Sociodemographic associations with abnormal estimated glomerular filtration rate (eGFR) in a large Canadian city: a cross-sectional observation study

Chronic kidney disease (CKD) represents a significant disease burden, with a prevalence of approximately 12.5% of adult Canadians and 15.2% of Americans affected [1, 2]. Patients living with CKD costs the Canadian health care system over $40 billion CAD per year, with US estimates of over $50 billion USD in Medicare costs [3, 4]. Early detection and management of CKD are critical for reducing comorbidities and mortality rates, as the condition may be reversible. Unfortunately, early identification of CKD is challenging, as patients with early stages of CKD are often asymptomatic, due to the variable and non-specific clinical presentation of the disease [5, 6]. In fact, CKD is often diagnosed serendipitously through other common comorbidities and risk factors, including diabetes mellitus, hypertension, and cardiovascular disease (CVD) [6‐8], which often meant their disease has progressed without detection. Individuals with certain sociodemographic factors may also be more vulnerable to developing CKD than others. Evidence show a higher prevalence of CKD in some visible minorities and certain Indigenous populations in Canada and the United States [9‐15]. Those with different levels of income, education and employment may also be vulnerable to developing CKD [16‐19]. However, it is clear that sociodemographic risk factors for CKD is population- and region-specific, as demonstrated by a study showing that low income, but not level of education, was strongly associated with CKD in the United States, while low education level, but not low income, was strongly associated with CKD in the Netherlands [18].

Despite the challenges of early identification and complexity of CKD risk, CKD is indicated and can be diagnosed when an individual have an abnormal estimated glomerular filtration rate (eGFR) < 60 ml/min/1.73m². According to the most recent guideline released by Kidney Disease: Improving Global Outcomes (KDIGO), adults with eGFR < 60 ml/min/1.73m² is considered to be at a moderately increased risk to very high risk for CKD [6]. When measuring renal function, eGFR is currently the clinical standard worldwide over serum creatinine measurement alone, as age, sex, diet, medication use, muscle mass and body size differences among individuals can significantly affect the interpretation of an abnormal creatinine result [20]. Today, the most widely used equation to estimate GFR is the Chronic Kidney Disease Epidemiology Collaboration (CKD-EPI) eq. (21), which not only accounts for the patient’s serum creatinine values, sex, age and ethnicity, but is also more accurate in diagnosing earlier stages of CKD in patients who have a higher eGFR [21, 22]. As a result, many clinical laboratories use the CKD-EPI eGFR equation to diagnose CKD worldwide [1, 6, 23‐25].

The purpose of this study is to evaluate the sociodemographic associations with CKD, a complicated chronic disease, using only one laboratory test result, an abnormal eGFR, in a Canadian healthcare setting. To our knowledge, we are the first to do this using a single laboratory test result for CKD, where we combined secondary laboratory data with publically available Canadian census data for a large metropolitan city of Calgary, Alberta. As CKD risk is population- and region-specific, geographic distribution of abnormal eGFR result rate in the city of Calgary will also be assessed.

In 2011, 346,664 adult community patients received an eGFR test result, but one patient was excluded from the study as their DOB was missing. Of the 346,663 adult patients who received their first eGFR test encounter for the 2011 calendar year (56.5% female, 43.5% male), 28,091 patients had an abnormal result (eGFR < 60 ml/min/1.73m²). The abnormal eGFR result rate in Calgary in 2011 was 8.1% (8.4% female, 7.7% male). See Table 1 for further details.

In order to investigate sociodemographic associations with abnormal eGFR test results, sociodemographic risk factors known to be associated with CKD were studied. All individual level and group level sociodemographic variables analyzed were adjusted for, thus making any significant associations an independent risk contribution. Poisson regression revealed that women and the elderly (age ≥ 70 years) were significantly associated with an increased risk for eGFR < 60 ml/min/1.73m², suggesting increased risk for CKD. Meanwhile, Chinese, South Asians, and those with a high MHI had a significantly reduced risk for an abnormal eGFR result. For every $100,000 increase in MHI, risk for abnormal eGFR test results significantly decreased by 12%. Refer to Table 2 for further details.

In order to investigate geographic distribution of abnormal eGFR result rate, geospatial analysis was conducted (Fig. 1), and revealed statistically significant regional variations of abnormal eGFR result rates in Calgary, with statistically significant hot spots (high abnormal eGFR result rates) in the northwest, and southwest quadrants of the city of Calgary; as well as along the Bow River, just east of downtown Calgary. Significantly cold spots (low abnormal eGFR result rates) was observed in the inner city of Calgary on the southwest end of downtown, and the outer edges of the city.

In this article, we present geospatial distribution, and sociodemographic risk associations with an abnormal eGFR result rate, suggesting the presence of chronic kidney disease. The methodology of combining secondary laboratory data with Statistics Canada’s Census data (27–29) revealed statistically significant differences in geospatial distribution of abnormal eGFR result rates within Calgary, Alberta. Statistically significant risk associations for abnormal eGFR result rates were also observed for specific sociodemographic groups in the city. To our knowledge, we are the first to validate known sociodemographic risk factors for CKD using a single laboratory test result – an abnormal eGFR.

The geospatial analysis conducted in Calgary demonstrated clear geographic differences in abnormal eGFR result rates, as supported by the regional-specificity of CKD prevalence associated with different sociodemographic factors [9‐11, 13, 16‐18, 36, 37]. It has been previously demonstrated that certain sociodemographic groups cluster in different parts of Calgary: those with a higher MHI and a higher level of education tend to live in the inner city of Calgary near downtown, while those with lower income, lower level of education, self-reported visible minorities and First Nations groups cluster in the northeast quadrant along the Bow River [28, 38]. This may explain why we observed significant cold (low proportion of eGFR < 60 ml/min/1.73m² result rates) and hot (high proportion of abnormal eGFR result rates) spots in these neighbourhoods, respectively. Another speculation as to why there are significant cold or hot spots in the remaining neighbourhoods, is that perhaps it is due younger families that tend to live in the newer neighbourhoods in the periphery of the city, while those living in the northwest and southwest quadrants in the hot spot areas may overlap with an older demographic. It is unlikely that these hot spots of abnormal eGFR result rates represent greater access to healthcare, as previous studies have shown that in Calgary, Alberta, those living in the neighbourhoods within the periphery of the city travel significantly shorter distances than those in the periphery of the city to phlebotomy sites [39], suggesting easier access to receive laboratory testing for those living inside the city limits. It is also unlikely the hot spots identified in the geomapping analysis represent higher population density, as Statistics Canada standardizes each DU into 400–700 individuals per polygon unit throughout the country [31]. However, as we could not quantitatively assess the sociodemographic associations with abnormal eGFR result rates from the geomapping model alone, we performed a separate analysis (Table 2) to investigate this.

Consistent with other findings, as reviewed by Cobo, et al. [40], there is a statistically significant higher risk of women and the elderly with abnormal eGFR (< 60 ml/min/1.73m²) in Calgary, with age having the strongest risk association. This is likely due to age-related changes, and the difference in muscle mass between genders, as both variables impact serum creatinine values, which influences eGFR measurement [41]. Also consistent with other studies [17‐19, 42], our analysis showed having a higher income reduces the risk of having an abnormal eGFR result, suggesting a decreased risk for CKD. Specifically, for every increase of $100,000 in MHI, the risk for developing CKD decreases by 12% in our analysis. Although not significant, being employed and having higher levels of education also show a decreased risk in abnormal eGFR result rate in this study. As expected, those who have a higher income, who are employed and who have a higher level of education in Canada tend to be healthier, as these sociodemographic factors influence health-related behaviours [43].

Interestingly, those who are Chinese or South Asian (East Indian, Pakistani, Sri Lankan [44]) are at a statistically significant lower risk of abnormal eGFR result rates compared to other ethnicities, suggesting a lower risk for CKD compared to other visible minorities reported in Census Canada. This result is difficult to interpret due to the fact that some guidelines state that certain ethnicities, including “Asians”, are a risk factor for CKD progression. However, rarely is the “Asian” population clearly defined in other international guidelines [24, 25], whereas in this study, we observed strong sociodemographic associations with specific self-identified visible minorities. Perhaps there was a limitation to our ecological analysis as studies have recommended using a different eGFR equation to include an Asian coefficient to account for the difference in muscle mass between different ethnicities [45, 46], which is not accounted for in the widely used CKD-EPI eq. (21). Finally, there may be possible co-segregation with other unmeasured socioeconomic or clinical variables that also decreased the risk of CKD for these visible minorities in Calgary.

Although there was an increased risk for abnormal eGFR result rates in First Nations and visible minority Black populations in Calgary, the analysis did not show statistical significance. This is interesting as many studies find those who are Indigenous Canadian or from a Black visible minority are more susceptible for CKD, including end stage renal disease (ESRD) [10, 12, 17, 36, 47]. The discrepancies may be due to the fact that Indigenous Canadians who live in an urban centre, such as Calgary, have a higher socioeconomic status [48] and have a decreased prevalence of CKD that is associated with easier access to healthcare [10] when compared to Indigenous Canadians living in more rural areas of the province. It is also important to note that although there was a higher prevalence of Indigenous First Nations with ESRD in Alberta, this was not the case for earlier stages of CKD when compared to non-Indigenous First Nations [9]. Additionally, statistical significance may not have been reached due to the relatively small sample size of First Nations and Black visible minority groups living in Calgary, at < 3% of Calgarian population [9, 33, 48].

By investigating sociodemographic risk associations with an abnormal eGFR result rate using publically available secondary laboratory and Census data, we observed similar known sociodemographic risk associations with CKD. As health is related to socioeconomic status (SES) [43], it is unlikely there is a wide-spread selection bias of eGFR testing for adult community patients in Calgary, as we only observed one of the three SES to have a significantly reduced risk of an abnormal eGFR result, suggesting a reduced risk for CKD.

In this cross-sectional observation study, there were statistically significant region-specific variations in abnormal eGFR result rates in a large Canadian city. Those who are female, or over the age of 70 were at a significantly higher risk for CKD, while those of visible minority Chinese or South Asian groups, or have a high median household income, were at a significantly lower risk for CKD in this analysis. Results from this study may be useful for policy makers to allow primary care providers to target at risk sociodemographic groups and neighbourhoods identified in this study through decreased eGFR for early identification of CKD progression. This study validated the methodology of using publically available census data and secondary laboratory data to investigate factors associated with CKD risk, which could be applied to investigate sociodemographic associations with other chronic disease conditions using only secondary laboratory data. It may be of interest to analyze and compare results from this study with other jurisdictions across Canada using the same model, as the results shown here may be specific to this particular jurisdiction.