Introduction
The prevalence of obesity has continued to increase worldwide over the last two decades [1]. Presently, over 20% of the global population is overweight (BMI ≥ 25 kg/m2), and 10% is considered clinically obese (BMI ≥ 30 kg/m2) [2]. This equates to approximately 1.5 billion individuals being overweight and 500 million being obese worldwide [3]. These estimates are expected to continue to increase by 2030 to 2.16 billion overweight individuals and 1.12 obese individuals [2]. Similarly, in Canada, approximately 60% of Canadians are overweight and 24% are clinically obese [4].
Despite modest weight loss following lifestyle modifications, bariatric surgery is the only evidence-based approach to producing marked and sustainable weight loss in severely obese individuals. Body mass index (BMI) remains the most common measure to estimate adiposity in these individuals, and current guidelines to select appropriateness for bariatric surgery are based on BMI, with Canadian bariatric centers typically offering bariatric surgical management to individuals with BMI ≥35 kg/m2 with obesity-related comorbidities (e.g., type 2 diabetes mellitus) or to any patient with a BMI ≥40 kg/m2. However, BMI alone may not be the optimal measure to guide patient selection for bariatric surgery. Thus, previous studies have suggested that BMI may be a poor prognostic predictor of mortality [5].
Recently, Sharma and Kushner proposed the Edmonton obesity staging system (EOSS) as a more comprehensive measure of obesity-related disease burden and predictor of mortality [6]. In this review, we explore the current evidence in support of EOSS and discuss its potential role to determine indications for bariatric surgery.
Edmonton Obesity Staging System
The EOSS is a staging system that takes into account severity of comorbidities and functional status in assigning stage (Box 1). Two recent studies in three large and independent populations have compared EOSS to anthropometric measures like BMI or waist circumference as a predictor of mortality. In the first study, Padwal et al. assessed the EOSS retrospectively using a representative cohort population of overweight and obese patients [7]. In this study, individuals with class III obesity (after adjustment for metabolic syndrome or waist line) had virtually no increased mortality risk compared to class II obese individuals (hazard ratio, HR 0.9), while individuals with EOSS 2 or 3 had a 4 to 12-fold greater hazard ratio, respectively, compared to individuals with EOSS 0/1 (Fig. 1). In the second study by Kuk et al., individuals with EOSS stage 2 or 3 had an increased risk of mortality (HR 1.6–1.7) from all causes compared to normal weight individuals [8]. However, neither stage 0 nor 1 was associated with increased mortality risk.
Box 1. The Edmonton obesity staging system
Stage 0. No apparent risk factors (e.g., blood pressure, serum lipid, and fasting glucose levels within normal range), physical symptoms, psychopathology, functional limitations, and/or impairment of well-being related to obesity |
Stage 1. Presence of obesity-related subclinical risk factors (e.g., borderline hypertension, impaired fasting glucose levels, elevated levels of liver enzymes), mild physical symptoms (e.g., dyspnea on moderate exertion, occasional aches and pains, fatigue), mild psychopathology, mild functional limitations, and/or mild impairment of well-being |
Stage 2. Presence of established obesity-related chronic disease (e.g., hypertension, type 2 diabetes, sleep apnea, osteoarthritis), moderate limitations in activities of daily living, and/or well-being |
Stage 3. Established end-organ damage such as myocardial infarction, heart failure, stroke, significant psychopathology, significant functional limitations, and/or impairment of well-being |
Stage 4. Severe (potentially end-stage) disabilities from obesity-related chronic diseases, severe disabling psychopathology, severe functional limitations, and/or severe impairment of well-being |
The Role of Edmonton Obesity Staging System in Bariatric Surgery
Currently, bariatric surgery patient selection is commonly based on BMI thresholds alone and a few obesity-related comorbidities. However, patient selection using BMI alone may be criticized as being inaccurate and subjective, since it may not identify those patients that benefit most from bariatric surgery. We suggest that prioritizing patients with increased EOSS scores may identify obese patients with greater mortality risk, since EOSS is better correlated with mortality risk [7]. Determining the urgency for surgical intervention allows for improved prioritization of obese patients. This is highlighted in the study by Kuk et al., which found that a substantial number of patients with class III obesity had minimal mortality risk [8]. With BMI alone used for determining priority for bariatric surgical intervention, many patients with EOSS scores of 2 or 3 may have been overlooked.
It may be argued that bariatric surgery prioritized to EOSS scores 2 and 3, who have increased severity of obesity-related comorbidities, rather than scores 0/1 may miss the opportunity to apply bariatric surgery as a preventative measure. However, in a public-funded health-care system, with limited access and resources, it is prudent to prioritize these resources to those in greatest need. In addition, there is little known about the natural history of obesity, and thus, it remains challenging to predict who will indeed progress to higher EOSS stages and who will remain stable. Therefore, the risk/benefit ratio bariatric surgery in obese individuals with no or minimal obesity-related comorbidities is relatively undetermined. Also, recent evidence suggests that obesity-related comorbidities, such as type 2 diabetes mellitus, may be reversible (in EOSS score ≤2 patients); thus, there may time to delay bariatric surgical management.
Bariatric surgery has been shown to be clinically effective at producing marked weight loss in obese individuals [9, 10]. An economic evaluation by Picot et al. supported the cost-effectiveness of bariatric surgery-induced weight loss [11]. However, health technology assessments specify that bariatric surgery is cost-effective in patients with diabetes (EOSS stage 2). In contrast, the cost-effectiveness of bariatric surgery in patients without comorbidities (EOSS <2) is far less clear. Thus, it is likely that a formal health economics analysis based on the EOSS criteria will support the cost-effectiveness of bariatric surgery for EOSS 2/3 patients, with minimal (if any) cost-effectiveness (even in the long-term) in EOSS 0/1 individuals.
Conclusion
The progressively increasing population of obese individuals is an ongoing global epidemic. Bariatric surgical intervention remains the only evidence-based approach to produce marked sustainable weight loss in severely obese patients. However, with limited health-care resources, it remains an important challenge to determine which patients will benefit most. The EOSS may be an important tool to redefine indications for bariatric surgery in obese individuals. Further research to determine how to incorporate the EOSS into clinical bariatric practice is needed.
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Conflict of Interest
The authors RSG, SK, and AMS have no conflict of interests to declare.
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Gill, R.S., Karmali, S. & Sharma, A.M. The Potential Role of the Edmonton Obesity Staging System in Determining Indications for Bariatric Surgery. OBES SURG 21, 1947–1949 (2011). https://doi.org/10.1007/s11695-011-0533-8
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DOI: https://doi.org/10.1007/s11695-011-0533-8