Abstract
The clinical approach to the critically ill patient has changed dramatically over the last several decades from one of deep sedation to that of mobilizing patients on mechanical ventilation and limiting sedation. The ABCDEF bundle is a multidisciplinary, evidence-based approach to the holistic management of critically ill patients that aims to optimize patient recovery, minimize iatrogenesis, and engage and empower the patient and family during their hospitalization. To achieve this goal, the bundle includes assessments for pain, delirium, and readiness to stop sedation and to start spontaneous breathing trials. It also encourages early mobilization of the patient, avoidance of restraints, and engagement with the family in bedside rounds to improve communication. Performance of this bundle reduces mortality, ventilator days, intensive care readmissions, delirium, coma, restraint use, and discharge to facilities in a dose-dependent manner. The respiratory therapist, as a key member of the critical care team, is essential to the implementation, performance, and success of the ABCDEF bundle. This review aims to describe each component of the ABCDEF bundle, provide evidence for both the impact of individual interventions as well as the entire bundle, and detail the importance of this multidisciplinary approach to the care of the critically ill patient.
- abcdef bundle
- analgesia
- sedation
- critical care
- delirium
- early mobility
- family engagement
- respiratory therapy
- intensive care unit
- intensive care unit liberation
- mechanical ventilation
Introduction
Millions of adults are admitted to ICUs in the United States each year,1 with improving survival rates despite increasing severity of illness.2 With falling mortality, critical care medicine now faces another growing challenge in the long-term cognitive, physical, and psychiatric impairments that follow critical illness.3–6 Given the growing recognition of these impairments and their link to in-hospital complications such as delirium, the first clinical practice guidelines for the management of pain, agitation, and delirium in adults patients in the intensive care unit (ICU PAD) were issued.7 These guidelines provided a framework for managing pain, agitation, and delirium in concordance with the most recent evidence highlighting the impact of sedation practices and delirium on the outcomes of ICU survivors. These recommendations were updated in the most recent 2018 Prevention and Management of Pain, Agitation/Sedation, Delirium, Immobility, and Sleep Disruption in the Adult Patients in the ICU (PADIS) Guidelines.8 These same evidence-based concepts were built into the ABCDE, and now ABCDEF, bundle as part of the ICU liberation campaign from the Society of Critical Care Medicine (SCCM) (Fig. 1).2,9,10 The ABCDEF bundle serves as a guide for multidisciplinary critical care, incorporating diverse specialties, including respiratory therapists (RTs), as partners in improving care for the sickest patients. The key components of the ABCDEF bundle are: (1) Assess, prevent, and manage pain; (2) Both spontaneous awakening trials (SAT) and spontaneous breathing trials (SBT); (3) Choice of analgesia and sedation; (4) Delirium – Assessment, Prevention, and Management; (5) Early Mobility and Exercise; and (6) Family engagement and empowerment.2 The ABCDEF bundle has been demonstrated to improve outcomes in multiples studies (Fig. 2). Compliance with the bundle is associated increased survival, reduced delirium, fewer days on mechanical ventilation, and fewer ICU readmissions in a dose-dependent manner.11 This review will discuss the evidence and implementation of each portion of the bundle, highlighting the benefits and remaining questions regarding the bundle and emphasizing the multidisciplinary nature of its success.
Assess, Prevent, and Manage Pain
Pain is a common, often daily, occurrence that can go unrecognized and undertreated in all types of ICUs.12 For example, prior to performance of various ICU procedures, pain is assessed only 35% of the time,13 although most ICU procedures cause a significant increase in pain.14 Pain is also a significant risk factor for the development of delirium in the critically ill.15–17 It is essential for the critical care team to actively assess and manage pain in the ICU to prevent complications and reduce suffering.
Critically ill patients are frequently sedated due to medication or their disease process and often are on mechanical ventilation, limiting their ability to report pain reliably. Due to those limitations, other methods of assessing pain are necessary in the ICU. There are two widely accepted and validated pain scales that utilize behavior and physiological measures to assess pain: the Behavioral Pain Scale,17 and the Critical-Care Pain Observation Tool.18,19 Both pain scales utilize a variety of bedside indicators to assess pain, such as facial expressions, body movements, and synchrony with the ventilator. A Behavioral Pain Scale score ≥ 5 or Critical-Care Pain Observation Tool score ≥ 3 represent significant pain that should be treated. The Critical-Care Pain Observation Tool has been shown to be feasible and simple to use at the bedside,20 and it improved the routine assessment of pain by nursing staff.21 Although these assessments are most often performed by nursing staff, RTs are critical in identifying manifestations of pain, which can include grimacing, asynchrony with the ventilator, and agitation.
When significant pain is identified by the care team, the preferred first-line pain management is the use of intravenous opioids.8 Adjunctive methods of pain control, such as nonsteroidal anti-inflammatory drugs and gabapentin, should also be considered and used in patients to reduce opioid doses in addition to nonpharmacologic measures that can reduce pain.22 Additionally, preprocedural analgesia should be provided to patients undergoing painful procedures or testing to limit discomfort. Adequately managing pain reduces delirium and facilitates performance of other components of the ABCDEF bundle, such as early mobilization and breathing trials.
Both SATs and SBTs
Coordinated and protocolized SATs and SBTs are foundational to liberation from mechanical ventilation and comprise an important part of the ABCDEF bundle. SATs involve the cessation of sedatives and narcotics in patients who pass an initial safety screen. Kress and colleagues23 demonstrated in a single-center, randomized, controlled trial of 128 subjects receiving mechanical ventilation that daily interruption of sedation and narcotics compared to usual care led to a significant decrease in ventilator days and improved ICU length of stay. In the same cohort, subjects in the intervention group had fewer symptoms related to post-traumatic stress disorder upon long-term follow-up than the usual care group.24 In a secondary analysis, subjects in the SAT group also had fewer instances of ventilator-associated pneumonia and other complications of ICU care.25 Similarly, deep sedation during critical illness has been associated with higher long- and short-term mortality and prolonged mechanical ventilation independent of severity of illness.26,27 Routine use of SATs reduces the overall dose of sedatives and narcotics and reduces time to liberation from mechanical ventilation and mortality.
Similar to the use of SATs, the routine use of SBTs facilitates ventilator weaning and liberation. Esteban et al28 reported that the use of breathing trials (2-h T-piece trials vs pressure support trials) reduced time on mechanical ventilation and was an acceptable method of discontinuing ventilator support. Subsequent work by Ely and colleagues29 demonstrated that daily screening and performance of SBTs resulted in a median of 4.5 d of mechanical ventilation compared to 6 d of mechanical ventilation in the control arm. In the multi-center, randomized, controlled Awakening and Breathing Controlled (ABC) trial, subjects randomized to a protocol of paired daily SATs and SBTs had fewer ventilator days (14.7 d vs 11.6 d; mean difference: 3.1 d, 95% CI 0.7–5.6) and shorter ICU and hospital length of stay compared to subjects randomized to a standard SBT protocol. This benefit extended beyond the acute hospitalization: subjects in the paired SAT/SBT group had lower mortality in the year following critical illness with a number needed to treat of 7.4 (hazard ratio 0.68, 95% CI 0.50–0.l92, P = .1).30
The use of protocolized paired SAT and SBT trials involves a coordinated set of steps to assess the safety of performing both the SAT and SBT individually (Fig. 3). If the patient passes the safety screen for the SAT, the SAT is then performed by the bedside critical care nurse by stopping any parenteral sedatives and narcotics. The bedside nurse subsequently assesses for signs of SAT failure as described in Figure 3. If the patient fails the SAT, sedation and analgesia is restarted at half the original dose and titrated to a specified goal. If the patient passes criteria for the SAT, the respiratory therapist will then perform an SBT safety screen. Similar to the screening process for the SAT, should the patient fail any of the safety criteria, then the patient remains on full ventilatory support and the steps are repeated again the next day. If the patient passes the safety screen, the SBT is attempted. The use of pressure support ventilation versus T-piece trials are often institution-dependent. Esteban et al28 showed that the rate of successful extubation (ie, remaining extubated for 48 h after an SBT) did not differ between the T-piece group and the pressure support ventilation group. Once the patient is on an SBT, the respiratory therapist then assesses the patient for any signs of SBT failure. If the patient shows any signs of SBT failure, the patient is then switched back to full mechanical ventilatory support. If the patient shows no sign of failure and tolerates 30–120 min of the SBT, the RT then informs the medical team and bedside nurse that the patient meets extubation criteria. The optimum duration of SBT is debated, although studies suggest that 30 min is likely sufficient and not different than 120-min trials.31 Once notified that the patient meets extubation criteria, the critical care physician at that time should consider extubation. Ultimately, the coordinated, multidisciplinary performance of SATs and SBTs as a part of the ABCDEF bundle results in earlier successful removal of mechanical ventilation and reduces ICU morbidity. RTs play an important role in helping liberate patients from ventilatory support.
Choice of Analgesia and Sedation
The C in the ABCDEF bundle refers to the choice of analgesia and sedation, consistent with the most recent PADIS guidelines. The focus is on goal-directed sedation and analgesia that reduces the overall drug burden and achieves light sedation. This includes routine assessment of pain in all ICU patients, utilizing validated measures as noted above as well as routine monitoring of level of consciousness and sedation depth. The recommended sedation scales from the PADIS guidelines include the Richmond Agitation-Sedation Scale (RASS) (Fig. 4) and the Riker Sedation-Agitation Scale (SAS). These instruments are similar in using graded point scales to describe patients level of consciousness from comatose (SAS = 1 or RASS = −5) to extreme agitation (SAS = 7 or RASS = +4).32 The RASS, for example, has exhibited reliability across multiple ICU settings and disciplines.33 The goal of analgesia and sedation in the critically ill patient should be a calm and alert state, allowing for patient–clinician and patient–family interactions but also facilitating ongoing medical support as needed in the ICU. Targeting light sedation (ie, a calm and alert level of consciousness) demonstrates a trend toward a shorter time to extubation and a reduced need for tracheostomy,8,34–36 and therefore should be the standard sedation goal in the absence of other extenuating clinical concerns necessitating deep sedation.
Pain control is considered the first-line therapy prior to considering the addition of sedating agents, which is a concept known as analgosedation (ie, an analgesia-first approach while limiting sedation as clinically appropriate). Parental opioids are the preferred first-line medications for pain control, and often the desired sedation depth, as well as pain control, can be achieved with analgesia alone.8 Should further sedation be needed for either patient comfort or for clinical indication, the guidelines recommend avoidance of benzodiazepines in favor of other agents such as dexmedetomidine or propofol and limitation of overall sedation exposure to the greatest extent possible. Higher exposure to sedatives is linked to greater mortality, longer time on mechanical ventilation, and delirium.26,37–39 The use of benzodiazepines has been reported to be an independent risk factor for the development of delirium in the ICU.40,41 Compared with the use of dexmedetomidine, the use of benzodiazepines was associated in multiple studies with fewer delirium-free days.42,43
While the PADIS Guidelines suggest the use of non-benzodiazepine sedatives, they provide limited guidance on a specific non-benzodiazepine agent of choice due to a research gap in the benefits and limitations of individual sedation agents. Based on several studies suggesting that propofol reduces time to extubation compared to benzodiazepines,44–46 the PADIS guidelines make a conditional recommendation for the use of propofol over benzodiazepines in critically ill patients who require sedation after cardiac surgery. In non-cardiac surgery patients undergoing mechanical ventilation, the parallel MIDEX-PRODEX trials evaluated whether dexmedetomidine was non-inferior to midazolam and propofol, respectively, in terms of time to target sedation and median duration of mechanical ventilation. Dexmedetomidine was found to be non-inferior to both midazolam and propofol in terms of time to target sedation without rescue medication and was associated with decreased duration of mechanical ventilation compared to midazolam but not propofol.47 The PADIS guidelines suggest the use of either dexmedetomidine or propofol over benzodiazepines in adults receiving mechanical ventilation, noting a low quality of evidence and the remaining unanswered questions regarding sedation choice.8 Ultimately, the choice of analgesia and sedation is focused on achieving light sedation through analgosedation.
Delirium: Assessment, Prevention, and Management
Delirium, the D in the ABCDEF bundle, is a pervasive form of acute brain failure in the critically ill and an important area of clinical investigation and management. Delirium is defined as an acute change in awareness and in attention that develops within hours to days with a waxing and waning course that is not explained by a preexisting neurocognitive disorder.48 Patients can develop hypoactive delirium, defined by a reduced level of consciousness with fluctuating attention and awareness, or hyperactive delirium, defined by increasing levels of agitation with fluctuating attention and awareness. Patients can also develop mixed delirium, consisting of both hyper- and hypoactive forms.49 Delirium is associated with increased mortality and long-term complications, such as long-term cognitive impairment, which is an acquired dementia after critical illness.3,50–52 The etiology of delirium is multifactorial, and certain precipitating factors include the use of sedating medications (particularly benzodiazepines), hypoxemia, sepsis, untreated pain, prolonged immobilization, sleep deprivation, and multiple medical comorbidities.53,54
Detection of delirium in the ICU is of paramount importance. A number of tools to screen and diagnose delirium at the bedside have been developed. The two most commonly used and validated instruments are the Intensive Care Delirium Screening Checklist (ICDSC)55 and the Confusion Assessment Method for the Intensive Care Unit (CAM-ICU) (Fig. 5). Both the ICDSC and the CAM-ICU have been shown to be sensitive in the detection of delirium compared to the criteria set out in the Diagnostic and Statistical Manual of Mental Disorders.56 The CAM-ICU demonstrates greater specificity for the diagnosis of delirium57 and consists of four components: (1) acute onset of mental status change or fluctuating course, (2) evidence of inattention, (3) evidence of disorganized thinking, and (4) altered level of consciousness (Fig. 5). Delirium is diagnosed when a patient exhibits components 1 and 2 in addition to either component 3 or 4.58 Delirium screening with one of the above tools should occur daily in the ICU, and ideally multiple times throughout the day.
Pharmacologic prevention of delirium remains an active area of investigation, although routine use of pharmacologic agents in all critically ill adults is not recommended in the 2018 PADIS Guidelines. The randomized, double-blind, placebo-controlled REDUCE trial investigated whether prophylactic use of haloperidol would improve survival or reduce delirium incidence and increase delirium- and coma-free days. It showed no improved survival in the intervention group and no statistical difference in any of the delirium outcomes compared to placebo.59 Work by Su and colleagues60 suggested that dexmedetomidine prevented delirium in elderly adults following non-cardiac surgery, although this work involved a low severity of illness in a postoperative patient population that limited its generalizability to most critically ill patients. A similar trial evaluated whether the use of low-dose nocturnal infusions of dexmedetomidine prevented delirium; the authors reported that the proportion of patients who remained free of delirium during their ICU admission was greater in the intervention group.61 Limitations of that study included its sample size and the limited number of total delirium-free days. Other agents, such as melatonin, have sparked interest but data regarding efficacy are limited. Currently, the PADIS guidelines do not recommend pharmacologic prevention of delirium and instead recommend a focus on improving sleep hygiene, practicing early mobilization, and improving the ICU environment to help prevent the development of delirium.
Management of delirium once it has developed should focus on the identification of any potentially modifiable precipitating factors, such as unrecognized infection or untreated disease, removing offending drugs, and optimizing the patient environment by promoting sleep, reducing noise, practicing early mobilization, and providing needed assistive devices such as hearing aids and eye glasses.62,63 The respiratory therapist will often note evidence of pain and patient–ventilator asynchrony, which could be signs of delirium as well as precipitating factors for its development. Treatment of the underlying critical illness remains the foundation for delirium resolution because there are few pharmacologic management options to treat delirium after it develops. Antipsychotics have traditionally been used to treat delirium, but there is no definitive evidence that these prevent or reduce the duration of delirium.64–66 The recent MIND-USA trial, a multi-center, double-blind, randomized, placebo-controlled trial of haloperidol and ziprasidone versus placebo in the treatment of delirium during critical illness, reported no difference in median days alive without delirium or coma.67 There were also no other significant differences in median days to ICU discharge, median days to freedom from mechanical ventilation, or 30- and 90-d mortality. The mounting evidence shows that the treatment of delirium with antipsychotics is not effective and that other potential therapeutic options need further exploration.
Early Mobility and Exercise
Early mobilization is an important but often underutilized component of the ABCDEF bundle. Critically ill patients are frequently bed-bound and immobile for days due to their illness, sedation, and hemodynamic instability. Often, there is significant concern from the care team regarding the safety of early mobilization and physical activity in ICU patients; however, mobilization has been demonstrated to be safe, even in patients receiving invasive support such as mechanical ventilation, renal replacement therapy, and extracorporeal membrane oxygenation cardiopulmonary support (Fig. 6).68–70 Prolonged immobilization results in muscle wasting and weakness, as well as the development of ICU-acquired weakness, leading to poor functional status, disability, and reduced exercise capacity in ICU survivors for years following their illness.71–74
RTs are integral in assisting patients with early mobilization, particularly patients receiving significant respiratory support, and can advocate for early mobility based on the evidence of safety and benefit. Schweickert and colleagues75 demonstrated that early (ie, < 3 d of mechanical ventilation) physical and occupational therapy and mobilization, paired with a daily SAT, reduced the duration of delirium and improved functional status at discharge with minimal risk. Notably, early mobilization has been the only intervention shown to decrease the number of days of delirium.76 Mobilizing patients early in their ICU course has also been shown to be safe and is associated with decreased ICU and hospital length of stay.77 Another study with later initiation of physical therapy and mobilization, however, did not demonstrate any improvement in long-term physical functioning,78 suggesting that mobilization early in the course of critical illness is important, although this was not corroborated in a similar study of early mobilization by Morris and colleagues.79 Taken together, all of these studies suggest that mobilization of critically ill patients, including those on mechanical ventilation, can be done safely and can improve long-term outcomes.
Early mobility is an integral part of the ABCDEF bundle of care, and increasing compliance with individual components of the bundle has demonstrated substantial improvements in mortality, delirium duration, ICU and hospital length of stay, and days free from mechanical ventilation.11,80 Given this, early mobility should be advocated as a part of the routine care of the critically ill patient.
Family Engagement and Empowerment
In the ICU, patients are often unable to communicate with their care team and their families due to their underlying illness and medical interventions. Patient-centered care respects individual patient values and informs clinical decision making. Failing to engage family members and adequately communicate represents a significant missed opportunity to identify treatment preferences that are in line with the values of the patient and that respect their inherent dignity and value.81 In the ICU setting, empowering family members to engage in shared decision making and facilitating open communication is of paramount importance.
Critical illness can lead to significant psychological burden for not only patients but also their families.5,82–84 The ABCDEF bundle has grown to include family engagement and empowerment for this very reason because fully engaging families during this time gives voice to patients and their loved ones. Heyland and colleagues85 showed that family satisfaction with medical care is higher when they are engaged and involved in their loved one's care, and clinician-facilitated support during family conferences also improved satisfaction with care and communication.86 Family presence during rounds also improved some families' impression of communication and understanding of the patients' care.87 Although a study evaluating a directed family-support intervention for surrogates of patients with critical illness did not show a reduction in psychological distress in family members, it did increase families' perception of quality communication and patient and family centered care as well as reduce ICU length of stay.88 Studies of ICU diaries, where patients or their families write down daily thoughts and memories of their ICU stay, have been associated with reduced symptoms of post-traumatic stress disorder in patients and families.89,90 For patients who ultimately have illnesses that are not survivable, focused communication with family members through conferences and palliative care or ethics consultation facilitated the transition of care goals to palliative and comfort-focused measures and limited a protracted dying process.91–93 Additionally, family presence during cardiopulmonary resuscitation has been associated with a reduced incidence of symptoms of anxiety and depression as compared to those who were not present during the resuscitation efforts.94
Family engagement and empowerment in the ICU is multidisciplinary and necessitates input from multiple clinicians, including RTs. Providing information regarding the role of each team member, answering questions regarding diagnosis and treatment, and engaging the family in the care of their loved one facilitates a supportive environment and can reduce the stress of acute illness. The experience of critical illness reaches beyond just the patient to family members and loved ones who continue in supportive roles. The ABCDEF bundle, by including family engagement, helps build a relationship of trust between patients, families, and their medical team that facilitates communication and respect and puts patients and their values at the forefront of care.
The ABCDEF Bundle: Synergistic Care Improving Outcomes
Combining processes of care together into a “bundle” is an oft-utilized tactic in medicine, and each of the individual components of the ABCDEF bundle have demonstrated benefit in multiple peer-reviewed studies in critically ill subjects. In the ICU, the track record of bundles in improving outcomes is mixed, however. Sepsis bundles and central venous catheter bundles have been successful in reducing mortality and complications from common ICU interventions.95,96 However, a complex quality-improvement bundle including low tidal volume ventilation, moderate sedation, venous thromboembolism prophylaxis, nutrition, head of bed elevation, and urinary and central venous catheter use in 118 Brazilian ICUs did not change mortality or improve patient outcomes.97 Each of these assorted interventions have been shown to be beneficial, but when combined into a larger, more complicated initiative, outcomes did not change. Although the reasons this particular bundle may not improve outcomes are complex, one important reason is that the individual interventions were not necessarily symbiotic.
The ABCDEF bundle is multi-faceted, but each of the individual components are synergistic and linked. For example, managing pain and achieving light sedation in a critically ill, mechanically ventilated patient helps prevent delirium but also facilitates early mobility as well as helps the patient be more interactive with family. The importance of this synergy has been demonstrated in 2 large studies. In a large quality-improvement study across 7 community hospitals in California, Barnes-Daly et al80 showed that compliance with the ABCDEF bundle, both total and partial, was associated with decreased mortality and an increase in delirium- and coma-free days independent of severity of illness and age (Fig. 1). Notably, the study showed that, for every 10% increase in partial bundle compliance, there was a 7% higher odds of hospital survival. In a seminal study of > 15,000 subjects across 68 academic, community, and federal ICUs, performance of the ABCDEF bundle was associated with multiple improved outcomes, including hospital death within 7 d, days of mechanical ventilation, days of delirium and coma, restraint use, ICU readmission, and discharge to a facility (Fig. 7 and Fig. 8).11 In this study, outcomes were related to the proportion of bundle performance in a dose-dependent manner, with higher proportions of bundle performance correlating with better outcomes. These results demonstrate the benefit of bundling and coordinating interdependent processes of care that address the complex nature of critical illness and highlight the importance of a multidisciplinary approach.
RTs are uniquely positioned to ensure the successful implementation of the ABCDEF bundle. Routine assessment of readiness for extubation through performance of SBTs, communicating evidence of pain or ventilator asynchrony to the bedside nurses, enabling early mobilization, and educating families on what to expect while patients are receiving respiratory support are all crucial elements related to the ABCDEF bundle. RTs also facilitate communication between physicians, nurses, physical therapists, and other members of the care team. Additionally, utilizing a multi-layered process of care can have barriers to implementation,98–100 so understanding the individual elements, the impact that the ABCDEF bundle has in the care of critically ill patients, and the unique culture and organization of ICUs puts RTs in an instrumental position to implement best practices and provide insight into the necessary requirements for building the bundle in their own institutions.
Conclusions and Future Directions
In the last several decades, the care of the critically ill patient has morphed from one of deep sedation, limited mobility, and minimal family engagement to one of light sedation, early mobility, recognition and management of delirium, and increasing family empowerment. These changes came in response to the recognition of the long-term consequences of critical illness and the impact of medical interventions routinely performed in the ICU. The ABCDEF bundle has been developed over time to address these needs, and it is improving the care of our sickest patients, but there is still more work to be done.101 Future research questions moving forward are numerous but include identifying optimum sedation agents for patients on mechanical ventilation both with and without delirium, optimizing implementation in ICUs with varying amounts of resources, and identifying strategies to reduce family and caregiver distress during and after critical illness. RTs are a vital link in the implementation the ABCDEF bundle and in promoting culture change, which will continue to be crucial to the success of critical care medicine in the years ahead.
Footnotes
- Correspondence: Matthew F Mart MD, Division of Allergy, Pulmonary, and Critical Care Medicine, Department of Medicine, Vanderbilt University Medical Center, Nashville, TN 37212. E-mail: matthew.f.mart{at}vumc.org.
This work was supported by the National Institutes of Health (grants T32HL087738, 1R01AG058639, and 1K76AG054864), and the Department of Veterans Affairs Tennessee Valley Healthcare System Geriatric Research, Education and Clinical Center.
- Copyright © 2019 by Daedalus Enterprises
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