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Original research
What stops hospital clinical staff from following protocols? An analysis of the incidence and factors behind the failure of bedside clinical staff to activate the rapid response system in a multi-campus Australian metropolitan healthcare service
  1. Bill Shearer1,2,
  2. Stuart Marshall2,3,
  3. Michael David Buist4,
  4. Monica Finnigan1,
  5. Simon Kitto5,
  6. Tonina Hore6,
  7. Tamica Sturgess6,
  8. Stuart Wilson6,
  9. Wayne Ramsay6
  1. 1Southern Health Quality Unit, Monash Medical Centre Clayton, Clayton, Melbourne, Australia
  2. 2Academic Board of Peri-operative Medicine, Monash University, Prahran, Melbourne, Australia
  3. 3Southern Health Simulation and Skills Centre, Monash Medical Centre, East Bentleigh, Melbourne, Australia
  4. 4University of Tasmania Rural Clinical School, Burnie, Tasmania, Australia
  5. 5University of Toronto, Department of Surgery, Toronto, Canada
  6. 6Monash Medical Centre, Clayton, Melbourne, Australia
  1. Correspondence to Professor Michael David Buist, School of Medicine, University of Tasmania, Private Bag 3513, Burnie, TAS 7320, Australia; michael.buist{at}utas.edu.au

Abstract

Objective To explore the causes of failure to activate the rapid response system (RRS). The organisation has a recognised incidence of staff failing to act when confronted with a deteriorating patient and leading to adverse outcomes.

Design A multi-method study using the following: a point prevalence survey to determine the incidence of abnormal simple bedside observations and activation of the rapid response team by clinical staff; a prospective audit of all patients experiencing a cardiac arrest, unplanned intensive care unit admission or death over an 8-week period; structured interviews of staff to explore cognitive and sociocultural barriers to activating the RRS.

Setting Southern Health is a comprehensive healthcare network with 570 adult in-patient beds across four metropolitan teaching hospitals in the south-eastern sector of Melbourne.

Measurements Frequency of physiological instability and outcomes within the in-patient hospital population. Qualitative data from staff interviews were thematically coded.

Results The incidence of physiological instability in the acute adult population was 4.04%. Nearly half of these patients (42%) did not receive an appropriate clinical response from the staff, despite most (69.2%) recognising their patient met physiological criteria for activating the RRS, and being ‘quite’, or ‘very’ concerned about their patient (75.8%). Structured interviews with 91 staff members identified predominantly sociocultural reasons for failure to activate the RRS.

Conclusions Despite an organisational commitment to the RRS, clinical staff act on local cultural rules within the clinical environment that are usually not explicit. Better understanding of these informal rules may lead to more appropriate activation of the RRS.

  • Rapid response systems (RRS)
  • medical emergency team (MET)
  • cardiac safety
  • cardiac arrest
  • hospital culture
  • adverse events
  • epidemiology and detection
  • crisis management
  • chronic disease management
  • comparative effectiveness research

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https://doi.org/10.1136/bmjqs-2011-000692

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    Objective

    Failure of bedside hospital clinical staff to follow established treatment protocols has been identified as a common factor in patients having an adverse event during their hospitalisation. Post hoc analysis1 of the data from the Australian Quality and Health Care Study (AQHCS)2 found that ‘that misapplication of, or failure to apply a rule; or use of a bad or inadequate rule’ and ‘violation of a protocol or rule’ together occurred in 13.6% of the adverse events identified in the AQHCS. These two iterative categories of adverse event causation were associated with death or permanent disability in 26% and 28% respectively of adverse events identified in the AQHCS. Of most concern, the authors rated the degree of preventability of these two causation categories at 90% and 80% respectively based on the actual adverse events in the AQHCS. Likewise, a number of smaller mostly retrospective single institution studies have found various associations between failure to follow established treatment protocols and guidelines for clinically deteriorating patients and increased mortality.3–7

    One strategy to counter the problem of in-hospital adverse events has been the use of the rapid response system (RRS) to manage clinically deteriorating patients. In essence a RRS has two essential components: first an afferent arm that is a system of rules that determine the criteria for activation of the rapid response team; and second, the efferent arm which is the system of response once the activation criteria are breached. Varying types of RRS are now common in many European, North American and Australasian hospitals.8 ,9 In its simplest form a RRS is merely a rule or protocol that requires the bedside clinical staff to comply with the critical requirement of activating the RRS for it to be of benefit.10 In the Medical Emergency Response Intervention Trial (MERIT).11 there was a significant rate of failure to activate such a system in the control and intervention hospitals that may have contributed to the equivocal results of the study. Specifically, in the 11 control hospitals over the 6-month study there were 246 cardiac arrests. In 44% of these arrests the bedside staff did not activate an emergency response despite the observations fulfilling the response criteria for an emergency team call. Similarly, of the 12 hospitals assigned to the RRS intervention, there was still a failure rate of 30% to activate the RRS in the 250 cardiac arrests that occurred.

    Anecdotally, failure to activate the RRS has been thought to be associated with inadequate education about recognition of clinically deteriorating patients or insufficient knowledge of the RRS. In support of this is a post hoc analysis of the MERIT data12 that indicates an inverse relationship between the frequency of emergency response team calls (in the control and intervention hospitals) and the primary outcome measures of cardiac arrest, critical unit admission and hospital mortality. Similarly, Santamaria et al13 reported data from one of the intervention hospitals of the MERIT study 5 years after the study suggesting that an intervention like a RRS takes years not months to derive benefits. Theoretically then, the rate of RRS activation should be high in a system where it has been in place for many years and the clinical staff have adequate training.

    In 2007 the Quality and Safety Unit, Southern Health, Melbourne identified 11 sentinel cases in which significant patient harm occurred in association with the failure of bedside staff to call the medical emergency team. This was despite the fact that our organisation had a mature policy and procedure in place for the activation of the RRS that has been well established with an organisational commitment to its use.14 ,15 Attempts to rationalise and pattern-match the underlying features of these incidents using clinical reviews and root cause analyses were unsuccessful. There appeared to be no obvious cause in terms of poor staff training, lack of motivation or understanding of the patients' clinical states.16

    While previous studies17–21 have documented the incidence of failure of bedside clinical staff to activate an emergency response team, to our knowledge no study has investigated the reasons why staff do not activate the RRS. As such, we undertook a multi-method examination to determine the incidence of clinical staff failing to call the RRS and the human and sociological factors that may be involved.

    Design

    Ethics approval

    The Southern Health Research and Ethics Committee exempted this study from requiring ethics approval because it fulfilled the NHMRC criteria for a quality assurance project.

    Methods and participants

    We have previously published the methodology for this study.22 In summary there were three parts to this study.

    Point prevalence study of missed RRS incidence

    On 17 April 2009 between 11:00 and 12:00 all adult inpatient observation charts were reviewed (excluding critical care areas such as intensive care units (ICUs), high dependency units, the emergency department and the theatre complex). Evidence of documented physiological instability as defined by the RRS activation criteria (table 1) was determined by review of the patient observation charts over the previous 24 h. If patients fulfilled these physiological criteria then the actions of the staff in response to clinical instability were recorded. If the RRS was not activated when RRS activation criteria were met, the event was termed a ‘missed RRS call’.

    View this table:
    Table 1

    The rapid response system physiological criteria or triggers

    Prospective study of missed RRS calls

    Over an 8-week period from 26 April to 7 July 2009 all cardiac arrests and unplanned ICU admissions from the ward areas were examined to determine if the patient fulfilled the activation criteria for a RRS call (table 1) for a minimum of 4 h in the 24 h period prior to the index event. In the event that the RRS was not activated, all the clinical staff involved were interviewed (see below) and these events were also labelled ‘missed RRS call’.

    Interviews of staff members involved in missed RRS calls

    The clinical staff involved in ‘missed RRS calls’ in the first two parts of the study were interviewed (online appendix 1). These staff members included the junior medical and nursing staff and members of the medical emergency or intensive care teams that were called to assist. The interview questions were derived from the cognitive theory of situation awareness23 and from brief open-ended questions designed to explore the sociocultural barriers identified in health systems.24

    Quantitative data were recorded as frequency data as this was an exploratory study and not designed to distinguish adverse event rates among clinical areas. Interview responses were coded independently by two coders for themes and the coding system iteratively developed until agreement was achieved.25

    Setting

    Southern Health is a comprehensive university tertiary healthcare provider for the south-eastern suburbs of Melbourne. Over 13 000 staff service a catchment population of 880 000 and provide acute health services at four hospital sites; all acute services are provided with the exception of burns, spinal injury and major organ transplantation. Southern Health was an early and enthusiastic adopter of the RRS with establishment of the medical emergency team in one hospital in 1996. This resulted in substantial and significant improvements in patient outcome14 ,15 and this system of care was standardised throughout the organisation by 2006. Additionally our organisation committed to training all junior members of clinical staff in the purpose built simulation centre.26

    Results

    Incidence of physiological and missed RRS calls

    On the day of the point prevalence study, 23 (4.04%) patients fulfilled the activation criteria for a RRS call in the 24 h before the index event according to the 570 observation charts that were surveyed (table 2). The RRS was not activated in 10 (1.75%) of these patients (missed RRS call). The research team activated the RRS for one patient who was subsequently admitted to the ICU and underwent emergency surgery that day. Hypotension and oxygen de-saturation were the most common reasons for RRS call activation (73.3% and 80.0% respectively).

    View this table:
    Table 2

    Adverse event and rapid response system (RRS) data collected from the point prevalence study and the prospective study period

    Prospective identification of missed RRS calls

    Over the prospective study period a further 31 cases were identified across the four acute hospital sites (table 2).

    Interviews of clinical staff involved in a missed RRS call

    Incomplete qualitative data were obtained from 8 of the 91 interviews for questions relating to sociocultural barriers to activation of the RRS and so were not used.

    Cognitive barriers for failing to activate the RRS

    Even though they did not activate the RRS, the majority of staff in the prospective study (63 of 91, 69%) recognised that the patients met the calling criteria. Furthermore, 69 of the 91 respondents (75.8%) were either ‘quite concerned’ (33 of 91, 36.3%) or ‘very concerned’ (36 of 91, 39.6%) about their patient at this time. Fifty-seven respondents (62%) were unaware that their patient had been classified as a missed RRS, and of these, 27 (47.4%) thought the patient would deteriorate despite treatment.

    Sociocultural barriers of failure to activate RRS

    Ten themes were identified in the responses of staff involved with missed RRS calls. The staff believed they would be perceived by their nursing and medical colleagues in similar ways had they activated the RRS. Many stated their colleagues would be supportive of whatever actions they felt necessary (40 of 83, 48.2% for nursing colleagues, 21 of 83, 25.3% for medical colleagues) with fewer concerned there would be a negative or hostile response (11 of 83, 13.3% for nursing colleagues and 22 of 83, 26.5% for medical colleagues) (figure 1).

    Figure 1
    Figure 1

    Thematic analysis of responses to the question: ‘How would you think you would be perceived by your nursing/medical colleagues if you called a MET call now?’

    One of the main barriers given by respondents was a feeling that they should be able to manage patients by themselves on the ward (34 of 83, 41.0% for nursing staff and 33 of 83, 39.8% for medical staff).

    Actions and explanations for the delay of activation of the RRS

    When activation of the RRS was delayed four themes were identified, including the need to wait for further investigations, and treatment and reviews by the treating and ICU teams. (table 3). When the RRS was not activated at all a further eight themes were identified (table 3). The most common of these were that the RRS did not need to be activated and that the assembled team had the necessary expertise. This was most commonly noted when the physiological instability was in the area of expertise of the treating team (eg, tachycardia on the cardiology ward). A significant proportion of interviewees (25 of 83, 30.1%) believed the patient had already been discussed with the ICU team and felt that continued responsibility for the patient was unclear.

    View this table:
    Table 3

    Thematic analysis of structured interview responses from the prospective data collection phase. All patients experienced a missed RRS call with an adverse clinical event

    Discussion

    Principle findings

    On the day of the point prevalence study, 1 in 25 patients across the four acute care hospitals fulfilled the activation criteria for the RRS. The RRS was not activated in 42% of instances, despite the maturity of the RRS and educational support for its use in our organisation.

    Interviews with staff involved with missed RRS calls revealed that, even though they did not activate the RRS, nearly three-quarters of respondents recognised that their patients met the RRS activation criteria and a similar proportion were concerned about their patients' wellbeing. In these situations the bedside staff took other actions to manage their patients, which in most cases involved further investigations, treatments or clinical reviews (table 3). Of concern though, a minority of respondents (nurses 13% and doctors 26%) were concerned about a negative or hostile reaction from colleagues for activating the RRS.

    The most common reason for failure to activate the RRS was that the bedside staff felt that the clinical situation was under control in the ward setting. The second most common reason was that the critical care team had already been involved but that there were no critical care beds available. Less common reasons were a feeling that the bedside clinical team had enough experience to manage the situation without activating the RRS; poor communication and prioritisation by the medical team involved; and failure to repeat abnormal observations. Taken together these reasons suggest that although staff recognised that their patients were in difficulty, they elected not to activate the RRS while further clinical investigations and clinical reviews were pending. Half of respondents felt that the clinical situation was under control in the ward setting. To a certain extent, data from the point prevalence study validate the experience of the bedside clinical staff; namely that among the 23 patients who met RRS activation criteria, only one had a serious adverse event. The other 22 patients had no adverse consequences irrespective of whether the RRS was activated or not. These results suggest that from the perspective of bedside staff there is not sufficient ‘face validity’ in the sensitivity and specificity of the RRS activation criteria. Therefore bedside staff re-prioritise the requirement for RRS activation based on the particular clinical scenario, taking into account a multitude of factors: the environment, the status of pending investigations, the perceived competence of attending medical staff, and the degree of involvement of critical care or critical outreach. However, one RRS missed call resulted in prolonged critical care admission with multiple reoperations. Potentially, if timely RRS activation had occurred this could have been avoided. Therefore, from an administrative and more specifically critical care viewpoint, prevention of these types of critical admissions is of huge benefit to the patient and the hospital as a whole. However, from the viewpoint of bedside staff, in most instances of RRS activation breach, the patients come to no harm. This may explain why it takes so long for the RRS to be completely accepted within the culture of a particular hospital system, simply because the frequency of useful RRS activations is low and that it takes years for bedside staff to accept and value such a system.

    An additional but less common reason for not activating the RRS was prior involvement of critical care teams in the management of patients who fulfilled activation criteria. Thirty per cent of respondents stated that if the critical care team had been involved with the patient (and particularly if no critical care bed was available) then the requirement for a RRS call was negated. This may reflect a perception that critical care teams should manage critically ill patients in the critical care unit and that other critically ill patients in the hospital should be managed by other clinical teams with the assistance of the critical care team.

    Across the four hospitals in this study there was a different pattern of events during the study period. Casey, one of the newer (2002) smaller community hospitals with no on-site critical care service, had 18 RRS activations, none of which were assessed as being missed. The other smaller hospital, Moorabbin, an elective surgical facility that also has no on-site critical care service, had 22 RRS activations but only one missed RRS call. In contrast, the two large acute tertiary referral centres accounted for almost all the missed RRS calls and accounted for all but one of the subsequent interviews. Although both hospitals had a similar RRS activation rate the incidence of missed RRS calls was much less at Dandenong (0.60 vs 1.46 events per 1000 acute adult bed days). As such, the majority of the staff interviews took place at Clayton. Also, at Dandenong, the incidence of cardiac arrest calls and unplanned critical care admissions was less than half that at Clayton. This may reflect a difference in case mix at these two hospitals as Clayton has a number of tertiary specialty referral units (neurology, renal, cardiac and neuro-surgery) that are not present at Dandenong. Alternatively, these differences may be because Dandenong had a RRS in place for 13 years at the time of the study whereas the RRS at Clayton had only been in place for 3 years. Despite this, there were still 13 missed RRS calls across the point prevalence and prospective parts of this study at Dandenong.

    Strengths and weaknesses of the study

    The main limitation of this study was the relatively low incidence of missed RRS calls that could be explained by the maturity of the RRS system. Consequently fewer interviews than anticipated could be performed during the point prevalence stage. Despite this, we were able to refine the coding of the qualitative responses for the prospective case collection stage. These qualitative data are contaminated in part by the knowledge that the patients involved had suffered an adverse event (cardiac arrest, unplanned ICU admission or death) following a period of physiological instability. Interviews were abandoned if conducted more than 72 h following the adverse event. This led to a reduced number of interviews, but ensured that the data collected were fresh in the respondents' minds. Although the data from this study come from a single organisation, the four acute hospitals involved each have unique characteristics and consequently we believe the results can be generalised.

    Conclusion

    There are two important messages from this study. First, the main reason why staff did not follow the RRS activation protocol was not failure of cognition, but rather local sociocultural factors and intra-professional hierarchies in the clinical areas. On this basis, we question the value of efforts to improve RRS effectiveness by making such patients more identifiable (eg, colour-coded observation charts), the push for an increase in the frequency of RRS activation and even the suggestion that RRS protocols become mandatory. Instead, the results suggest that there should be more effort in understanding individual and bedside cultural issues that may be preventing staff from activating the RRS. For example, in this study, referral to or involvement of critical care teams, particularly when the critical care unit has no beds, may confuse the situation for the general bedside ward staff caring for the patient.

    Second, implementing systems of care that significantly alter the traditional hierarchical referral model of care, regardless of their potential benefits, takes years to appropriately implement. As mentioned above, we believe this may reflect the lack of ‘face validity’ that bedside staff may have for the RRS because of the perceived poor sensitivity and specificity of the activation criteria. The decision of whether to activate the RRS was often made by junior staff members who do not have the clinical experience to safely make this decision. While a RRS call gives junior staff members the opportunity to ask for help if they are uncomfortable with the clinical situation, some clearly believed that their colleagues expect them to cope with some situations. This expectation was confirmed by Stewart27 in a study across 21 hospitals in the UK which analysed decision-making by pre-registration house officers on whether or not to call for senior help. This study found that the decision to call for help is a complex judgement that balanced the desire for clinical autonomy with the understanding of certain consequences to self, senior colleagues and patients. In our study, there was a common belief that the treating team should be able to deal with problems close to their area of specialty. For example, the cardiothoracic surgery team would be able to manage patients with tachy-arrhythmias but may perhaps struggle to deal with patients who had a drop in their Glasgow Coma Score. When deterioration occurred within the area of specialty the junior staff would be more likely to call senior nurses and doctors within the specialty rather than activate the RRS. This context sensitivity of the RRS has not previously been described but appears to be a strong sociocultural influence on whether junior staff activate the RRS.

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    Footnotes

    • Guarantor for the study: Dr Bill Shearer.

    • Funding This study was supported by a grant of $75 000 from the Victorian Managed Insurance Agency.

    • Competing interests None.

    • Provenance and peer review Not commissioned; externally peer reviewed.