- Email: [email protected]
A Population-Based Cohort Study on the Drug-Specific Effect of Statins on Sepsis Outcome
Accepted Manuscript A population-based cohort study on the drug specific effect of statins on sepsis outcome Chien-Chang Lee, MD, ScD, Meng-tse Gabriel Lee, PhD, Tzu-Chun Hsu, BSc, Lorenzo Porta, MD, Shy-Shin Chang, MD, PhD, Chia-Hung Yo, MD, Kuang-Chau Tsai, MD, MSc, Matthew Lee, PhD, JD PII:
S0012-3692(17)32803-9
DOI:
10.1016/j.chest.2017.09.024
Reference:
CHEST 1353
To appear in:
CHEST
Received Date: 17 April 2017 Revised Date:
16 July 2017
Accepted Date: 6 September 2017
Please cite this article as: Lee CC, Lee MtG, Hsu TC, Porta L, Chang SS, Yo CH, Tsai KC, Lee M, A population-based cohort study on the drug specific effect of statins on sepsis outcome, CHEST (2017), doi: 10.1016/j.chest.2017.09.024. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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A population-based cohort study on the drug specific effect of statins on sepsis outcome
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Chien-Chang Lee1 MD, ScD, Meng-tse Gabriel Lee1 PhD, Tzu-Chun Hsu1 BSc, Lorenzo Porta2 MD, Shy-Shin Chang3 MD, PhD, Chia-Hung Yo4 MD, Kuang-Chau Tsai4 MD, MSc , Matthew Lee5 PhD, JD.
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Department of Emergency Medicine, National Taiwan University Hospital, Taipei, Taiwan 2
Dipartimento di scienze Biomediche e Cliniche, Ospedale "L. Sacco", Università degli Studi di Milano, Milan, Italy.
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Department of Family Medicine, Taipei Medical University Hospital and School of Medicine, Taipei Medical University, Taipei, Taiwan
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Funding: This study is supported by the Taiwan National Science Foundation Grant NSC 102-2314-B-002 -131 -MY3; Taiwan National Ministry of Science and Technology Grants MOST 104-2314-B-002 -039 -MY3, and MOST 105-2811-B-002-031. No funding bodies had any role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
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Running title: Drug specific effect of statins
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Department of Emergency Medicine, Far Eastern Memorial Hospital, New Taipei City, Taiwan Medical Wisdom Consultants Inc. Houston, USA
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* Correspondence and address reprint request to: Dr. Chien-Chang Lee, Department of Emergency Medicine, National Taiwan University Hospital, No. 7, Chung-Shan South Road, Taipei 100, Taiwan. E-mail: [email protected]
Manuscript words: 3395
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ABBREVIATION LIST
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PS: Propensity score
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CI: Confidence Interval
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ICD-9: International Classification of Disease version 9 PS: Propensity Score
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Abstract
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Background: Whether statin treatment, proved by recent experimental studies to have an antimicrobial activity, exerts a drug or a class specific effect in sepsis remains unknown.
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Methods: Short-term mortality in sepsis patients was analyzed using data from the National Health Insurance Research Database. Use of statins was defined as the cumulative use of a specific statin (atorvastatin, simvastatin or rosuvastatin) for more than 30 days prior to the index sepsis admission. We determined the association between statin and sepsis outcome by multivariate-adjusted Cox models and propensity score (PS) matched analysis, using a 1:1:1 PS matching technique.
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Results: A total of 52,737 sepsis patients fulfilled the inclusion criteria, of which 1855 were prescribed atorvastatin, 916 simvastatin, and 732 rosuvastatin. Compared with nonusers, simvastatin (Hazard Ratio [HR] 0.72, 95% CI 0.58-0.90) or atorvastatin (HR 0.78, 95% CI 0.68-0.90) were associated with an improved 30-day survival, while rosuvastatin was not (HR 0.87, 95% CI 0.73-1.04). Using rosuvastatin as the reference, atorvastatin (HR 0.79, 95% CI 0.64-0.99) and simvastatin (HR 0.77, 95% CI 0.59-0.99) had superior effectiveness in preventing mortality.
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Conclusions: Compatible with in vitro experimental findings, our results suggest that the drug specific effect of statins on sepsis, not correlated to their lipid-lowering potency.
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Introduction
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Sepsis is defined as a life-threatening organ dysfunction caused by a dysregulated host
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response to an infection. Despite major advancements in medical care, the mortality of
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sepsis remains high, with a case-fatality rate around 17 to 26%.1-4 Empirical
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antibiotic and organ supportive care have been the cornerstones of sepsis management.
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However, the global escalation in antimicrobial-resistant bacteria is increasingly
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compromising the effectiveness of antimicrobial therapy. Thus, therapies that can
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attenuate the dysregulated immune response in sepsis have been intensively studied in
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the past decade.
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Due to the pleiotropic immunomodulatory effects of statins demonstrated in animal
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models of sepsis, several clinical observational studies and randomized controlled trials
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have investigated whether the use of statins could improve the outcome of sepsis in
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humans.5-8 Most observational studies have found that preadmission use of statin
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improves the outcome of sepsis and a meta-analysis of 27 observational studies has
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concluded that statin treatment can decrease sepsis mortality by 35% (RR, 0.65; 95% CI,
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0.57 to 0.75).9-11 In contrast to observational studies, randomized control trials, however,
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did not observe beneficial effects of post-admission use of statins in sepsis patients.12-16
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It has been controversially debated if the observed protective effect of preadmission use
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of statin was due solely to the healthy user effect. Healthy-user effect describes the
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phenomenon in which patients prescribed with statins tend to have a constellation of
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healthier behaviors and, thus, improved outcomes in most systemic diseases.
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Just when the enthusiasm in the potential role of statins in improving sepsis outcome
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has tempered, emerging new evidence demonstrates that statins may have direct
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antibacterial effects and modulate the bacterial virulence.17-19 The antibacterial or anti-
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virulence effects may be statin-specific, not directly correlating with their lipid-lowering
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potency.17,20 For example, while simvastatin was associated with better antibacterial
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effects than rosuvastatin, the latter was found to have a more potent lipid-lowering
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capacity.21,22 Thus, the primary aim of this research is to determine if the protective
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effects of statins are drug or class specific. In addition, a head to head comparison on
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different types of statins may provide insights on whether the protective effect of statins
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is solely due to the healthy user effect.
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Methods
Data source
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Taiwan’s National Health Insurance (NHI) program is a single-payer government operated
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compulsory health insurance program, which covers over 98.4% of the 23 million people
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that reside in Taiwan. Specific data subsets were constructed for different research
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purposes. We used the year 2000 version of the Longitudinal Health Insurance Database
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(LHID) for this analysis, which used a systematic approach to randomly sample 1 million
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beneficiaries from the Registry for Beneficiaries of the NHIRD at 2000 to ensure the
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selected sample represents demographic and geographic region distribution of the
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entire Taiwanese population. The selected participants were followed from 2000 to 2011
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to form a longitudinal close cohort for research use. The longitudinal nature of LHID
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permits to identify a cohort based on diagnoses, health services and drugs utilization, to
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track medical history, to establish a prescription drug profile, and to determine the
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endpoint of drug treatments. The LHID included detailed information on patient
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demographics, inpatient and outpatient electronic claims records, individual diagnoses,
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surgical and medical operations, dispositions, and detailed data on prescribed
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medication, such as brand/generic name of the prescribed drugs, route, quantity and
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number
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National Taiwan University Hospital Research Ethics Committee (IRB No.201311044RINB)
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and patients’ consent was waived for this anonymized electronic research database.
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Study cohort and identification of sepsis patient
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The study cohort consisted of all the LHID participants hospitalized for sepsis between
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year 2001 and 2011. Year 2000 was used for assessment of covariates and statin use of
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sepsis patients identified in 2001. Compatible with the sepsis-3 definition, sepsis was
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defined as a life-threatening organ dysfunction caused by a dysregulated host response
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to an infection. However, as the laboratory test results for Sequential [Sepsis-related]
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Organ Failure Assessment (SOFA) score were not available in a health claims database,
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we identified sepsis cases using a validated International Classification of Diseases – 9th
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revision- Clinical Modification (ICD-9-CM) coding system proposed by Angus DC,3 in
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which at least one acute organ dysfunction and a diagnosis of bacterial or fungal
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infections is required to define an episode of sepsis. Acute organ dysfunctions used for
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this study were cardiovascular/shock, respiratory, central nervous system, hematologic,
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hepatic, renal and metabolic system dysfunctions. Supplementary eAppendix 1 lists the
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ICD-9-CM codes used to identify patients with bacterial and fungal infections and acute
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administration.
This
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approved
by
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organ dysfunctions. We defined index date as the first day of an emergency department
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or hospital visit due to sepsis within one given year, and recurrent sepsis admissions in
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the same year were not considered in our analysis. Patients were followed from the
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index admission date to the occurrence of death, termination of health insurance
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coverage or the end of the study period, whichever came first.
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Outcomes and covariates
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The primary endpoint for the analysis is 30-day all-cause mortality; the secondary
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endpoints are 90-day all-cause mortality and acute respiratory failure. Acute respiratory
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failure was defined by the requirement of ventilation during the index sepsis admission
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episode. Based on literature review, we collected a total of 61 covariates in the following
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dimensions: demographics, sources of infection, pre-existing comorbidities, proxies for
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lifestyle factors, health care facilities utilization and use of specific medications. Chronic
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comorbidities and risk factors for sepsis were collected from 1999 to the index sepsis
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event, and exposure to specific medications including statin was assessed one year prior
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to the index sepsis event
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Medication exposure
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In this study, we took three statins into account: atorvastatin, rosuvastatin, and
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simvastatin. We defined statin use by having a prescription record of statin ≥ 30 days
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duration in the 1-year period before the index sepsis event.
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Data Analysis
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Patients’ baseline characteristics were presented as percentages for categorical
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variables, and means with standard deviations for continuous variables. To examine the
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differences in patient characteristics, we used Mann-Whitney U tests for continuous
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variables and Pearson chi-square tests for dichotomous variables. Cox proportional
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hazard regression models were used to assess the association between statins and
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mortality. We tested the proportional hazard assumption by introducing an interaction
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term of exposure and follow-up time in the model. In addition, we confirmed the
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assumption of proportional hazards by an examination of the log (minus log) curves.
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To consolidate the strength of our findings, three methods were used to calculate hazard
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ratios. The first method obtains an unadjusted estimate, and the second adjusted for all
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individual covariates in the Cox models. In the third methods, we conducted a
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propensity score (PS) matched analysis, using the greedy matching algorithm.23 We built
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a PS to predict statin use in a full cohort and then applied the PS to different subgroup
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analysis. The validity of this approach has been proved by an empirical and simulation
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study.24 PS was defined as the conditional probability of any statin use derived from the
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logistic regression model that includes all potential predictors of statin prescription.
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Supplementary eAppendix 2 lists the component variables of the PS model and their
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corresponding weights. To verify baseline covariates were balanced after PS matching,
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we calculated standardized differences of baseline covariates for the simvastatin-
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atorvastatin, simvastatin-rosuvastatin, and atorvastatin-rosuvastatin pairs before and
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after PS matching. Values less than 10% were considered to be sufficiently balanced.
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Results were presented with a standardized difference plots. Finally, we conducted a
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1:1:1 propensity score (PS)-matched analysis using the triad optimized nearest-neighbor
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matching algorithm developed by Rassen et al.25 Each triad was selected using a distance
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function defined by the perimeter of a triangle with the maximum allowable propensity-
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score distance between patients set at 0.05. We plotted the cumulative hazard plots for
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mortality in the original and PS-matched cohort according to three different statin users.
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The survival difference between of three types of statin users were tested by a log rank
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test. All statistical analysis was performed using SAS 9.4 for Windows (SAS Institute Inc,
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Cary, NC), except for the cumulative hazard graphs, which were plotted with
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the survminer package in R-statistical software. A two-sided P value of 0.05 was deemed
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as significant for all analysis.
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Result
Cohort Enrollment and Baseline Characteristics
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We identified 52,737 individuals with sepsis, who met the inclusion criteria. The process
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of cohort assembling was demonstrated by a flow chart in Figure 1. In this cohort, 9188
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patients died at 30 days (17.4 %) and 11953 patients died at 90 days (22.7%) after
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hospital admission. 3598 patients (6.82%) received statin treatment before the index
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sepsis episodes, of which 916 received simvastatin, 1855 received atorvastatin, and 732
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received rosuvastatin. 95 patients used more than 1 types of statins and were excluded
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from analysis.
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Characteristics of the three types of statin users are presented in Table 1. There were no
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significant differences in the demographics, living areas, and major sources of infection
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among the three types of statin users. Rosuvastatin users are more likely to pay higher
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insurance premium and to have higher comorbidity score, history of chronic pulmonary
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diseases, fluid and electrolytes disorders and liver diseases than simvastatin or
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atorvastatin users. While simvastatin users are more likely to have lower combined
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comorbidity score, congestive heart failure, renal failure, cardiac arrhythmias and
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chronic pulmonary disease than the other two types of statins, atorvastatin users are
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more likely to have a history of alcohol-related diseases and complicated diabetes.
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Association between preadmission statin treatment and sepsis outcome
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Compared to patients who have never received statin treatment prior to developing
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sepsis, the use of statins before sepsis development was associated with a decreased
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risk of 30-day mortality in crude (HR 0.84, 95% CI: 0.77-0.91), confounder-adjusted (HR
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0.86, 95% CI:0.78-0.94), and propensity score matched (HR 0.88, 95% CI:0.78-0.99)
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analysis (Table 2). The beneficial effect of statins was attenuated, but remains significant
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for 90 day-mortality (PS-matched HR: 0.93, 95% CI: 0.88-0.99).
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Next, we compared use of individual type of statins to non-use (Table 2). Simvastatin
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tends to associate with the best outcome, followed by atorvastatin and rosuvastatin.
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Simvastatin and atorvastatin were associated with a decreased 30-day mortality, while
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rosuvastatin were not. For 90-day mortality, all three types of statins were associated
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with a reduced mortality in the PS-matched analysis, but the differences in the three
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types of statins were attenuated.
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Head to head comparison of individual class of statins
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To further analyze the comparative beneficial effect among the three types of statins, we
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performed confounder adjusted and PS-matched pairwise comparison on mortality and
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acute respiratory failure. Results of pairwise comparison were summarized in table 3.
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Using 1:1:1 PS matching, we matched 536 simvastatin users with 536 atorvastatin and
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536 rosuvastatin users. The standardized difference plot showed minimal standardized
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differences between the three groups after matching (Supplementary efigure 1).
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The effect estimates on the 30-day and 90-day mortality endpoints were very similar.
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However, due to more deceased outcomes, there were more significant differences
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between various types of statins users at the 90-day mortality endpoint. Even though
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there was no significant discrepancy between simvastatin and atorvastatin, these two
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statins consistently showed a superior beneficial effect over rosuvastatin in both
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confounder-adjusted and PS-matched analysis. In the PS-matched comparison cohort,
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use of simvastatin was associated with a 23% reduction (HR 0.77; 95%CI: 0.59-0.99), and
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use of atorvastatin was associated with a 21% reduction (HR 0.79; 95% CI: 0.64-0.99) of
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90-day mortality, compared with rosuvastatin. For acute respiratory failure, no
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significant difference was found for any pair of comparison.
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We created cumulative hazard plots according to three types of statin users in the
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original and PS-matched cohorts. In the original cohort, rosuvastatin users consistently
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had a higher cumulative probability of death at 30 (Figure 2 A, log-rank test, P= 0.013) or
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90 days (Figure 2 B, log-rank test, P= 0.0025) than atorvastatin or simvastatin users. In
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the PS-matched cohort, rosuvastatin users remained to have a significantly higher
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cumulative mortality at 30 (Figure 2 C, log-rank test, P= 0.0072) or 90 days (Figure 2 D,
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log-rank test, P= 0.0048) when compared to atorvastatin or simvastatin users.
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Discussion
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In this population based study, chronic statin treatment prior to sepsis development was
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associated with a 12% reduction in 30-day mortality in comparison to no prior statin
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treatment. When compared to non statin users, Simvastatin was associated with the
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most pronounced reduction in the 30-day mortality rate (28%), followed by atorvastatin
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(22%) and lastly by rosuvastatin (13%) of which the association was not significant. The
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beneficial effect of statins was attenuated at 90 days, but remains significant for the
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three types of statins. By applying 1:1:1 PS matching, we were able to make a head to
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head comparison among the three types of statins. In comparison to rosuvastatin,
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simvastatin and atorvastatin were associated with a significantly lower 30-day mortality.
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Even though in a previous study Ou et al. demonstrated that high potency statins
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(rosuvastatin, atorvastatin, and simvastatin) had better survival than low potency statins
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(fluvastatin, lovastatin, pitavastatin, pravastatin), they did not perform a head to head
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comparison of the individual type of statins. While Ou et al. study used one-year
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mortality as the main outcome measure to investigate the chronic cardiovascular
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complications of sepsis, we used 30-day mortality, as we were more interested in the
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potential pleiotropic effects of individual statins on the acute phase of sepsis.
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Furthermore, Ou et al. might have missed up to 70% of severe sepsis patients since they
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identified septicemia patients (ICD-9 CM code: 038.9) without including acute organ
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dysfunction.26,27 In fact, this approach lacks sensitivity, as the clinical diagnosis of
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septicemia requires a positive microbiological culture, which is only present in 20-40% of
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sepsis patients.28,29 To avoid this problem, we used the modified comprehensive coding
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system proposed by Angus DC, in which ICD-9CM codes for both infectious diseases and
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acute organ dysfunctions are required to identify sepsis. The approach mimics the
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clinical diagnosis and had been shown to have nearly three folds higher sensitivity than
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the septicemia approach in a validation study using chart review.30
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Previous experimental studies using animal model of sepsis, found that pre-treatment
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with statins can improve sepsis survival. Specifically, pre-treatment with simvastatin has
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been found to improve sepsis survival through preservation of cardiac function,
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attenuation of inflammatory cytokines, attenuation of neutrophil infiltration in the lung,
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and inhibiting T-cell dysfunction.31-33 Recently, specific statins were also associated with
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direct anti-microbial and anti-virulence effects.17-19 Of note, simvastatin was shown by
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several reports to have the most potent antibacterial activity. The antimicrobial
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spectrum includes methicillin-sensitive Staphylococcus aureus (MSSA), methicillin-
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resistant Staphylococcus aureus (MRSA), and several Gram positive and Gram negative
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bacteria.22,34-37 Atorvastatin, pravastatin, and rosuvastatin were also associated with
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antimicrobial potential, but had a higher minimal inhibitory concentration (MIC) than
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simvastatin.17,22,38 In a head to head comparison of MICs among the three statins of
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interest in this study, Masadeh M. et al. found that simvastatin and atorvastatin have a
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more potent antibacterial activity than rosuvastatin.22 Interestingly, our results correlate
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well with the previous findings, and provide support for the notion that antibacterial
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activity is playing a role in the observed mortality association.
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The exact mechanism of the differential antibacterial activity between different types of
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statins has not been elucidated, but several mechanisms have been proposed. Firstly,
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statins’ ability to inactivate the 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA)
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reductase (HMGR) is not only vital for cholesterol biosynthesis, but also contributes to
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the production of isoprenoids and lipid compounds that are essential for cell signaling
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and structure in the pathogen.39 Secondly, the chemical property of different types of
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statins may affect their targeting to bacteria. The lipophilic properties of simvastatin or
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atorvastatin may allow better binding to bacteria cell wall than the hydrophilic
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properties of rosuvastatin.40
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Clinical evidence on the benefits of statins in sepsis patients have been inconsistent.
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While early observational studies showed favorable effects of statins on sepsis patients,
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recent randomized trial using de novo statin treatment in ICU patients with severe sepsis
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failed to demonstrate clinical benefits.10,14 Healthy user bias, connected to the higher
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health awareness and healthier lifestyle of patients under statin treatment, was thought
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to account for the observed benefits in early observational studies.12 In fact, for most
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clinical studies the lifestyle factors and preventive service seeking behavior were difficult
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to measure and could not be adjusted for in the analysis. Even though our study could
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not obtain lifestyle information as well, we took into account several factors that may
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minimize the effect of healthy user bias. Firstly, in Taiwan statins are not available over-
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the-counter and are covered by the government health insurance; the decision on the
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initiation of statin treatment is based on a set of objective laboratory and clinical criteria,
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regardless of patients’ income status or education level. Secondly, we used insurance
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premium categories as a proxy to adjust for the socioeconomic status and frequency of
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healthcare utilization as a proxy to adjust for the preventive service seeking behavior.
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Lastly and most importantly, the unmeasured health behaviors associated with statin
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users would not be different in patients receiving different types of statins, thus the
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presence of a significant difference in the outcome of sepsis in patients receiving
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different types of statins would be an evidence against a strong influence of the healthy
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user bias in this observational study.
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We do not think the contradictory results between RCTs and observational studies could
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be explained by healthy user bias alone, instead the difference in results might be
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explained by three other factors: the specific type of statin, timing of statin treatment,
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and severity of patient population. Firstly, as described in this manuscript, the benefit of
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statin on sepsis patients is not equivalent across the entire class. Secondly, results of our
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previous research and the majority of observational studies found that pre-admission
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use of statin was associated with improved survival.9-11 Most of RCTs, however,
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examined the de novo use of statin after hospital admission.12-16 There is biological and
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pharmacokinetic plausibility that the anti-inflammatory properties of statins require
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appropriate treatment duration before taking effect.41,42 Finally, the majority of RCTs
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were performed on ICU patients who were severely ill. In our previous analysis, we
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found that the beneficial effects of statins disappeared in patients requiring ICU
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admission or patients with acute organ dysfunctions such as respiratory failure
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(Supplementary eTable1).
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Results of this study have to be interpreted in light of several limitations. Firstly, due to
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the administrative nature of the dataset, we do not have laboratory data to verify the
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distribution of infectious pathogens in patients receiving the three types of statins.
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Simvastatin has been shown to be more effective against Staphylococcus aureus.
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However, we found that the sources of infection were balanced in three types of statin
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users. In addition, we also did not have data on the lipid profile and could not analyze
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the effect of lipid control on sepsis outcome. Secondly, as encountered in all
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observational studies, we could not totally exclude the possibility of residual
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confounding. By applying the newly developed 1:1:1 PS matching technique, we were
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able to construct a comparison cohort with balanced covariates between the three
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groups. Finally, the observational nature of the study is an intrinsic limitation because
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the lack of randomization precludes a definite analysis of statin benefits. However, it
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may be difficult to enroll a sufficient number of chronic statin users for randomization in
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a short period. In this cohort of 52,737 patients with sepsis, only 6.8% of patients were
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chronic user of statins. Thus, a randomized control trial on the effect of long-term statin
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treatment on the outcome of sepsis would require tens of thousands of participants,
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which is highly unlikely in the near future. Observational data may currently remain the
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best available evidence for a class effect of statins for this indication.
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In conclusion, results of this population-based study suggest that the benefit of statin on
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sepsis patients is not equivalent across the entire class. Our results suggest superiority of
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simvastatin and atorvastatin to rosuvastatin in reducing short-term mortality of sepsis.
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The favorable effects of statins correlate with statin’s in vitro antibacterial activity, but
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not with the lipid-lowering potency. The evidence also supports that the benefits of
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statin in sepsis patients is not entirely due to healthy user bias. To conclude, our results
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suggest the possibility for physicians to selectively prescribe simvastatin to patients who
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are indicated for dyslipidemia treatment and are also at high risk of developing sepsis.
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These high sepsis risk patients include those with cancer, diabetes, old age,
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immunocompromised conditions, and a history of sepsis. Further studies in different
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populations or using different study designs are warranted to validate our findings.
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Figure legends Figure 1. Flowchart for cohort assembling process.
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349 Figure 2. Cumulative hazard plots for mortality before and after PS matching. (A) 30-day
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mortality before matching, (B) 90-day mortality before matching, (C) 30-day mortality
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after PS matching, (D) 90-day mortality after PS matching.
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Ethical approval This study was approved by the institutional review board of National Taiwan University Hospital.
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Conflict of Interest The authors declare that they had no competing interests when conducting the research.
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Acknowledgement We thank the staff of the Core Labs, the Department of Medical Research, and National Taiwan University Hospital for technical support, and medical wisdom consulting group for technical assistance in statistical analysis.
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Contributors C-CLee designed the study, obtained funding, drafted the analytical plan, guided the statistical analysis, interpreted the data, wrote the final draft, and critically revised the manuscript. M-TL interpreted the results, wrote the first and final draft and point-topoint response. T-CH performed most of the statistical analysis. L P helped with language editing and provided critical comments C-HY, K-CT, LP and S-CC reviewed the manuscript and provided critical insights in the medical contents. M-L, analyzed the data, provided critical feedback, and authorized the final manuscript.
Transparency The lead author (the manuscript’s guarantor) affirms that the manuscript is an honest, accurate, and transparent account of the study; that no important aspects of the study have been omitted; and that any discrepancies from the study as planned (and, if relevant, registered) have been explained.
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Declarations Disclaimer The interpretation and conclusions contained herein do not represent those of Bureau of National Health Insurance, Department of Health or National Health Research Institutes.
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1 Rhodes A, Evans LE, Alhazzani W, et al. Surviving Sepsis Campaign: International Guidelines for Management of Sepsis and Septic Shock: 2016. Intensive Care Med 2017; 43:304-377 2 Rhodes A, Evans LE, Alhazzani W, et al. Surviving Sepsis Campaign: International Guidelines for Management of Sepsis and Septic Shock: 2016. Crit Care Med 2017; 45:486-552 3 Angus DC, Linde-Zwirble WT, Lidicker J, et al. Epidemiology of severe sepsis in the United States: analysis of incidence, outcome, and associated costs of care. Crit Care Med 2001; 29:1303-1310 4 Fleischmann C, Scherag A, Adhikari NK, et al. Assessment of Global Incidence and Mortality of Hospital-treated Sepsis. Current Estimates and Limitations. Am J Respir Crit Care Med 2016; 193:259-272 5 Gao F, Linhartova L, Johnston AM, et al. Statins and sepsis. British Journal of Anaesthesia 2008; 100:288-298 6 Crisby M. Modulation of the inflammatory process by statins. Timely Top Med Cardiovasc Dis 2005; 9:E3 7 Crisby M. Modulation of the inflammatory process by statins. Drugs Today (Barc) 2003; 39:137-143 8 Hackam DG, Mamdani M, Li P, et al. Statins and sepsis in patients with cardiovascular disease: a population-based cohort analysis. The Lancet 2006; 367:413-418 9 Al Harbi SA, Tamim HM, Arabi YM. Association between statin therapy and outcomes in critically ill patients: a nested cohort study. BMC Pharmacology and Toxicology 2011; 11:12 10 Wan YD, Sun TW, Kan QC, et al. Effect of statin therapy on mortality from infection and sepsis: a meta-analysis of randomized and observational studies. Crit Care 2014; 18:R71 11 Mansur A, Steinau M, Popov AF, et al. Impact of statin therapy on mortality in patients with sepsis-associated acute respiratory distress syndrome (ARDS) depends on ARDS severity: a prospective observational cohort study. BMC Med 2015; 13:128 12 Brookhart MA, Patrick AR, Dormuth C, et al. Adherence to lipid-lowering therapy and the use of preventive health services: an investigation of the healthy user effect. American journal of epidemiology 2007; 166:348-354 13 Dinglas VD, Hopkins RO, Wozniak AW, et al. One-year outcomes of rosuvastatin versus placebo in sepsis-associated acute respiratory distress syndrome: prospective follow-up of SAILS randomised trial. Thorax 2016; 5:401-10 14 Deshpande A, Pasupuleti V, Rothberg MB. Statin therapy and mortality from sepsis: a meta-analysis of randomized trials. Am J Med 2015; 128:410-417 e411 15 McAuley DF, Laffey JG, O'Kane CM, et al. Simvastatin in the acute respiratory distress syndrome. New England Journal of Medicine 2014; 371:1695-1703 16 Heart TN. Rosuvastatin for sepsis-associated acute respiratory distress
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syndrome. The New England journal of medicine 2014; 370:2191 17 Hennessy E, Adams C, Reen FJ, et al. Is there potential for repurposing statins as novel antimicrobials? Antimicrobial Agents and Chemotherapy 2016; 60:5111-5121 18 Ting M, Whitaker EJ, Albandar JM. Systematic review of the in vitro effects of statins on oral and perioral microorganisms. Eur J Oral Sci 2016; 124:4-10 19 Jerwood S, Cohen J. Unexpected antimicrobial effect of statins. J Antimicrob Chemother 2008; 61:362-364 20 Shepherd J, Hunninghake DB, Barter P, et al. Guidelines for lowering lipids to reduce coronary artery disease risk: a comparison of rosuvastatin with atorvastatin, pravastatin, and simvastatin for achieving lipid-lowering goals. Am J Cardiol 2003; 91:11C-17C; discussion 17C-19C 21 Kamat SA, Gandhi SK, Davidson M. Comparative effectiveness of rosuvastatin versus other statin therapies in patients at increased risk of failure to achieve low-density lipoprotein goals. Current medical research and opinion 2007; 23:1121-1130 22 Masadeh M, Mhaidat N, Alzoubi K, et al. Antibacterial activity of statins: a comparative study of atorvastatin, simvastatin, and rosuvastatin. Ann Clin Microbiol Antimicrob 2012; 11:13 23 Parsons LS. Reducing bias in a propensity score matched-pair sample using greedy matching techniques. Proceedings of the Twenty-sixth Annual SAS Users group international conference: SAS Institute, Cary, NC, 2001; 214-226 24 Rassen JA, Glynn RJ, Rothman KJ, et al. Applying propensity scores estimated in a full cohort to adjust for confounding in subgroup analyses. Pharmacoepidemiol Drug Saf 2012; 21:697-709 25 Rassen JA, Shelat AA, Franklin JM, et al. Matching by propensity score in cohort studies with three treatment groups. Epidemiology 2013; 24:401-409 26 Wilhelms SB, Huss FR, Granath G, et al. Assessment of incidence of severe sepsis in Sweden using different ways of abstracting International Classification of Diseases codes: difficulties with methods and interpretation of results. Critical care medicine 2010; 38:1442-1449 27 Gaieski DF, Edwards JM, Kallan MJ, et al. Benchmarking the incidence and mortality of severe sepsis in the United States. Critical care medicine 2013; 41:1167-1174 28 Serody JS, Berrey MM, Albritton K, et al. Utility of obtaining blood cultures in febrile neutropenic patients undergoing bone marrow transplantation. Bone Marrow Transplant 2000; 26:533-538 29 Glerant JC, Hellmuth D, Schmit JL, et al. Utility of blood cultures in communityacquired pneumonia requiring hospitalization: influence of antibiotic treatment before admission. Respir Med 1999; 93:208-212 30 Iwashyna TJ, Angus DC. Declining case fatality rates for severe sepsis: good data bring good news with ambiguous implications. JAMA 2014; 311:1295-1297 31 Merx MW, Liehn EA, Janssens U, et al. HMG-CoA reductase inhibitor simvastatin profoundly improves survival in a murine model of sepsis. Circulation 2004; 109:2560-2565 32 Zhang S, Luo L, Wang Y, et al. Simvastatin protects against T cell immune
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dysfunction in abdominal sepsis. Shock 2012; 38:524-531 33 Zhang S, Rahman M, Zhang S, et al. Simvastatin antagonizes CD40L secretion, CXC chemokine formation, and pulmonary infiltration of neutrophils in abdominal sepsis. J Leukoc Biol 2011; 89:735-742 34 Wang CC, Yang PW, Yang SF, et al. Topical simvastatin promotes healing of Staphylococcus aureus-contaminated cutaneous wounds. Int Wound J 2016; 13:1150-1157 35 Graziano TS, Cuzzullin MC, Franco GC, et al. Statins and Antimicrobial Effects: Simvastatin as a Potential Drug against Staphylococcus aureus Biofilm. PloS one 2015; 10:e0128098 36 Thangamani S, Mohammad H, Abushahba MFN, et al. Exploring simvastatin, an antihyperlipidemic drug, as a potential topical antibacterial agent. Scientific reports 2015; 5:16407 37 Emani S, Gunjiganur GV, Mehta DS. Determination of the antibacterial activity of simvastatin against periodontal pathogens, Porphyromonas gingivalis and Aggregatibacter actinomycetemcomitans: An in vitro study. Contemp Clin Dent 2014; 5:377-382 38 Welsh A-M, Kruger P, Faoagali J. Antimicrobial action of atorvastatin and rosuvastatin. Pathology 2009; 41:689-691 39 Haeri MR, White K, Qharebeglou M, et al. Cholesterol suppresses antimicrobial effect of statins. Iranian journal of basic medical sciences 2015; 18:1253 40 Schachter M. Chemical, pharmacokinetic and pharmacodynamic properties of statins: an update. Fundamental & clinical pharmacology 2005; 19:117-125 41 Plenge JK, Hernandez TL, Weil KM, et al. Simvastatin lowers C-Reactive protein within 14 days an effect independent of low-density lipoprotein cholesterol reduction. Circulation 2002; 106:1447-1452 42 Chen WT, Krishnan GM, Sood N, et al. Effect of statins on atrial fibrillation after cardiac surgery: a duration- and dose-response meta-analysis. J Thorac Cardiovasc Surg 2010; 140:364-372
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ACCEPTED MANUSCRIPT Table 1. Baseline characteristics of the three types of statin users. Simvastatin, N= 916
Atorvastatin, N=1855
Rosuvastatin, N=732
P-value
436 (47.6%) 69.47±12.78
894 (48.19%) 70.57±12.57
379 (51.78%) 69.79±12.67
0.18
Urban Area
378(41.27)
839(45.23)
329(44.88)
Metro Area
251(27.4)
485(26.15)
190(25.92)
Suburban Area
198(21.62)
357(19.25)
142(19.37)
89(9.72)
174(9.38)
72(9.82)
Demographics Gender male (%) Age (mean ± SD)
0.072
Insurance premium level Dependent
137(14.96)
$1-$19,999
71(7.75)
SC
Countryside Area
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Areas of residence
0.58
268(14.45)
82(11.19)
184(9.92)
76(10.37)
767(41.35)
235(32.06)
342(37.34)
636(34.29)
340(46.38)
424(46.29)
918(49.49)
363(49.52)
0.25
55(6)
100(5.39)
38(5.18)
0.73
15(1.64)
33(1.78)
9(1.23)
0.61
328(35.81)
656(35.36)
242(33.02)
0.44
43(4.69)
105(5.66)
43(5.87)
0.49
52(5.68)
107(5.77)
53(7.23)
0.32
3.42±2.7
4.11±2.9
4.1±2.8
<0.0001*
27(2.95)
71(3.83)
16(2.18)
0.087
315(34.39)
807(43.50)
332(45.29)
<0.0001*
102(11.14)
254(13.69)
92(12.55)
0.16
202(22.05)
561(30.24)
224(30.56)
<0.0001*
16(1.75)
38(2.05)
13(1.77)
0.82
113(12.34)
238(12.83)
96(13.10)
0.89
15(1.64)
16(0.86)
16(2.18)
0.021*
163(17.79)
365(19.68)
142(19.37)
0.486
Cardiac arrhythmias
247(26.97)
597(32.18)
222(30.29)
0.019*
Chronic pulmonary disease
467(50.98)
1074(57.9)
434(59.21)
0.0006*
26(2.84)
55(2.96)
17(2.32)
0.67
Complicated diabetes
442(48.25)
982(52.94)
362(49.39)
0.043*
Deficiency anemia
235 (25.66)
502(27.06)
226(30.83)
0.054
366(39.96)
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$20,000-$39,999 >=$40,000 Sources of infection Lower respiratory infection Intra-abdominal infection Biliary tract infection
Orthopedic infection Comorbidity Combined comorbidity score Metastatic cancer Congestive heart failure
Renal failure Weight loss Hemiplegia Alcohol abuse Any tumor
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Dementia
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Skin infection
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Genitourinary tract infection
Coagulopathy
<0.0001*
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ACCEPTED MANUSCRIPT 195(21.29)
467(25.18)
203(27.69)
0.0087*
Liver disease
321(35.04)
680(36.66)
300 (40.93)
0.0405*
Peripheral vascular disorder
148(16.16)
356(19.19)
133(18.14)
0.15
Psychosis Pulmonary circulation disorders
85(9.28)
178(9.6)
61(8.32)
25(2.73)
67(3.61)
28(3.82)
0.60 0.39
HIV/AIDS
1(0.11)
2(0.11)
1(0.14)
0.98
797(87.01)
1675(90.3)
660(90.04)
0.025*
Number of OPD visit
45±28.95
42.68±26.42
43.59±26.86
0.016
Number of emergency department visit
0.69±1.77
1.05±3.022
1.17±2.22
0.0002*
Number of hospitalization
1.1±1.784
1.21±1.81
1.28±2.03
0.12
775(41.78)
323(44.07)
0.0002*
925(49.87)
359(48.98)
0.0025*
24(1.29)
21(2.86)
Healthcare utilization
Comedications use 458(50.00)
NSAIDs
394(43.01)
Aspirin Systemic immunosuppressive agents and biologics Systemic corticosteroids
0.022*
220(24.02)
402(21.67)
185(25.24)
0.108
17(1.86)
52(2.82)
21(2.86)
0.28
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DMARDs * means p-value <0.05
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19(2.07)
SC
Hypertension
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Fluid and electrolyte disorder
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ACCEPTED MANUSCRIPT Table 2. Crude and adjusted effect measures for the association between use of statins and risk of sepsis in-hospital mortality. Crude effect estimate Confounder adjusted Propensity score (HR, 95% confidence effect estimate matched effect estimate interval) (HR, 95% confidence (HR, 95% confidence interval) interval)
0.84(0.77 – 0.91)***
0.86(0.78 – 0.94)***
0.88(0.78 – 0.99)*
Simvastatin
0.82(0.70-0.98)*
0.88(0.74-1.04)
0.72(0.58-0.90)**
Atorvastatin
0.86(0.77-0.97)*
0.86(0.76-0.96)*
0.78(0.68-0.90)***
Rosuvastatin
1.12(0.95-1.32)
1.12(0.95-1.32)
0.87(0.73-1.04)
Statin use
0.91(0.87-0.95)***
0.94(0.90-0.98)**
0.93(0.88-0.99)**
Simvastatin
0.93(0.86-1.01)**
0.99(0.91-1.08)
0.87(0.78-0.98)*
Atorvastatin
0.91(0.86-0.97)
0.93(0.88-0.99)*
Rosuvastatin
0.94(0.85-1.03)
0.98(0.90-1.08)
90-day mortality
0.90(0.83-0.97)**
0.90(0.82-0.99)**
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*** means p-value <0.001, ** means p-value <0.01, * means p-value <0.05
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Statin use
SC
30-day mortality
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ACCEPTED MANUSCRIPT Table 3. Head to head comparison of the three types of statin users. Simvastatin vs. Simvastatin vs. Atorvastatin Rosuvastatin (HR, 95% confidence interval) (HR, 95% confidence interval) 30 days mortality
Atorvastatin vs. Rosuvastatin (HR, 95% confidence interval)
Confounder adjusted analysis
1.03(0.83-1.27)
0.78(0.61-0.99)*
0.77(0.62-0.94)*
Propensity score matched analysis
1.05(0.82-1.36)
0.80(0.60-1.06)
0.82(0.64-1.06)
Confounder adjusted analysis
1.01(0.84-1.22)
0.78(0.63-0.97)*
Propensity score matched analysis
1.03(0.82-1.29)
0.77(0.59-0.99)*
Confounder adjusted analysis
1.07(0.97-1.19)
1.04 (0.92-1.19)
Propensity score matched analysis
1.04(0.91-1.18)
1.00 (0.85-1.18)
SC
Acute respiratory failure
RI PT
90 days mortality
0.79(0.64-0.99)*
0.96 (0.86-1.07)
0.93 (0.80-1.08)
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* means p-value <0.05
0.76(0.63-0.90)*
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Codes associated with infection Gastrointestinal infection 001, Cholera; 002, Typhoid/paratyphoid fever; 003, Other salmonella infection; 004, Shigellosis; 005 Other food poisoning; 008, Intestinal infection not otherwise classified; 009, Ill-defined intestinal infection; 562.01, Diverticulitis of small intestine without hemorrhage; 562.03, Diverticulitis of small intestine with hemorrhage; 562.11, Diverticulitis of colon without hemorrhage; 562.13, Diverticulitis of colon with hemorrhage;
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e-Appendix 1: Codes associated with infection and organ dysfunction
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Zoonosis 020, Plague; 021, Tularemia; 022, Anthrax; 023, Brucellosis; 024, Glanders; 025, Melioidosis; 026, Rat-bite fever; 027, other bacterial zoonoses;
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Tuberculosis 010, Primary tuberculosis infection; 011 Pulmonary tuberculosis; 012, Other respiratory tuberculosis; 013, Central nervous system tuberculosis; 014, Intestinal tuberculosis; 015, Tuberculosis of bone and joint; 016, Genitourinary tuberculosis; 017, Tuberculosis not otherwise classified; 018, Miliary tuberculosis;
Other mycobacterial disease 030, Leprosy; 031, Other mycobacterial disease; Syphilis 090, Congenital syphilis; 091, Early symptomatic syphilis; 092, Early syphilis latent; 093, Cardiovascular syphilis; 094, Neurosyphilis; 095, Other late symptomatic syphilis; 096, Late syphilis latent; Online supplements are not copyedited prior to posting and the author(s) take full responsibility for the accuracy of all data.
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Other and unspecified syphilis; Yaws; Pinta; Other spirochetal infection;
037, Tetanus;
infection Bacterial meningitis; Meningitis, unspecified; Central nervous system abscess; Phlebitis of intracranial sinus; Meningococcal infection;
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CNS 320, 322, 324, 325, 036,
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Systematic fungal infection 110, Dermatophytosis; 111, Dermatomycosis not otherwise classified or specified; 112, Candidiasis; 114, Coccidioidomycosis; 115, Histoplasmosis; 116, Blastomycotic infection; 117, Other mycoses; 118, Opportunistic mycoses; 117.9 Disseminated fungal infection 112.5 Dissemintaed candidal infection 112.81 Disseminated fungal endocarditis 039, Actinomycotic infections;
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Other bacterial diseases 040, Other bacterial diseases; 041, Bacterial infection in other diseases not otherwise specified;
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097, 102, 103, 104,
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Cardiovascular infection 420, Acute pericarditis; 421, Acute or subacute endocarditis; 451, Thrombophlebitis;
Upper respiratory tract infection 461, Acute sinusitis; 462, Acute pharyngitis; 463, Acute tonsillitis; 464, Acute laryngitis/ tracheitis; 465, Acute upper respiratory infection of multiple sites/not otherwise specified; 101, Vincent’s angina; 034, Streptococcal throat/scarlet fever; 032, Diphtheria; Online supplements are not copyedited prior to posting and the author(s) take full responsibility for the accuracy of all data.
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Biliary tract infection 572.1, Portal pyremia; 575.0, Acute cholecystitis;
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Intra-abdominal infection 540, Acute appendicitis; 541, Appendicitis not otherwise specified; 542, Other appendicitis; 566, Anal and rectal abscess; 567, Peritonitis; 569.5, Intestinal abscess; 569.83, Perforation of intestine; 572.0, Abscess of liver;
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Lower respiratory tract infection 481, Pneumococcal pneumonia; 482, Other bacterial pneumonia; 485, Bronchopneumonia with organism not otherwise specified; 486, Pneumonia, organism not otherwise specified; 491.21, Acute exacerbation of obstructive chronic bronchitis; 494 Bronchiectasis; 510, Empyema; 513, Lung/mediastinum abscess; 033, Whooping cough; 484 Pneumonia classified in elsewhere 483 Pneumonia by other pathogens
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Genitourinary tract infection 590, Kidney infection; 597, Urethritis/urethral syndrome; 599.0, Urinary tract infection not otherwise specified; 601, Prostatic inflammation; 098, Gonococcal infections; Gynecological infection 614, Female pelvic inflammation disease; 615, Uterine inflammatory disease; 616, Other female genital inflammation; 681, Cellulitis, finger/ toe; 098, Gonococcal infections; Skin and appendix structure infection 682, Other cellulitis or abscess; 683, Acute lymphadenitis; 686, Other local skin infection; 035, Erysipelas; Online supplements are not copyedited prior to posting and the author(s) take full responsibility for the accuracy of all data.
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Post-operative complication 998.5, Postoperative infection;
Septicemia o o o o
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Nosocomial infection 999.3, Infectious complication of medical care not otherwise classified.
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Musculoskeletal infection 711.0, Pyogenic arthritis; 730, Osteomyelitis; 790.7, Bacteremia; 996.6, Infection or inflammation of device/graft;
Streptococcal septicemia Staphylococcal septicemia Pneumococcal septicemia [Streptococcus pneumoniae septicemia] Septicemia due to anaerobes Septicemia due to bacteroides Excludes: gas gangrene (040.0) § that due to anaerobic streptococci (038.0) o 038.4 Septicemia due to other gram-negative organisms § 038.40 Gram-negative organism, unspecified § Gram-negative septicemia NOS § 038.41 Hemophilus influenzae [H. influenzae] § 038.42 Escherichia coli [E. coli] § 038.43 Pseudomonas § 038.44 Serratia § 038.49 Other o 038.8 Other specified septicemias § Excludes: septicemia (due to): § anthrax (022.3) § gonococcal (098.89) § herpetic (054.5) § meningococcal (036.2) § septicemic plague (020.2) o 038.9 Unspecified septicemia § Septicemia NOS § Excludes: bacteremia NOS (790.7) 995.92 Severe sepsis 790.7 Bacteremia
o o
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038.0 038.1 038.2 038.3 § §
Codes associated with organ dysfunction Cardiovascular dysfunction/Shock Shock 785.5 or hypotension 458
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Hematologic system dysfunction Hematologic Secondary thrombocytopenia 287.4 Thrombocytopenia, unspecified 287.5 Other/unspecified coagulation defect 286.9 Defibrination syndrome 286.6
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Hepatic system dysfunction Hepatic Acute and subacute necrosis of liver 570 Hepatic encephalopathy 572.2 Hepatorenal syndrome 572,4 Other squeal of chronic liver disease 572.8 Hepatic infarction 573.4, 573.8 Liver replaced by transplant V42.7
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Central nervous system dysfunction Neurologic Encephalopathy 348.3 Transient organic psychosis 293 Anoxic brain damage 348.1
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Acute respiratory failure Mechanical ventilation 96.7 or use of ventilator 57001B,57002B, 57023B, 57029C
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Renal system dysfunction Acute renal failure 584 or Use of CVVH (58014C)
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Metabolic system dysfunction Diabetic ketoscidosis 250.1 Hyperosmolar hyperglycemic state 250.2
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e-Table 1. Empirical predictors for prescription of statin and associated odds ratios of the propensity score model. The c-statistic for the propensity score model is 0.82. Adjusted odds ratio (95%CI)
Chronic pulmonary disease
EP
<.0001 <.0001
1.49 (1.31 – 1.71) 1.29 (1.12 – 1.48) 1.09 (0.94 – 1.25)
<.0001
0.99 (0.89 – 1.12) 1.37 (1.21 – 1.55) 1.50 (1.27 – 1.78)
<.0001
0.91 1.46 1.17 1.26 1.02 1.02
<.0001 <.0001 0.01 .0008 0.66 0.74
SC
Rheumatologic disease Peptic ulcer disease Mild liver disease Diabetes without chronic complications Diabetes with chronic complications Hemiplegia or paraplegia Renal disease Any malignancy, including leukemia and lymphoma Moderate or severe liver disease Metastatic solid tumor AIDS/HIV cardiovascular comorbidities Stroke or transient ischemic attack Peripheral arterial disease Angina Other ischemic heart disease Cerebral atherosclerosis Percutaneous coronary/coronary artery bypass graft intervention Additional comorbidities Alcohol/drug use Psychiatric disorder Neurologic disorder
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0.68 (0.62 – 0.73) 1.11 (1.08 – 1.13)
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Demographics Gender male Age Area (countryside area as reference) Urban Area Metro Area Suburban Area Insurance type (dependent as reference) $1-$19,999 $20,000-$39,999 >=$40,000 Comorbidity Combined comorbidity score Myocardial infarction Congestive heart failure Peripheral vascular disease Cerebrovascular disease Dementia
P-value
RI PT
Characteristics
(0.89 (1.29 (1.05 (1.10 (0.92 (0.89
– – – – – –
0.94) 1.64) 1.31) 1.44) 1.13) 1.17)
1.03 (0.92 – 1.17)
0.59
0.98 1.02 1.08 2.18 1.59 1.12 1.38 0.85 0.35 1.50 0.68
(0.83 (0.94 (1.00 (1.94 (1.45 (0.98 (1.25 (0.77 (0.26 (1.15 (0.23
– – – – – – – – – – –
1.15) 1.11) 1.18) 2.39) 1.75) 1.27) 1.52) 0.98) 0.47) 1.96) 2.65)
0.79 0.70 0.05 <.0001 <.0001 0.09 <.0001 0.01 <.0001 0.003 0.68
1.22 0.91 1.22 1.31 1.02 1.50
(1.10 (0.77 (1.11 (1.20 (0.88 (1.32
– – – – – –
1.36) 1.07) 1.34) 1.44) 1.18) 1.72)
0.0002 0.27 <.0001 <.0001 0.82 <.0001
0.91 (0.77 – 1.07) 1.11 (1.02 – 1.20) 0.75 (0.67 – 0.84)
0.26 0.01 <.0001
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(1.09 (1.09 (0.85 (0.67 (0.77 (0.44
1.82) 1.31) 1.05) 1.04) 3.75) 0.89)
1.00 (1.00 – 1.01) 1.03 (1.02 – 1.04) 0.89 (0.86 – 0.91)
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0.98 1.48 1.18 1.00 1.16 1.25 1.21 1.18 2.10 0.90 1.14 1.00 1.03 1.37 0.99
(0.90 (1.37 (0.78 (0.91 (0.89 (1.14 (1.11 (1.08 (1.93 (0.78 (1.03 (0.76 (0.91 (1.26 (0.91
– – – – – – – – – – – – – – –
1.06) 1.61) 1.80) 1.10) 1.52) 1.36) 1.31) 1.29) 2.28) 1.04) 1.26) 1.33) 1.17) 1.48) 1.07)
0.008 .0002 0.27 0.11 0.18 0.009 <.0001 <.0001 <.0001 0.64 <.0001 0.43 0.98 0.28 <.0001 <.0001 0.0002 <.0001 0.15 0.01 0.98 0.60 <.0001 0.73
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– – – – – –
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1.41 1.19 0.94 0.84 1.70 0.63
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Obesity Other Cancer except Metastatic solid tumor Gastrointestinal or esophageal hemorrhage Bed-ridden status Solid organ transplantation such as renal or heart transplantation Malnutrition Healthcare utilization Number of OPD visit Number of emergency department visit Number of hospitalization Medication NSAID (Nonsteroidal anti-inflammatory drugs) Aspirin Systemic immunosuppressive agents and biologics Systemic corticosteroids DMARDs (disease modifying anti-rheumatic drugs) ACE inhibitors Beta blockers Loop diuretics Angiotensin II antagonists Digoxin Nitrates Antipsychotics Proton-pump inhibitors(PPI) Calcium channel blocker Acetaminophen
Online supplements are not copyedited prior to posting and the author(s) take full responsibility for the accuracy of all data.
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Propensity score adjusted HR (95% Confidence interval)
P-value
>75 years of age
0.92 (0.77 - 1.11)
0.38
<75 years of age
0.71 (0.59 - 0.87)
0.0006
Male
0.82 (0.68 - 0.98)
0.032
Female
0.80 (0.66 - 0.98)
0.027
Diabetes
0.76 (0.65 - 0.89)
0.0007
Non diabetes
0.83 (0.70 - 0.99)
0.039
With congestive heart failure
0.83 (0.68 - 1.00)
0.055
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e-Table 2. Risk of mortality in different patient subgroups
0.80 (0.67 - 0.96)
0.017
0.88 (0.64 - 1.21)
0.430
0.80 (0.69 - 0.92)
0.003
0.71 (0.53 - 0.96)
0.024
0.84 (0.73 - 0.98)
0.025
0.94 (0.85,1.04)
0.204
0.79 (0.64,0.98)
0.033
1.17 (0.72,1.91)
0.536
No Hematologic system dysfunction
0.87 (0.80,0.96)
0.004
Use of vasopressor
0.94 (0.85,1.03)
0.177
0.95 (0.73,1.23)
0.689
0.91 (0.64,1.30)
0.606
0.87(0.79,0.95)
0.003
1 or 2 organ dysfunction
0.87(0.78,0.96)
0.004
>= 3 organ dysfunction
1.00(0.80,1.25)
0.999
0.90 (0.78 - 1.03)
0.194
0.88 (0.81 – 0.97)
<0.0001
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Patient subgroups
Without congestive heart failure Myocardial infarction Non myocardial infarction Cancer Non cancer
Non Ventilator Support
Dialysis No dialysis
ICU Non-ICU
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No use of vasopressor
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Hematologic system dysfunction
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Ventilator Support
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e-Figure1. Standardized differences in the baseline covariates after propensity score matching. Simvastatin vs. atorvastatin (A), and simvastatin vs. rosuvastatin (B).
170913
Online supplements are not copyedited prior to posting and the author(s) take full responsibility for the accuracy of all data.
S0012-3692(17)32803-9
DOI:
10.1016/j.chest.2017.09.024
Reference:
CHEST 1353
To appear in:
CHEST
Received Date: 17 April 2017 Revised Date:
16 July 2017
Accepted Date: 6 September 2017
Please cite this article as: Lee CC, Lee MtG, Hsu TC, Porta L, Chang SS, Yo CH, Tsai KC, Lee M, A population-based cohort study on the drug specific effect of statins on sepsis outcome, CHEST (2017), doi: 10.1016/j.chest.2017.09.024. This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain.
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A population-based cohort study on the drug specific effect of statins on sepsis outcome
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Chien-Chang Lee1 MD, ScD, Meng-tse Gabriel Lee1 PhD, Tzu-Chun Hsu1 BSc, Lorenzo Porta2 MD, Shy-Shin Chang3 MD, PhD, Chia-Hung Yo4 MD, Kuang-Chau Tsai4 MD, MSc , Matthew Lee5 PhD, JD.
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1
Department of Emergency Medicine, National Taiwan University Hospital, Taipei, Taiwan 2
Dipartimento di scienze Biomediche e Cliniche, Ospedale "L. Sacco", Università degli Studi di Milano, Milan, Italy.
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Department of Family Medicine, Taipei Medical University Hospital and School of Medicine, Taipei Medical University, Taipei, Taiwan
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Funding: This study is supported by the Taiwan National Science Foundation Grant NSC 102-2314-B-002 -131 -MY3; Taiwan National Ministry of Science and Technology Grants MOST 104-2314-B-002 -039 -MY3, and MOST 105-2811-B-002-031. No funding bodies had any role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
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Running title: Drug specific effect of statins
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Department of Emergency Medicine, Far Eastern Memorial Hospital, New Taipei City, Taiwan Medical Wisdom Consultants Inc. Houston, USA
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* Correspondence and address reprint request to: Dr. Chien-Chang Lee, Department of Emergency Medicine, National Taiwan University Hospital, No. 7, Chung-Shan South Road, Taipei 100, Taiwan. E-mail: [email protected]
Manuscript words: 3395
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ABBREVIATION LIST
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PS: Propensity score
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CI: Confidence Interval
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ICD-9: International Classification of Disease version 9 PS: Propensity Score
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Abstract
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Background: Whether statin treatment, proved by recent experimental studies to have an antimicrobial activity, exerts a drug or a class specific effect in sepsis remains unknown.
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Methods: Short-term mortality in sepsis patients was analyzed using data from the National Health Insurance Research Database. Use of statins was defined as the cumulative use of a specific statin (atorvastatin, simvastatin or rosuvastatin) for more than 30 days prior to the index sepsis admission. We determined the association between statin and sepsis outcome by multivariate-adjusted Cox models and propensity score (PS) matched analysis, using a 1:1:1 PS matching technique.
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Results: A total of 52,737 sepsis patients fulfilled the inclusion criteria, of which 1855 were prescribed atorvastatin, 916 simvastatin, and 732 rosuvastatin. Compared with nonusers, simvastatin (Hazard Ratio [HR] 0.72, 95% CI 0.58-0.90) or atorvastatin (HR 0.78, 95% CI 0.68-0.90) were associated with an improved 30-day survival, while rosuvastatin was not (HR 0.87, 95% CI 0.73-1.04). Using rosuvastatin as the reference, atorvastatin (HR 0.79, 95% CI 0.64-0.99) and simvastatin (HR 0.77, 95% CI 0.59-0.99) had superior effectiveness in preventing mortality.
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Conclusions: Compatible with in vitro experimental findings, our results suggest that the drug specific effect of statins on sepsis, not correlated to their lipid-lowering potency.
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Introduction
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Sepsis is defined as a life-threatening organ dysfunction caused by a dysregulated host
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response to an infection. Despite major advancements in medical care, the mortality of
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sepsis remains high, with a case-fatality rate around 17 to 26%.1-4 Empirical
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antibiotic and organ supportive care have been the cornerstones of sepsis management.
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However, the global escalation in antimicrobial-resistant bacteria is increasingly
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compromising the effectiveness of antimicrobial therapy. Thus, therapies that can
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attenuate the dysregulated immune response in sepsis have been intensively studied in
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the past decade.
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Due to the pleiotropic immunomodulatory effects of statins demonstrated in animal
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models of sepsis, several clinical observational studies and randomized controlled trials
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have investigated whether the use of statins could improve the outcome of sepsis in
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humans.5-8 Most observational studies have found that preadmission use of statin
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improves the outcome of sepsis and a meta-analysis of 27 observational studies has
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concluded that statin treatment can decrease sepsis mortality by 35% (RR, 0.65; 95% CI,
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0.57 to 0.75).9-11 In contrast to observational studies, randomized control trials, however,
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did not observe beneficial effects of post-admission use of statins in sepsis patients.12-16
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It has been controversially debated if the observed protective effect of preadmission use
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of statin was due solely to the healthy user effect. Healthy-user effect describes the
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phenomenon in which patients prescribed with statins tend to have a constellation of
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healthier behaviors and, thus, improved outcomes in most systemic diseases.
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Just when the enthusiasm in the potential role of statins in improving sepsis outcome
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has tempered, emerging new evidence demonstrates that statins may have direct
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antibacterial effects and modulate the bacterial virulence.17-19 The antibacterial or anti-
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virulence effects may be statin-specific, not directly correlating with their lipid-lowering
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potency.17,20 For example, while simvastatin was associated with better antibacterial
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effects than rosuvastatin, the latter was found to have a more potent lipid-lowering
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capacity.21,22 Thus, the primary aim of this research is to determine if the protective
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effects of statins are drug or class specific. In addition, a head to head comparison on
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different types of statins may provide insights on whether the protective effect of statins
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is solely due to the healthy user effect.
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Methods
Data source
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Taiwan’s National Health Insurance (NHI) program is a single-payer government operated
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compulsory health insurance program, which covers over 98.4% of the 23 million people
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that reside in Taiwan. Specific data subsets were constructed for different research
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purposes. We used the year 2000 version of the Longitudinal Health Insurance Database
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(LHID) for this analysis, which used a systematic approach to randomly sample 1 million
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beneficiaries from the Registry for Beneficiaries of the NHIRD at 2000 to ensure the
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selected sample represents demographic and geographic region distribution of the
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entire Taiwanese population. The selected participants were followed from 2000 to 2011
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to form a longitudinal close cohort for research use. The longitudinal nature of LHID
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permits to identify a cohort based on diagnoses, health services and drugs utilization, to
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track medical history, to establish a prescription drug profile, and to determine the
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endpoint of drug treatments. The LHID included detailed information on patient
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demographics, inpatient and outpatient electronic claims records, individual diagnoses,
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surgical and medical operations, dispositions, and detailed data on prescribed
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medication, such as brand/generic name of the prescribed drugs, route, quantity and
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number
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National Taiwan University Hospital Research Ethics Committee (IRB No.201311044RINB)
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and patients’ consent was waived for this anonymized electronic research database.
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Study cohort and identification of sepsis patient
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The study cohort consisted of all the LHID participants hospitalized for sepsis between
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year 2001 and 2011. Year 2000 was used for assessment of covariates and statin use of
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sepsis patients identified in 2001. Compatible with the sepsis-3 definition, sepsis was
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defined as a life-threatening organ dysfunction caused by a dysregulated host response
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to an infection. However, as the laboratory test results for Sequential [Sepsis-related]
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Organ Failure Assessment (SOFA) score were not available in a health claims database,
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we identified sepsis cases using a validated International Classification of Diseases – 9th
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revision- Clinical Modification (ICD-9-CM) coding system proposed by Angus DC,3 in
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which at least one acute organ dysfunction and a diagnosis of bacterial or fungal
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infections is required to define an episode of sepsis. Acute organ dysfunctions used for
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this study were cardiovascular/shock, respiratory, central nervous system, hematologic,
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hepatic, renal and metabolic system dysfunctions. Supplementary eAppendix 1 lists the
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ICD-9-CM codes used to identify patients with bacterial and fungal infections and acute
days
of
administration.
This
study
was
approved
by
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organ dysfunctions. We defined index date as the first day of an emergency department
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or hospital visit due to sepsis within one given year, and recurrent sepsis admissions in
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the same year were not considered in our analysis. Patients were followed from the
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index admission date to the occurrence of death, termination of health insurance
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coverage or the end of the study period, whichever came first.
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Outcomes and covariates
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The primary endpoint for the analysis is 30-day all-cause mortality; the secondary
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endpoints are 90-day all-cause mortality and acute respiratory failure. Acute respiratory
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failure was defined by the requirement of ventilation during the index sepsis admission
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episode. Based on literature review, we collected a total of 61 covariates in the following
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dimensions: demographics, sources of infection, pre-existing comorbidities, proxies for
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lifestyle factors, health care facilities utilization and use of specific medications. Chronic
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comorbidities and risk factors for sepsis were collected from 1999 to the index sepsis
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event, and exposure to specific medications including statin was assessed one year prior
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to the index sepsis event
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Medication exposure
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In this study, we took three statins into account: atorvastatin, rosuvastatin, and
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simvastatin. We defined statin use by having a prescription record of statin ≥ 30 days
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duration in the 1-year period before the index sepsis event.
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Data Analysis
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Patients’ baseline characteristics were presented as percentages for categorical
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variables, and means with standard deviations for continuous variables. To examine the
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differences in patient characteristics, we used Mann-Whitney U tests for continuous
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variables and Pearson chi-square tests for dichotomous variables. Cox proportional
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hazard regression models were used to assess the association between statins and
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mortality. We tested the proportional hazard assumption by introducing an interaction
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term of exposure and follow-up time in the model. In addition, we confirmed the
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assumption of proportional hazards by an examination of the log (minus log) curves.
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To consolidate the strength of our findings, three methods were used to calculate hazard
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ratios. The first method obtains an unadjusted estimate, and the second adjusted for all
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individual covariates in the Cox models. In the third methods, we conducted a
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propensity score (PS) matched analysis, using the greedy matching algorithm.23 We built
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a PS to predict statin use in a full cohort and then applied the PS to different subgroup
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analysis. The validity of this approach has been proved by an empirical and simulation
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study.24 PS was defined as the conditional probability of any statin use derived from the
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logistic regression model that includes all potential predictors of statin prescription.
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Supplementary eAppendix 2 lists the component variables of the PS model and their
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corresponding weights. To verify baseline covariates were balanced after PS matching,
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we calculated standardized differences of baseline covariates for the simvastatin-
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atorvastatin, simvastatin-rosuvastatin, and atorvastatin-rosuvastatin pairs before and
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after PS matching. Values less than 10% were considered to be sufficiently balanced.
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Results were presented with a standardized difference plots. Finally, we conducted a
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1:1:1 propensity score (PS)-matched analysis using the triad optimized nearest-neighbor
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matching algorithm developed by Rassen et al.25 Each triad was selected using a distance
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function defined by the perimeter of a triangle with the maximum allowable propensity-
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score distance between patients set at 0.05. We plotted the cumulative hazard plots for
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mortality in the original and PS-matched cohort according to three different statin users.
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The survival difference between of three types of statin users were tested by a log rank
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test. All statistical analysis was performed using SAS 9.4 for Windows (SAS Institute Inc,
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Cary, NC), except for the cumulative hazard graphs, which were plotted with
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the survminer package in R-statistical software. A two-sided P value of 0.05 was deemed
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as significant for all analysis.
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Result
Cohort Enrollment and Baseline Characteristics
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We identified 52,737 individuals with sepsis, who met the inclusion criteria. The process
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of cohort assembling was demonstrated by a flow chart in Figure 1. In this cohort, 9188
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patients died at 30 days (17.4 %) and 11953 patients died at 90 days (22.7%) after
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hospital admission. 3598 patients (6.82%) received statin treatment before the index
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sepsis episodes, of which 916 received simvastatin, 1855 received atorvastatin, and 732
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received rosuvastatin. 95 patients used more than 1 types of statins and were excluded
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from analysis.
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Characteristics of the three types of statin users are presented in Table 1. There were no
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significant differences in the demographics, living areas, and major sources of infection
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among the three types of statin users. Rosuvastatin users are more likely to pay higher
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insurance premium and to have higher comorbidity score, history of chronic pulmonary
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diseases, fluid and electrolytes disorders and liver diseases than simvastatin or
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atorvastatin users. While simvastatin users are more likely to have lower combined
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comorbidity score, congestive heart failure, renal failure, cardiac arrhythmias and
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chronic pulmonary disease than the other two types of statins, atorvastatin users are
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more likely to have a history of alcohol-related diseases and complicated diabetes.
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Association between preadmission statin treatment and sepsis outcome
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Compared to patients who have never received statin treatment prior to developing
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sepsis, the use of statins before sepsis development was associated with a decreased
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risk of 30-day mortality in crude (HR 0.84, 95% CI: 0.77-0.91), confounder-adjusted (HR
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0.86, 95% CI:0.78-0.94), and propensity score matched (HR 0.88, 95% CI:0.78-0.99)
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analysis (Table 2). The beneficial effect of statins was attenuated, but remains significant
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for 90 day-mortality (PS-matched HR: 0.93, 95% CI: 0.88-0.99).
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Next, we compared use of individual type of statins to non-use (Table 2). Simvastatin
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tends to associate with the best outcome, followed by atorvastatin and rosuvastatin.
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Simvastatin and atorvastatin were associated with a decreased 30-day mortality, while
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rosuvastatin were not. For 90-day mortality, all three types of statins were associated
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with a reduced mortality in the PS-matched analysis, but the differences in the three
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types of statins were attenuated.
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Head to head comparison of individual class of statins
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To further analyze the comparative beneficial effect among the three types of statins, we
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performed confounder adjusted and PS-matched pairwise comparison on mortality and
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acute respiratory failure. Results of pairwise comparison were summarized in table 3.
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Using 1:1:1 PS matching, we matched 536 simvastatin users with 536 atorvastatin and
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536 rosuvastatin users. The standardized difference plot showed minimal standardized
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differences between the three groups after matching (Supplementary efigure 1).
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The effect estimates on the 30-day and 90-day mortality endpoints were very similar.
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However, due to more deceased outcomes, there were more significant differences
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between various types of statins users at the 90-day mortality endpoint. Even though
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there was no significant discrepancy between simvastatin and atorvastatin, these two
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statins consistently showed a superior beneficial effect over rosuvastatin in both
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confounder-adjusted and PS-matched analysis. In the PS-matched comparison cohort,
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use of simvastatin was associated with a 23% reduction (HR 0.77; 95%CI: 0.59-0.99), and
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use of atorvastatin was associated with a 21% reduction (HR 0.79; 95% CI: 0.64-0.99) of
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90-day mortality, compared with rosuvastatin. For acute respiratory failure, no
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significant difference was found for any pair of comparison.
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We created cumulative hazard plots according to three types of statin users in the
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original and PS-matched cohorts. In the original cohort, rosuvastatin users consistently
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had a higher cumulative probability of death at 30 (Figure 2 A, log-rank test, P= 0.013) or
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90 days (Figure 2 B, log-rank test, P= 0.0025) than atorvastatin or simvastatin users. In
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the PS-matched cohort, rosuvastatin users remained to have a significantly higher
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cumulative mortality at 30 (Figure 2 C, log-rank test, P= 0.0072) or 90 days (Figure 2 D,
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log-rank test, P= 0.0048) when compared to atorvastatin or simvastatin users.
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Discussion
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In this population based study, chronic statin treatment prior to sepsis development was
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associated with a 12% reduction in 30-day mortality in comparison to no prior statin
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treatment. When compared to non statin users, Simvastatin was associated with the
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most pronounced reduction in the 30-day mortality rate (28%), followed by atorvastatin
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(22%) and lastly by rosuvastatin (13%) of which the association was not significant. The
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beneficial effect of statins was attenuated at 90 days, but remains significant for the
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three types of statins. By applying 1:1:1 PS matching, we were able to make a head to
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head comparison among the three types of statins. In comparison to rosuvastatin,
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simvastatin and atorvastatin were associated with a significantly lower 30-day mortality.
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Even though in a previous study Ou et al. demonstrated that high potency statins
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(rosuvastatin, atorvastatin, and simvastatin) had better survival than low potency statins
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(fluvastatin, lovastatin, pitavastatin, pravastatin), they did not perform a head to head
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comparison of the individual type of statins. While Ou et al. study used one-year
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mortality as the main outcome measure to investigate the chronic cardiovascular
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complications of sepsis, we used 30-day mortality, as we were more interested in the
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potential pleiotropic effects of individual statins on the acute phase of sepsis.
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Furthermore, Ou et al. might have missed up to 70% of severe sepsis patients since they
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identified septicemia patients (ICD-9 CM code: 038.9) without including acute organ
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dysfunction.26,27 In fact, this approach lacks sensitivity, as the clinical diagnosis of
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septicemia requires a positive microbiological culture, which is only present in 20-40% of
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sepsis patients.28,29 To avoid this problem, we used the modified comprehensive coding
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system proposed by Angus DC, in which ICD-9CM codes for both infectious diseases and
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acute organ dysfunctions are required to identify sepsis. The approach mimics the
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clinical diagnosis and had been shown to have nearly three folds higher sensitivity than
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the septicemia approach in a validation study using chart review.30
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Previous experimental studies using animal model of sepsis, found that pre-treatment
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with statins can improve sepsis survival. Specifically, pre-treatment with simvastatin has
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been found to improve sepsis survival through preservation of cardiac function,
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attenuation of inflammatory cytokines, attenuation of neutrophil infiltration in the lung,
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and inhibiting T-cell dysfunction.31-33 Recently, specific statins were also associated with
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direct anti-microbial and anti-virulence effects.17-19 Of note, simvastatin was shown by
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several reports to have the most potent antibacterial activity. The antimicrobial
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spectrum includes methicillin-sensitive Staphylococcus aureus (MSSA), methicillin-
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resistant Staphylococcus aureus (MRSA), and several Gram positive and Gram negative
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bacteria.22,34-37 Atorvastatin, pravastatin, and rosuvastatin were also associated with
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antimicrobial potential, but had a higher minimal inhibitory concentration (MIC) than
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simvastatin.17,22,38 In a head to head comparison of MICs among the three statins of
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interest in this study, Masadeh M. et al. found that simvastatin and atorvastatin have a
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more potent antibacterial activity than rosuvastatin.22 Interestingly, our results correlate
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well with the previous findings, and provide support for the notion that antibacterial
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activity is playing a role in the observed mortality association.
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The exact mechanism of the differential antibacterial activity between different types of
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statins has not been elucidated, but several mechanisms have been proposed. Firstly,
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statins’ ability to inactivate the 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA)
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reductase (HMGR) is not only vital for cholesterol biosynthesis, but also contributes to
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the production of isoprenoids and lipid compounds that are essential for cell signaling
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and structure in the pathogen.39 Secondly, the chemical property of different types of
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statins may affect their targeting to bacteria. The lipophilic properties of simvastatin or
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atorvastatin may allow better binding to bacteria cell wall than the hydrophilic
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properties of rosuvastatin.40
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Clinical evidence on the benefits of statins in sepsis patients have been inconsistent.
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While early observational studies showed favorable effects of statins on sepsis patients,
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recent randomized trial using de novo statin treatment in ICU patients with severe sepsis
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failed to demonstrate clinical benefits.10,14 Healthy user bias, connected to the higher
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health awareness and healthier lifestyle of patients under statin treatment, was thought
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to account for the observed benefits in early observational studies.12 In fact, for most
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clinical studies the lifestyle factors and preventive service seeking behavior were difficult
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to measure and could not be adjusted for in the analysis. Even though our study could
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not obtain lifestyle information as well, we took into account several factors that may
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minimize the effect of healthy user bias. Firstly, in Taiwan statins are not available over-
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the-counter and are covered by the government health insurance; the decision on the
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initiation of statin treatment is based on a set of objective laboratory and clinical criteria,
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regardless of patients’ income status or education level. Secondly, we used insurance
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premium categories as a proxy to adjust for the socioeconomic status and frequency of
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healthcare utilization as a proxy to adjust for the preventive service seeking behavior.
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Lastly and most importantly, the unmeasured health behaviors associated with statin
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users would not be different in patients receiving different types of statins, thus the
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presence of a significant difference in the outcome of sepsis in patients receiving
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different types of statins would be an evidence against a strong influence of the healthy
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user bias in this observational study.
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We do not think the contradictory results between RCTs and observational studies could
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be explained by healthy user bias alone, instead the difference in results might be
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explained by three other factors: the specific type of statin, timing of statin treatment,
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and severity of patient population. Firstly, as described in this manuscript, the benefit of
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statin on sepsis patients is not equivalent across the entire class. Secondly, results of our
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previous research and the majority of observational studies found that pre-admission
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use of statin was associated with improved survival.9-11 Most of RCTs, however,
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examined the de novo use of statin after hospital admission.12-16 There is biological and
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pharmacokinetic plausibility that the anti-inflammatory properties of statins require
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appropriate treatment duration before taking effect.41,42 Finally, the majority of RCTs
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were performed on ICU patients who were severely ill. In our previous analysis, we
315
found that the beneficial effects of statins disappeared in patients requiring ICU
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admission or patients with acute organ dysfunctions such as respiratory failure
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(Supplementary eTable1).
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Results of this study have to be interpreted in light of several limitations. Firstly, due to
319
the administrative nature of the dataset, we do not have laboratory data to verify the
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distribution of infectious pathogens in patients receiving the three types of statins.
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Simvastatin has been shown to be more effective against Staphylococcus aureus.
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However, we found that the sources of infection were balanced in three types of statin
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users. In addition, we also did not have data on the lipid profile and could not analyze
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the effect of lipid control on sepsis outcome. Secondly, as encountered in all
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observational studies, we could not totally exclude the possibility of residual
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confounding. By applying the newly developed 1:1:1 PS matching technique, we were
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able to construct a comparison cohort with balanced covariates between the three
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groups. Finally, the observational nature of the study is an intrinsic limitation because
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the lack of randomization precludes a definite analysis of statin benefits. However, it
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may be difficult to enroll a sufficient number of chronic statin users for randomization in
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a short period. In this cohort of 52,737 patients with sepsis, only 6.8% of patients were
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chronic user of statins. Thus, a randomized control trial on the effect of long-term statin
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treatment on the outcome of sepsis would require tens of thousands of participants,
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which is highly unlikely in the near future. Observational data may currently remain the
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best available evidence for a class effect of statins for this indication.
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In conclusion, results of this population-based study suggest that the benefit of statin on
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sepsis patients is not equivalent across the entire class. Our results suggest superiority of
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simvastatin and atorvastatin to rosuvastatin in reducing short-term mortality of sepsis.
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The favorable effects of statins correlate with statin’s in vitro antibacterial activity, but
340
not with the lipid-lowering potency. The evidence also supports that the benefits of
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statin in sepsis patients is not entirely due to healthy user bias. To conclude, our results
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suggest the possibility for physicians to selectively prescribe simvastatin to patients who
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are indicated for dyslipidemia treatment and are also at high risk of developing sepsis.
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These high sepsis risk patients include those with cancer, diabetes, old age,
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immunocompromised conditions, and a history of sepsis. Further studies in different
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populations or using different study designs are warranted to validate our findings.
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347 348
Figure legends Figure 1. Flowchart for cohort assembling process.
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349 Figure 2. Cumulative hazard plots for mortality before and after PS matching. (A) 30-day
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mortality before matching, (B) 90-day mortality before matching, (C) 30-day mortality
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after PS matching, (D) 90-day mortality after PS matching.
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Ethical approval This study was approved by the institutional review board of National Taiwan University Hospital.
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Conflict of Interest The authors declare that they had no competing interests when conducting the research.
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Acknowledgement We thank the staff of the Core Labs, the Department of Medical Research, and National Taiwan University Hospital for technical support, and medical wisdom consulting group for technical assistance in statistical analysis.
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Contributors C-CLee designed the study, obtained funding, drafted the analytical plan, guided the statistical analysis, interpreted the data, wrote the final draft, and critically revised the manuscript. M-TL interpreted the results, wrote the first and final draft and point-topoint response. T-CH performed most of the statistical analysis. L P helped with language editing and provided critical comments C-HY, K-CT, LP and S-CC reviewed the manuscript and provided critical insights in the medical contents. M-L, analyzed the data, provided critical feedback, and authorized the final manuscript.
Transparency The lead author (the manuscript’s guarantor) affirms that the manuscript is an honest, accurate, and transparent account of the study; that no important aspects of the study have been omitted; and that any discrepancies from the study as planned (and, if relevant, registered) have been explained.
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Declarations Disclaimer The interpretation and conclusions contained herein do not represent those of Bureau of National Health Insurance, Department of Health or National Health Research Institutes.
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References
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syndrome. The New England journal of medicine 2014; 370:2191 17 Hennessy E, Adams C, Reen FJ, et al. Is there potential for repurposing statins as novel antimicrobials? Antimicrobial Agents and Chemotherapy 2016; 60:5111-5121 18 Ting M, Whitaker EJ, Albandar JM. Systematic review of the in vitro effects of statins on oral and perioral microorganisms. Eur J Oral Sci 2016; 124:4-10 19 Jerwood S, Cohen J. Unexpected antimicrobial effect of statins. J Antimicrob Chemother 2008; 61:362-364 20 Shepherd J, Hunninghake DB, Barter P, et al. Guidelines for lowering lipids to reduce coronary artery disease risk: a comparison of rosuvastatin with atorvastatin, pravastatin, and simvastatin for achieving lipid-lowering goals. Am J Cardiol 2003; 91:11C-17C; discussion 17C-19C 21 Kamat SA, Gandhi SK, Davidson M. Comparative effectiveness of rosuvastatin versus other statin therapies in patients at increased risk of failure to achieve low-density lipoprotein goals. Current medical research and opinion 2007; 23:1121-1130 22 Masadeh M, Mhaidat N, Alzoubi K, et al. Antibacterial activity of statins: a comparative study of atorvastatin, simvastatin, and rosuvastatin. Ann Clin Microbiol Antimicrob 2012; 11:13 23 Parsons LS. Reducing bias in a propensity score matched-pair sample using greedy matching techniques. Proceedings of the Twenty-sixth Annual SAS Users group international conference: SAS Institute, Cary, NC, 2001; 214-226 24 Rassen JA, Glynn RJ, Rothman KJ, et al. Applying propensity scores estimated in a full cohort to adjust for confounding in subgroup analyses. Pharmacoepidemiol Drug Saf 2012; 21:697-709 25 Rassen JA, Shelat AA, Franklin JM, et al. Matching by propensity score in cohort studies with three treatment groups. Epidemiology 2013; 24:401-409 26 Wilhelms SB, Huss FR, Granath G, et al. Assessment of incidence of severe sepsis in Sweden using different ways of abstracting International Classification of Diseases codes: difficulties with methods and interpretation of results. Critical care medicine 2010; 38:1442-1449 27 Gaieski DF, Edwards JM, Kallan MJ, et al. Benchmarking the incidence and mortality of severe sepsis in the United States. Critical care medicine 2013; 41:1167-1174 28 Serody JS, Berrey MM, Albritton K, et al. Utility of obtaining blood cultures in febrile neutropenic patients undergoing bone marrow transplantation. Bone Marrow Transplant 2000; 26:533-538 29 Glerant JC, Hellmuth D, Schmit JL, et al. Utility of blood cultures in communityacquired pneumonia requiring hospitalization: influence of antibiotic treatment before admission. Respir Med 1999; 93:208-212 30 Iwashyna TJ, Angus DC. Declining case fatality rates for severe sepsis: good data bring good news with ambiguous implications. JAMA 2014; 311:1295-1297 31 Merx MW, Liehn EA, Janssens U, et al. HMG-CoA reductase inhibitor simvastatin profoundly improves survival in a murine model of sepsis. Circulation 2004; 109:2560-2565 32 Zhang S, Luo L, Wang Y, et al. Simvastatin protects against T cell immune
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dysfunction in abdominal sepsis. Shock 2012; 38:524-531 33 Zhang S, Rahman M, Zhang S, et al. Simvastatin antagonizes CD40L secretion, CXC chemokine formation, and pulmonary infiltration of neutrophils in abdominal sepsis. J Leukoc Biol 2011; 89:735-742 34 Wang CC, Yang PW, Yang SF, et al. Topical simvastatin promotes healing of Staphylococcus aureus-contaminated cutaneous wounds. Int Wound J 2016; 13:1150-1157 35 Graziano TS, Cuzzullin MC, Franco GC, et al. Statins and Antimicrobial Effects: Simvastatin as a Potential Drug against Staphylococcus aureus Biofilm. PloS one 2015; 10:e0128098 36 Thangamani S, Mohammad H, Abushahba MFN, et al. Exploring simvastatin, an antihyperlipidemic drug, as a potential topical antibacterial agent. Scientific reports 2015; 5:16407 37 Emani S, Gunjiganur GV, Mehta DS. Determination of the antibacterial activity of simvastatin against periodontal pathogens, Porphyromonas gingivalis and Aggregatibacter actinomycetemcomitans: An in vitro study. Contemp Clin Dent 2014; 5:377-382 38 Welsh A-M, Kruger P, Faoagali J. Antimicrobial action of atorvastatin and rosuvastatin. Pathology 2009; 41:689-691 39 Haeri MR, White K, Qharebeglou M, et al. Cholesterol suppresses antimicrobial effect of statins. Iranian journal of basic medical sciences 2015; 18:1253 40 Schachter M. Chemical, pharmacokinetic and pharmacodynamic properties of statins: an update. Fundamental & clinical pharmacology 2005; 19:117-125 41 Plenge JK, Hernandez TL, Weil KM, et al. Simvastatin lowers C-Reactive protein within 14 days an effect independent of low-density lipoprotein cholesterol reduction. Circulation 2002; 106:1447-1452 42 Chen WT, Krishnan GM, Sood N, et al. Effect of statins on atrial fibrillation after cardiac surgery: a duration- and dose-response meta-analysis. J Thorac Cardiovasc Surg 2010; 140:364-372
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ACCEPTED MANUSCRIPT Table 1. Baseline characteristics of the three types of statin users. Simvastatin, N= 916
Atorvastatin, N=1855
Rosuvastatin, N=732
P-value
436 (47.6%) 69.47±12.78
894 (48.19%) 70.57±12.57
379 (51.78%) 69.79±12.67
0.18
Urban Area
378(41.27)
839(45.23)
329(44.88)
Metro Area
251(27.4)
485(26.15)
190(25.92)
Suburban Area
198(21.62)
357(19.25)
142(19.37)
89(9.72)
174(9.38)
72(9.82)
Demographics Gender male (%) Age (mean ± SD)
0.072
Insurance premium level Dependent
137(14.96)
$1-$19,999
71(7.75)
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Countryside Area
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Areas of residence
0.58
268(14.45)
82(11.19)
184(9.92)
76(10.37)
767(41.35)
235(32.06)
342(37.34)
636(34.29)
340(46.38)
424(46.29)
918(49.49)
363(49.52)
0.25
55(6)
100(5.39)
38(5.18)
0.73
15(1.64)
33(1.78)
9(1.23)
0.61
328(35.81)
656(35.36)
242(33.02)
0.44
43(4.69)
105(5.66)
43(5.87)
0.49
52(5.68)
107(5.77)
53(7.23)
0.32
3.42±2.7
4.11±2.9
4.1±2.8
<0.0001*
27(2.95)
71(3.83)
16(2.18)
0.087
315(34.39)
807(43.50)
332(45.29)
<0.0001*
102(11.14)
254(13.69)
92(12.55)
0.16
202(22.05)
561(30.24)
224(30.56)
<0.0001*
16(1.75)
38(2.05)
13(1.77)
0.82
113(12.34)
238(12.83)
96(13.10)
0.89
15(1.64)
16(0.86)
16(2.18)
0.021*
163(17.79)
365(19.68)
142(19.37)
0.486
Cardiac arrhythmias
247(26.97)
597(32.18)
222(30.29)
0.019*
Chronic pulmonary disease
467(50.98)
1074(57.9)
434(59.21)
0.0006*
26(2.84)
55(2.96)
17(2.32)
0.67
Complicated diabetes
442(48.25)
982(52.94)
362(49.39)
0.043*
Deficiency anemia
235 (25.66)
502(27.06)
226(30.83)
0.054
366(39.96)
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$20,000-$39,999 >=$40,000 Sources of infection Lower respiratory infection Intra-abdominal infection Biliary tract infection
Orthopedic infection Comorbidity Combined comorbidity score Metastatic cancer Congestive heart failure
Renal failure Weight loss Hemiplegia Alcohol abuse Any tumor
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Dementia
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Skin infection
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Genitourinary tract infection
Coagulopathy
<0.0001*
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467(25.18)
203(27.69)
0.0087*
Liver disease
321(35.04)
680(36.66)
300 (40.93)
0.0405*
Peripheral vascular disorder
148(16.16)
356(19.19)
133(18.14)
0.15
Psychosis Pulmonary circulation disorders
85(9.28)
178(9.6)
61(8.32)
25(2.73)
67(3.61)
28(3.82)
0.60 0.39
HIV/AIDS
1(0.11)
2(0.11)
1(0.14)
0.98
797(87.01)
1675(90.3)
660(90.04)
0.025*
Number of OPD visit
45±28.95
42.68±26.42
43.59±26.86
0.016
Number of emergency department visit
0.69±1.77
1.05±3.022
1.17±2.22
0.0002*
Number of hospitalization
1.1±1.784
1.21±1.81
1.28±2.03
0.12
775(41.78)
323(44.07)
0.0002*
925(49.87)
359(48.98)
0.0025*
24(1.29)
21(2.86)
Healthcare utilization
Comedications use 458(50.00)
NSAIDs
394(43.01)
Aspirin Systemic immunosuppressive agents and biologics Systemic corticosteroids
0.022*
220(24.02)
402(21.67)
185(25.24)
0.108
17(1.86)
52(2.82)
21(2.86)
0.28
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DMARDs * means p-value <0.05
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19(2.07)
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Hypertension
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Fluid and electrolyte disorder
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ACCEPTED MANUSCRIPT Table 2. Crude and adjusted effect measures for the association between use of statins and risk of sepsis in-hospital mortality. Crude effect estimate Confounder adjusted Propensity score (HR, 95% confidence effect estimate matched effect estimate interval) (HR, 95% confidence (HR, 95% confidence interval) interval)
0.84(0.77 – 0.91)***
0.86(0.78 – 0.94)***
0.88(0.78 – 0.99)*
Simvastatin
0.82(0.70-0.98)*
0.88(0.74-1.04)
0.72(0.58-0.90)**
Atorvastatin
0.86(0.77-0.97)*
0.86(0.76-0.96)*
0.78(0.68-0.90)***
Rosuvastatin
1.12(0.95-1.32)
1.12(0.95-1.32)
0.87(0.73-1.04)
Statin use
0.91(0.87-0.95)***
0.94(0.90-0.98)**
0.93(0.88-0.99)**
Simvastatin
0.93(0.86-1.01)**
0.99(0.91-1.08)
0.87(0.78-0.98)*
Atorvastatin
0.91(0.86-0.97)
0.93(0.88-0.99)*
Rosuvastatin
0.94(0.85-1.03)
0.98(0.90-1.08)
90-day mortality
0.90(0.83-0.97)**
0.90(0.82-0.99)**
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Statin use
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30-day mortality
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ACCEPTED MANUSCRIPT Table 3. Head to head comparison of the three types of statin users. Simvastatin vs. Simvastatin vs. Atorvastatin Rosuvastatin (HR, 95% confidence interval) (HR, 95% confidence interval) 30 days mortality
Atorvastatin vs. Rosuvastatin (HR, 95% confidence interval)
Confounder adjusted analysis
1.03(0.83-1.27)
0.78(0.61-0.99)*
0.77(0.62-0.94)*
Propensity score matched analysis
1.05(0.82-1.36)
0.80(0.60-1.06)
0.82(0.64-1.06)
Confounder adjusted analysis
1.01(0.84-1.22)
0.78(0.63-0.97)*
Propensity score matched analysis
1.03(0.82-1.29)
0.77(0.59-0.99)*
Confounder adjusted analysis
1.07(0.97-1.19)
1.04 (0.92-1.19)
Propensity score matched analysis
1.04(0.91-1.18)
1.00 (0.85-1.18)
SC
Acute respiratory failure
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90 days mortality
0.79(0.64-0.99)*
0.96 (0.86-1.07)
0.93 (0.80-1.08)
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* means p-value <0.05
0.76(0.63-0.90)*
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Codes associated with infection Gastrointestinal infection 001, Cholera; 002, Typhoid/paratyphoid fever; 003, Other salmonella infection; 004, Shigellosis; 005 Other food poisoning; 008, Intestinal infection not otherwise classified; 009, Ill-defined intestinal infection; 562.01, Diverticulitis of small intestine without hemorrhage; 562.03, Diverticulitis of small intestine with hemorrhage; 562.11, Diverticulitis of colon without hemorrhage; 562.13, Diverticulitis of colon with hemorrhage;
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e-Appendix 1: Codes associated with infection and organ dysfunction
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Zoonosis 020, Plague; 021, Tularemia; 022, Anthrax; 023, Brucellosis; 024, Glanders; 025, Melioidosis; 026, Rat-bite fever; 027, other bacterial zoonoses;
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Tuberculosis 010, Primary tuberculosis infection; 011 Pulmonary tuberculosis; 012, Other respiratory tuberculosis; 013, Central nervous system tuberculosis; 014, Intestinal tuberculosis; 015, Tuberculosis of bone and joint; 016, Genitourinary tuberculosis; 017, Tuberculosis not otherwise classified; 018, Miliary tuberculosis;
Other mycobacterial disease 030, Leprosy; 031, Other mycobacterial disease; Syphilis 090, Congenital syphilis; 091, Early symptomatic syphilis; 092, Early syphilis latent; 093, Cardiovascular syphilis; 094, Neurosyphilis; 095, Other late symptomatic syphilis; 096, Late syphilis latent; Online supplements are not copyedited prior to posting and the author(s) take full responsibility for the accuracy of all data.
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Other and unspecified syphilis; Yaws; Pinta; Other spirochetal infection;
037, Tetanus;
infection Bacterial meningitis; Meningitis, unspecified; Central nervous system abscess; Phlebitis of intracranial sinus; Meningococcal infection;
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Systematic fungal infection 110, Dermatophytosis; 111, Dermatomycosis not otherwise classified or specified; 112, Candidiasis; 114, Coccidioidomycosis; 115, Histoplasmosis; 116, Blastomycotic infection; 117, Other mycoses; 118, Opportunistic mycoses; 117.9 Disseminated fungal infection 112.5 Dissemintaed candidal infection 112.81 Disseminated fungal endocarditis 039, Actinomycotic infections;
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097, 102, 103, 104,
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Cardiovascular infection 420, Acute pericarditis; 421, Acute or subacute endocarditis; 451, Thrombophlebitis;
Upper respiratory tract infection 461, Acute sinusitis; 462, Acute pharyngitis; 463, Acute tonsillitis; 464, Acute laryngitis/ tracheitis; 465, Acute upper respiratory infection of multiple sites/not otherwise specified; 101, Vincent’s angina; 034, Streptococcal throat/scarlet fever; 032, Diphtheria; Online supplements are not copyedited prior to posting and the author(s) take full responsibility for the accuracy of all data.
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Biliary tract infection 572.1, Portal pyremia; 575.0, Acute cholecystitis;
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Intra-abdominal infection 540, Acute appendicitis; 541, Appendicitis not otherwise specified; 542, Other appendicitis; 566, Anal and rectal abscess; 567, Peritonitis; 569.5, Intestinal abscess; 569.83, Perforation of intestine; 572.0, Abscess of liver;
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Lower respiratory tract infection 481, Pneumococcal pneumonia; 482, Other bacterial pneumonia; 485, Bronchopneumonia with organism not otherwise specified; 486, Pneumonia, organism not otherwise specified; 491.21, Acute exacerbation of obstructive chronic bronchitis; 494 Bronchiectasis; 510, Empyema; 513, Lung/mediastinum abscess; 033, Whooping cough; 484 Pneumonia classified in elsewhere 483 Pneumonia by other pathogens
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Genitourinary tract infection 590, Kidney infection; 597, Urethritis/urethral syndrome; 599.0, Urinary tract infection not otherwise specified; 601, Prostatic inflammation; 098, Gonococcal infections; Gynecological infection 614, Female pelvic inflammation disease; 615, Uterine inflammatory disease; 616, Other female genital inflammation; 681, Cellulitis, finger/ toe; 098, Gonococcal infections; Skin and appendix structure infection 682, Other cellulitis or abscess; 683, Acute lymphadenitis; 686, Other local skin infection; 035, Erysipelas; Online supplements are not copyedited prior to posting and the author(s) take full responsibility for the accuracy of all data.
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Post-operative complication 998.5, Postoperative infection;
Septicemia o o o o
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Musculoskeletal infection 711.0, Pyogenic arthritis; 730, Osteomyelitis; 790.7, Bacteremia; 996.6, Infection or inflammation of device/graft;
Streptococcal septicemia Staphylococcal septicemia Pneumococcal septicemia [Streptococcus pneumoniae septicemia] Septicemia due to anaerobes Septicemia due to bacteroides Excludes: gas gangrene (040.0) § that due to anaerobic streptococci (038.0) o 038.4 Septicemia due to other gram-negative organisms § 038.40 Gram-negative organism, unspecified § Gram-negative septicemia NOS § 038.41 Hemophilus influenzae [H. influenzae] § 038.42 Escherichia coli [E. coli] § 038.43 Pseudomonas § 038.44 Serratia § 038.49 Other o 038.8 Other specified septicemias § Excludes: septicemia (due to): § anthrax (022.3) § gonococcal (098.89) § herpetic (054.5) § meningococcal (036.2) § septicemic plague (020.2) o 038.9 Unspecified septicemia § Septicemia NOS § Excludes: bacteremia NOS (790.7) 995.92 Severe sepsis 790.7 Bacteremia
o o
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038.0 038.1 038.2 038.3 § §
Codes associated with organ dysfunction Cardiovascular dysfunction/Shock Shock 785.5 or hypotension 458
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Hematologic system dysfunction Hematologic Secondary thrombocytopenia 287.4 Thrombocytopenia, unspecified 287.5 Other/unspecified coagulation defect 286.9 Defibrination syndrome 286.6
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Hepatic system dysfunction Hepatic Acute and subacute necrosis of liver 570 Hepatic encephalopathy 572.2 Hepatorenal syndrome 572,4 Other squeal of chronic liver disease 572.8 Hepatic infarction 573.4, 573.8 Liver replaced by transplant V42.7
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Central nervous system dysfunction Neurologic Encephalopathy 348.3 Transient organic psychosis 293 Anoxic brain damage 348.1
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Acute respiratory failure Mechanical ventilation 96.7 or use of ventilator 57001B,57002B, 57023B, 57029C
TE D
Renal system dysfunction Acute renal failure 584 or Use of CVVH (58014C)
AC C
EP
Metabolic system dysfunction Diabetic ketoscidosis 250.1 Hyperosmolar hyperglycemic state 250.2
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e-Table 1. Empirical predictors for prescription of statin and associated odds ratios of the propensity score model. The c-statistic for the propensity score model is 0.82. Adjusted odds ratio (95%CI)
Chronic pulmonary disease
EP
<.0001 <.0001
1.49 (1.31 – 1.71) 1.29 (1.12 – 1.48) 1.09 (0.94 – 1.25)
<.0001
0.99 (0.89 – 1.12) 1.37 (1.21 – 1.55) 1.50 (1.27 – 1.78)
<.0001
0.91 1.46 1.17 1.26 1.02 1.02
<.0001 <.0001 0.01 .0008 0.66 0.74
SC
Rheumatologic disease Peptic ulcer disease Mild liver disease Diabetes without chronic complications Diabetes with chronic complications Hemiplegia or paraplegia Renal disease Any malignancy, including leukemia and lymphoma Moderate or severe liver disease Metastatic solid tumor AIDS/HIV cardiovascular comorbidities Stroke or transient ischemic attack Peripheral arterial disease Angina Other ischemic heart disease Cerebral atherosclerosis Percutaneous coronary/coronary artery bypass graft intervention Additional comorbidities Alcohol/drug use Psychiatric disorder Neurologic disorder
AC C
0.68 (0.62 – 0.73) 1.11 (1.08 – 1.13)
M AN U
TE D
Demographics Gender male Age Area (countryside area as reference) Urban Area Metro Area Suburban Area Insurance type (dependent as reference) $1-$19,999 $20,000-$39,999 >=$40,000 Comorbidity Combined comorbidity score Myocardial infarction Congestive heart failure Peripheral vascular disease Cerebrovascular disease Dementia
P-value
RI PT
Characteristics
(0.89 (1.29 (1.05 (1.10 (0.92 (0.89
– – – – – –
0.94) 1.64) 1.31) 1.44) 1.13) 1.17)
1.03 (0.92 – 1.17)
0.59
0.98 1.02 1.08 2.18 1.59 1.12 1.38 0.85 0.35 1.50 0.68
(0.83 (0.94 (1.00 (1.94 (1.45 (0.98 (1.25 (0.77 (0.26 (1.15 (0.23
– – – – – – – – – – –
1.15) 1.11) 1.18) 2.39) 1.75) 1.27) 1.52) 0.98) 0.47) 1.96) 2.65)
0.79 0.70 0.05 <.0001 <.0001 0.09 <.0001 0.01 <.0001 0.003 0.68
1.22 0.91 1.22 1.31 1.02 1.50
(1.10 (0.77 (1.11 (1.20 (0.88 (1.32
– – – – – –
1.36) 1.07) 1.34) 1.44) 1.18) 1.72)
0.0002 0.27 <.0001 <.0001 0.82 <.0001
0.91 (0.77 – 1.07) 1.11 (1.02 – 1.20) 0.75 (0.67 – 0.84)
0.26 0.01 <.0001
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(1.09 (1.09 (0.85 (0.67 (0.77 (0.44
1.82) 1.31) 1.05) 1.04) 3.75) 0.89)
1.00 (1.00 – 1.01) 1.03 (1.02 – 1.04) 0.89 (0.86 – 0.91)
M AN U
0.98 1.48 1.18 1.00 1.16 1.25 1.21 1.18 2.10 0.90 1.14 1.00 1.03 1.37 0.99
(0.90 (1.37 (0.78 (0.91 (0.89 (1.14 (1.11 (1.08 (1.93 (0.78 (1.03 (0.76 (0.91 (1.26 (0.91
– – – – – – – – – – – – – – –
1.06) 1.61) 1.80) 1.10) 1.52) 1.36) 1.31) 1.29) 2.28) 1.04) 1.26) 1.33) 1.17) 1.48) 1.07)
0.008 .0002 0.27 0.11 0.18 0.009 <.0001 <.0001 <.0001 0.64 <.0001 0.43 0.98 0.28 <.0001 <.0001 0.0002 <.0001 0.15 0.01 0.98 0.60 <.0001 0.73
AC C
EP
TE D
– – – – – –
RI PT
1.41 1.19 0.94 0.84 1.70 0.63
SC
Obesity Other Cancer except Metastatic solid tumor Gastrointestinal or esophageal hemorrhage Bed-ridden status Solid organ transplantation such as renal or heart transplantation Malnutrition Healthcare utilization Number of OPD visit Number of emergency department visit Number of hospitalization Medication NSAID (Nonsteroidal anti-inflammatory drugs) Aspirin Systemic immunosuppressive agents and biologics Systemic corticosteroids DMARDs (disease modifying anti-rheumatic drugs) ACE inhibitors Beta blockers Loop diuretics Angiotensin II antagonists Digoxin Nitrates Antipsychotics Proton-pump inhibitors(PPI) Calcium channel blocker Acetaminophen
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Propensity score adjusted HR (95% Confidence interval)
P-value
>75 years of age
0.92 (0.77 - 1.11)
0.38
<75 years of age
0.71 (0.59 - 0.87)
0.0006
Male
0.82 (0.68 - 0.98)
0.032
Female
0.80 (0.66 - 0.98)
0.027
Diabetes
0.76 (0.65 - 0.89)
0.0007
Non diabetes
0.83 (0.70 - 0.99)
0.039
With congestive heart failure
0.83 (0.68 - 1.00)
0.055
M AN U
e-Table 2. Risk of mortality in different patient subgroups
0.80 (0.67 - 0.96)
0.017
0.88 (0.64 - 1.21)
0.430
0.80 (0.69 - 0.92)
0.003
0.71 (0.53 - 0.96)
0.024
0.84 (0.73 - 0.98)
0.025
0.94 (0.85,1.04)
0.204
0.79 (0.64,0.98)
0.033
1.17 (0.72,1.91)
0.536
No Hematologic system dysfunction
0.87 (0.80,0.96)
0.004
Use of vasopressor
0.94 (0.85,1.03)
0.177
0.95 (0.73,1.23)
0.689
0.91 (0.64,1.30)
0.606
0.87(0.79,0.95)
0.003
1 or 2 organ dysfunction
0.87(0.78,0.96)
0.004
>= 3 organ dysfunction
1.00(0.80,1.25)
0.999
0.90 (0.78 - 1.03)
0.194
0.88 (0.81 – 0.97)
<0.0001
SC
RI PT
Patient subgroups
Without congestive heart failure Myocardial infarction Non myocardial infarction Cancer Non cancer
Non Ventilator Support
Dialysis No dialysis
ICU Non-ICU
AC C
No use of vasopressor
EP
Hematologic system dysfunction
TE D
Ventilator Support
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AC C
EP
TE D
M AN U
SC
RI PT
e-Figure1. Standardized differences in the baseline covariates after propensity score matching. Simvastatin vs. atorvastatin (A), and simvastatin vs. rosuvastatin (B).
170913
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