.86 |
* The groups of others, nursing assistant, and no response were merged. Abbreviations: SPO2, Peripheral capillary oxygen saturation; NIBP, Non Invasive Blood Pressure; ECG, Electrocardiography; RR, Respiratory Rate; S.P, Syringe pump
Discussion
In this study, 1216 alarms were recorded over 200 hours of observation, with the mean of 6.08 alarms per hour. Of the 1216 recorded alarms, 66.3% were false alarms, 33.1% were true alarms, and 0.4% were technical alarms. In their study, Graham et al. recorded 1 clinically significant alarm every 92 seconds.16 Baillargeon reports that of the 174 alarms recorded in her study, 44.8% were false alarms, 47.7% were true alarms, and 7.4% were technical alarms.6 In the study of Inokuchi et al. only 6.4% of the 11591 recorded alarms were found to be clinically significant; 93.6% were false alarms and 0.02% were technical alarms.19 The findings of the present study are consistent with those of the studies of Graham et al., and Inokuchi et al. but do not agree with the results of Baillargeon's study, which may be due to the shorter time span of Baillargeon's study or the fact that her study was conducted in an internal unit where telemetry monitoring was used.
Before the introduction of the educational intervention, 694 alarms were recorded, 79.5% of which were false alarms, 20.3% were true alarms, and 0.1% were technical alarms. After the intervention, of the 522 recorded alarms, 48.9% were false alarms, 50.2% were true alarms, and 1% were technical alarms. The 53.8% reduction in the occurrence of false alarms after the intervention can be attributed to the education which the nurses received in the workshops. Graham et al. report a 43% posttest reduction in the frequency of physiologic alarms.16 In their study of the effect of daily replacement of ECG electrodes on the alarms of electrocardiogram monitors in CCU (Coronary Care Unit) and MPCU (Medical Progressive Care Unit), Cvach et al. report that the total number of daily alarms per bed decreased by 47% in MPCU and by 44% in CCU. Moreover, the number of technical alarms in MPCU and CCU decreased by 34% and 45% respectively; the number of audio alarms in MPCU and CCU decreased by 52% and 46% respectively; finally, the number of alert alarms in MPCU and CCU decreased by 47% and 46% respectively. However, the frequency of high-priority (critical) alarms did not change.13 The results of the studies of Graham et al., and Cvach et al. are consistent-the greater reduction in the post-intervention number of false alarms in the study of Cvach et al. can be due to the fact that they included the entire monitoring systems in their study.
The results of this study showed that the difference between the pre-intervention response time (51.9±67.21 seconds) and the post-intervention response time (30.8±15.09 seconds) is statistically significant. In Baillargeon's study, alarm response time ranges between 1 minute and 20 seconds and 10 minutes, with the mean being 7.01 minutes6 which is far more than the response time in the present study. In the present study, before the intervention, the longest response time was for SPO2 monitoring (17.3 minutes). After the intervention, the longest response time, at 1.6 minutes, was for ECG (Electrocardiography), RR, and SPO2 monitoring.
Of the 1216 alarms recorded in the present study, 38.4% were for SPO2, 23.9% were for ECG, 14.8% were for RR, 13.7% were for NIBP, 7.2 % were for ventilator, and 1.9% were for syringe pump monitoring systems. The difference between the pre- and post-intervention frequency distributions of monitoring parameters was not statistically significant (p-value=0.92). In other words, even though the number of false alarms (as the primary source of alarm fatigue in nurses) decreased as a result of the educational interventions, the change in the frequency of monitoring parameters after the intervention was not statistically significant, which can be attributed to the higher frequency of true alarms from monitoring parameters in the post-intervention stage. However, in their study conducted at the Johns Hopkins Hospital, Taenzer et al. report a 63% reduction in the number of alarms after lowering the threshold of SPO2 monitor.20 In the study of Cvach et al. the frequency of alarms related to arrhythmia and RR electrodes dropped in CCU and MPCU by 74% and 60% respectively for arrhythmia and by 65% and 36% for RR.13
According to the results of the present study, 59.53% of the alarms occurred during the morning shifts. The majority of the alarms were recorded during the morning shifts. The increased workload of nurses in the morning, the execution of many of the clinical procedures in the morning, doctors' rounds, and the presence of patients' visitors during morning visiting hours can account for the higher frequency of alarms in morning shifts. The findings of our study show a statistically significant difference between the nurses' pre- and post-intervention types of response to alarms: 42.35% of the alarms were responded to effectively and 57.65% received ineffective responses. Before the intervention, 38.9% of the alarms were responded to effectively and 61.1% were responded to ineffectively, while after the intervention, 46.93% of the alarms were responded to effectively and 53.06% were responded to ineffectively. Effective responses were those in which the type of alarm was checked, the signs were interpreted by a nurse and, subsequently, steps were taken to deal with the cause of the alarm or the doctors were informed. Ineffective responses were characterized by silencing alarms, delay in responding to alarms, ignoring alarms or deactivating them without investigating the cause of the alarm. According to Harris et al. the number of false and nuisance alarms is a determining factor in clinical alarm response time.21 Jennings reports that when the frequency of nuisance alarms is high, the medical staff is more likely to ignore relevant alarms.22 Similarly, Graham et al. state that positive false alarms or nuisance alarms can result in delayed response time or reduce the likelihood of nurses' responding to alarms.16
In this study, before the intervention, none of the alarms were personalized by the nurses for the monitoring of patients and all the alarms were on default settings. However, after the intervention and the visual and practical education on the use of monitors in the workshops, the situation improved: of the 522 alarms recorded in the post-intervention stage, 14.17% of them made the nurses examine the sensitivity range of the monitors and alter them if necessary. Even though the difference between the pre- and post-intervention personalization of settings for the monitoring of each patient was statistically significant (P-value=0.001), a large number (85.8%) of alarms and parameters remained unchanged. These findings are consistent with the results of the study of Graham et al.: they found that modification of the default settings of monitors and informing nurses about the significance of personalization of monitor parameters can help reduce excess alarms.16
Based on the findings of this study, 51.23% of the alarms were responded to by nurses, 7.15% were responded to by nursing assistants, and 2.71% were responded to by others, including patients' visitors and the cleaning staff. 38.89% of the alarms were never responded to. It was also noticed that the cleaning staff occasionally silenced alarms that went off while they were cleaning the rooms and equipment. Before the intervention, 43.1% of the alarms were responded to by the nurses, while after the educational intervention, the nurses responded to 62.1% of the alarms. The results of the statistical tests show a significant difference (p-value=0.007) between the pre- and post-intervention frequency of responders to alarms: the nurses became more responsive. Even though the responsiveness of the nurses in charge of checking the clinical conditions of patients and the monitoring parameters improved in the present study after the intervention, the number of alarms which did not receive a response was still high (33.5%).
Limitations. One of the limitations of the study was its use of the observation method for data collection: changes in the observers' behavior, perception errors, and environmental factors can adversely affect the reliability of the data. To reduce the impact of such factors, the researchers excluded the results of the first 5 observations. Also, to minimize the impact of the observers' presence, the researchers wore the same uniform as the personnel, established a friendly relationship with the personnel, and entered and exited the intensive care unit at the same time as the personnel.
Conclusion
According to the results of the field observations, aside from nurses who are considered the primary responders to alarms, other individuals, including the cleaning staff and even patients' visitors, occasionally respond to alarms. Application of the manual for management of alarms in intensive care units can prove useful in decreasing the number of alarms and, consequently, their negative consequences. Considering the broadness of the issue of alarm fatigue and its serious consequences for both patients and nurses, it is suggested that alarm fatigue be measured in nurses and the necessary steps, including educational workshops and classes, be taken to deal with this issue.