Hostname: page-component-78c5997874-94fs2 Total loading time: 0 Render date: 2024-11-10T15:32:03.725Z Has data issue: false hasContentIssue false
  • English
  • Français

Association between nurse staffing level in intensive care settings and hospital-acquired pneumonia among surgery patients: result from the Korea National Health Insurance cohort

Published online by Cambridge University Press:  08 February 2024

Yu Shin Park ,
Il Yun ,
Suk-Yong Jang ,
Eun-Cheol Park  and
Sung-In Jang Open the ORCID record for Sung-In Jang [Opens in a new window]
Yu Shin Park
Affiliation:
Department of Public Health, Graduate School, Yonsei University, Seoul, Republic of Korea Institute of Health Services Research, Yonsei University, Seoul, Republic of Korea
Il Yun
Affiliation:
Department of Public Health, Graduate School, Yonsei University, Seoul, Republic of Korea Institute of Health Services Research, Yonsei University, Seoul, Republic of Korea
Suk-Yong Jang
Affiliation:
Department of Public Health, Graduate School, Yonsei University, Seoul, Republic of Korea Institute of Health Services Research, Yonsei University, Seoul, Republic of Korea Department of Healthcare Management, Graduate School of Public Health, Yonsei University, Seoul, South Korea
Eun-Cheol Park
Affiliation:
Institute of Health Services Research, Yonsei University, Seoul, Republic of Korea Department of Preventive Medicine, Yonsei University College of Medicine, Seoul, Republic of Korea
Sung-In Jang*
Affiliation:
Institute of Health Services Research, Yonsei University, Seoul, Republic of Korea Department of Preventive Medicine, Yonsei University College of Medicine, Seoul, Republic of Korea
*
Corresponding author: Sung-In Jang; Email: jangsi@yuhs.ac
Rights & Permissions [Opens in a new window]

Abstract

This study examined the association between the number of nursing staff in intensive care units (ICUs) and hospital-acquired pneumonia (HAP) among surgical patients in South Korea. Data were obtained between 2008 and 2019 from the Korean National Health Insurance Service Cohort Database; 37,706 surgical patients who received critical care services were included in the analysis. Patients with a history of pneumonia 1 year prior to surgery or those who had undergone lung-related surgery were excluded. The ICU nursing management fee is an admission fee that varies based on the grading determined by nurse-to-bed ratio. Using this grading system, we classified four groups from the highest to the lowest level based on the proportion of beds to nurses (high, high-mid, mid-low, and low group). HAP was defined by the International Classification of Disease, 10th revision (ICD-10) code. Multilevel logistic regression was used to investigate the relationship between the level of ICU nurse staffing and pneumonia, controlling for variables at the individual and hospital levels. Lower levels of nurse staffing were associated with a greater incidence of HAP than higher levels of nurse staffing (mid-high, OR: 1.33, 95% CI: 1.12–1.57; mid-low, OR: 1.61, 95% CI: 1.27–2.04; low, OR: 2.13, 95% CI: 1.67–2.71). The intraclass correlation coefficient value was 0.177, and 17.7% of the variability in HAP was accounted for by the hospital. Higher ICU nursing management fee grades (grade 5 and above) in general and hospital settings were significantly associated with an increased risk of HAP compared to grade 1 admissions. Similarly, in tertiary hospitals, grade 2 and higher ICU nursing management fees were significantly associated with an increased risk of HAP compared to grade 1 admissions. Especially, a lower level of nurse staffing was associated with bacterial pneumonia but not pneumonia due to aspiration. In conclusion, this study found an association between the level of ICU nurse staffing and HAP among surgical patients. A lower level of nurse staffing in the ICU was associated with increased rates of HAP among surgical patients. This indicates that having fewer beds assigned to nurses in the ICU setting is a significant factor in preventing HAP, regardless of the size of the hospital.

Keywords

hospital-acquired infectionhospital-acquired pneumonianursing staffquality of care
Type
Original Paper
Information
Epidemiology & Infection , Volume 152 , 2024 , e62
Check for updates
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2024. Published by Cambridge University Press

Introduction

In the intensive care unit (ICU), advanced medical procedures include the use of invasive monitoring and mechanical devices to support and assist malfunctioning organs or systems, such as the respiratory system [Reference Wałaszek1]. As a result, patients in the ICU are at a higher risk of acquiring hospital-acquired infections (HAIs). Hospital-acquired pneumonia (HAP) is the most prevalent among these infections, representing 26% of all HAI cases [2].

HAP is categorized into two distinct groups: ventilator-associated pneumonia (VAP) and severe pneumonia that occurs while a patient is hospitalized [Reference Koulenti, Tsigou and Rello3]. Specifically, among postoperative patients, pneumonia ranks as the third most frequent complication across all surgical procedures and is linked to higher patient morbidity and mortality rates [Reference Kazaure, Martin, Yoon and Wren4].

It is estimated that about 20% of HAIs can be prevented through improved infection control measures [Reference Harbarth, Sax and Gastmeier5]. Numerous international guidelines for the prevention of HAP have been published. Most of these guidelines incorporate strategies that focus on staff education, hand hygiene, patient positioning, ventilator management, the frequency of humidifier changes, and proper suctioning techniques [Reference Masterton6Reference Masterton8]. Nurses working in the critical care unit are tasked with various responsibilities related to implementing these infection prevention strategies. Consequently, critically ill patients necessitate increased nursing staff resources and nurses with specialized knowledge and skills to effectively prevent HAP [Reference Aragon Penoyer9].

Several studies have examined the connection between nurse staffing levels and patient health outcomes, including factors like mortality, hospital stay duration, and complications, in both general acute care units and non-critical care units [Reference Halm10Reference Mark, Harless and Berman13]. Nonetheless, the nurse staffing requirements for patients with critical care conditions may differ from those in general ward settings. Therefore, studies on nurse staffing that report outcomes in general acute care settings may not be applicable to the ICU, and there is a shortage of studies regarding nurse staffing levels, specifically in intensive care settings in Korea.

Furthermore, determining what constitutes satisfactory nurse staffing levels remains a topic of debate in hospitals around the world [Reference Aragon Penoyer9]. In South Korea, a financial incentive program was introduced in 1999. It provides higher inpatient nursing fees to hospitals that establish nursing staff standards using a ratio of beds to registered nurses (RNs). The grading of nursing levels is determined by the type of hospital, differentiating between general and tertiary hospitals. This system was extended to the ICU setting starting in 2008 [Reference Kim and Kim14]. Annually, the government collects information on the total number of nursing staff and the number of hospital beds in almost all hospitals and provides differentiated payment based on these data.

Following this policy, it is possible to clearly confirm the ICU nurse staffing level in all hospitals using the claim code. It is hence possible to evaluate the association between nurse staffing level and HAP nationwide. Therefore, this study examined the association between nurse staffing level and HAP in operative patients in the ICU using nationwide representative cohort data. This might enrich international evidence of the impact of nursing staff in different national and organizational contexts.

Method

Study design and data source

This study was a cross-sectional analysis of claim data from the Korean National Health Insurance (NHI) Service National Sample Cohort from 2008 to 2019. The NHI data (NHID) consist of medical claim records that represent nationally representative random samples of the Korean population, accounting for approximately 2.2% of the entire population. The Korean National Health Insurance Service (NHIS) supplies data for academic research and policy formulation, encompassing all claims data collected through the NHIS application procedure. Patients in the cohort were monitored, except in cases of exclusion due to death or relocation. The National Health Insurance Database (NHID) contains details regarding socioeconomic status and clinically ascertained International Classification of Disease, 10th revision (ICD-10) codes [Reference Lee, Lee, Park, Shin and Kim15]. The present study was approved as exempt by the Institutional Review Board of Yonsei University’s Health System, and informed consent was waived by the Ethics Committee as NHID pseudonymized patient data for research purposes (IRB number: 4-2023-1190).

Grade of the nursing management fee

In South Korea, a fee-for-service system operates under payment system. The number of beds in hospitals varies by hospital type, but under the Medical Service Act, they can be roughly categorized into about four types: tertiary hospitals, general hospitals, hospitals, and clinics. Typically, clinics primarily handle outpatient cases and hospitals have 30 or more beds, while general hospitals have 100 or more beds and offer services in at least nine different medical specialties. Tertiary general hospitals, on the other hand, are defined by their specialization in providing highly advanced and specialized medical care for severe or complex conditions and offer services in more than 20 medical specialties.

Since 2008, the inpatient fees for ICUs have been determined based on the “Grade of the Nursing Management Fee,” which is linked to the level of nursing staff availability. Tertiary hospitals are categorized into grades ranging from 1 to 5, and general hospitals and hospitals are categorized into grades ranging from 1 to 9 based on the ratio of the number of beds to the number of nurses. This system was implemented to address the undesirable situation where the quality of nursing care in ICUs was compromised due to inadequate nursing staffing levels at hospitals. The grades are as follows, as shown in Supplementary Table 1. These grades were identified by claim codes.

Participants

We extracted patients who were admitted to critical care units in general hospitals, hospitals, or tertiary hospitals by identifying them by the claim fee code (n = 84,397). We excluded patients (1) who had received lung surgery, according to the surgery claim fee code (n = 1,226); (2) who did not undergo surgery during their hospitalization, and we selected those who had checked “No” for “Underwent surgery during admission” (n = 40,673); (3) who were diagnosed with any type of pneumonia in the year before admission to the hospital (n = 350); and (4) who admitted to NICU or PICU (n = 2,301); and (5) with missing covariate values (n = 3,247). The total number of study participants in the 2008–2019 period was 36,600.

Level of nursing staffing

To divide tertiary hospitals, general hospitals, and hospitals into quartiles based on the level of nursing staffing, we categorized grades 1–2 for tertiary hospitals, general hospitals, and hospitals as the high group, grades 3–4 as the mid-high group, grades 5 for tertiary hospitals, grades 5–6 for general hospitals and hospitals as the mid-low group, and grades 7–9 for general hospitals as the low group. We conducted a sensitivity analysis by dividing the type of hospitals (tertiary, general hospitals, and hospitals) and each nursing grade to further investigate the precise associations with HAP.

Hospital-acquired pneumonia

Our dependent variable was HAP, which was defined using data obtained from all hospitalizations with diagnoses specified by ICD-10 codes J13, J14, J150-J159, J168, J180, J188, J690, and J698. To minimize the inclusion of patients with a history of pneumonia, we excluded individuals with a pulmonary disease history within 1 year before surgery. Additionally, those who were admitted for pulmonary surgery were also excluded from the study population. Furthermore, the fact that patients with pneumonia are not recommended for surgery might increase the accuracy of identifying HAP. Furthermore, we defined our second dependent variable by categorizing HAP into two types: bacterial pneumonia (J15) and aspiration pneumonia (J69).

Variables

Individual-level variables included various categories, such as sociodemographic factors, socioeconomic status, health status, and treatment. Sociodemographic aspects covered age as a continuous variable, gender (male or female), and residential area (metropolitan, urban, or rural). Socioeconomic status was represented by household income (categorized as high, middle, or low). Health status encompassed disability status (yes or no) and the Charlson comorbidity index with three categories (1, 2, or ≥3). Medical utilization considered whether the patient received invasive mechanical ventilation (yes or no) and renal replacement therapy (yes or no) and total days in the ICU divided into tertiles: The group of individuals who were hospitalized in the ICU for just 1 day was categorized as the low group, those who stayed in the ICU for 2 to 4 days were classified as the middle group, and those who were in the ICU for 5 days or more were designated as the high group.

Hospital-level variables were based on hospital characteristics, namely the type of hospital (tertiary hospital, general hospital, or hospital), location of hospital (metropolitan, city, or rural location), and the number of doctors per bed which was calculated for each hospital by dividing the total number of beds by the total number of doctors and then categorizing them into quartiles. Hospitals with a value equal to or greater than 0.54 were labelled as the high group, those with values exceeding 0.41 but less than 0.54 were classified as the high-mid group, those with values higher than 0.23 but less than 0.41 were considered the mid-low group, and hospitals with values equal to or less than 0.23 were designated as the low group.

Statistical analysis

The chi-square test and t-test were used to determine significant differences in variables between participants who had and did not have a diagnosis of HAP. The null hypothesis (H0) was that there was no difference between groups for a particular variable. To investigate the effect of individual- and hospital-level variables on an individual’s likelihood of HAP, we used two-level hierarchical models that assessed the relationship between HAP and both individual- and hospital-level variables.

To investigate the relationships between individual factors at level 1 and hospital-related factors at level 2 with our study outcomes, we employed generalized linear mixed models for our multilevel regression analysis. We constructed four models for this analysis. The initial model served as a null model with no variables. In the second model (model 2), we introduced individual-level variables to assess their impact on HAP. Model 3 focused on the influence of hospital-level variables, with the addition of 200 hospitals as random effects to explore their unique contributions. Finally, our fourth model (model 4) incorporated both individual and hospital-level variables. We utilized intraclass correlations (ICCs) to evaluate whether there was significant variation between different groups compared to variation within those groups. The ICC is calculated as the ratio of the variance between clusters to the total variance. Additionally, we conducted subgroup analyses to examine the associations between the level of nursing staffing and HAP, stratified by the severity of the patient’s illness (including factors such as invasive mechanical ventilation, ICU stay, and primary admission diagnosis) as well as the hospital’s characteristics (hospital location). We used PROC GLIMMIX to estimate a generalized linear mixed model with a binary distribution and logit link function. Odds ratios (ORs) and 95% confidence intervals (CIs) were also calculated. Data were analyzed using SAS (version 9.4; SAS Institute Inc., Cary, NC, USA).

Results

Table 1 presents the general characteristics of the study participants. Of the 36,660 participants included in our study, 2,231 (6.1%) developed HAP. Among those who received ventilator care, 1,364 patients (12.1%) experienced HAP, while only 3.4% of those who did not receive ventilator care had HAP. Furthermore, in the group with an ICU stay of 5 days or more, 15.1% experienced HAP. Among patients who underwent surgery at the low level of nursing staff, 10.7% had HAP, and patients with HAP were higher in tertiary general hospitals (3.8%) but lower than in general hospitals (7.8%). Among patients who underwent surgery at hospitals in rural areas, 7.9% had HAP.

Table 1. General characteristics of the study population

p values reflect t-tests for continuous variables and χ 2 tests for dichotomous/categorical variables.

a Column percentage.

b Row percentage.

Table 2 presents the findings of the multilevel logistic regression analysis of the association between ICU nursing staff and HAP among surgical patients. Between-area variance in HAP was 0.708 (standard error: 0.085) in model 1, and the intraclass correlation coefficient (ICC) value was 0.177, indicating that 17.7% of the variability in HAP was accounted for by the hospital. In model 2, after including individual-level variables, the percentage change in variation was found to be 8.9%. Patients who received invasive ventilator care were at increased risk of HAP than those who did not (OR: 2.56, 95% CI 2.30–2.85), and patients who were hospitalized longer in ICU were also at increased risk of HAP (OR: 7.05; 95% CI: 5.98–2.63). In model 3, low levels of nurse staffing were associated with a higher incidence of HAP (low group: OR:1.88; 95% CI: 1.49–2.37). Model 4 included individual and hospital variables. Adjustment for both individual level and hospital level (model 4) led to a further reduction in area-level variance. Model 4 also presented that low levels of nurse staffing were associated with a higher incidence of HAP (mid-high, OR: 1.33, 95% CI: 1.12–1.57; mid-low, OR: 1.61, 95% CI: 1.27–2.04; low, OR: 2.13, 95% CI: 1.67–2.71).

Table 2. Adjusted odds ratio of HAP by characteristics of individual- and hospital-level, multi-level model

OR, odds ratio; CI, confidence interval; SE, standard error.

a 17.7% of the variability in HAP is accounted for by the hospital in the study.

* p < 0.0001.

Table 3 shows the association between ICU nurse staffing and HAP by covariate. Among patients who received VT care, patients in hospitals with a low level of nurse staffing had a significantly higher likelihood of HAP (mid-high, OR: 1.34, 95% CI: 1.09–1.64; low, OR: 1.82, 95% CI: 1.31–2.51). Patients whose length of stay in the ICU fell in tertile 2 had a greater association with HAP (mid-high, OR: 1.67, 95% CI: 1.20–2.32; mid-low, OR: 2.31, 95% CI: 1.48–3.62; low, OR: 2.70, 95% CI: 1.69–4.29). Among patients who utilized hospitals in the city, the lower the level of nurse staffing, the higher the association with HAP (mid-high, OR: 1.38, 95% CI: 1.10–1.74; mid-low, OR: 1.80, 95% CI: 1.27–2.56; low, OR: 2.39, 95% CI: 1.70–3.36).

Table 3. Subgroup analysis stratified by covariates

Adjusted for all covariates.

Table 4 presents a subgroup analysis that assessed the relationship between grade of the nursing management fee in ICU and HAP by hospital type. The likelihood of HAP was higher when patients were admitted to ICUs with higher nursing management fee grades, specifically grade 5 and above, compared to grade 1 admissions, both in general hospital and hospital settings. Likewise, within tertiary hospitals, ICU admissions with nursing management fees of grade 2 or higher were also significantly linked to an increased association of HAP when compared to grade 1 admissions.

Table 4. Association between grade of the nursing management fee in ICU and HAP by type of hospital

Adjusted for all covariates.

Table 5 shows the relationship between the level of nurse staffing and the type of HAP. A lower level of nurse staffing had a stronger association with bacterial pneumonia (mid-high, OR: 1.88, 95% CI: 1.41–2.51; mid-low, OR: 2.44, 95% CI: 1.68–3.54; low: OR: 3.32, 95% CI: 2.28–4.85). Also, as the nursing staff level decreased, the association with aspiration pneumonia increased, although it was not statistically significant (mid-high, OR: 1.07, 95% CI: 0.87–1.32; mid-low, OR: 1.16, 95% CI: 0.84–1.58; low: OR: 1.25, 95% CI: 0.90–1.74).

Table 5. Association between level of nursing staff and type of pneumonia

Adjusted for all covariates.

Discussion

Our study investigated the association between the level of nurse staffing in the ICU and HAP among surgical patients using National Health Insurance cohort data. Our results showed that surgical patients experiencing lower levels of nurse staffing in the ICU were more likely to develop HAP than those experiencing standard levels of nurse staffing. We determined factors associated with HAP at both individual and hospital levels. Also, our results might suggest the association with HAP varies across hospitals and that differences in hospital conditions should be considered to prevent HAI.

National representative data on the relationship between nurse staffing levels and HAP are scarce in previous studies. Some reports on the relationship between staffing level and HAP are available [Reference Aragon Penoyer9]. A systematic review investigated the relationship between healthcare-associated pneumonia and nurse staffing levels. Almost all studies found a relationship between the proportion of total hours of nursing care provided by RNs or the number of registered hours per day and pneumonia among patients [Reference Aragon Penoyer9, Reference Needleman, Buerhaus, Mattke, Stewart and Zelevinsky11, Reference Unruh16Reference Cho, Ketefian, Barkauskas and Smith18]. However, there have been few studies on how many RNs per patient are appropriate to improve the quality of care. Additionally, some studies found no link between staffing levels and the risk of pneumonia. However, this may be due to the severity of patients’ conditions, hospital size, and hospital-specific differences. Our study design reflected both hospital and individual health characteristics, using a multilevel analysis.

Previous studies demonstrated that adequate nurse staffing levels are linked to positive patient outcomes in the ICU [Reference Kane, Shamliyan, Mueller, Duval and Wilt19, Reference Lankshear, Sheldon and Maynard20]. Patients admitted to the ICU in general hospital with a grade 5 of ICU nursing management fee showed a significantly increased association with HAP compared to patients admitted to a grade 1. Patients admitted to ICU in tertiary hospital with a grade 2 of ICU nursing management fee showed a significantly increased association with HAP compared to patients admitted to a grade 1. This suggests that in the ICU setting, the number of beds assigned to nurses is a meaningful factor in preventing HAP in hospitals of all sizes. Another study in Korea showed that less than grade 5 of ICU nursing management fee in the ICU was associated with a shorter length of stay [Reference Kim and Kim21]. The results showed that a similar grade of the nursing management fee was associated with acceptable quality of medical care.

Furthermore, we found a relationship between the level of nurse staffing and pneumonia; in particular, staffing differences were associated with bacterial pneumonia rather than aspiration pneumonia. Various studies have shown that risk factors for aspiration pneumonia are related to individual health conditions, not hospital conditions, such as oral health, alcohol consumption, dehydration, and dementia, and studies related to hospital characteristics and nurse staffing levels have been limited [Reference Manabe, Teramoto, Tamiya, Okochi and Hizawa22Reference Terpenning, Taylor, Lopatin, Kerr, Dominguez and Loesche25]. However, patients, staff, and equipment clearly contribute to bacterial transmission, increasing the risk of infection [Reference Lax26, Reference Marinella, Pierson and Chenoweth27]. A low level of nurse staffing might result in nurses caring for more patients, which can lead to increased workload, which is associated with HAP [Reference Needleman, Buerhaus, Mattke, Stewart and Zelevinsky11].

Our results showed that the relationship between nurse staffing levels and HAP differs according to according to patients’ medical needs or hospital location. The association between nurse staffing level and HAP appeared to differ according to patients’ diagnoses. There was a relatively low association between nursing staff levels and HAP for hospitals located in rural areas. Due to the characteristics of the healthcare delivery system in Korea, patients with severe and acute conditions frequently utilize hospitals in the metropolitan or city, and most such hospitals have a high level of nurse staffing.

This study had several limitations. First, we only considered ICUs used by adults, excluding neonatal or paediatric ICUs. This did not permit derivation of the association between pneumonia and the overall level of intensive care nurse staffing in Korea. Further research is needed because there is a large difference in health characteristics when analyzing the nursing level for each population. Second, since there was a claim data limitation regarding clearly distinguishing HAP, we screened for HAP by specific clerical definition. However, we made efforts to improve the accuracy of HAP by excluding individuals with a history of pneumonia within the past year and those who had undergone lung-related surgery before surgery. Third, after 2019, a financial incentive system related to the level of nurse staffing changed the method of calculation from nurse-to-bed ratio to nurse-to-patient ratio. Our data used the nurse-to-bed ratio in the study period before the calculation method changed. Therefore, additional research on the appropriate number of nurses per patient is needed using the data after the change. Fourth, our data did not consider the characteristics of nursing staff, such as the nurses’ educational level and clinical experience. However, the grade of nurse staffing is highly accurate because it is measured as the number of nurses reported to the government every year compared with the number of ICU beds in Korean medical institutions.

Conclusion

In conclusion, this study found an association between the level of nurse staffing and HAP in surgical patients. A lower level of nurse staffing in the ICU had a strong relationship with HAP among surgical patients. This indicates that having fewer beds assigned to nurses in the ICU setting is a significant factor in preventing HAP regardless of the size of the hospital.

Supplementary material

The supplementary material for this article can be found at https://doi.org/10.1017/S0950268824000232.

Data availability statement

The data that support the findings of this study are available from the corresponding author, SI Jang, upon reasonable request.

Acknowledgements

We would like to thank the colleagues from the Department of Public Health, Graduate School of Yonsei University for advice on this manuscript.

Author contribution

Y.S.P. conceived the presented idea. Y.S.P. and I.Y. developed the theory and performed the computations. Y.S.P. and S.-y.J. verified the analytical methods. E.-C.P. and S.-I.J. supervised the findings of this work. All authors discussed the results and contributed to the final manuscript.

Competing interest

The authors have no conflicts of interest to declare.

Funding statement

This research was supported by a grant from the Korea Health Technology R&D Project through the Korea Health Industry Development Institute (KHIDI), funded by the Ministry of Health and Welfare, Republic of Korea (grant number: HI20C1130).

References

Wałaszek, M, et al. (2016). The risk factors for hospital-acquired pneumonia in the intensive care unit. Przegla̧d Epidemiologiczny 70(1), 1520.Google ScholarPubMed
Union OE (2018) Healthcare-associated infections. In Health at a Glance: Europe 2018: State of Health in the EU Cycle. Brussels: Paris/European Union.Google Scholar
Koulenti, D, Tsigou, E and Rello, J (2017) Nosocomial pneumonia in 27 ICUs in Europe: Perspectives from the EU-VAP/CAP study. European Journal of Clinical Microbiology & Infectious Diseases 36, 19992006.CrossRefGoogle Scholar
Kazaure, HS, Martin, M, Yoon, JK, Wren, SM (2014) Long-term results of a postoperative pneumonia prevention program for the inpatient surgical ward. JAMA Surgery 149(9), 914918.CrossRefGoogle ScholarPubMed
Harbarth, S, Sax, H and Gastmeier, P (2003) The preventable proportion of nosocomial infections: An overview of published reports. Journal of Hospital Infection 54(4), 258266; quiz 321.CrossRefGoogle ScholarPubMed
Masterton, R (2007) The place of guidelines in hospital-acquired pneumonia. Journal of Hospital Infection 66(2), 116122.CrossRefGoogle ScholarPubMed
Masterton, RG, et al. (2008) Guidelines for the management of hospital-acquired pneumonia in the UK: Report of the working party on hospital-acquired pneumonia of the British Society for Antimicrobial Chemotherapy. Journal of Antimicrobial Chemotherapy 62(1), 534.CrossRefGoogle Scholar
Masterton, RG, et al. (2008) Guidelines for the management of hospital-acquired pneumonia in the UK: Report of the working party on hospital-acquired pneumonia of the British Society for Antimicrobial Chemotherapy. Journal of Antimicrobial Chemotherapy 62(1), 534.CrossRefGoogle Scholar
Aragon Penoyer, D (2010) Nurse staffing and patient outcomes in critical care: A concise review. Critical Care Medicine 38(7), 15211528.CrossRefGoogle Scholar
Halm, M, et al. (2005) Hospital nurse staffing and patient mortality, emotional exhaustion, and job dissatisfaction. Clinical Nurse Specialist 19(5), 241251.CrossRefGoogle ScholarPubMed
Needleman, J, Buerhaus, P, Mattke, S, Stewart, M and Zelevinsky, K (2002) Nurse-staffing levels and the quality of care in hospitals. New England Journal of Medicine 346(22), 17151722.CrossRefGoogle ScholarPubMed
Tschannen, D and Kalisch, BJ (2009) The effect of variations in nurse staffing on patient length of stay in the acute care setting. Western Journal of Nursing Research 31(2), 153170.CrossRefGoogle ScholarPubMed
Mark, BA, Harless, DW and Berman, WF (2007) Nurse staffing and adverse events in hospitalized children. Policy, Politics, & Nursing Practice 8(2), 8392.CrossRefGoogle Scholar
Kim, Y and Kim, J (2015) Impact of a financial incentive policy on Korean nurse staffing. International Nursing Review 62(2), 171179.CrossRefGoogle ScholarPubMed
Lee, J, Lee, JS, Park, S-H, Shin, SA and Kim, K (2017) Cohort profile: The National Health Insurance Service–National Sample Cohort (NHIS-NSC), South Korea. International Journal of Epidemiology 46(2), e15.Google ScholarPubMed
Unruh, L (20073) Licensed nurse staffing and adverse events in hospitals. Medical Care 41(1).Google Scholar
Kovner, C and Gergen, PJ (1998) Nurse staffing levels and adverse events following surgery in U.S. hospitals. Image: The Journal of Nursing Scholarship 30(4), 315321.Google ScholarPubMed
Cho, S-H, Ketefian, S, Barkauskas, VH and Smith, DG (2003) The effects of nurse staffing on adverse events, morbidity, mortality, and medical costs. Nursing Research 52(2), 7179.CrossRefGoogle ScholarPubMed
Kane, RL, Shamliyan, TA, Mueller, C, Duval, S and Wilt, TJ (2007) The association of registered nurse staffing levels and patient outcomes: systematic review and meta-analysis. Medical Care, 45(12),11951204.CrossRefGoogle Scholar
Lankshear, AJ, Sheldon, TA and Maynard, A (2005) Nurse staffing and healthcare outcomes: A systematic review of the international research evidence. Advances in Nursing Science 28(2), 163174.CrossRefGoogle ScholarPubMed
Kim, S and Kim, TH (2022) The association between nurse staffing level and length of stay in general ward and intensive care unit in Korea. Applied Nursing Research 63, 151558.CrossRefGoogle ScholarPubMed
Manabe, T, Teramoto, S, Tamiya, N, Okochi, J and Hizawa, N (2015) Risk factors for aspiration pneumonia in older adults. PLoS One 10(10), e0140060.CrossRefGoogle ScholarPubMed
Taylor, JK, Fleming, GB, Singanayagam, A, Hill, AT and Chalmers, JD (2013) Risk factors for aspiration in community-acquired pneumonia: Analysis of a hospitalized UK cohort. The American Journal of Medicine 126(11), 9951001.CrossRefGoogle Scholar
Vonghia, L, et al. (2008) Acute alcohol intoxication. European Journal of Internal Medicine 19(8), 561567.CrossRefGoogle ScholarPubMed
Terpenning, MS, Taylor, GW, Lopatin, DE, Kerr, CK, Dominguez, BL and Loesche, WJ (2001) Aspiration pneumonia: Dental and oral risk factors in an older veteran population. Journal of the American Geriatrics Society 49(5), 557563.CrossRefGoogle Scholar
Lax, S, et al. (2017) Bacterial colonization and succession in a newly opened hospital. Science Translational Medicine 9(391), eaah6500.CrossRefGoogle Scholar
Marinella, MA, Pierson, C and Chenoweth, C (1997) The stethoscope: A potential source of nosocomial infection? Archives of Internal Medicine 157(7), 786790.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. General characteristics of the study population

Figure 1

Table 2. Adjusted odds ratio of HAP by characteristics of individual- and hospital-level, multi-level model

Figure 2

Table 3. Subgroup analysis stratified by covariates

Figure 3

Table 4. Association between grade of the nursing management fee in ICU and HAP by type of hospital

Figure 4

Table 5. Association between level of nursing staff and type of pneumonia

Supplementary material: File

Park et al. supplementary material

Park et al. supplementary material
Download Park et al. supplementary material(File)
File 16.4 KB