Explaining Neighbourhood Disparities in Cardiovascular Disease in Hamilton, Ontario, Canada

University of Toronto Journal of Public Health Pub Date : 2022-02-25 DOI:10.33137/utjph.v3i1.38128

Gabriella Christopher

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Exploratory ordinary least squares (OLS) regression was performed to understand which indicators may explain geographic variation in CVD ER visits. Linear regression assumptions were assessed by testing the residuals for heteroskedasticity using the Koenker test, spatial autocorrelation using Global Moran’s I, and normality using the Kolmogorov-Smirnov test.\nResults: Initial analysis from 2016 and 2017 revealed that the rate of CVD ER visits in Hamilton is spatially autocorrelated (global Moran’s I score of 0.516 (p<0.001) and ranged from less than 3 in 1000 to over 30 in 1000 people per year. For regression analysis, factor scores for material deprivation and dependency domains of the well validated ON-Marg Index were used together with the percentage of patients with no family physician. OLS regression using the four regressors resulted in a statistically significant model (F=65.94, p<0.001) that explains about 65% of the variability in CVD ER visits in Hamilton (R2 = 0.653). 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Abstract

Introduction: In 2010, Hamilton’s local newspaper published a series of articles highlighting the inequities in numerous health outcomes across the city, with cardiovascular disease (CVD) Emergency Room (ER) visits among them (DeLuca et al., 2012). In Canada CVD is the second leading cause of death and the leading cause of hospitalizations, however, previous research has demonstrated that CVD risk may vary geographically (Chu et al., 2019). Furthermore, health analyses are rarely conducted in ways accessible to non-scientific communities. Given inequities in the distribution of COVID-19 across Hamilton communities, the need for population level analysis of comorbidities and risk factors is of heightened importance. The aim of this study is to identify the underlying factors that explain neighbourhood differences in the rate of CVD across Hamilton, Ontario. Methods: Census Tract (CT) aggregated Ontario Marginalization (ON-Marg) values and health data from Cancer Care Ontario were used. The material deprivation dimension of ON-Marg includes information on income, employment, education, and lone parent households, which have previously been linked to increased CVD risk, while the dependency dimension represents those who do not have income from employment which captures older age and disability (Matheson & van Ingen, 2018). Factor analysis was performed to identify underlying factors that account for common variance. Spatial associations were analyzed using choropleth maps as well as measures of both global spatial autocorrelation (i.e., global Moran’s I) and local indicators of association (i.e., local Moran’s I). Contiguity was based on rook-weights (sharing a common boundary). Exploratory ordinary least squares (OLS) regression was performed to understand which indicators may explain geographic variation in CVD ER visits. Linear regression assumptions were assessed by testing the residuals for heteroskedasticity using the Koenker test, spatial autocorrelation using Global Moran’s I, and normality using the Kolmogorov-Smirnov test. Results: Initial analysis from 2016 and 2017 revealed that the rate of CVD ER visits in Hamilton is spatially autocorrelated (global Moran’s I score of 0.516 (p<0.001) and ranged from less than 3 in 1000 to over 30 in 1000 people per year. For regression analysis, factor scores for material deprivation and dependency domains of the well validated ON-Marg Index were used together with the percentage of patients with no family physician. OLS regression using the four regressors resulted in a statistically significant model (F=65.94, p<0.001) that explains about 65% of the variability in CVD ER visits in Hamilton (R2 = 0.653). Residuals were tested for heteroscedasticity (Koenker = 4.33, p=0.363), autocorrelation (global Moran’s I = 0.042, p = 0.367) and normality (Kolmogorov-Smirnov = 0.072, p = 0.079). Discussion: This information can help inform neighbourhood-level public health interventions and broader policy decisions to help address local CVD disparities. Patterns of high CVD and poorer socioeconomic conditions also correspond with COVID-19 disparities and support the need for greater neighbourhood-level research of both infectious and chronic conditions. Furthermore, geographic outputs of this work also provide visual and interactive neighbourhood-level health information accessible to non-scientific audiences that may support community-centred health and social action. References DeLuca, P. F., Buist, S., & Johnston, N. (2012). The Code Red Project: Engaging communities in health system change in Hamilton, Canada. Social Indicators Research, 108(2), 317–327. https://doi.org/10.1007/s11205-012-0068-y Chu, M., Truscott, R., Young, S., Harrington, D., Keller-Olaman, S., Heather, M., & Orr, S. (2019). The Burden of Chronic Diseases in Ontario: Key estimates to support efforts in prevention. Cancer Care Ontario & Public Health Ontario. Matheson, F. I., Dunn, J. R., Smith, K. L. W., Moineddin, R., & Glazier, R. H. (2012). Development of the Canadian Marginalization Index: A New Tool for the Study of Inequality. Canadian Journal of Public Health / Revue Canadienne de Sante’e Publique, 103, S12–S16. https://www.jstor.org/stable/41995683

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解释加拿大安大略省汉密尔顿地区心血管疾病的邻里差异

简介:2010年，汉密尔顿当地报纸发表了一系列文章，强调了整个城市众多健康结果的不平等，其中包括心血管疾病(CVD)急诊室(ER)就诊(DeLuca et al.， 2012)。在加拿大，心血管疾病是第二大死亡原因和住院治疗的主要原因，然而，之前的研究表明，心血管疾病的风险可能因地而异(Chu等人，2019)。此外，健康分析很少以非科学界可以获得的方式进行。鉴于COVID-19在汉密尔顿社区的分布不公平，对合并症和风险因素进行人口水平分析的必要性变得更加重要。这项研究的目的是确定解释安大略省汉密尔顿地区心血管疾病发病率差异的潜在因素。方法:使用人口普查区(CT)汇总的安大略省边缘化(ON-Marg)值和安大略省癌症护理中心的健康数据。on - marg的物质剥夺维度包括收入、就业、教育和单亲家庭的信息，这些信息以前被认为与心血管疾病风险增加有关，而依赖维度代表那些没有就业收入的人，其中包括老年人和残疾人(Matheson & van Ingen, 2018)。进行因子分析以确定导致共同方差的潜在因素。空间关联分析使用了choropleth地图以及全局空间自相关性(即全局Moran’s I)和局部关联指标(即局部Moran’s I)，相邻性基于rookweight(共享共同边界)。采用探索性普通最小二乘(OLS)回归来了解哪些指标可以解释心血管疾病ER就诊的地理差异。使用Koenker检验检验异方差残差，使用Global Moran’s I检验空间自相关，使用Kolmogorov-Smirnov检验检验正态性来评估线性回归假设。结果:2016年和2017年的初步分析显示，汉密尔顿心血管疾病ER就诊率具有空间自相关性(全球Moran 's I评分为0.516 (p<0.001))，范围从1000人中每年少于3人到1000人中每年超过30人。为了进行回归分析，我们将经过验证的ON-Marg指数的物质剥夺和依赖域的因子得分与没有家庭医生的患者的百分比一起使用。使用这四个回归因子进行OLS回归得到了一个具有统计学意义的模型(F=65.94, p<0.001)，该模型解释了汉密尔顿心血管疾病ER就诊的65%的变异性(R2 = 0.653)。残差检验为异方差(Koenker = 4.33, p=0.363)、自相关(全局Moran 's I = 0.042, p= 0.367)和正态性(Kolmogorov-Smirnov = 0.072, p= 0.079)。讨论:这些信息有助于为社区一级的公共卫生干预和更广泛的政策决定提供信息，以帮助解决当地心血管疾病的差异。心血管疾病高发病率和社会经济条件较差的模式也与COVID-19的差异相对应，并支持需要在社区一级对传染病和慢性病进行更多研究。此外，这项工作的地理产出还为非科学受众提供了可视和互动式的社区一级卫生信息，可支持以社区为中心的卫生和社会行动。参考文献deluca, P. F, Buist, S.， & Johnston, N.(2012)。红色代码项目:让社区参与加拿大汉密尔顿的卫生系统变革。社会指标研究，2008(2)，317-327。https://doi.org/10.1007/s11205-012-0068-yChu, M.， Truscott, R.， Young, S.， Harrington, D.， Keller-Olaman, S.， Heather, M.， & Orr, S.(2019)。安大略省慢性病负担:支持预防工作的关键估计。安大略省癌症护理和安大略省公共卫生部。Matheson, F. I, Dunn, J. R.， Smith, K. L. W.， Moineddin, R.和Glazier, R. H.(2012)。加拿大边缘化指数的发展:研究不平等的新工具。加拿大公共卫生杂志/加拿大公共卫生杂志，103,S12-S16。https://www.jstor.org/stable/41995683

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