- Email: [email protected]
Modified Frailty Index Can Be Used to Predict Adverse Outcomes and Mortality after Lower Extremity Bypass Surgery
Accepted Manuscript Modified Frailty Index Can be used to Predict Adverse Outcomes and Mortality After Lower Extremity Bypass Surgery Tarik Ali, MD, Erik Lehman, MS, Faisal Aziz, MD, FACS PII:
S0890-5096(17)30902-0
DOI:
10.1016/j.avsg.2017.07.007
Reference:
AVSG 3498
To appear in:
Annals of Vascular Surgery
Received Date: 24 March 2017 Revised Date:
10 July 2017
Accepted Date: 11 July 2017
Please cite this article as: Ali T, Lehman E, Aziz F, Modified Frailty Index Can be used to Predict Adverse Outcomes and Mortality After Lower Extremity Bypass Surgery, Annals of Vascular Surgery (2017), doi: 10.1016/j.avsg.2017.07.007. 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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Modified Frailty Index Can be used to Predict Adverse Outcomes and
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Mortality After Lower Extremity Bypass Surgery
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Tarik Ali, MD1, Erik Lehman, MS2, Faisal Aziz, MD, FACS1.
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Pennsylvania State University College of Medicine.
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of Medicine.
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Division of Vascular Surgery, Penn State Heart and Vascular Institute,
Department of Public Health Sciences, Pennsylvania State University, College
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Correspondence to:
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Faisal Aziz, MD, FACS.
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Penn State Milton S. Hershey Medical Center, 500 University Drive
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Mail Code H053, Hershey, PA 17033
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Tel: 717-531-8898, Fax: 717-531-4151, E-Mail: [email protected]
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Presented at the Annual Meeting, Vascular and Endovascular Surgery Society,
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2017
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Modified Frailty Index Can be used to Predict Adverse Outcomes and
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Mortality After Lower Extremity Bypass Surgery
Objectives
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Frailty has been increasingly used as a prognostic indicator for various surgical
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operations. Patients with peripheral arterial disease represent a cohort of
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population with advanced medical comorbidities. The aim of this study is to
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correlate the postoperative outcomes after lower extremity bypass surgery with
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pre operative modified frailty index.
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Methods
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Using 2010 American College of Surgeons National Surgical Quality
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Improvement Program (ACS-NSQIP) database, patients undergoing infrainguinal
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arterial bypass surgery were identified. Modified frailty index (mFI) with 11
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variables, based on the Canadian Study of Health and Aging Frailty Index was
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utilized. Based on mFI score, the patients were divided into four groups: Group
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1 (mFI score: 0-0.09), Group 2 (mFI score: 0.18-0.27), Group 3 (mFI score: 0.36-
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0.45), and Group 4 (mFI score: 0.54-0.63). A bivariate and multivariate analysis
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was done using logistic regression analysis.
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Results
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A total of 4,704 patients (64% Males, 36% Females) underwent infrainguinal
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arterial bypass. Mean age: 67.9 ± 11.7 years. Distribution of patients based on
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mFI was as follows: Group 1: 14.6%, Group 2: 55.9%, Group 3: 26.9% and
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Group 4: 2.6%. Increase in mFI was associated with higher mortality rates.
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Incidence of mortality for Group 1 was 0.6%, for Group 2, it was 1.4%, for Group
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3, it was 4% and for Group 4, it was 7.4%. Likewise, the incidence of other
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postoperative complications such as myocardial infarction, stroke, progressive
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renal failure and graft failure was significantly high among patients with high mFI
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scores. Following factors were associated with increased risk of mortality: high
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mFI score, black race, dialysis dependency, post operative renal insufficiency,
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myocardial infarction and post operative acute renal failure.
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Conclusions
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This study demonstrates that the mFI can be used as a valuable tool to identify
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patients at a higher risk for developing postoperative complications after lower
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extremity revascularization. For patients with mFI score of 0.54-0.63, the risk of
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mortality and complications increases significantly. mFI can be used as a useful
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screening tool to identify patients who are at a high risk for developing
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complications.
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Introduction: While surgeons have realized that frailty is an important determinant of surgical outcomes, exact definition of frailty remains unknown.
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geriatric literature1,2 fails to identify a consensus statement on definition of frailty.
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Some authors suggest muscle size measurements3 to be the surrogates of frailty,
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while others stress the importance of gait, balance and hand grip strength4-6 in
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determining frailty of an individual.
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syndrome resulting from multisystem impairments. These impairments include
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sacropenia, functional decline and neuroendocrine dysregulation. In presence of
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such impairments, clinical outcomes are considered to be worse. Patients with
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combination of such impairments are at an even higher risk for development of
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complications.
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electively, it is imperative that identification of high-risk patients can potentially
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prevent postoperative complications.
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used to determine frailty. Elderly patients are more likely to be frail as compared
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to the general population. According to the U.S. Census Bureau8, the geriatric
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population is the fastest growing segment of the U.S. population. It is projected
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that by year 2030 one in five Americans will be more than 65 years of age8.
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Elderly patients are considered frail and are deemed to be a high risk for
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developing postoperative complications. Health care providers are faced with the
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challenge of providing a reliable and cost effective healthcare to an aging
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population. Frailty has been associated with poor outcomes after major surgical
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procedures, including cardiac, colo-rectal, general surgery and urologic
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operations4-6,9,10. Patients with peripheral arterial disease tend to have severe
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Abellan et al7 define frailty as a clinical
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Since the majority of the surgical operations are performed
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Advanced age is just one of the criteria
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coexisting comorbidities, which place them at a high risk for developing
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postoperative complications. Traditionally age and coexisting comorbidities have been employed in
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addition to other tools to predict outcomes for patients undergoing an operation.
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In recent years there has been a lot of interest in Frailty in the surgical patient
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and its implication on outcomes. A simplified form of the original Frailty index
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from the Canadian Study of Health and Aging has been established as the
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modified frailty index (mFI). In this study, we sought to apply the mFI to below the
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inguinal ligament vascular bypass surgery in an effort to predict outcomes and
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validate it as a low cost, noninvasive tool to help clinicians better screen and
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inform patients.
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Methods:
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Dataset: The American College of Surgeons National Surgical Quality
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Improvement Program (ACS-NSQIP)11 Participant User Files (PUF) were
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reviewed for the year 2010.
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information and is compliant with Health Insurance Portability and Accountability
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Act (HIPPA). Therefore, no institutional review board (IRB) approval or patient
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consent was required. Methods used to extract data from this database are well
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described in the literature12-15.
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responsible for collecting all data points and excluding patients with incomplete
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data. ACS performs regular audits of the dataset and the outcomes based on
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NSQIP database are shown to be highly reliable14. This database provides a
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comprehensive list of pre-operative comorbidities, laboratory values, intra-
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operative variables and postoperative outcomes. Patients younger than 16 years
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were not included and patients older than 89 years of age were coded as 90+ to
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protect patient confidentiality.
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Patients: Using Current Procedural Terminology (CPT) codes (37220-37235);
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patients who had undergone infrainguinal arterial bypass surgery during 2010
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were identified in the NSQIP-PUF file.
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Modified Frailty Index: Modified Frailty index (mFI) was calculated using 11
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variables, based on the Canadian Study of Health and Aging Frailty Index (CSHA
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FI)2,16 and validated in the ACS- NSQIP database. Table I depicts the variables
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used by CSHA FI and the corresponding variables used in ACS-NSQIP
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database. The modified Frailty index (mFI) for a patient is calculated by adding
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one point for the presence of each of these variables divided by 11. This
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produces a number between 0 and 1. Based on mFI score, the patients were
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divided into four groups: Group 1 (mFI score: 0-0.09), Group 2 (mFI score: 0.18-
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0.27), Group 3 (mFI score: 0.36-0.45), and Group 4 (mFI score: 0.54-0.63).
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Outcomes: ACS-NSQIP database provides information for any complications
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within 30 days after surgery.
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primary outcome and post op myocardial infarction, stroke, renal failure and graft
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failure were chosen as secondary outcomes.
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Statistical Analysis:
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All variables were initially summarized with frequencies and percentages or
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means, medians, and standard deviations. Binomial logistic regression was used
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to determine any bivariate associations between the four-group mFI variables
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and post-operative outcome variables and between other potential covariates
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and 30-day mortality.
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direction of any significant associations.
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independent variables from the bivariate analysis of 30-day mortality along with
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demographic variables (age, gender, race, and BMI) were then used in a process
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of stepwise, forward, and backward selection methods to find the group of
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variables collectively that were most significantly associated with 30-day
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readmission in a multivariable logistic regression model.
Prior to the
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multivariable
checked
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multicollinearity with one another using variance inflation factor (VIF) statistics.
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With so many variables and a large sample size, a more stringent entry criteria of
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p<0.05 and a stay criteria of p<0.05 were used for the process of variable
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selection to be more conservative. The fit of the final model was checked using
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For this analysis mortality was chosen as the
The statistically significant (p<0.05)
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Odds ratios were used to quantify the magnitude and
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the Hosmer and Lemeshow goodness-of-fit test (p=0.6309).
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(c=0.887) shows adequate prediction strength of the final model. All analyses
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were performed using SAS version 9.4 (SAS Institute, Cary, NC).
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The c-statistic
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Results:
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Demographics:
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36% Females), who underwent an infrainguinal arterial bypass in 2010. Mean
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age was 67.9 ± 11.7 years (Range 19 to >90 years). Race distribution was as
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follows: 74% White, 16% African American, 10% unknown. Mean BMI was 27.7
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± 6.4 (BMI<25: 1,637 patients (35.5%), BMI 25-29: 1,593 patients (34.5%) and
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BMI 30-40: 1,216 patients (26.4%) and BMI ≥ 40: 165 patients (3.6%). Incidence
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of pre-operative variables was as fellows: hypertension (3981: 84.6%), history of
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rest pain (2,205: 46.9%), history of transient ischemic attack (302: 6.4%), history
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of stroke (364 (7.7%), American Society of Anesthesiology (ASA) Score 1 (No
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disturbance/mild disturbance): 303 (6.4%), ASA Score 2 (Severe Disturbance):
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3,459 (73.6%) and ASA Score 3 and 4 (Life threatening emergency/ moribund
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condition): 941 (20%), Active smoking status (1,915 patients: 41%), emergency
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operation (258 (5.5%) and end-stage renal disease on hemodialysis (336: 7%).
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Post Operative Complications: The distribution of postoperative complications
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was as fellows: superficial surgical site infection (SSI): 356 (7.6%), deep wound
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infection: 110 (2.3%), stroke: 28 (0.6%), graft failure: 206 (4.4%), deep venous
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thrombosis: 47 (1%), return to operating room: 773 (16.4%), acute renal failure:
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38 (0.8%) and mortality: 100 (2.1%).
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Modified Frailty Index: Modified Frailty Index was calculated for all patients and
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distribution of mFI was as follows:
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mFI = 0/11 = 0
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mFI = 1/11 = 0.09 (Number of Patients = 564 (11.9%)
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mFI = 2/11 = 0.18 (Number of Patients = 1,177 (25.02%)
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ACS-NSQIP database identified 4,704 patients (64% Males,
(Number of Patients = 121 (2.6%)
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mFI = 3/11 = 0.27 (Number of Patients = 1,456 (30.95%)
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mFI = 4/11 = 0.36 (Number of Patients = 914 (19.43%)
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mFI = 5/11 = 0.45 (Number of Patients = 351 (7.46%)
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mFI = 6/11 = 0.54 (Number of Patients = 92 (1.96%)
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mFI = 7/11 = 0.63 (Number of Patients = 29 (0.62%)
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mFI= 8/11 = 0.72 (Number of Patients = 0, (0%)
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mFI = 9/11 = 0.81 (Number of Patients = 0, (0%)
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mFI = 10/11 = 0.90 (Number of Patients = 0, (0%)
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mFI = 11/11 = 1
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When grouped together, as described in methods section, the distribution of mFI
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scores was as follows:
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Group 1 (mFI score: 0-0.09): 685 Patients (14.56%)
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Group 2 (mFI score: 0.18-0.27): 2,633 Patients (55.97%)
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Group 3 (mFI score: 0.36-0.45): 1,265 Patients (26.89%)
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Group 4 (mFI score: 0.54-0.63): 121 Patients (2.57%)
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Outcomes: Thirty day mortality was chosen as primary outcome. Increase in
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mFI was associated with higher mortality rates. Incidence of mortality for Group 1
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was 0.6%, for Group 2, it was 1.4%, for Group 3, it was 4% and for Group 4, it
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was 7.4%. The incidence of MI for Group 1 was 1%, for Group 2, it was 2%, for
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Group 3, it was 3.1% and for Group 4, it was 4.2%. The incidence of stroke
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among Group 1 patients was 0.6%, for Group 2, it was 0.5% , for Group 3, it was
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0.6% and for Group 4, it was 1.7%.
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insufficiency, the incidence among Group 1 patients was 0.6%, among Group 2
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For postoperative progressive renal
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patients, it was 0.6%, among Group 3 patients, it was 0.6 and among Group 4
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patients, it was 0.8%. The incidence of graft failure for Group 1 patients was
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4.8%, for Group 2 patients, it was 4.3%, for Group 3 patients, it was 4.1% and for
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Group 4 patients, it was 7.4%. In regards to any occurrence for any of these
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complications, the incidence among Group 1 patients was 6.9%, for Group 2
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patients, it was 8.1% , for Group 3 patients, it was 11.1% and for Group 4
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patients, it was 19% (Table II).
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The Univariate analysis identified following independent variables to be
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associated with higher risk of mortality: Age >80 years , higher ASA score (4-5),
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transfer from nursing home, impaired sensorium, dependent functional status ,
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diabetes, history of COPD, history of congestive heart failure, history of previous
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coronary stenting history of angina, history of rest, emergency operation, dialysis
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dependency, increased length of hospital stay, post operative progressive renal
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insufficiency, post operative stroke, post operative myocardial infarction, sepsis,
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return to the operating room, increased length of hospital stay and acute renal
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failure (Table III).
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Multivariant analysis identified following factors to be associated with increased
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risk of mortality: mFI 0.18-0.27 vs. 0-0.09, mFI 0.36-0.45 vs. 0-0.09 , mFI 0.54-
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0.63 vs. 0-0.09, age 60-70 vs. <60, age 70-80 vs. <60, age >80 vs. <60, black
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race vs. white race, other races vs. white race, dialysis dependency, post
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operative progressive renal insufficiency, post operative myocardial infraction
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and post operative acute renal failure (Table IV).
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Discussion: Our study shows that variables described in ACS-NSQIP database can be
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used to calculate a mFI and that a higher mFI score for patients undergoing
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lower extremity revascularization surgery accurately predicts a higher 30-day
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mortality and myocardial infarction. For years, vascular surgeons have been
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relying on a variety of factors and measures to assess a patient’s ability to
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withstand the stressors of surgery. Routine cardiac testing and pulmonary
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assessment is regularly performed in anticipation for major surgery, however,
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rarely are factors such as functional status, congestive heart failure and history of
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previous cerebral ischemic events are used in such assessments. Our study
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shows successful use of the mFI scoring system to predict major postoperative
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complications after lower extremity bypass surgery. It is worth mentioning that
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frailty is fundamentally different from existence of several comorbidities, as the
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variables used to calculate the mFI encompass mental and social factors in
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addition to relying on markers for physical dysfunction. Our study has shown that
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it can be a reliable and an important low cost, noninvasive tool to aid in the
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clinical decision making. It shows a noticeable increase in morbidity and mortality
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with an increasing m-FI. Patients with a mFI score of greater than 0.54 (i.e.
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presence of 6 or more variables), the 30-day mortality after lower extremity
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surgical bypass can be as high as 7.4% (OR 13.7, CI 4.14-45.2, p<0.001) and
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the risk of myocardial infarction is around 4% (OR 4.2, CI 1.3-13.4, p=0.013).
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With a better understanding of the impact of pre-operative factors on the
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post-operative outcomes, there has been an increasing focus of attention on
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determining the factors associated with postoperative morbidity and mortality.
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Historically, surgeons have focused on cardiac causes of morbidity and mortality
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after the surgical operations. Poldermans et al17 have shown that patients with a
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positive stress test before a major vascular surgery operations are at a high risk
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for developing post operative cardiac complications.
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have identified advanced age, pre-existing cardiac and renal diseases, high ASA
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scores and the use of general anesthesia to be associated with a significantly
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high risk of developing post operative complications after lower extremity bypass
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surgery. The eleven variables used to calculate a mFI score represent physical,
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mental, social assessment and a combination of these factors can accurately
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reflect the outcomes after elective operations. Several authors4-6,9,19 have used
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prospective data to calculate frailty scores for surgical patients.
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studies10,20,21 have used retrospective methodology to determine frailty scores for
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surgical patients and predicted the incidence of postoperative complications
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based on mFI scores. Veanovich et al22 have shown that patients with increased
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frailty
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otolaryngology, general, orthopedic, neurosurgical, thoracic, gynecological and
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urologic procedures. Likewise, Hewitt et al23 have shown that frail patients, who
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were more than 65 years of age undergoing emergent general surgical
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procedures had increased incidence of postoperative mortality.
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Some
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Patients with PAD represent a cohort of patient population, which often
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reserve. Outcomes of any intervention for patients with PAD are dependent on
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anatomic, physiologic and disease severity factors24.
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surgeons have considered surgical bypasses to have the advantage over
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endovascular interventions in terms of long term patency and avoiding re-
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interventions25.
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surgical bypass should take into account the possibility of all the postoperative
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complications. As stated above, surgeons in the past have relied heavily on using
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age and cardiac history as predictors for postoperative outcomes, however
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applying mFI scores to patients undergoing arterial bypass for PAD provides a
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better assessment tool to predict postoperative complications. A recent study of
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patients undergoing lower extremity bypass surgery26 showed that elderly
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patients (age >80 years) had no increased risk of postoperative complications as
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compared to those patients who were younger than 80 years of age. Our data
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clearly shows that age more than 80 years is associated with significantly high
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risk for mortality after lower extremity bypass surgery.
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previous major amputation and female gender have been associated with major
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adverse limb events after lower extremity bypass surgery27. Our analysis shows
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that the mFI can be used as a useful tool to accurately predict postoperative
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complications.
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vascular surgery operations also showed that preoperative mFI could accurately
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predict postoperative mortality. Interestingly, this analysis showed mFI to be a
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better predictor of postoperative mortality than other variables for open
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operations. Our study only consists of open lower extremity bypasses and our
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results correlate with the findings of Ehlert et al.
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Higher ASA scores,
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between patients with different mFI scores should be recognized and the
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informed consent process should include a frank discussion about the risk of
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complications based on mFI scores. Our data clearly shows that frailty may be
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present in the younger patient population and relying solely on age to predict
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postoperative complications may not be a reliable strategy.
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Patients presenting with severe PAD have some degree of frailty at
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baseline. Most surgeons would recommend surgical bypasses for PAD only for
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the select group of patients who have either critical limb ischemia or severe,
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disabling claudication. While the purpose of revascularization in patients with
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critical limb ischemia is limb salvage, the goal of surgical bypass in claudicants is
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improvement in quality of life. The decision to proceed with surgical bypass
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should be made after careful evaluation of all risks and benefits. Many factors
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play an important role in determining the balance between risks and benefits of
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an operation. This data serves to add one more data point i.e. mFI, in helping
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vascular surgeons determining the risk/benefit ratio.
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surgeons would still recommend revascularization for patients with severe tissue
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loss, our analysis clearly shows that it may not be advisable to offer an open
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revascularization procedure on a claudicant with high mFI. Our data should be
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interpreted with caution and operative decisions should be made after careful
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consideration of all risk factors and tailoring the outcomes to individual patients.
While most vascular
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Our analysis is limited by the inherent nature of any retrospective study.
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The NSQIP database does not contain the variables as gait speed or grip
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strength, which can provide additional information while calculating frailty. The
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database is also limited to 30-day outcomes making it difficult to evaluate long-
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term progress of these patients. The findings are limited to only those hospitals,
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which were enrolled in the NSQIP database and may not be applicable to all
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patients. Despite these limitations, The NSQIP provides us with a large and
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diverse sample size and the statistics performed on such a large sample do
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provide results with statistical significance. It also provides us access to a
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diversity of surgeons and institutions where patients are cared.
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To summarize, this study demonstrates that the m-FI does identify
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patients at a higher risk for morbidity and mortality. It shows that for a m-FI 0.54-
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0.63 the risk of 30-day mortality and post-operative complications increases
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significantly. When used appropriately, the mFI can be a valuable, low cost,
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noninvasive tool in accessing and stratifying patients preoperatively.
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References
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. 12. Khuri SF, Daley J, Henderson W, Hur K, Gibbs JO, Barbour G, et al. Risk adjustment of the postoperative mortality rate for the comparative assessment of the quality of surgical care: results of the National Veterans Affairs Surgical Risk Study. J Am Coll Surg 1997;185:315-27. 13. Bilimoria KY, Cohen ME, Ingraham AM, Bentrem DJ, Richards K, Hall BL, et al. Effect of postdischarge morbidity and mortality on comparisons of hospital surgical quality. Ann Surg 2010;252:183-90. 14. Shiloach M, Frencher SK, Jr., Steeger JE, Rowell KS, Bartzokis K, Tomeh MG, et al. Toward robust information: data quality and inter-rater reliability in the American College of Surgeons National Surgical Quality Improvement Program. J Am Coll Surg 2010;210:6-16.
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1. Morley JE, Vellas B, van Kan GA, Anker SD, Bauer JM, Bernabei R, et al. Frailty consensus: a call to action. J Am Med Dir Assoc 2013;14:392-7. 2. Rockwood K, Andrew M, Mitnitski A. A comparison of two approaches to measuring frailty in elderly people. J Gerontol A Biol Sci Med Sci 2007;62:73843. 3. Sheetz KH, Zhao L, Holcombe SA, Wang SC, Reddy RM, Lin J, et al. Decreased core muscle size is associated with worse patient survival following esophagectomy for cancer. Dis Esophagus 2013;26:716-22. 4. Makary MA, Segev DL, Pronovost PJ, Syin D, Bandeen-Roche K, Patel P, et al. Frailty as a predictor of surgical outcomes in older patients. J Am Coll Surg 2010;210:901-8. 5. Robinson TN, Wu DS, Pointer L, Dunn CL, Cleveland JC, Jr., Moss M. Simple frailty score predicts postoperative complications across surgical specialties. Am J Surg 2013;206:544-50. 6. Revenig LM, Canter DJ, Taylor MD, Tai C, Sweeney JF, Sarmiento JM, et al. Too frail for surgery? Initial results of a large multidisciplinary prospective study examining preoperative variables predictive of poor surgical outcomes. J Am Coll Surg 2013;217:665-70 e1. 7. Abellan van Kan G, Rolland Y, Houles M, Gillette-Guyonnet S, Soto M, Vellas B. The assessment of frailty in older adults. Clin Geriatr Med 2010;26:27586. 8. Colby S OJ. Projections of the Size and Composition of the U.S. Population: 2014 to 2060, Current Population Reports. US Census Bureau 2014:P25-1143. 9. Lee DH, Buth KJ, Martin BJ, Yip AM, Hirsch GM. Frail patients are at increased risk for mortality and prolonged institutional care after cardiac surgery. Circulation 2010;121:973-8. 10. Adams P, Ghanem T, Stachler R, Hall F, Velanovich V, Rubinfeld I. Frailty as a predictor of morbidity and mortality in inpatient head and neck surgery. JAMA Otolaryngol Head Neck Surg 2013;139:783-9. 11. Improvement ACoSNSQ, at: PA. https://www.facs.org/qualityprograms/acs-nsqip. Accessed January 10, 2017
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15. Khuri SF, Daley J, Henderson W, Barbour G, Lowry P, Irvin G, et al. The National Veterans Administration Surgical Risk Study: risk adjustment for the comparative assessment of the quality of surgical care. J Am Coll Surg 1995;180:519-31. 16. Mitnitski AB, Mogilner AJ, Rockwood K. Accumulation of deficits as a proxy measure of aging. ScientificWorldJournal 2001;1:323-36. 17. Poldermans D, Fioretti PM, Forster T, Thomson IR, Boersma E, el-Said EM, et al. Dobutamine stress echocardiography for assessment of perioperative cardiac risk in patients undergoing major vascular surgery. Circulation 1993;87:1506-12. 18. Kehlet M, Jensen LP, Schroeder TV. Risk Factors for Complications after Peripheral Vascular Surgery in 3,202 Patient Procedures. Ann Vasc Surg 2016;36:13-21. 19. Kim SW, Han HS, Jung HW, Kim KI, Hwang DW, Kang SB, et al. Multidimensional frailty score for the prediction of postoperative mortality risk. JAMA Surg 2014;149:633-40. 20. Etzioni DA, Liu JH, Maggard MA, Ko CY. The aging population and its impact on the surgery workforce. Ann Surg 2003;238:170-7. 21. Karam J, Tsiouris A, Shepard A, Velanovich V, Rubinfeld I. Simplified frailty index to predict adverse outcomes and mortality in vascular surgery patients. Ann Vasc Surg 2013;27:904-8. 22. Velanovich V, Antoine H, Swartz A, Peters D, Rubinfeld I. Accumulating deficits model of frailty and postoperative mortality and morbidity: its application to a national database. J Surg Res 2013;183:104-10. 23. Hewitt J, Moug SJ, Middleton M, Chakrabarti M, Stechman MJ, McCarthy K, et al. Prevalence of frailty and its association with mortality in general surgery. Am J Surg 2015;209:254-9. 24. Lo RC, Darling J, Bensley RP, Giles KA, Dahlberg SE, Hamdan AD, et al. Outcomes following infrapopliteal angioplasty for critical limb ischemia. J Vasc Surg 2013;57:1455-63; discussion 63-4. 25. Feinglass J, Pearce WH, Martin GJ, Gibbs J, Cowper D, Sorensen M, et al. Postoperative and late survival outcomes after major amputation: findings from the Department of Veterans Affairs National Surgical Quality Improvement Program. Surgery 2001;130:21-9. 26. Shirasu T, Hoshina K, Nishiyama A, Akagi D, Miyahara T, Yamamoto K, et al. Favorable outcomes of very elderly patients with critical limb ischemia who undergo distal bypass surgery. J Vasc Surg 2016;63:377-84. 27. Brothers TE, Zhang J, Mauldin PD, Tonnessen BH, Robison JG, Vallabhaneni R, et al. Predicting outcomes for infrapopliteal limb-threatening ischemia using the Society for Vascular Surgery Vascular Quality Initiative. J Vasc Surg 2016;63:114-24 e5.
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28. Ehlert BA, Najafian A, Orion KC, Malas MB, Black JH 3rd, Abularrage CJ. Validation of a modified frailty index to predict mortality in vascular surgery patients. J Vasc Surg 2016 Jun;63(6):1595-1601.
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Table I: Variables Used to Calculate mFI by the Canadian Study of Health and Aging (CSHA) and the Corresponding Variables Identified in the American College of Surgeons National Surgical Quality Improvement Program (ACSNSQIP).
Impaired Sensorium
Pre-Operative Functional Status: - Independent - Partially dependent - Totally dependent
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History relevant to cognitive impairment or loss Problems with bathing Problems with dressing Problems with cooking Problems with personal grooming Problems with going out alone Cardiac Disease
Congestive Heart Failure
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Myocardial Infarction
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ACS-NSQIP
Clouding or Delirium
Arterial hypertension History of diabetes mellitus
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Chronic/Acute lung disease
Cereberovascular problems History of Stroke
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Pre-Operative Comorbidities
CSHA
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Category of Variables Functional and Cognitive Impairment
Decreased peripheral pulses
- Previous percutaneous coronary intervention or cardiac surgery - History of angina <1 month before surgery Congestive heart failure <1 month before surgery History of myocardial infarction <6 months before surgery Hypertension requiring medication Diabetes Mellitus - Insulin dependent - Non-insulin dependent History of severe COPD Current pneumonia History of transient ischemic attack Cerebrovascular accident or stroke with neurologic deficit - History of revascularization or amputation for peripheral vascular disease - Rest pain or gangrene
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Table II
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Modified Frailty N (%) with Outcome (N=4704) Index Outcome OR (95% CI)* P-value* 30-day mortality 0.0 – 0.09 4 (0.6) Reference <0.001 0.18 – 0.27 37 (1.4) 2.4 (0.86, 6.83) 0.36 – 0.45 50 (4.0) 7 (2.52, 19.48) 0.54 – 0.63 9 (7.4) 13.7 (4.14, 45.18) Post-operative myocardial infarction 0.0 – 0.09 7 (1.0) Reference 0.013 0.18 – 0.27 53 (2.0) 2 (0.90, 4.39) 0.36 – 0.45 39 (3.1) 3.1 (1.37, 6.92) 0.54 – 0.63 5 (4.1) 4.2 (1.30, 13.37) Post-operative stroke (CVA) 0.0 – 0.09 4 (0.6) Reference 0.516 0.18 – 0.27 14 (0.5) 0.9 (0.29,2.77) 0.36 – 0.45 8 (0.6) 1.1 (0.33,3.611) 0.54 – 0.63 2 (1.7) 2.9 (0.52,15.79) Post-operative progressive renal 0.0 – 0.09 4 (0.6) Reference 0.985 failure 0.18 – 0.27 16 (0.6) 1 (0.35,3.124) 0.36 – 0.45 7 (0.6) 1 (0.28,3.25) 0.54 – 0.63 1 (0.8) 1.4 (0.16,12.80) Graft/prosthesis/flap failure 0.0 – 0.09 33 (4.8) Reference 0.354 0.18 – 0.27 112 (4.3) 0.9 (0.59,1.31) 0.36 – 0.45 52 (4.1) 0.9 (0.54,1.32) 0.54 – 0.63 9 (7.4) 1.6 (0.74,3.41) Any occurrence (of the above 0.0 – 0.09 47 (6.9) Reference < 0.001 outcomes) 0.18 – 0.27 213 (8.1) 1.2 (0.86,1.66) 0.36 – 0.45 140 (11.1) 1.7 (1.2,2.38) 0.54 – 0.63 23 (19.0) 3.2 (1.85,5.48) * All odds ratios and p-values are from binomial logistic regression modeling the outcome variables. Odds ratios with 95% confidence limits not including 1 are considered significant. The unit of reference for the odds ratios is mFI 0.0-0.09
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P-value*
Reference 2.3 (0.95, 5.40) 5.5 (2.44, 12.30) 9.2 (4.05, 20.69)
<0.001
1.2 (0.78, 1.77) Reference
0.431
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OR (95% CI)*
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Table III: Univariable Analysis for Factors Affecting Mortality No 30-day 30-day Mortality Mortality Variable (N=4604) (N=100) Age (years) 1227 (99.4) 7 (0.6) ≤60 >60-70 1471 (98.7) 19 (1.3) 1217 (97.0) 38 (3.0) >70-80 >80 689 (95.0) 36 (5.0) Sex Female 1626 (97.7) 39 (2.3) Male 2947 (98.0) 60 (2.0) Race Non-Hispanic Black 713 (97.1) 21 (2.9) Non-Hispanic American Indian or 12 (100) 0 (0) Alaska native 38 (95.0) 2 (5.0) Non-Hispanic Asian 70 (2.0) 3400 (98.0) Non-Hispanic White BMI (kg/m^2) <25 1592 (97.3) 45 (2.8) 25-<30 1567 (98.3) 26 (1.6) 30-<40 1192 (98.3) 21 (1.7) >40 163 (98.8) 2 (1.2) ASA class No Disturbance-Mild Disturbance (1-2) 303 (100) 0 (0) Severe Disturbance (3) 3415 (98.7) 44 (1.3) Life Threatening-Moribund (4-5) 885 (94.0) 56 (6.0) Transfer status From acute care hospital inpatient 155 (96.9) 5 (3.1) Not transferred (admitted from home) 4246 (98.2) 78 (1.8) Nursing home - Chronic care 139 (89.7) 16 (10.3) Intermediate care Outside emergency department 33 (97.1) 1 (2.9) Transfer from other 28 (100) 0 (0) Smoker Yes 1895 (99.0) 20(1.0) No 2709 (97.1) 80 (2.9) Alcohol use Yes 281 (97.9) 6 (2.1) No 4323 (97.9) 94 (2.1) Impaired sensorium Yes 28 (82.4) 6 (17.7) No 4576 (97.7) 94 (2.0)
1.4 (0.87,2.35) <0.001(<0.001,>999.9) 2.6 (0.61,10.81) Reference
0.015
Reference 0.6 (0.36,0.96) 0.6 (0.37,1.05) 0.4 (0.10,1.81)
0.092
Reference 5.6 (1.25,Infinity) 27.4 (6.184,Infinity)
<0.001
Reference 1.8 (0.70,4.40) 6.3 (3.57,11.01) 1.7(0.22,12.21) <0.001(<0.001,>999.9)
<0.001
0.4 (0.22,0.59) Reference
<0.001
1.0 (0.43,2.26) Reference
0.966
10.4 (4.22,25.79) Reference
<0.001
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39 (6.3) 61 (98.5)
4.4 (2.90,6.67) Reference
<0.001
1990 (97.2) 2614 (98.4)
58 (2.8) 42 (1.6)
1.8 (1.21,2.71) Reference
0.004
612 (96.4) 3992 (98.1)
23 (3.6) 77 (1.9)
11 (100) 4593 (97.9)
0 (0) 100 (2.1)
1.06 (93.0) 4498 (98.0)
8 (7.0) 92 (2.0)
3.7 (1.75,7.80) Reference
<0.001
938 (97.8) 3.666 (98.0)
21 (2.2) 79 (2.1)
1.0 (0.64,1.69) Reference
0.876
1074 (96.9) 3530 (98.2)
34 (3.1) 66 (1.8)
1.7 (1.11,2.58) Reference
0.014
84 (93.3) 4520 (98.0)
6 (6.7) 94 (2.0)
3.4 (1.46,8.06) Reference
<0.005
3893 (97.8) 711 (98.3)
88 (2.2) 12 (1.7)
1.3 (0.73,2.46) Reference
0.347
2608 (98.2) 1996 (97.4)
47 (1.8) 53 (2.6)
0.7 (0.456,1.009) Reference
0.056
2140 (97.1) 2464 (98.6)
65 (3.0) 35 (1.4)
2.1 (1.41,3.24) Reference
<0.001
293 (97.0) 4311 (97.9)
9 (3.0) 91 (2.1)
1.5 (0.73,2.92) Reference
0.290
355 (97.5) 4249 (97.9) 2.69 ± 2.63
9 (2.5) 91 (2.1) 2.87 ± 2.46
1.2 (0.59,2.37) Reference 1.0 (0.95, 1.11)
0.633 0.492
242 (93.8) 4362 (98.1)
16 (6.2) 84 (1.9)
3.4 (1.98,5.95) Reference
<0.001
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582 (93.7) 4022 (98.5)
2.0 (1.21,3.13) Reference
0.006
<0.001(<0.001,>999.9) Reference
0.983
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Dependent Functional status Yes No Diabetes Yes No History of COPD Yes No History of pneumonia Yes No History of CHF Yes No History of PCI Yes No History of PCS Yes No History of angina Yes No Hypertension Yes No History of PVD Yes No History of rest pain Yes No History of TIA Yes No History of CVA Yes No PGY level (1-unit increase) Emergency operation Yes No
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312.04 ± 129.43
Dialysis Yes No
309 (92.0) 4295 (98.3)
Hospital length of stay (7-day increase)
8.08 ± 8.54
27 (8.0) 73 (1.7) 12.96 ± 10.59 2 (0.6) 98 (2.3)
106 (96.4) 4498 (97.9)
4 (3.6) 96 (2.1)
10 (100) 4594 (97.9)
0 (0) 100 (2.1)
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5.1 (3.26,8.11) Reference 1.3 (1.16, 1.39)
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0.121
<0.001 <0.001
0.3 (0.06,0.10) Reference
0.050
1.8 (0.064,4.90) Reference
0.273
<0.001 (<0.001,999.9) Reference
0.984
SC
354 (99.4) 4250 (97.8)
23 (82.1) 4581 (98.0)
5 (17.9) 95 (82.1)
10.5 (3.90,28.16) Reference
<0.001
25 (89.3) 4579 (97.9)
3 (10.7) 97 (2.1)
10.5 (3.90,28.16) Reference
0.005
86 (82.7) 4518 (98.2)
18 (17.3) 82 (1.8)
11.5 (6.63,20.05) Reference
<0.001
201 (97.6) 4403 (97.9)
5 (2.4) 95 (2.1)
1.2 (0.46,2.87) Reference
0.759
47 (100) 4557 (97.8)
0 (0) 100 (2.2)
<0.001 (<0.001,999.9) Reference
0.985
123 (91.8) 4481 (98.0)
11 (8.2) 89 (2.0)
4.5 (2.35,8.64) Reference
<0.001
748 (96.8) 3856 (98.1)
25 (3.2) 75 (1.9)
1.7 (1.09,2.72) Reference
0.021
6.21 ± 6.58
9.04 ± 7.80
1.3 (1.12, 1.40)
154 (96.2) 4450 (97.9) 13.97 ±
6 (3.8) 94 (2.1) 8.83 ±
1.9 (0.80,4.28) Reference 0.68 (0.47, 0.99)
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Superficial incisional SSI Yes No Deep incisional SSI Yes No Post-op pulmonary embolism Yes No Post-op progressive renal insufficiency Yes No Post-op stroke Yes No Post-op MI Yes No Graft/prosthesis/flap failure Yes No DVT requiring therapy Yes No Sepsis Yes No Return to OR Yes No Days from operation to discharge (7-day increase) Steroid use Yes No Pre-op albumin serum level
1.1 (0.97, 1.32)
RI PT
293.75 ± 116.62
Anesthesia time (100-minute increase)
<0.001
0.154 0.041
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19.49 16.08 Acute renal failure requiring dialysis w/in 30 days of operation 31.1 (15.54,62.11) Yes 24 (63.2) 14 (36.8) <0.001 No 4580 (98.2) 86 (1.8) Reference * All odds ratios and p-values are from binomial logistic regression modeling 30-day mortality, exact logistic regression used as needed. Odds ratios with 95% confidence limits not including 1 are considered significant.
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Table IV: Multivariant Analysis for Factors Affecting 30-day Mortality
Odd’s Ratio (CI)
mFI 0.18-0.27 vs. 0-0.09
4.4 (0.9-21.9)
mFI 0.36-0.45 vs. 0-0.09
7 (1.4-34.5)
mFI 0.54-0.63 vs. 0-0.09
7.9 (1.3-48.01)
Age 60-70 vs. <60
1.7 (0.64-4.3)
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Variables
Age 70-80 vs. <60
3.1 (1.3-7.4) 3.1 (1.2-7.9)
Black Race Vs. White Race Other Race Vs. White Race Dialysis Dependency
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Age >80 vs. <60
1.4 (0.8-2.6)
3.1 (0.98-9.8) 2.7 (1.5-4.8)
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Post operative progressive renal insufficiency
7.7 (2.1-28.9)
7.5 (3.7-15.1)
Post operative Acute Renal Failure requiring Dialysis
13.8 (5.4-35.3)
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Post operative Myocardial infarction
S0890-5096(17)30902-0
DOI:
10.1016/j.avsg.2017.07.007
Reference:
AVSG 3498
To appear in:
Annals of Vascular Surgery
Received Date: 24 March 2017 Revised Date:
10 July 2017
Accepted Date: 11 July 2017
Please cite this article as: Ali T, Lehman E, Aziz F, Modified Frailty Index Can be used to Predict Adverse Outcomes and Mortality After Lower Extremity Bypass Surgery, Annals of Vascular Surgery (2017), doi: 10.1016/j.avsg.2017.07.007. 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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Modified Frailty Index Can be used to Predict Adverse Outcomes and
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Mortality After Lower Extremity Bypass Surgery
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Tarik Ali, MD1, Erik Lehman, MS2, Faisal Aziz, MD, FACS1.
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Pennsylvania State University College of Medicine.
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of Medicine.
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Division of Vascular Surgery, Penn State Heart and Vascular Institute,
Department of Public Health Sciences, Pennsylvania State University, College
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Correspondence to:
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Faisal Aziz, MD, FACS.
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Penn State Milton S. Hershey Medical Center, 500 University Drive
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Mail Code H053, Hershey, PA 17033
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Tel: 717-531-8898, Fax: 717-531-4151, E-Mail: [email protected]
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Presented at the Annual Meeting, Vascular and Endovascular Surgery Society,
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2017
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Modified Frailty Index Can be used to Predict Adverse Outcomes and
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Mortality After Lower Extremity Bypass Surgery
Objectives
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Frailty has been increasingly used as a prognostic indicator for various surgical
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operations. Patients with peripheral arterial disease represent a cohort of
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population with advanced medical comorbidities. The aim of this study is to
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correlate the postoperative outcomes after lower extremity bypass surgery with
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pre operative modified frailty index.
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Methods
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Using 2010 American College of Surgeons National Surgical Quality
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Improvement Program (ACS-NSQIP) database, patients undergoing infrainguinal
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arterial bypass surgery were identified. Modified frailty index (mFI) with 11
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variables, based on the Canadian Study of Health and Aging Frailty Index was
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utilized. Based on mFI score, the patients were divided into four groups: Group
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1 (mFI score: 0-0.09), Group 2 (mFI score: 0.18-0.27), Group 3 (mFI score: 0.36-
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0.45), and Group 4 (mFI score: 0.54-0.63). A bivariate and multivariate analysis
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was done using logistic regression analysis.
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Results
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A total of 4,704 patients (64% Males, 36% Females) underwent infrainguinal
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arterial bypass. Mean age: 67.9 ± 11.7 years. Distribution of patients based on
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mFI was as follows: Group 1: 14.6%, Group 2: 55.9%, Group 3: 26.9% and
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Group 4: 2.6%. Increase in mFI was associated with higher mortality rates.
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Incidence of mortality for Group 1 was 0.6%, for Group 2, it was 1.4%, for Group
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3, it was 4% and for Group 4, it was 7.4%. Likewise, the incidence of other
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postoperative complications such as myocardial infarction, stroke, progressive
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renal failure and graft failure was significantly high among patients with high mFI
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scores. Following factors were associated with increased risk of mortality: high
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mFI score, black race, dialysis dependency, post operative renal insufficiency,
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myocardial infarction and post operative acute renal failure.
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Conclusions
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This study demonstrates that the mFI can be used as a valuable tool to identify
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patients at a higher risk for developing postoperative complications after lower
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extremity revascularization. For patients with mFI score of 0.54-0.63, the risk of
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mortality and complications increases significantly. mFI can be used as a useful
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screening tool to identify patients who are at a high risk for developing
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complications.
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Introduction: While surgeons have realized that frailty is an important determinant of surgical outcomes, exact definition of frailty remains unknown.
Review of
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geriatric literature1,2 fails to identify a consensus statement on definition of frailty.
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Some authors suggest muscle size measurements3 to be the surrogates of frailty,
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while others stress the importance of gait, balance and hand grip strength4-6 in
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determining frailty of an individual.
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syndrome resulting from multisystem impairments. These impairments include
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sacropenia, functional decline and neuroendocrine dysregulation. In presence of
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such impairments, clinical outcomes are considered to be worse. Patients with
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combination of such impairments are at an even higher risk for development of
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complications.
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electively, it is imperative that identification of high-risk patients can potentially
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prevent postoperative complications.
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used to determine frailty. Elderly patients are more likely to be frail as compared
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to the general population. According to the U.S. Census Bureau8, the geriatric
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population is the fastest growing segment of the U.S. population. It is projected
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that by year 2030 one in five Americans will be more than 65 years of age8.
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Elderly patients are considered frail and are deemed to be a high risk for
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developing postoperative complications. Health care providers are faced with the
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challenge of providing a reliable and cost effective healthcare to an aging
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population. Frailty has been associated with poor outcomes after major surgical
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procedures, including cardiac, colo-rectal, general surgery and urologic
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operations4-6,9,10. Patients with peripheral arterial disease tend to have severe
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Abellan et al7 define frailty as a clinical
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coexisting comorbidities, which place them at a high risk for developing
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postoperative complications. Traditionally age and coexisting comorbidities have been employed in
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addition to other tools to predict outcomes for patients undergoing an operation.
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In recent years there has been a lot of interest in Frailty in the surgical patient
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and its implication on outcomes. A simplified form of the original Frailty index
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from the Canadian Study of Health and Aging has been established as the
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modified frailty index (mFI). In this study, we sought to apply the mFI to below the
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inguinal ligament vascular bypass surgery in an effort to predict outcomes and
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validate it as a low cost, noninvasive tool to help clinicians better screen and
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inform patients.
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Methods:
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Dataset: The American College of Surgeons National Surgical Quality
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Improvement Program (ACS-NSQIP)11 Participant User Files (PUF) were
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reviewed for the year 2010.
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information and is compliant with Health Insurance Portability and Accountability
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Act (HIPPA). Therefore, no institutional review board (IRB) approval or patient
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consent was required. Methods used to extract data from this database are well
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described in the literature12-15.
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responsible for collecting all data points and excluding patients with incomplete
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data. ACS performs regular audits of the dataset and the outcomes based on
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NSQIP database are shown to be highly reliable14. This database provides a
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comprehensive list of pre-operative comorbidities, laboratory values, intra-
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operative variables and postoperative outcomes. Patients younger than 16 years
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were not included and patients older than 89 years of age were coded as 90+ to
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protect patient confidentiality.
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Patients: Using Current Procedural Terminology (CPT) codes (37220-37235);
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patients who had undergone infrainguinal arterial bypass surgery during 2010
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were identified in the NSQIP-PUF file.
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Modified Frailty Index: Modified Frailty index (mFI) was calculated using 11
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variables, based on the Canadian Study of Health and Aging Frailty Index (CSHA
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FI)2,16 and validated in the ACS- NSQIP database. Table I depicts the variables
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used by CSHA FI and the corresponding variables used in ACS-NSQIP
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database. The modified Frailty index (mFI) for a patient is calculated by adding
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one point for the presence of each of these variables divided by 11. This
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This dataset contains patient de-identified
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produces a number between 0 and 1. Based on mFI score, the patients were
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divided into four groups: Group 1 (mFI score: 0-0.09), Group 2 (mFI score: 0.18-
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0.27), Group 3 (mFI score: 0.36-0.45), and Group 4 (mFI score: 0.54-0.63).
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Outcomes: ACS-NSQIP database provides information for any complications
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within 30 days after surgery.
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primary outcome and post op myocardial infarction, stroke, renal failure and graft
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failure were chosen as secondary outcomes.
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Statistical Analysis:
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All variables were initially summarized with frequencies and percentages or
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means, medians, and standard deviations. Binomial logistic regression was used
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to determine any bivariate associations between the four-group mFI variables
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and post-operative outcome variables and between other potential covariates
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and 30-day mortality.
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direction of any significant associations.
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independent variables from the bivariate analysis of 30-day mortality along with
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demographic variables (age, gender, race, and BMI) were then used in a process
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of stepwise, forward, and backward selection methods to find the group of
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variables collectively that were most significantly associated with 30-day
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readmission in a multivariable logistic regression model.
Prior to the
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multivariable
checked
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multicollinearity with one another using variance inflation factor (VIF) statistics.
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With so many variables and a large sample size, a more stringent entry criteria of
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p<0.05 and a stay criteria of p<0.05 were used for the process of variable
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selection to be more conservative. The fit of the final model was checked using
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The statistically significant (p<0.05)
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the
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for
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the Hosmer and Lemeshow goodness-of-fit test (p=0.6309).
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(c=0.887) shows adequate prediction strength of the final model. All analyses
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were performed using SAS version 9.4 (SAS Institute, Cary, NC).
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The c-statistic
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Results:
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Demographics:
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36% Females), who underwent an infrainguinal arterial bypass in 2010. Mean
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age was 67.9 ± 11.7 years (Range 19 to >90 years). Race distribution was as
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follows: 74% White, 16% African American, 10% unknown. Mean BMI was 27.7
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± 6.4 (BMI<25: 1,637 patients (35.5%), BMI 25-29: 1,593 patients (34.5%) and
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BMI 30-40: 1,216 patients (26.4%) and BMI ≥ 40: 165 patients (3.6%). Incidence
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of pre-operative variables was as fellows: hypertension (3981: 84.6%), history of
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rest pain (2,205: 46.9%), history of transient ischemic attack (302: 6.4%), history
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of stroke (364 (7.7%), American Society of Anesthesiology (ASA) Score 1 (No
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disturbance/mild disturbance): 303 (6.4%), ASA Score 2 (Severe Disturbance):
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3,459 (73.6%) and ASA Score 3 and 4 (Life threatening emergency/ moribund
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condition): 941 (20%), Active smoking status (1,915 patients: 41%), emergency
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operation (258 (5.5%) and end-stage renal disease on hemodialysis (336: 7%).
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Post Operative Complications: The distribution of postoperative complications
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was as fellows: superficial surgical site infection (SSI): 356 (7.6%), deep wound
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infection: 110 (2.3%), stroke: 28 (0.6%), graft failure: 206 (4.4%), deep venous
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thrombosis: 47 (1%), return to operating room: 773 (16.4%), acute renal failure:
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38 (0.8%) and mortality: 100 (2.1%).
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Modified Frailty Index: Modified Frailty Index was calculated for all patients and
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distribution of mFI was as follows:
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mFI = 0/11 = 0
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mFI = 1/11 = 0.09 (Number of Patients = 564 (11.9%)
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mFI = 2/11 = 0.18 (Number of Patients = 1,177 (25.02%)
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ACS-NSQIP database identified 4,704 patients (64% Males,
(Number of Patients = 121 (2.6%)
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mFI = 3/11 = 0.27 (Number of Patients = 1,456 (30.95%)
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mFI = 4/11 = 0.36 (Number of Patients = 914 (19.43%)
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mFI = 5/11 = 0.45 (Number of Patients = 351 (7.46%)
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mFI = 6/11 = 0.54 (Number of Patients = 92 (1.96%)
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mFI = 7/11 = 0.63 (Number of Patients = 29 (0.62%)
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mFI= 8/11 = 0.72 (Number of Patients = 0, (0%)
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mFI = 9/11 = 0.81 (Number of Patients = 0, (0%)
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mFI = 10/11 = 0.90 (Number of Patients = 0, (0%)
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mFI = 11/11 = 1
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When grouped together, as described in methods section, the distribution of mFI
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scores was as follows:
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Group 1 (mFI score: 0-0.09): 685 Patients (14.56%)
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Group 2 (mFI score: 0.18-0.27): 2,633 Patients (55.97%)
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Group 3 (mFI score: 0.36-0.45): 1,265 Patients (26.89%)
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Group 4 (mFI score: 0.54-0.63): 121 Patients (2.57%)
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Outcomes: Thirty day mortality was chosen as primary outcome. Increase in
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mFI was associated with higher mortality rates. Incidence of mortality for Group 1
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was 0.6%, for Group 2, it was 1.4%, for Group 3, it was 4% and for Group 4, it
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was 7.4%. The incidence of MI for Group 1 was 1%, for Group 2, it was 2%, for
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Group 3, it was 3.1% and for Group 4, it was 4.2%. The incidence of stroke
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among Group 1 patients was 0.6%, for Group 2, it was 0.5% , for Group 3, it was
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0.6% and for Group 4, it was 1.7%.
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insufficiency, the incidence among Group 1 patients was 0.6%, among Group 2
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For postoperative progressive renal
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patients, it was 0.6%, among Group 3 patients, it was 0.6 and among Group 4
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patients, it was 0.8%. The incidence of graft failure for Group 1 patients was
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4.8%, for Group 2 patients, it was 4.3%, for Group 3 patients, it was 4.1% and for
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Group 4 patients, it was 7.4%. In regards to any occurrence for any of these
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complications, the incidence among Group 1 patients was 6.9%, for Group 2
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patients, it was 8.1% , for Group 3 patients, it was 11.1% and for Group 4
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patients, it was 19% (Table II).
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The Univariate analysis identified following independent variables to be
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associated with higher risk of mortality: Age >80 years , higher ASA score (4-5),
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transfer from nursing home, impaired sensorium, dependent functional status ,
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diabetes, history of COPD, history of congestive heart failure, history of previous
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coronary stenting history of angina, history of rest, emergency operation, dialysis
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dependency, increased length of hospital stay, post operative progressive renal
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insufficiency, post operative stroke, post operative myocardial infarction, sepsis,
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return to the operating room, increased length of hospital stay and acute renal
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failure (Table III).
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Multivariant analysis identified following factors to be associated with increased
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risk of mortality: mFI 0.18-0.27 vs. 0-0.09, mFI 0.36-0.45 vs. 0-0.09 , mFI 0.54-
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0.63 vs. 0-0.09, age 60-70 vs. <60, age 70-80 vs. <60, age >80 vs. <60, black
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race vs. white race, other races vs. white race, dialysis dependency, post
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operative progressive renal insufficiency, post operative myocardial infraction
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and post operative acute renal failure (Table IV).
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Discussion: Our study shows that variables described in ACS-NSQIP database can be
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used to calculate a mFI and that a higher mFI score for patients undergoing
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lower extremity revascularization surgery accurately predicts a higher 30-day
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mortality and myocardial infarction. For years, vascular surgeons have been
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relying on a variety of factors and measures to assess a patient’s ability to
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withstand the stressors of surgery. Routine cardiac testing and pulmonary
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assessment is regularly performed in anticipation for major surgery, however,
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rarely are factors such as functional status, congestive heart failure and history of
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previous cerebral ischemic events are used in such assessments. Our study
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shows successful use of the mFI scoring system to predict major postoperative
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complications after lower extremity bypass surgery. It is worth mentioning that
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frailty is fundamentally different from existence of several comorbidities, as the
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variables used to calculate the mFI encompass mental and social factors in
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addition to relying on markers for physical dysfunction. Our study has shown that
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it can be a reliable and an important low cost, noninvasive tool to aid in the
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clinical decision making. It shows a noticeable increase in morbidity and mortality
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with an increasing m-FI. Patients with a mFI score of greater than 0.54 (i.e.
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presence of 6 or more variables), the 30-day mortality after lower extremity
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surgical bypass can be as high as 7.4% (OR 13.7, CI 4.14-45.2, p<0.001) and
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the risk of myocardial infarction is around 4% (OR 4.2, CI 1.3-13.4, p=0.013).
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With a better understanding of the impact of pre-operative factors on the
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post-operative outcomes, there has been an increasing focus of attention on
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determining the factors associated with postoperative morbidity and mortality.
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Historically, surgeons have focused on cardiac causes of morbidity and mortality
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after the surgical operations. Poldermans et al17 have shown that patients with a
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positive stress test before a major vascular surgery operations are at a high risk
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for developing post operative cardiac complications.
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have identified advanced age, pre-existing cardiac and renal diseases, high ASA
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scores and the use of general anesthesia to be associated with a significantly
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high risk of developing post operative complications after lower extremity bypass
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surgery. The eleven variables used to calculate a mFI score represent physical,
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mental, social assessment and a combination of these factors can accurately
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reflect the outcomes after elective operations. Several authors4-6,9,19 have used
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prospective data to calculate frailty scores for surgical patients.
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studies10,20,21 have used retrospective methodology to determine frailty scores for
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surgical patients and predicted the incidence of postoperative complications
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based on mFI scores. Veanovich et al22 have shown that patients with increased
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frailty
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otolaryngology, general, orthopedic, neurosurgical, thoracic, gynecological and
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urologic procedures. Likewise, Hewitt et al23 have shown that frail patients, who
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were more than 65 years of age undergoing emergent general surgical
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procedures had increased incidence of postoperative mortality.
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Likewise, Kehlet et al18
had
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undergoing
Some
cardiac,
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Patients with PAD represent a cohort of patient population, which often
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reserve. Outcomes of any intervention for patients with PAD are dependent on
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anatomic, physiologic and disease severity factors24.
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surgeons have considered surgical bypasses to have the advantage over
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endovascular interventions in terms of long term patency and avoiding re-
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interventions25.
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surgical bypass should take into account the possibility of all the postoperative
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complications. As stated above, surgeons in the past have relied heavily on using
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age and cardiac history as predictors for postoperative outcomes, however
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applying mFI scores to patients undergoing arterial bypass for PAD provides a
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better assessment tool to predict postoperative complications. A recent study of
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patients undergoing lower extremity bypass surgery26 showed that elderly
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patients (age >80 years) had no increased risk of postoperative complications as
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compared to those patients who were younger than 80 years of age. Our data
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clearly shows that age more than 80 years is associated with significantly high
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risk for mortality after lower extremity bypass surgery.
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previous major amputation and female gender have been associated with major
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adverse limb events after lower extremity bypass surgery27. Our analysis shows
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that the mFI can be used as a useful tool to accurately predict postoperative
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complications.
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vascular surgery operations also showed that preoperative mFI could accurately
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predict postoperative mortality. Interestingly, this analysis showed mFI to be a
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better predictor of postoperative mortality than other variables for open
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operations. Our study only consists of open lower extremity bypasses and our
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results correlate with the findings of Ehlert et al.
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Higher ASA scores,
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A recent analysis28 of all the patients undergoing different
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between patients with different mFI scores should be recognized and the
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informed consent process should include a frank discussion about the risk of
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complications based on mFI scores. Our data clearly shows that frailty may be
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present in the younger patient population and relying solely on age to predict
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postoperative complications may not be a reliable strategy.
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Patients presenting with severe PAD have some degree of frailty at
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baseline. Most surgeons would recommend surgical bypasses for PAD only for
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the select group of patients who have either critical limb ischemia or severe,
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disabling claudication. While the purpose of revascularization in patients with
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critical limb ischemia is limb salvage, the goal of surgical bypass in claudicants is
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improvement in quality of life. The decision to proceed with surgical bypass
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should be made after careful evaluation of all risks and benefits. Many factors
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play an important role in determining the balance between risks and benefits of
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an operation. This data serves to add one more data point i.e. mFI, in helping
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vascular surgeons determining the risk/benefit ratio.
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surgeons would still recommend revascularization for patients with severe tissue
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loss, our analysis clearly shows that it may not be advisable to offer an open
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revascularization procedure on a claudicant with high mFI. Our data should be
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interpreted with caution and operative decisions should be made after careful
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consideration of all risk factors and tailoring the outcomes to individual patients.
While most vascular
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Our analysis is limited by the inherent nature of any retrospective study.
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The NSQIP database does not contain the variables as gait speed or grip
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strength, which can provide additional information while calculating frailty. The
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database is also limited to 30-day outcomes making it difficult to evaluate long-
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term progress of these patients. The findings are limited to only those hospitals,
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which were enrolled in the NSQIP database and may not be applicable to all
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patients. Despite these limitations, The NSQIP provides us with a large and
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diverse sample size and the statistics performed on such a large sample do
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provide results with statistical significance. It also provides us access to a
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diversity of surgeons and institutions where patients are cared.
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To summarize, this study demonstrates that the m-FI does identify
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patients at a higher risk for morbidity and mortality. It shows that for a m-FI 0.54-
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0.63 the risk of 30-day mortality and post-operative complications increases
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significantly. When used appropriately, the mFI can be a valuable, low cost,
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noninvasive tool in accessing and stratifying patients preoperatively.
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References
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. 12. Khuri SF, Daley J, Henderson W, Hur K, Gibbs JO, Barbour G, et al. Risk adjustment of the postoperative mortality rate for the comparative assessment of the quality of surgical care: results of the National Veterans Affairs Surgical Risk Study. J Am Coll Surg 1997;185:315-27. 13. Bilimoria KY, Cohen ME, Ingraham AM, Bentrem DJ, Richards K, Hall BL, et al. Effect of postdischarge morbidity and mortality on comparisons of hospital surgical quality. Ann Surg 2010;252:183-90. 14. Shiloach M, Frencher SK, Jr., Steeger JE, Rowell KS, Bartzokis K, Tomeh MG, et al. Toward robust information: data quality and inter-rater reliability in the American College of Surgeons National Surgical Quality Improvement Program. J Am Coll Surg 2010;210:6-16.
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1. Morley JE, Vellas B, van Kan GA, Anker SD, Bauer JM, Bernabei R, et al. Frailty consensus: a call to action. J Am Med Dir Assoc 2013;14:392-7. 2. Rockwood K, Andrew M, Mitnitski A. A comparison of two approaches to measuring frailty in elderly people. J Gerontol A Biol Sci Med Sci 2007;62:73843. 3. Sheetz KH, Zhao L, Holcombe SA, Wang SC, Reddy RM, Lin J, et al. Decreased core muscle size is associated with worse patient survival following esophagectomy for cancer. Dis Esophagus 2013;26:716-22. 4. Makary MA, Segev DL, Pronovost PJ, Syin D, Bandeen-Roche K, Patel P, et al. Frailty as a predictor of surgical outcomes in older patients. J Am Coll Surg 2010;210:901-8. 5. Robinson TN, Wu DS, Pointer L, Dunn CL, Cleveland JC, Jr., Moss M. Simple frailty score predicts postoperative complications across surgical specialties. Am J Surg 2013;206:544-50. 6. Revenig LM, Canter DJ, Taylor MD, Tai C, Sweeney JF, Sarmiento JM, et al. Too frail for surgery? Initial results of a large multidisciplinary prospective study examining preoperative variables predictive of poor surgical outcomes. J Am Coll Surg 2013;217:665-70 e1. 7. Abellan van Kan G, Rolland Y, Houles M, Gillette-Guyonnet S, Soto M, Vellas B. The assessment of frailty in older adults. Clin Geriatr Med 2010;26:27586. 8. Colby S OJ. Projections of the Size and Composition of the U.S. Population: 2014 to 2060, Current Population Reports. US Census Bureau 2014:P25-1143. 9. Lee DH, Buth KJ, Martin BJ, Yip AM, Hirsch GM. Frail patients are at increased risk for mortality and prolonged institutional care after cardiac surgery. Circulation 2010;121:973-8. 10. Adams P, Ghanem T, Stachler R, Hall F, Velanovich V, Rubinfeld I. Frailty as a predictor of morbidity and mortality in inpatient head and neck surgery. JAMA Otolaryngol Head Neck Surg 2013;139:783-9. 11. Improvement ACoSNSQ, at: PA. https://www.facs.org/qualityprograms/acs-nsqip. Accessed January 10, 2017
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15. Khuri SF, Daley J, Henderson W, Barbour G, Lowry P, Irvin G, et al. The National Veterans Administration Surgical Risk Study: risk adjustment for the comparative assessment of the quality of surgical care. J Am Coll Surg 1995;180:519-31. 16. Mitnitski AB, Mogilner AJ, Rockwood K. Accumulation of deficits as a proxy measure of aging. ScientificWorldJournal 2001;1:323-36. 17. Poldermans D, Fioretti PM, Forster T, Thomson IR, Boersma E, el-Said EM, et al. Dobutamine stress echocardiography for assessment of perioperative cardiac risk in patients undergoing major vascular surgery. Circulation 1993;87:1506-12. 18. Kehlet M, Jensen LP, Schroeder TV. Risk Factors for Complications after Peripheral Vascular Surgery in 3,202 Patient Procedures. Ann Vasc Surg 2016;36:13-21. 19. Kim SW, Han HS, Jung HW, Kim KI, Hwang DW, Kang SB, et al. Multidimensional frailty score for the prediction of postoperative mortality risk. JAMA Surg 2014;149:633-40. 20. Etzioni DA, Liu JH, Maggard MA, Ko CY. The aging population and its impact on the surgery workforce. Ann Surg 2003;238:170-7. 21. Karam J, Tsiouris A, Shepard A, Velanovich V, Rubinfeld I. Simplified frailty index to predict adverse outcomes and mortality in vascular surgery patients. Ann Vasc Surg 2013;27:904-8. 22. Velanovich V, Antoine H, Swartz A, Peters D, Rubinfeld I. Accumulating deficits model of frailty and postoperative mortality and morbidity: its application to a national database. J Surg Res 2013;183:104-10. 23. Hewitt J, Moug SJ, Middleton M, Chakrabarti M, Stechman MJ, McCarthy K, et al. Prevalence of frailty and its association with mortality in general surgery. Am J Surg 2015;209:254-9. 24. Lo RC, Darling J, Bensley RP, Giles KA, Dahlberg SE, Hamdan AD, et al. Outcomes following infrapopliteal angioplasty for critical limb ischemia. J Vasc Surg 2013;57:1455-63; discussion 63-4. 25. Feinglass J, Pearce WH, Martin GJ, Gibbs J, Cowper D, Sorensen M, et al. Postoperative and late survival outcomes after major amputation: findings from the Department of Veterans Affairs National Surgical Quality Improvement Program. Surgery 2001;130:21-9. 26. Shirasu T, Hoshina K, Nishiyama A, Akagi D, Miyahara T, Yamamoto K, et al. Favorable outcomes of very elderly patients with critical limb ischemia who undergo distal bypass surgery. J Vasc Surg 2016;63:377-84. 27. Brothers TE, Zhang J, Mauldin PD, Tonnessen BH, Robison JG, Vallabhaneni R, et al. Predicting outcomes for infrapopliteal limb-threatening ischemia using the Society for Vascular Surgery Vascular Quality Initiative. J Vasc Surg 2016;63:114-24 e5.
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28. Ehlert BA, Najafian A, Orion KC, Malas MB, Black JH 3rd, Abularrage CJ. Validation of a modified frailty index to predict mortality in vascular surgery patients. J Vasc Surg 2016 Jun;63(6):1595-1601.
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Table I: Variables Used to Calculate mFI by the Canadian Study of Health and Aging (CSHA) and the Corresponding Variables Identified in the American College of Surgeons National Surgical Quality Improvement Program (ACSNSQIP).
Impaired Sensorium
Pre-Operative Functional Status: - Independent - Partially dependent - Totally dependent
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History relevant to cognitive impairment or loss Problems with bathing Problems with dressing Problems with cooking Problems with personal grooming Problems with going out alone Cardiac Disease
Congestive Heart Failure
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Myocardial Infarction
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ACS-NSQIP
Clouding or Delirium
Arterial hypertension History of diabetes mellitus
EP
Chronic/Acute lung disease
Cereberovascular problems History of Stroke
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Pre-Operative Comorbidities
CSHA
SC
Category of Variables Functional and Cognitive Impairment
Decreased peripheral pulses
- Previous percutaneous coronary intervention or cardiac surgery - History of angina <1 month before surgery Congestive heart failure <1 month before surgery History of myocardial infarction <6 months before surgery Hypertension requiring medication Diabetes Mellitus - Insulin dependent - Non-insulin dependent History of severe COPD Current pneumonia History of transient ischemic attack Cerebrovascular accident or stroke with neurologic deficit - History of revascularization or amputation for peripheral vascular disease - Rest pain or gangrene
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Table II
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Modified Frailty N (%) with Outcome (N=4704) Index Outcome OR (95% CI)* P-value* 30-day mortality 0.0 – 0.09 4 (0.6) Reference <0.001 0.18 – 0.27 37 (1.4) 2.4 (0.86, 6.83) 0.36 – 0.45 50 (4.0) 7 (2.52, 19.48) 0.54 – 0.63 9 (7.4) 13.7 (4.14, 45.18) Post-operative myocardial infarction 0.0 – 0.09 7 (1.0) Reference 0.013 0.18 – 0.27 53 (2.0) 2 (0.90, 4.39) 0.36 – 0.45 39 (3.1) 3.1 (1.37, 6.92) 0.54 – 0.63 5 (4.1) 4.2 (1.30, 13.37) Post-operative stroke (CVA) 0.0 – 0.09 4 (0.6) Reference 0.516 0.18 – 0.27 14 (0.5) 0.9 (0.29,2.77) 0.36 – 0.45 8 (0.6) 1.1 (0.33,3.611) 0.54 – 0.63 2 (1.7) 2.9 (0.52,15.79) Post-operative progressive renal 0.0 – 0.09 4 (0.6) Reference 0.985 failure 0.18 – 0.27 16 (0.6) 1 (0.35,3.124) 0.36 – 0.45 7 (0.6) 1 (0.28,3.25) 0.54 – 0.63 1 (0.8) 1.4 (0.16,12.80) Graft/prosthesis/flap failure 0.0 – 0.09 33 (4.8) Reference 0.354 0.18 – 0.27 112 (4.3) 0.9 (0.59,1.31) 0.36 – 0.45 52 (4.1) 0.9 (0.54,1.32) 0.54 – 0.63 9 (7.4) 1.6 (0.74,3.41) Any occurrence (of the above 0.0 – 0.09 47 (6.9) Reference < 0.001 outcomes) 0.18 – 0.27 213 (8.1) 1.2 (0.86,1.66) 0.36 – 0.45 140 (11.1) 1.7 (1.2,2.38) 0.54 – 0.63 23 (19.0) 3.2 (1.85,5.48) * All odds ratios and p-values are from binomial logistic regression modeling the outcome variables. Odds ratios with 95% confidence limits not including 1 are considered significant. The unit of reference for the odds ratios is mFI 0.0-0.09
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P-value*
Reference 2.3 (0.95, 5.40) 5.5 (2.44, 12.30) 9.2 (4.05, 20.69)
<0.001
1.2 (0.78, 1.77) Reference
0.431
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OR (95% CI)*
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M AN U
SC
Table III: Univariable Analysis for Factors Affecting Mortality No 30-day 30-day Mortality Mortality Variable (N=4604) (N=100) Age (years) 1227 (99.4) 7 (0.6) ≤60 >60-70 1471 (98.7) 19 (1.3) 1217 (97.0) 38 (3.0) >70-80 >80 689 (95.0) 36 (5.0) Sex Female 1626 (97.7) 39 (2.3) Male 2947 (98.0) 60 (2.0) Race Non-Hispanic Black 713 (97.1) 21 (2.9) Non-Hispanic American Indian or 12 (100) 0 (0) Alaska native 38 (95.0) 2 (5.0) Non-Hispanic Asian 70 (2.0) 3400 (98.0) Non-Hispanic White BMI (kg/m^2) <25 1592 (97.3) 45 (2.8) 25-<30 1567 (98.3) 26 (1.6) 30-<40 1192 (98.3) 21 (1.7) >40 163 (98.8) 2 (1.2) ASA class No Disturbance-Mild Disturbance (1-2) 303 (100) 0 (0) Severe Disturbance (3) 3415 (98.7) 44 (1.3) Life Threatening-Moribund (4-5) 885 (94.0) 56 (6.0) Transfer status From acute care hospital inpatient 155 (96.9) 5 (3.1) Not transferred (admitted from home) 4246 (98.2) 78 (1.8) Nursing home - Chronic care 139 (89.7) 16 (10.3) Intermediate care Outside emergency department 33 (97.1) 1 (2.9) Transfer from other 28 (100) 0 (0) Smoker Yes 1895 (99.0) 20(1.0) No 2709 (97.1) 80 (2.9) Alcohol use Yes 281 (97.9) 6 (2.1) No 4323 (97.9) 94 (2.1) Impaired sensorium Yes 28 (82.4) 6 (17.7) No 4576 (97.7) 94 (2.0)
1.4 (0.87,2.35) <0.001(<0.001,>999.9) 2.6 (0.61,10.81) Reference
0.015
Reference 0.6 (0.36,0.96) 0.6 (0.37,1.05) 0.4 (0.10,1.81)
0.092
Reference 5.6 (1.25,Infinity) 27.4 (6.184,Infinity)
<0.001
Reference 1.8 (0.70,4.40) 6.3 (3.57,11.01) 1.7(0.22,12.21) <0.001(<0.001,>999.9)
<0.001
0.4 (0.22,0.59) Reference
<0.001
1.0 (0.43,2.26) Reference
0.966
10.4 (4.22,25.79) Reference
<0.001
ACCEPTED MANUSCRIPT
39 (6.3) 61 (98.5)
4.4 (2.90,6.67) Reference
<0.001
1990 (97.2) 2614 (98.4)
58 (2.8) 42 (1.6)
1.8 (1.21,2.71) Reference
0.004
612 (96.4) 3992 (98.1)
23 (3.6) 77 (1.9)
11 (100) 4593 (97.9)
0 (0) 100 (2.1)
1.06 (93.0) 4498 (98.0)
8 (7.0) 92 (2.0)
3.7 (1.75,7.80) Reference
<0.001
938 (97.8) 3.666 (98.0)
21 (2.2) 79 (2.1)
1.0 (0.64,1.69) Reference
0.876
1074 (96.9) 3530 (98.2)
34 (3.1) 66 (1.8)
1.7 (1.11,2.58) Reference
0.014
84 (93.3) 4520 (98.0)
6 (6.7) 94 (2.0)
3.4 (1.46,8.06) Reference
<0.005
3893 (97.8) 711 (98.3)
88 (2.2) 12 (1.7)
1.3 (0.73,2.46) Reference
0.347
2608 (98.2) 1996 (97.4)
47 (1.8) 53 (2.6)
0.7 (0.456,1.009) Reference
0.056
2140 (97.1) 2464 (98.6)
65 (3.0) 35 (1.4)
2.1 (1.41,3.24) Reference
<0.001
293 (97.0) 4311 (97.9)
9 (3.0) 91 (2.1)
1.5 (0.73,2.92) Reference
0.290
355 (97.5) 4249 (97.9) 2.69 ± 2.63
9 (2.5) 91 (2.1) 2.87 ± 2.46
1.2 (0.59,2.37) Reference 1.0 (0.95, 1.11)
0.633 0.492
242 (93.8) 4362 (98.1)
16 (6.2) 84 (1.9)
3.4 (1.98,5.95) Reference
<0.001
RI PT
582 (93.7) 4022 (98.5)
2.0 (1.21,3.13) Reference
0.006
<0.001(<0.001,>999.9) Reference
0.983
SC
M AN U
TE D
AC C
EP
Dependent Functional status Yes No Diabetes Yes No History of COPD Yes No History of pneumonia Yes No History of CHF Yes No History of PCI Yes No History of PCS Yes No History of angina Yes No Hypertension Yes No History of PVD Yes No History of rest pain Yes No History of TIA Yes No History of CVA Yes No PGY level (1-unit increase) Emergency operation Yes No
ACCEPTED MANUSCRIPT
312.04 ± 129.43
Dialysis Yes No
309 (92.0) 4295 (98.3)
Hospital length of stay (7-day increase)
8.08 ± 8.54
27 (8.0) 73 (1.7) 12.96 ± 10.59 2 (0.6) 98 (2.3)
106 (96.4) 4498 (97.9)
4 (3.6) 96 (2.1)
10 (100) 4594 (97.9)
0 (0) 100 (2.1)
EP
AC C
5.1 (3.26,8.11) Reference 1.3 (1.16, 1.39)
M AN U
0.121
<0.001 <0.001
0.3 (0.06,0.10) Reference
0.050
1.8 (0.064,4.90) Reference
0.273
<0.001 (<0.001,999.9) Reference
0.984
SC
354 (99.4) 4250 (97.8)
23 (82.1) 4581 (98.0)
5 (17.9) 95 (82.1)
10.5 (3.90,28.16) Reference
<0.001
25 (89.3) 4579 (97.9)
3 (10.7) 97 (2.1)
10.5 (3.90,28.16) Reference
0.005
86 (82.7) 4518 (98.2)
18 (17.3) 82 (1.8)
11.5 (6.63,20.05) Reference
<0.001
201 (97.6) 4403 (97.9)
5 (2.4) 95 (2.1)
1.2 (0.46,2.87) Reference
0.759
47 (100) 4557 (97.8)
0 (0) 100 (2.2)
<0.001 (<0.001,999.9) Reference
0.985
123 (91.8) 4481 (98.0)
11 (8.2) 89 (2.0)
4.5 (2.35,8.64) Reference
<0.001
748 (96.8) 3856 (98.1)
25 (3.2) 75 (1.9)
1.7 (1.09,2.72) Reference
0.021
6.21 ± 6.58
9.04 ± 7.80
1.3 (1.12, 1.40)
154 (96.2) 4450 (97.9) 13.97 ±
6 (3.8) 94 (2.1) 8.83 ±
1.9 (0.80,4.28) Reference 0.68 (0.47, 0.99)
TE D
Superficial incisional SSI Yes No Deep incisional SSI Yes No Post-op pulmonary embolism Yes No Post-op progressive renal insufficiency Yes No Post-op stroke Yes No Post-op MI Yes No Graft/prosthesis/flap failure Yes No DVT requiring therapy Yes No Sepsis Yes No Return to OR Yes No Days from operation to discharge (7-day increase) Steroid use Yes No Pre-op albumin serum level
1.1 (0.97, 1.32)
RI PT
293.75 ± 116.62
Anesthesia time (100-minute increase)
<0.001
0.154 0.041
ACCEPTED MANUSCRIPT
AC C
EP
TE D
M AN U
SC
RI PT
19.49 16.08 Acute renal failure requiring dialysis w/in 30 days of operation 31.1 (15.54,62.11) Yes 24 (63.2) 14 (36.8) <0.001 No 4580 (98.2) 86 (1.8) Reference * All odds ratios and p-values are from binomial logistic regression modeling 30-day mortality, exact logistic regression used as needed. Odds ratios with 95% confidence limits not including 1 are considered significant.
ACCEPTED MANUSCRIPT
Table IV: Multivariant Analysis for Factors Affecting 30-day Mortality
Odd’s Ratio (CI)
mFI 0.18-0.27 vs. 0-0.09
4.4 (0.9-21.9)
mFI 0.36-0.45 vs. 0-0.09
7 (1.4-34.5)
mFI 0.54-0.63 vs. 0-0.09
7.9 (1.3-48.01)
Age 60-70 vs. <60
1.7 (0.64-4.3)
SC
RI PT
Variables
Age 70-80 vs. <60
3.1 (1.3-7.4) 3.1 (1.2-7.9)
Black Race Vs. White Race Other Race Vs. White Race Dialysis Dependency
M AN U
Age >80 vs. <60
1.4 (0.8-2.6)
3.1 (0.98-9.8) 2.7 (1.5-4.8)
TE D
Post operative progressive renal insufficiency
7.7 (2.1-28.9)
7.5 (3.7-15.1)
Post operative Acute Renal Failure requiring Dialysis
13.8 (5.4-35.3)
AC C
EP
Post operative Myocardial infarction