Predicting death and readmission after intensive care discharge

doi:10.1093/bja/aen069

BJA Advance Access published online on April 2, 2008
British Journal of Anaesthesia, doi:10.1093/bja/aen069

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Predicting death and readmission after intensive care discharge

A. J. Campbell¹^,*, J. A. Cook², G. Adey³ and B. H. Cuthbertson²

¹ Department of Anaesthesia, Western Infirmary, Glasgow G11 6NT, UK
² Health Services Research Unit, Health Sciences Building, University of Aberdeen, Foresterhill, Aberdeen AB25 2ZD, UK
³ Intensive Care Unit, Aberdeen Royal Infirmary, Foresterhill, Aberdeen AB25 2ZN, UK

^* Corresponding author: Department of Anaesthesia, Western Infirmary, Gartnavel General Hospital, 30 Shelly Court, Glasgow G12 0YN, UK. E-mail: alison.campbell3{at}nhs.net

Accepted for publication February 12, 2008.

Abstract

Top
Abstract
Introduction
Methods
Results
Discussion
Acknowledgement
References

Background: Despite initial recovery from critical illness, many patientsdeteriorate after discharge from the intensive care unit (ICU).We examined prospectively collected data in an attempt to identifypatients at risk of readmission or death after intensive caredischarge.

Methods: This was a secondary analysis of clinical audit data from patientsdischarged alive from a mixed medical and surgical (non-cardiac)ICU.

Results: Four hundred and seventy-five patients (11.2%) died in hospitalafter discharge from the ICU. Increasing age, time in hospitalbefore intensive care admission, Acute Physiology and ChronicHealth Evaluation II (APACHE II) score, and discharge TherapeuticIntervention Scoring System (TISS) score were independent riskfactors for death after intensive care discharge. Three hundredand eighty-five patients (8.8%) were readmitted to intensivecare during the same hospital admission. Increasing age, timein hospital before intensive care, APACHE II score, and dischargeto a high dependency unit were independent risk factors forreadmission. One hundred and forty-three patients (3.3%) werereadmitted within 48 h of intensive care discharge. APACHE IIscores and discharge to a high dependency or other ICU wereindependent risk factors for early readmission. The overalldiscriminant ability of our models was moderate with only marginalbenefit over the APACHE II scores alone.

Conclusions: We identified risk factors associated with death and readmissionto intensive care. It was not possible to produce a definitivemodel based on these risk factors for predicting death or readmissionin an individual patient.

Keywords: complications, death; complications, morbidity; intensive care; model, statistical

Introduction

Top
Abstract
Introduction
Methods
Results
Discussion
Acknowledgement
References

Despite initial recovery from critical illness requiring intensivecare unit (ICU) admission, many patients remain at risk of subsequentdeterioration and death. This may result in readmission to ICUor death on another ward or during the ICU readmission. Earlyidentification of patients at the highest risk would allow resourcesto be targeted appropriately and prevent avoidable morbidityand mortality. ICU readmission rates have been advocated asa marker of ICU quality on the basis that early readmissions(within 48 h) may indicate premature discharge or dischargeto an inappropriate clinical area.^{¹ ²} Although using readmissionrates as a quality indicator remains controversial,^³ early readmissionsare certainly a group who merit special attention. They havedisproportionately high hospital mortality^⁴–⁷ and includepatients in whom deterioration could probably have been avoided.Some may have been discharged prematurely from ICU due to eitherclinical resource limitations or poor discharge planning.^{⁵ ⁶}Similarly, some deaths after ICU may be preventable.^⁸ Interventionsaimed at reducing readmission or death after ICU requires timelyidentification of patients at highest risk. At present, thereis no validated scoring system to predict readmission or deathafter ICU discharge.

We aimed to determine whether we could utilize prospectivelycollected clinical data to identify which patients are at highrisk of readmission or death after ICU discharge. Identificationof these patients before they leave the ICU might allow thesepatients to be kept in ICU for a further period, to triage thepatient to an appropriate level of ongoing care, and to focusefforts in identifying early signs of deterioration.^⁹

Methods

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Abstract
Introduction
Methods
Results
Discussion
Acknowledgement
References

Local research ethics committee approval was not required asthe study was a secondary analysis of routinely collected andanonymized clinical audit data. We analysed the existing ScottishIntensive Care Society Audit Group database of all admissionsto a single mixed medical–surgical ICU over a 10 yr periodfrom January 1995 to January 2005. The ICU in Aberdeen operatesas a closed unit led by consultants in intensive care medicine.There are no strict protocols governing admission and dischargepolicies. Patients from all adult medical and surgical specialtiesare accommodated with the exception of cardiac surgery patientswho are cared for in a separate unit. A small number of postoperativecardiac patients requiring a prolonged stay for non-cardiaccomplications are transferred from the cardiac ICU. Data arecollected prospectively using Ward Watcher^TM software (CriticalCare Audit Ltd, Yorkshire, UK). Data recorded include patientage, sex, hospital and ICU admission diagnosis, severity ofillness scoring [Acute Physiology and Chronic Health Evaluation(APACHE) II and Simplified Acute Physiology Score (SAPS) II],date and time of unit and hospital admission and discharge,and patient outcome up to hospital discharge. The study cohortcomprised adult patients (>16 yr) admitted during this period.These patients were considered as a derivation cohort to attemptto identify factors associated with death and readmission tothe ICU. In order to study the number of patients readmittedrather than the number of readmissions, only the first ICU admissionduring the same hospital admission was analysed. Patients whodied during their first ICU admission were excluded from analysisbecause they were not at risk of readmission or death afterICU. Patients who were recorded as discharged for palliativecare or expected to die (as assessed by their consultant inintensive care medicine) were also excluded from the main analysis(Fig. 1). These patients and those who died in ICU wereincluded only in the presentation of baseline data.

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Fig 1 Flow diagram of patients included in study cohort.

Three different outcome groups were examined: patients who diedafter ICU discharge; patients who were readmitted within 48h of ICU discharge (early readmissions); and patients who werereadmitted at any time during the same hospital admission. Patientsfalling into more than one of these poor outcome groups wereincluded in each category since their outcome could not be identifiedprospectively. Data relating to each outcome category shouldtherefore be interpreted independently.

APACHE II^¹⁰ and SAPS II scores^¹¹ were calculated using standardmethods during the first 24 h of the first ICU admission. SAPSII has been found to have the best overall performance and APACHEII to have the best calibration when various severity of illnessscoring systems were tested in a large Scottish ICU databaseto predict hospital mortality.^¹² Daily Therapeutic InterventionScoring System (TISS) scores^¹³ were recorded over each 24 hperiod during ICU admission.

Data are presented as median (inter-quartile range) or as thenumber of cases and the proportion as appropriate. The associationof individual factors was assessed separately in a simple logisticregression model for each of the outcomes in turn. We then useda multivariable logistic regression to evaluate the relationshipbetween potential variables and outcome.

Gender and age were included in the multivariable analyses.Other predictor variables were included in multivariable logisticregression model if they were associated with ICU readmissionor death with P $≤$ 0.2 in the simple logistic regression analysis.An a priori decision was made that variables with more than5% missing data or with obvious co-linearity were not enteredinto multivariable logistic regression model. SPSS version 14was used for analysis. A base case analysis which included onlythe APACHE II score was also performed for each outcome. Calibrationand discrimination of the prediction model were assessed usingHosmer and Lemeshow goodness of fit test and the area underthe curve (AUC), respectively. Nagelkerke R² statistic was alsocalculated.

Results

Top
Abstract
Introduction
Methods
Results
Discussion
Acknowledgement
References

Over a 10 yr period, there were 6208 adult ( $≥$ 16 yr) admissions,of which 5725 were index admissions (first admission in a singleepisode of hospital admission). One thousand one hundred andninety patients died during their first ICU admission. One hundredand fifty-nine were recorded as discharged for palliative careor were expected not to survive. Four thousand three hundredand seventy-six adult patients were thus discharged alive fromICU without being recorded as expected to die or for palliativecare (Fig. 1). Patient characteristics are shown in Table 1.An outline of patient characteristics is presented in 2 yr timeslots to allow an assessment of potential changes over the 10yr study period (Table 2). Both case mix and ICU managementhave evolved over the 10 yr period, but no specific changesin policy have been implemented.

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Table 1 Patient characteristics for all ICU admissions during study period. Data are presented as median (inter-quartile range) or as percentages. APACHE, Acute Physiological and Chronic Health Evaluation; SAPS, Simplified Acute Physiology Score; ICU, intensive care unit; LOS, length of stay

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Table 2 Patient characteristics presented in 2 yr time slots over the study period. Data are presented as median (inter-quartile range) and numbers (percentages). CPR, cardiopulmonary resuscitation; ICU, intensive care unit; N/A, information not available

Four hundred and seventy-five patients (11.2%) of the studycohort died after ICU discharge. Hospital length of stay inthose who died after initial discharge from ICU was similarto those who survived to hospital discharge [14 (5–27)vs 13 (7–27) days]. Three hundred and eighty-five patients(8.8%) were readmitted to ICU during the same hospital admission.Hospital mortality in those who were readmitted at any timewas 40.2% and hospital length of stay after initial dischargefrom ICU was 32 (18–51) days.

The subgroup of readmissions who were readmitted within 48 hwas also examined. One hundred and forty-three patients (3.3%)were readmitted within 48 h of ICU discharge. Hospital mortalityin these early readmissions was 27.7% and hospital length ofstay after initial discharge from ICU was 31 (15–47) days.

Hospital mortality in those who were not readmitted was 8.4%and hospital length of stay after ICU discharge was 13 (7–24)days.

Factors associated with death, readmission, or readmission within48 h are shown in Tables 3–5.

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Table 3 Simple logistic regression of patients who died after ICU discharge with those who survived to hospital discharge. Data are presented as median (inter-quartile range) and numbers (percentages). OR, odds ratio; CPR, cardiopulmonary resuscitation; ICU, intensive care unit; HDU, high dependency unit; APACHE, Acute Physiological and Chronic Health Evaluation; SAPS, Simplified Acute Physiology Score; TISS, Therapeutic Intervention Scoring System. *Variable with <95% of data available

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Table 4 Simple logistic regression of patients who were readmitted to ICU at any time during index admission with patients who were not readmitted to ICU. Data are presented as median (inter-quartile range) and numbers (percentages) as appropriate. OR, odds ratio; CPR, cardiopulmonary resuscitation; ICU, intensive care unit; HDU, high dependency unit; APACHE, Acute Physiological and Chronic Health Evaluation; SAPS, Simplified Acute Physiology Score; TISS, Therapeutic Intervention Scoring System. *Variable with <95% of data available

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Table 5 Simple logistic regression of patients readmitted to ICU within 48 h with patients who were not readmitted within 48 h. Data are presented as median (inter-quartile range) and numbers (percentages) as appropriate. OR, odds ratio; CPR, cardiopulmonary resuscitation; ICU, intensive care unit; HDU, high dependency unit; APACHE, Acute Physiological and Chronic Health Evaluation; SAPS, Simplified Acute Physiology Score; TISS, Therapeutic Intervention Scoring System. *Variable with <95% of data available

Reason for readmission
Admitting diagnoses were grouped according to whether it wasthe same pathology as original admission or a new diagnosis.Diagnoses were further grouped on the basis of organ systeminvolved. Admitting diagnosis for both initial and readmissionwere available for 121/143 patients (85%). Forty-nine per centwere readmitted for the same or related diagnosis and 51% fora different diagnosis. Twenty-eight per cent of the total wasreadmitted with a new diagnosis of chest infection (initialadmitting diagnosis not respiratory infection); 2.5% with newsepsis (not chest); 2.5% after in-hospital cardiac arrest; 3%with new acute respiratory distress or acute lung injury; 4%with fluid overload; and 2% with cardiac failure. Between them,these diagnoses account for 42% of the 49% of readmissions fornew diagnoses. The remaining 7% were for miscellaneous reasons.

Multivariable logistic regression analysis
Admitting specialty was excluded from the multivariable analysisbecause of more than 5% missing data (28% missing). This wasnot recorded routinely until 1998. SAPS II scores and totalTISS scores were excluded because of expected co-linearity withAPACHE II scores and ICU length of stay, respectively. Factorsassociated with death or ICU readmission on multivariable analysisare shown in Tables 6–8.

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Table 6 Multivariable logistic regression of death after initial ICU discharge before hospital discharge. Data presented as adjusted odds ratios (95% confidence intervals). With continuous variables, odds ratio refers to odds associated with a unit increase in the predictor variable. Nagelkerke R² statistic was 0.162. Hosmer and Lemeshow goodness of fit test was not significant at 5%, P=0.103. AUC was 0.74. CPR, cardiopulmonary resuscitation; OR, odds ratio; APACHE, Acute Physiological and Chronic Health Evaluation; TISS, Therapeutic Intervention Scoring System

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Table 7 Multivariable logistic regression of readmission at any time after initial ICU discharge and before hospital discharge. Data presented as odds ratios (95% confidence intervals). With continuous variables, odds ratio refers to odds associated with a unit increase in the predictor variable. Nagelkerke R² statistic was 0.046. Hosmer and Lemeshow goodness of fit test was not significant at 5%, P=0.216. AUC was 0.65. CPR, cardiopulmonary resuscitation; ICU, intensive care unit; HDU, high dependency unit; OR, odds ratio; APACHE, Acute Physiological and Chronic Health Evaluation; TISS, Therapeutic Intervention Scoring System

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Table 8 Multivariable logistic regression of readmission within 48 h of initial ICU discharge. Data presented as odds ratios (95% confidence intervals). With continuous variables, odds ratio refers to odds associated with a unit increase in the predictor variable. Nagelkerke R² statistic was 0.02. Hosmer and Lemeshow goodness of fit test was not significant at 5%, P=0.269. Area under curve was 0.62. CPR, cardiopulmonary resuscitation; ICU, intensive care unit; HDU, high dependency unit; OR, odds ratio; APACHE, Acute Physiological and Chronic Health Evaluation; TISS, Therapeutic Intervention Scoring System

Discrimination ability was moderate for the three models: AUCof 0.74, 0.67, and 0.62 for predicting death after ICU discharge,early readmissions, and readmissions, respectively. On the basisof the Hosmer and Lemeshow goodness of fit test, there was noevidence of poor calibration for any of the three logistic regressionmodels. However, discrimination ability based only upon theAPACHE score was: AUC of 0.69, 0.63, and 0.59, respectively,suggesting limited gain from using the full model. The highestNagelkerke R² statistic was 0.162 for death after ICU discharge.Because of their limited usefulness, prospective validationof these models was not considered to be warranted.

Discussion

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Abstract
Introduction
Methods
Results
Discussion
Acknowledgement
References

A significant minority of patients deteriorate after dischargefrom intensive care. In our study, 8.8% of initial survivorswere readmitted to ICU and 11.2% died in hospital after ICUdischarge. These are consistent with data from other units.^⁶Not all of these deaths and readmissions will be preventable.A few patients discharged from ICU, although not expected todie, will have been assessed as unsuitable for readmission inthe event of deterioration. Despite this, some will inevitablyhave been readmitted and subsequently died. These patients arenot reliably detected by our data collection system and willcontribute to the post-ICU and readmission mortality figures.However, identification of other high-risk patients before theyleave ICU may allow extra resources to be targeted towards them.This may include delayed discharge; discharge to a high dependencyunit (HDU) or other ‘step-down’ unit; or more aggressivefollow-up on the wards.

Early readmissions may be particularly important. Within thisgroup, there may be a number of problems which might be attributedto premature discharge from ICU and which could have been prevented.^²⁶ Undoubtedly, other factors will also impinge on the earlyreadmission rate, including local high dependency facilities,quality of care on the ward after ICU discharge, and the presenceof ICU follow-up services. Whatever the reason for their deteriorationand readmission, it is clear that patients readmitted to ICUare at much higher risk of subsequent death than those who arenot readmitted.^⁴–⁶ It would be useful to be able to identifythose at risk of readmission before initial ICU discharge.

Not surprisingly, our data show that death after ICU is independentlyassociated with increasing illness severity, age, and time inhospital before ICU admission. Time in hospital before ICU mayreflect a failure to respond to treatment on a general wardor late referral to ICU.^⁴ It is tempting to speculate that thismight be amenable to earlier intervention, perhaps facilitatedby early warning systems and hospital outreach teams. For readmissionsoverall, the risk factors are similar and also include dischargeto an HDU. This last factor may reflect illness severity atdischarge or an earlier recognition of deterioration becauseof higher levels of monitoring. Only surgical HDU facilitiesexist in our hospital and it is possible that surgical patientsare discharged earlier in their recovery phase because a higherlevel of step-down care is available. The only factors associatedwith early readmissions are severity of illness at ICU admissionand discharge to an HDU. Our findings are consistent with previousstudies.^{⁵–⁷ ¹⁴} Better predictive models might be producedby including more patient variables at the time of ICU discharge.Status at discharge would seem a more relevant factor and isalso when we might have the opportunity to intervene. HigherTISS scores at discharge have been found in other studies tobe associated with an increased risk of readmission and death,but we did not confirm this finding in our patients.^{² ¹⁵ ¹⁶}Although discharge TISS score was statistically associated withdeath in our study, the difference between scores in those whodied and survived (29 vs 28) is not clinically useful. We donot currently collect other measures of illness severity atthe time of patient discharge.

Other factors associated with death or readmission after ICUhave been identified, but none has yet translated into a usefulpredictive model for individual patients.^⁶ A US study in a medicalICU found the acute physiology score component of APACHE IIat ICU discharge to be the independent risk factor most associatedwith readmission to ICU.^⁴ These data are not collected routinelyin our unit at present. Another study showed proximity of extubationto time of discharge and the need for organ support on the dayof discharge to be independently associated with readmission.^²These might indicate unresolved organ failure and prematuredischarge or substandard care after ICU discharge. Premorbidfunctional status and several severity of illness-related factorssuch as delirium and muscle weakness might also be relevantin determining outcome. None of these is currently recordedin our clinical audit system.

If discharges are indeed premature, would delaying dischargemake any difference? A model developed in the UK suggested thatabout one-third of ICU patients are at increased risk of deathafter ICU and that delaying their discharge by 48 h might reducetheir risk of death.^⁹ Decisions on discharge from ICU are currentlybased on clinical judgement rather than objective criteria.The effect on mortality and readmission of introducing a dischargepolicy based around a ‘physiological discharge score’is unlikely to be straightforward but deserves further investigation.We do know that night-time discharge, used as an indicator forpremature discharge, is associated with poorer outcome.^{¹⁶ ¹⁷}Our findings did not note any influence of night-time discharge,perhaps because the absolute number of night-time dischargesin our unit was very small. Other potentially relevant organizationalfactors not considered in our study include ICU bed occupancyand the level of ward care. Increasing length of stay in ICUor increasing the provision of high dependency care has beensuggested as strategies for improvement.^¹⁶ Each of these solutionshas major resource implications so cost-effectiveness needsto be demonstrated by prospective study. Case-by-case analysismight be valuable in identifying avoidable readmissions anddeaths. This has been studied elsewhere to assess quality ofcare before admission to intensive care and found several casesof suboptimal care but rather fewer cases of preventability.^¹⁸A study of 97 early readmissions to a surgical ICU concludedthat most (63%) initial discharges were appropriate, 22% ofreadmissions were preventable, 11% of readmissions may havebeen anticipated, and 5% might have been prematurely discharged.^⁵Other studies report that up to 40% of readmissions may havebeen associated with premature discharge.^⁶ Such results arenot easily extrapolated to different units because of differingpatient and organizational factors, particularly between countries.One strategy for obtaining local information is the developmentof follow-up teams who monitor patients after ICU discharge,can provide early warning of deterioration, and perhaps suggestinterventions to prevent further deterioration.^¹⁹ One studyof a critical care outreach team found preliminary evidenceof benefit in both survival and reduced readmission rates,^²⁰although this is not a universal finding.^²¹ Effective and aggressivefollow-up may actually increase readmission rate. As the mortalityof patients deteriorating after ICU discharge is so high, someclinicians may elect to readmit at an early stage to avert furtherdeterioration. This may be clinically appropriate but will confoundthe use of readmission rate as a quality marker. Caution musttherefore be exercised when interpreting comparative data onreadmission rates.

The above studies and our results give some insight into theproblem of unexpected deterioration after ICU discharge. Differenthospitals, particularly in different countries have differentcase mixes, different step-down arrangements, and differentorganizational factors such as numbers of transfers betweenhospitals, each of which might affect readmission rates. Thismakes comparisons and identification of common predictors moredifficult.^{³ ⁴ ⁶} Nonetheless, readmission rates and unexpecteddeaths may be a relevant quality marker, particularly at a locallevel.

In conclusion, the risk of death after ICU is independentlyassociated with increasing illness severity at time of ICU admission,age, and time in hospital before ICU admission. Risk factorsfor readmission to ICU are similar and also include dischargeto an HDU. Risk factors for early readmissions are severityof illness at ICU admission and discharge to an HDU. Prognosticmodels based on these risk factors had moderate discriminationability, but only performed slightly better than models basedonly upon APACHE score at ICU admission. We conclude that ourroutinely collected data cannot be used to produce models thatare more clinically useful in predicting death or readmissionthan admission APACHE II scores alone. In future, the most logicalarea on which to focus efforts to predict outcome might be onphysiological variables at discharge. This could be based aroundthe same acute physiological score components included in theAPACHE II score, not currently collected at the time of dischargefrom our unit. Follow-up of patients after discharge providesthe ideal opportunity to study reasons for deterioration andto assess the likely preventability of each readmission or unexpecteddeath. Only when we have answered these questions, will we beable to target our resources best at those at highest risk ofpoor outcome, despite a good response to treatment of theirinitial illness.

Acknowledgement

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Abstract
Introduction
Methods
Results
Discussion
Acknowledgement
References

Data entry by Miss Jane Wordie and the medical and nursing staffof the intensive care unit in Aberdeen Royal Infirmary.

References

Top
Abstract
Introduction
Methods
Results
Discussion
Acknowledgement
References

1 Society of Critical Care Medicine Quality Indicators Committee. Candidate Critical Care Quality Indicators (1995) Anaheim, CA: Society of Critical Care Medicine.

2 Metnitz PG, Fieux F, Jordan B, et al. Critically ill patients readmitted to intensive care units-lessons to learn? Intensive Care Med (2003) 29:241–8.[Web of Science][Medline]

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