Changes in the incidence of cardiopulmonary resuscitation before and after implementation of the Life-Sustaining Treatment Decisions Act

Article information

Acute Crit Care. 2022;37(2):237-246

Publication date (electronic) : 2022 February 24

doi : https://doi.org/10.4266/acc.2021.01095

Hyunjae Im ¹

, Hyun Woo Choe ²

, Seung-Young Oh ¹

, Ho Geol Ryu ¹^,²

, Hannah Lee^,²

¹Department of Critical Care Medicine, Seoul National University Hospital, Seoul National University College of Medicine, Seoul, Korea

²Department of Anesthesiology and Pain Medicine, Seoul National University Hospital, Seoul National University College of Medicine, Seoul, Korea

Corresponding author: Hannah Lee Department of Anesthesiology and Pain Medicine, Seoul National University Hospital, Seoul National University College of Medicine, 103 Daehak-ro, Jongno-gu, Seoul 03080, Korea Tel: +82-2-2072-2065, Fax: +82-2-747-8363 E-mail: closerthan@gmail.com

Received 2021 August 16; Revised 2021 October 28; Accepted 2021 November 13.

Abstract

Background

The Life-Sustaining Treatment (LST) Decisions Act allows withholding and withdrawal of LST, including cardiopulmonary resuscitation (CPR). In the present study, the incidence of CPR before and after implementation of the Act was compared.

Methods

This was a retrospective review involving hospitalized patients who underwent CPR at a single center between February 2016 and January 2020 (pre-implementation period, February 2016 to January 2018; post-implementation period, February 2018 to January 2020). The primary outcome was monthly incidence of CPR per 1,000 admissions. The secondary outcomes were duration of CPR, return of spontaneous circulation (ROSC) rate, 24-hour survival rate, and survival-to-discharge rate. The study outcomes were compared before and after implementation of the Act.

Results

A total of 867 patients who underwent CPR was included in the analysis. The incidence of CPR per 1,000 admissions showed no significant difference before and after implementation of the Act (3.02±0.68 vs. 2.81±0.75, P=0.255). The ROSC rate (67.20±0.11 vs. 70.99±0.12, P=0.008) and survival to discharge rate (20.24±0.09 vs. 22.40±0.12, P=0.029) were higher after implementation of the Act than before implementation.

Conclusions

The incidence of CPR did not significantly change for 2 years after implementation of the Act. Further studies are needed to assess the changes in trends in the decisions of CPR and other LSTs in real-world practice.

Keywords: advance directives; cardiopulmonary resuscitation; withholding treatment

INTRODUCTION

Withholding and withdrawal of life-sustaining treatment (LST) have been focal points in ethical debates on emerging concerns associated with dignified death of humans and end-of-life (EOL) care [1,2]. Prolonging life by LST is not always beneficial, and LST can extend hospital time for patients and family members, without a probability of recovery. Cardiopulmonary resuscitation (CPR), including cardiac massage, which is a main component of LST, can cause severe mechanical injuries such as rib fractures, hemothorax, and other internal organ injury to the patient [3,4]. In a previous study, post-traumatic stress disorder symptoms were reported in family members who had witnessed unsuccessful CPR attempts on their loved ones [5]. The Act on Hospice and Palliative Care and Decisions on LST for Patients at the EOL were enforced in South Korea in February 2018 and allowed physicians and patients to establish default orders concerning EOL care, including CPR. In two retrospective studies, implementation of the LST Decisions Act showed the effect of increased self-determination rates and early decision-making for LST [6,7]. In addition, in a systematic review, do-not-resuscitate (DNR) orders were reportedly associated with decreased CPR [8]. However, to the best of our knowledge, the effects of the LST Decisions Act and advance care planning on the overall incidence of CPR have not been investigated.

We hypothesized that implementation of the LST Decisions Act and subsequent establishment of proactive preparation for physician orders for LST (POLST) reduces unnecessary CPR in accordance with the purpose of the Act on Hospice and Palliative Care and Decisions on LST for patients at the EOL. In addition, other CPR-related outcomes were compared assuming the patients at the EOL who underwent CPR would be affected by prior preparation for POLST.

MATERIALS AND METHODS

Study Design and Patients

This was a single-center, retrospective, observational study. Adult patients (>18 years of age) who underwent CPR during the study period (February 2016 to January 2020) were included. The Act on Hospice and Palliative Care and Decisions on LST for patients at the EOL was enforced on February 4, 2018, in South Korea, and data were compared between the 2 years before implementation of the Act (pre-implementation period: February 2016 to January 2018) and the 2 years after implementation of the Act (post-implementation period: February 2018 to January 2020).

The study protocol was approved by the Institutional Review Board of Seoul National University Hospital (IRB No. H-1802-111-924). The requirement for informed consent was waived by the institutional review board due to the retrospective study design.

Data Collection

Baseline characteristics

Electronic medical records were reviewed and data regarding baseline characteristics such as age, sex, and pre-existing comorbidities included in the Charlson Comorbidity Index were extracted as well as the case-mix indices (CMIs). The CMI is the relative value assigned to the diagnostic group of patients in the medical environment used for allocating resources to the care and treatment of patients in the group and represents the diversity or complexity of the hospital [9]. The CMI data for each period were collected to verify that patients from the two periods could be compared. The monthly total number of hospital admissions also was collected to calculate the incidence of CPR per 1,000 admissions.

Data associated with CPR

Only CPR for hospitalized patients in wards or intensive care units (ICUs) was included based on documentation of LST before the cardiac arrest. In addition, only the first recorded cardiac arrest for each patient was included in the analysis. The causes of cardiac arrest were classified according to the 5 Hs and 5 Ts (hypoxia, hypovolemia, hydrogen ions, hyperkalemia/hypokalemia, hypothermia; tension pneumothorax, tamponade-cardiac, toxins, thrombosis-coronary, thrombosis-pulmonary) [10], and multiple selections were possible. Duration of CPR, return of spontaneous circulation (ROSC), 24-hour survival rate, and survival-to-discharge rate were recorded for each CPR performed. ROSC was defined as return of any palpable pulse in the absence of ongoing chest compressions for at least 20 consecutive minutes [11].

Definitions

CPR due to delayed documentation was defined as that performed because the DNR or POLST documentation was not completed before the initial cardiac arrest despite discussion of LST for terminally ill patients. Preventable CPR was defined as CPR that could be detected several hours before the adverse event using pre-alarm signs and that was avoidable through appropriate and prompt medical management. The time and date of CPR events were monitored to determine any pre-existing pre-alarm signs that existed within 48 hours of events and whether the events were potentially avoidable. The pre-alarm signs were abnormal vital signs based on the rapid response system trigger criteria (Supplementary Table 1).

Documentation for withholding or withdrawal of LST

The monthly numbers of DNR and POLST documentations during the study period were recorded. Additional information regarding DNR and POLST included the timing of writing the documents (before or after cardiac arrest) and whether the documents were written in the ICU or general ward. Data on the detailed form of written POLST were also collected regarding of whether POLST was completed according to the patient’s own will or that of surrogates (Supplementary Table 2).

Study Outcomes

The primary outcome was the incidence of CPR per 1,000 admissions before and after implementation of the Act on Hospice and Palliative Care and Decisions on LST for patients at the EOL. The secondary outcomes were duration of CPR, ROSC rate, 24-hour survival rate, and survival-to-discharge rate. Subgroup analysis was conducted based on the location of CPR for each study outcome.

Statistical Analysis

Categorical variables were expressed as frequencies with percentages, and continuous variables were expressed as means with standard deviations. Normally distributed quantitative variables were compared using Student t-test, and non-normally distributed quantitative variables were compared using the Mann-Whitney U-test. Qualitative variables were compared using the chi-square test.

The interrupted time series was subjected to segmented regression analysis [12] to identify the correlation between enforcement of the Act and incidence of CPR per 1,000 admissions, CPR duration, ROSC rate, 24-hour survival rate, and survival-to-discharge rate. The time after the intervention variable was considered in the model to determine the time, intervention, and trend after intervention. The Durbin-Watson test [13] was performed to determine whether autocorrelation existed. The Pearson correlation coefficient was calculated to measure the statistical relationship between the monthly numbers of POLST documentation for all hospitalized patients and the incidence of CPR per 1,000 admissions.

RESULTS

From February 2016 to January 2020, a total of 867 patients who underwent CPR was included in the analysis: 446 and 421 patients in the pre-implementation and post-implementation periods, respectively (Table 1). Significant difference was not observed in the baseline characteristics including Charlson Comorbidity Index scores between the two periods, except for the prevalence of comorbidities. For all hospitalized patients in the two periods, the CMI was comparable (1.09±0.05 vs. 1.05±0.05, P=0.515) and overall hospital mortality was not significantly different between the two periods (2.3% vs. 2.3%, P=0.762).

Table 1.

Baseline characteristics of CPR patients

Characteristics of CPR between the Two Periods

The descriptive clinical data and causes of CPR are summarized in Table 2. The location and time of CPR were similar in the two periods. Significant difference was not observed in the number of CPRs due to delayed DNR or POLST documentation (7.0% vs. 6.4%, P=0.752). Unpreventable CPRs accounted for more than 80% in both periods, and the proportion of preventable CPRs did not differ significantly before and after implementation of the Act. Acidosis and hypoxia were the two most common causes of CPR based on the 5 Hs and 5 Ts, and significant differences were not observed between the two periods for any cause of CPR.

Table 2.

Descriptive clinical data and causes of CPR

Outcomes

The incidence of CPR per 1,000 admissions during the post-implementation period was not significantly different than during the pre-implementation period (P=0.255) (Table 3). The ROSC rate (70.99%±0.12% vs. 67.20%±0.11%, P=0.008) and survival-to-discharge rate (22.40%±0.12% vs. 20.24%±0.09%, P=0.029) increased significantly after implementation of the Act; however, CPR duration (21.16±5.19 minutes vs. 20.62±5.81 minutes, P=0.755) and 24-hour survival rate (47.05%±0.13% vs. 47.54%±0.12%, P=0.075) were not significantly different. In the subgroup analysis based on CPR location, the variables did not differ significantly between the two periods, except for the survival-to-discharge rate in the general ward subgroup. The survival-to-discharge rate of CPR in the ward significantly increased after implementation of the Act. In addition, significant statistical correlation was not observed between the monthly number of written DNR or POLST in all hospitalized patients and the incidence of CPR per 1,000 admissions (Figure 1).

Table 3.

Primary and secondary study outcomes

Figure 1.

Monthly trends of do-not-resuscitate (DNR) and physician orders for life-sustaining treatment (POLST) documentation and the incidence of cardiopulmonary resuscitation (CPR) per 1,000 admissions. Pre-implementation: February 2016 to January 2018; Post-implementation: February 2018 to January 2020. The orange bars represent the number of DNR orders per month among hospitalized patients (Pre-implementation period, 14.92±6.87 vs. Post-implementation period, 14.92±4.88; P=1.000). The blue bars represent the number of POLST documents per month among hospitalized patients (61.83±22.00). The gray lines represent the incidence of CPR per 1,000 admissions per month among hospitalized patients (2.92±0.71).

Characteristics of DNR and POLST between the Two Periods

The number of DNR documentations for patients with CPR decreased after implementation of the LST Act (Table 4). Most DNR documentations in the two periods were completed after the initial cardiac arrest. Among the 421 patients undergoing CPR in the post-implementation period, 22.6% completed POLST documentation, and most of the POLST documentation was written with DNR after the initial cardiac arrest. In terms of whether the patient’s will was reflected, the majority of POLST documentation (96.8%) was completed by the patient’s family members as surrogates because they did not know the patient’s will or the patients did not express or decide their will regarding LST. The execution rate of withdrawal or withholding LSTs was 98.9% for CPR, 53.7% for hemodialysis, and 48.4% for mechanical ventilation in the POLST documents of CPR patients (Supplementary Table 3). Statistical difference was not observed in the number of DNR documents per month in total hospitalized patients (Figure 1). The characteristics of written DNR and POLST for hospitalized patients throughout the study period are described in Supplementary Table 4.

Table 4.

The characteristics of written DNR, POLST in CPR patients

DISCUSSION

In the present study, the effect of introduction of the LST Decisions Act on the incidence of CPR, a main component of LST, was evaluated. The incidence of CPR and other related outcomes, such as CPR duration and 24-hour survival rate, did not differ before and after implementation of the Act. The enforcement of the LST Decisions Act legitimately allows withholding and withdrawal of LST. POLST, based on the Act, helps to ensure that patients receive care consistent with their preferences. CPR, including external cardiac massage, is an aggressive LST and might be physically harmful in patients at the EOL [4]. Therefore, when withholding or withdrawing LST is discussed with patients or caregivers and physicians, the decision whether to perform CPR is often the first and most frequently made decision [14,15]. The effect of the implementation of the LST Decisions Act and subsequent advance care planning and directives have been previously studied [16,17]. However, the changes in the overall incidence of CPR and after implementation of the LST Decisions Act have not been reported. Therefore, whether the implementation of the LST Decisions Act and application of standardized documentation regarding advance directives and care planning actually affects the incidence of CPR in the present study in terms of its original purpose was investigated in the present study.

CPR included in the present study had several similarities and differences compared with previous studies. The causes of cardiac arrest in the present study were consistent with a previous report showing predominant detectable causes of in-hospital cardiac arrest to be cardiac causes and hypoxia [18]. In contrast, the proportion of cardiac arrests with myocardial infarction was relatively low compared with results reported in two observational studies [19,20]. The proportion of unpreventable CPR was comparable with or slightly higher than that in previous studies [21,22]. The ROSC rate and 24-hour survival rate were similar to or higher than those reported in other studies [19,20], but the total survival-to-discharge rate was lower [19,20]. In subgroup analysis, the survival outcomes of CPR were poor for patients in the ICU setting, consistent with a previous study [23]. The unadjusted results in the present study are likely because patients in the ICU often experience organ failure in addition to serious preexisting comorbidities [24]. The ROSC rate and survival-to-discharge rate showed a moderate increase after implementation of the LST Decisions Act and appear mainly associated with improved outcomes of CPR in the ward based on subgroup analysis. Because various factors affecting the clinical outcomes of CPR were not excluded and outcome indices mainly improved in CPR in the ward, external factors such as improved CPR quality or a rapid response team might be involved [25].

In the present study, significant difference was not observed in the incidence of CPR before and after implementation of the LST Decisions Act. We hypothesized the implementation of the LST Decisions Act and the subsequent proactive preparation for POLST reduce unnecessary CPR in terminally ill patients. To confirm the incidence of CPR based on this hypothesis, a significant portion of CPRs in the pre-implementation period must be attributed to delayed LST documentation in patients at EOL [26]. In the present study, only 7% of the CPRs in hospitalized patients during the pre-implementation period were associated with delayed DNR documentation, likely indicating the majority of CPRs during the study period occurred irrespective of the presence of terminal illness or EOL. Thus, the incidence of CPR might not decrease regardless of the proportion of completed documentation before initial cardiac arrest. Second, the unestablished practice of proactive preparation of POLST might have contributed to the results. In this study, the proportion of CPRs due to delayed documentation remained the same without any significant difference, even after implementation of the LST Decisions Act. Although a system that withheld or withdrew the LST was introduced, LST including CPR for terminally ill patients continued if the proactive preparation for POLST was not widespread. In summary, CPR that occurred in terminally ill patients with DNR or POLST documentation accounted for only a minor portion, and implementation of the LST Decisions Act did not reduce the frequency of CPR due to delayed documentation in those patients, which could have contributed to the current results.

There were several notable points after implementation of the LST Decisions Act. First, the proportion of DNR documentation significantly decreased. Because DNR documentation was mostly written after initial cardiac arrest during both periods in CPR patients, the changes in the proportion of DNR documentation unlikely affected the incidence of CPR. This might be because the LST Decisions Act provided a new approach, the POLST, to withhold or withdraw LST including re-CPR in terminally ill patients who underwent CPR. Second, the proportion of completed DNR or POLST documentation in CPR patients decreased. Because most DNR or POLST documentation was completed immediately before death in CPR patients after initial cardiac arrest, the lower proportion of completed DNR or POLST in CPR patients can be explained partially by the significantly better outcomes of CPR in the post-implementation period. Thus, because the proportion of recovery was higher in the post-implementation period, the number of completed DNR or POLST documentation in CPR patients without probability of recovery was assumedly lower in the post-implementation period. Lastly, the ratio of DNR or POLST documents and death among hospitalized patients was much higher in the post-implementation period, indicating the proportion of withholding or withdrawal of LST based on documentation significantly increased. However, as the self-determination rate was low and the interval between completion of DNR or POLST and death was short compared with Western countries [27-29], many additional procedures are needed to broadly establish the LST Decisions Act.

The change in the incidence of CPR, the main component of LST, was analyzed for the first time before and after implementation of LST decisions and is the main strength of the present study. However, the present study had several limitations that should be considered before interpreting the results. First, due to the retrospective design, the results might be subjected to biases and limitations of retrospective studies. Estimating the effectiveness of the LST Decisions Act and related POLST forms to protect patients from unwanted LST is difficult. The present study did not include information regarding the exact timing when discussion of POLST and each component of LST other than CPR were started, which might have helped better explain the results. In addition, confounding factors that could affect the incidence of CPR and CPR-related outcomes were not excluded. However, patient groups in the two periods were comparable because the age, sex, CMI, and Charlson comorbidity index scores were not significantly different. Furthermore, because most patients and their surrogates agreed that CPR should not be performed when implementing the POLST, the effect of LST components other than CPR on the incidence of CPR was limited. Second, data on all terminally ill patients who were hospitalized in our hospital during the study period were not included in the analysis and only the proportion of terminally ill patients among CPR patients was estimated indirectly. Finally, generalizing the study results is difficult because decisions on LST are mainly influenced by country and sociocultural differences.

In conclusion, the incidence of CPR before and after implementation of the LST Decisions Act basically remained the same. Further studies are needed to determine how LST decisions affect whether CPR and other LSTs are performed in real practice.

KEY MESSAGES

▪ Implementation of life-sustaining treatment (LST) decisions did not affect the incidence of cardiopulmonary resuscitation in hospitalized patients at 2 years after enforcement of the Act.

▪ Cardiac arrests that occurred in terminally ill patients who had a written document regarding withholding and withdrawal of LST comprised a small proportion of the total cardiac arrests in our center, and the proportions before and after implementation of the Act were the same.

▪ Proactive preparation of documentation regarding withholding and withdrawal of LST with universalization of the Act will be needed to avoid unnecessary resuscitation at end-of-life stages.

Notes

CONFLICT OF INTEREST

No potential conflict of interest relevant to this article was reported.

AUTHOR CONTRIBUTIONS

Conceptualization: HI, HL. Data curation: HI, HWC, HL. Formal analysis: HI, SYO, HL. Methodology: HI, HL, HGR, SYO. Project administration: HI, HWC, HL. Visualization: HI. Writing–original draft: HI. Writing–review & editing: HI, HL, HGR.

Acknowledgements

The authors thank Wonho Choi in the Center for Palliative Care and Clinical Ethics of Seoul National University Hospital for providing summarized data and detailed information regarding the physician orders for life-sustaining treatment forms.

SUPPLEMENTARY MATERIALS

Supplementary materials can be found via https://doi.org/10.4266/acc.2021.01095.

Supplementary Table 1.

Criteria for triggering the rapid response system for rapid response team activation

acc-2021-01095-suppl1.pdf

Supplementary Table 2.

Detailed information about the POLST forms

acc-2021-01095-suppl2.pdf

Supplementary Table 3.

Detailed information about withholding or withdrawal of LST in patients with POLST

acc-2021-01095-suppl3.pdf

Supplementary Table 4.

The characteristics of written DNR and POLST in total hospitalized patients in whole study period

acc-2021-01095-suppl4.pdf

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Variable	Pre-implementation (n=446)	Post-implementation (n=421)	P-value
Age (yr)	65.95±14.15	66.47±13.58	0.580
<50	55 (12.3)	44 (10.5)
50–59	72 (16.1)	61 (14.5)
60–69	119 (26.7)	125 (29.7)
70–79	130 (29.2)	130 (30.9)
≥80	70 (15.7)	61 (14.5)
Male	266 (59.6)	259 (61.5)	0.572
Charlson comorbidity index score	5.80±2.65	5.68±2.88	0.519
Comorbidity^a
Myocardial infarction	44 (9.9)	64 (15.2)	0.017
Congestive heart disease	51 (11.4)	48 (11.4)	0.988
Peripheral vascular disease	15 (3.4)	24 (5.7)	0.097
Cerebral vascular disease	60 (13.5)	43 (10.2)	0.141
Dementia	15 (3.4)	21 (5.0)	0.231
Chronic obstructive pulmonary disease	19 (4.3)	7 (1.7)	0.025
Rheumatic disease	19 (4.3)	16 (3.8)	0.731
Peptic ulcer disease	26 (5.8)	1 (0.2)	<0.001
Liver disease
Mild	46 (10.3)	7 (1.7)	<0.001
Moderate to severe	64 (14.4)	34 (8.1)	0.004
Diabetes mellitus
Uncomplicated	103 (23.1)	74 (17.6)	0.044
Complicated	50 (11.2)	44 (10.5)	0.719
Hemiplegia	5 (1.1)	3 (0.7)	0.530
Chronic kidney disease
Moderate to severe	97 (21.8)	92 (21.9)	0.970
Solid tumor
Localized	116 (26.0)	59 (14.0)	<0.001
Metastatic	65 (14.6)	88 (20.9)	0.015
Leukemia	23 (5.2)	34 (8.1)	0.083
Lymphoma	20 (4.5)	21 (5.0)	0.727
Acquired immune deficiency syndrome	1 (0.2)	1 (0.2)	0.967
Medical or surgical patients			0.307
Medical	358 (80.3)	326 (77.4)
Surgical	88 (19.7)	95 (22.6)

Variable	Pre-implementation (n=446)	Post-implementation (n=421)	P-value
Location of CPR			0.496
ICU	227 (50.9)	224 (53.2)
Ward	219 (49.1)	197 (46.8)
Time of CPR			0.788
Morning (06:00–12:00)	113 (25.3)	117 (27.8)
Afternoon (12:00–18:00)	120 (26.9)	103 (24.5)
Evening (18:00–24:00)	114 (25.6)	110 (26.1)
Night (24:00–06:00)	99 (22.2)	91 (21.6)
CPR due to delayed documentation^a	31 (7.0)	27 (6.4)	0.752
Preventable/unpreventable CPR			0.462
Preventable CPR	76 (17.0)	64 (15.2)
Unpreventable CPR	370 (83.0)	357 (84.8)
Cause of cardiac arrest
Hypoxia	138 (30.9)	144 (34.2)	0.305
Hypovolemic shock	62 (13.9)	44 (10.5)	0.121
Acidosis	151 (33.9)	163 (38.7)	0.137
Hyperkalemia/hypokalemia	10 (2.2)	15 (3.6)	0.245
Cardiac tamponade	4 (0.9)	5 (1.2)	0.673
Tension pneumothorax	0	0	1.000
Pulmonary thromboembolism	13 (2.9)	15 (3.6)	0.590
Acute myocardial infarction	34 (7.6)	29 (6.9)	0.677
Other cardiogenic	91 (20.4)	79 (18.8)	0.544
Anaphylaxis	1 (0.2)	4 (1.0)	0.158
Neurologic	28 (6.3)	18 (4.3)	0.189
Unknown	34 (7.6)	28 (6.7)	0.579

Variable	Pre-implementation (n=446)	Post-implementation (n=421)	P-value
Primary outcome
CPRs/1,000 admissions	3.02±0.68	2.81 ±0.75	0.255
Secondary outcome
Duration of CPR (min)	21.16±5.19	20.62±5.81	0.755
ROSC rate (%)	67.20±0.11	70.99±0.12	0.008
24-Hour survival rate	47.05±0.13	47.54±0.12	0.075
Survival to discharge rate (%)	20.24±0.09	22.40±0.12	0.029
Subgroup analysis according to the location of CPR
CPR at ICU
CPR/1,000 admissions	1.53±0.61	1.49±0.61	0.474
Duration of CPR (min)	19.30±8.41	18.41±8.41	0.810
ROSC rate (%)	65.17±0.18	65.37±0.20	0.229
24-Hour survival rate (%)	41.00±0.21	38.99±0.15	0.067
Survival to discharge rate (%)	15.12±0.11	19.05±0.13	0.070
CPR at ward
CPR/1,000 admissions	1.49±0.40	1.31±0.56	0.454
Duration of CPR (min)	23.50±7.61	24.09±10.22	0.718
ROSC rate (%)	68.20±0.16	77.22±0.19	0.070
24-Hour survival rate (%)	49.28±0.17	57.53±0.20	0.207
Survival to discharge rate (%)	23.83±0.13	25.28±0.18	0.049

Variable	Pre-implementation (n=446)	Post-implementation (n=421)	P-value
Total number of documentations	240 (53.8)	143 (34.0)	<0.001
DNR document	240 (53.8)	48 (11.4)	<0.001
Timing of writing DNR			0.173
Before initial cardiac arrest	6^a (2.5)	3^a (6.3)
After initial cardiac arrest	234 (97.5)	45 (93.8)
Place where DNR was written			0.007
ICU	177 (73.8)	44 (91.7)
General ward	63 (26.3)	4 (8.3)
DNR in medical or surgical patients			0.472
Medical	200 (83.3)	42 (87.5)
Surgical	40 (16.7)	6 (12.5)
POLST document	NA	95 (22.6)
Whether patient’s will was reflected^b
Yes	NA	3^c (3.2)
No	NA	92 (96.8)
Timing of writing POLST
Before initial cardiac arrest	NA	2^a (2.1)
After initial cardiac arrest	NA	93 (97.9)
Place where POLST was written
ICU	NA	85 (89.5)
General ward	NA	10 (10.5)
POLST in medical or surgical patients
Medical	NA	80 (84.2)
Surgical	NA	15 (15.8)