Vol 81, No 2 (2023)
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Environmental and socioeconomic determinants of heart failure

Sylwia Roszkowska12, Barbara Kula1, Natalia Pawelec1, Michał Święczkowski3, Anna Tomaszuk-Kazberuk4, Hanna Bachórzewska-Gajewska3, Sławomir Dobrzycki3, Łukasz Kuźma3
Pubmed: 36354114
Kardiol Pol 2023;81(2):160-167.

Abstract

Background: Over 1.5 million people in Poland suffer from heart failure (HF). The risk of hospitalization is related to environmental and socioeconomic factors and the organization of the healthcare system.
Aims: The study aimed to assess the influence of environmental and socioeconomic factors on the prevalence of hospitalization for HF.
Methods: The impact of environmental and socioeconomic factors on HF hospitalizations in Poland in 2012–2019 based on data from the National Institute of Public Health and Central Statistical Office in Poland was estimated by panel data regression techniques.
Results: There were 1 618 734 HF-related hospitalizations (51.3% male; 82.6% aged >65 years). An increase in the number of physicians by 10/10 000 population and healthcare expenditure of 100 PLN per capita resulted in 3.5% (–0.035; 95% confidence interval [CI], –0.06 to –0.01; P = 0.002) and 3% (–0.029; 95% CI, –0.04 to –0.013; P <0.001) decrease in hospitalizations, respectively. For each new outpatient healthcare facility per 10 000 population, there was a 3% (–0.031; 95% CI, –0.048 to –0.014; P <0.001) decrease in hospitalizations. One percentage point increase in the proportion of green areas resulted in a 2.7% (–0.027; 95% CI, –0.042 to –0.01; P = 0.049) decrease in hospitalizations. However, an increase in cars by 1000 inhabitants and a 1 percentage point increase in the unemployment rate were associated with a 6% increase in HF hospitalizations (0.064; 95% CI, 0.008–0.121; P = 0.026).
Conclusions: The number of HF-related hospitalizations has been increasing in the last decade. This trend is most noticeable in regions with low socioeconomic development and poor medical facilities. Our study indicates that health policy measures including environmental and socioeconomic instruments may result in positive health outcomes. Additional analyses are needed to compare the impact of socioeconomic and environmental factors against the impact of healthcare alone.

Original article

Environmental and socioeconomic determinants of heart failure

Sylwia Roszkowska12Barbara Kula1Natalia Pawelec1Michał Święczkowski3Anna Tomaszuk-Kazberuk4Hanna Bachórzewska-Gajewska3Sławomir Dobrzycki3Łukasz Kuźma3
1Department of Economic Mechanisms, Faculty of Economics and Sociology, University of Łódź, Łódź, Poland
2Faculty of Management, Warsaw University, Warszawa, Poland
3Department of Invasive Cardiology, Medical University of Bialystok, Bialystok, Poland
4Department of Cardiology, Medical University of Bialystok, Białystok, Poland

Correspondence to:

Łukasz Kuźma, MD, PhD,

Department of Invasive Cardiology,

Medical University of Bialystok,

M Skłodowskiej-Curie 24 A, 15–276 Białystok, Poland,

phone: +48 85 746 84 96,

e-mail: kuzma.lukasz@gmail.com

Copyright by the Author(s), 2023

DOI: 10.33963/KP.a2022.0251

Received: October 12, 2022

Accepted: October 21, 2022

Early publication date: November 10, 2022

ABSTRACT
Background: Over 1.5 million people in Poland suffer from heart failure (HF). The risk of hospitalization is related to environmental and socioeconomic factors and the organization of the healthcare system.
Aims: The study aimed to assess the influence of environmental and socioeconomic factors on the prevalence of hospitalization for HF.
Methods: The impact of environmental and socioeconomic factors on HF hospitalizations in Poland in 20122019 based on data from the National Institute of Public Health and Central Statistical Office in Poland was estimated by panel data regression techniques.
Results: There were 1 618 734 HF-related hospitalizations (51.3% male; 82.6% aged >65 years). An increase in the number of physicians by 10/10 000 population and healthcare expenditure of 100 PLN per capita resulted in 3.5% (–0.035; 95% confidence interval [CI], –0.06 to –0.01; P = 0.002) and 3% (–0.029; 95% CI, –0.04 to –0.013; P <0.001) decrease in hospitalizations, respectively. For each new outpatient healthcare facility per 10 000 population, there was a 3% (–0.031; 95% CI, –0.048 to –0.014; P <0.001) decrease in hospitalizations. One percentage point increase in the proportion of green areas resulted in a 2.7% (–0.027; 95% CI, –0.042 to –0.01; P = 0.049) decrease in hospitalizations. However, an increase in cars by 1000 inhabitants and a 1 percentage point increase in the unemployment rate were associated with a 6% increase in HF hospitalizations (0.064; 95% CI, 0.0080.121; P = 0.026).
Conclusions: The number of HF-related hospitalizations has been increasing in the last decade. This trend is most noticeable in regions with low socioeconomic development and poor medical facilities. Our study indicates that health policy measures including environmental and socioeconomic instruments may result in positive health outcomes. Additional analyses are needed to compare the impact of socioeconomic and environmental factors against the impact of healthcare alone.
Key words: environment, economic development, healthcare system, heart failure, public health policy

WHAT’S NEW?

Our study addresses socioeconomic and environmental conditions of heart failure (HF) in Poland and Europe. This study, to date, is the largest of its kind; it researched 1.6 million hospitalizations over 8 years of observation. In our research, we look not only at the national data, but additionally, we analyze regional-level hospitalizations. The results of the provided analyses indicate that an increase in regional indicators, such as the number of physicians and healthcare expenditure, green areas density, or the working-age population, and a decrease in the unemployment rate and number of cars can cause a reduction in HF-related hospitalizations.

Introduction

The document “A New Perspective on the Health of Canadians” created by Marc Lalonde [1] described the first holistic health determinant model and introduced the concept of health fields as four overarching categories of health determinants. The greatest influence on health was attributed to the lifestyle and living environment. A novelty was the recognition of the significant contribution of factors related to socioeconomic and psychosocial determinants, including access to healthcare [1]. This concept was later developed, among others, by Göran Dahlgren and Margaret Whitehead [2], who created the rainbow model of health determinants, showing the links between biological factors and, among others, lifestyle and broadly defined socio-economic, cultural, and environmental factors. Since the turn of the century, the concept of socioeconomic determinants of health has been one of the paradigms used by the World Health Organization (WHO). WHO emphasizes the importance of shaping a new multisectoral approach to the implementation of public health policy [3].

Despite the development of knowledge about holistic health determinants, primary and secondary prevention measures are still a significant subject of interest in the healthcare sector, while socioenvironmental factors are often overlooked although they are of great importance, particularly in the field of cardiovascular diseases (CVD) [4–6]. CVDs are the greatest threat to the health and life of the Polish population, and heart failure (HF) is one of the major factors for morbidity and mortality in Poland [7]. Despite significant progress in the understanding of pathophysiology and implementation of extensive primary and secondary prevention, HF is also a significant social problem. The frequency of hospitalizations for HF is steadily increasing, and it is the main cause of hospitalization of patients over 65 years of age. Due to the aging of the population, the need for the introduction of new drugs and invasive procedures will increase [8].

The incidence and prevalence of HF show a large geographical variation, which can only be partly explained by the prevalence of classical risk factors for the development of the disease [8]. Nowadays, there is convincing evidence that environmental factors particularly air pollution are associated with increased cardiovascular morbidity and mortality, but there is highly limited evidence regarding the impact of socioeconomic factors. In our view, these factors are one of the key determinants of health outcomes in patients with HF. Furthermore, socioeconomic deprivation may increase vulnerability to cardiovascular complications caused by environmental factors.

The hypothesis about the influence of environmental and socioeconomic factors on the prevalence of HF became the basis for conducting our study. We sought to establish the extent to which these factors are associated with the rate of HF hospitalizations. Our analysis covered over 1.6 million hospitalizations in over 8 years of follow-up.

Aim

To assess the influence of environmental and socioeconomic factors on the prevalence of hospitalizations for HF in Poland.

Methods

Study design

We conducted retrospective analyses. We evaluated whether socioeconomic and environmental factors affect hospitalizations for HF in Poland. The data were obtained from the National Institute of Public Health the National Institute of Hygiene in Poland and aggregated to 380 counties (NUTS4) level as the 3-year means. The data provider adopted the Polish population age structure as the standard age structure (HF hospitalization in Poland equals 1).

The set of explanatory variables included environmental and socioeconomic factors. Information on air pollutant concentrations was obtained from the Chief Inspectorate for Environmental Protection. Socioeconomic variables were obtained from the Central Statistical Office in Poland. Both aggregation and averaging procedures solved the problems of random fluctuations. The aforementioned factors were divided into three groups, in particular the sets concerning medical care, economic and environmental conditions. The group of medical variables consisted of the number of medical doctors per 10 000 inhabitants, health expenditure per capita, and the number of ambulatory departments subordinate to the local government. In the group of variables describing the economic condition of regions, we included gross domestic product (GDP) per capita, industrial sales per capita, investment per capita, the proportion of the workforce employed in agriculture, services, working-age population share, and finally the unemployment rate. Some of these variables were aggregated from the municipality to county levels, the rest of them were already available on this level.

The last group of variables was related to the environment in the studied areas. It was defined by the number of wastewater treatment plants, amount of industrial wastewater discharged, bicycle tracks density, forests density, protected area density, vehicles per 1000 inhabitants, population density, and concentration of air pollutants such as particulate matter with a diameter of 2.5 μm or less (PM2.5), 10 μm or less (PM10), and nitrogen dioxide (NO2). All environmental variables except air quality were aggregated from the municipality to county levels. Air pollution variables were analyzed at the voivodeship level.

Statistical analysis

The distribution of the variables was assessed with the Shapiro-Wilk test. Data are expressed as means and standard deviations (SD). Statistical significance between variables was determined using Student’s t-test. Panel regression methods were used in the statistical analysis (mainly fixed and random effects methods), as well as the generalized least squares method (GLS) [9, 10]. Parameters were estimated using three-year averages for both HF hospitalizations and three-year averages of the explanatory variables. Not only were the parameters of the equations estimated but we also assessed the marginal effects associated with the influence of the mentioned factors on HF. Those semi-elasticities are interpreted as the percentage change in standardized rates of HF hospitalization per unit change in the explanatory variables ceteris paribus.

To get robust estimates and sensitivity analyses, the elasticities were estimated independently for subgroups of variables and additionally separately in sub-periods. Results are presented as marginal effects (semi-elasticities) and 95% confidence intervals (95% CI).

The threshold of statistical significance for all tests was set at P <0.05. All analyses were performed using Stata Statistical Software, (StataCorp, 2022, version 17, TX, US).

The study was financed from the funds of the National Science Center granted under the contract number UMO-2021/41/B/NZ7/03716 and registered at ClinicalTrials.gov (NCT05198492).

Results

We analyzed 1 618 734 hospitalizations for HF in Poland in 20122019 (51% males). There was a significant predominance of people aged 65 and over (82% of all hospital admissions for HF; P <0.001).

Data on hospitalizations for HF per 100 000 inhabitants on average per year in the analyzed period 20122019 is presented in Figure 1.

Figure 1. Hospitalizations for heart failure per 100 000 inhabitants per year in 20122019 in Polish voivodeships

The spread of HF cases was enormous among Polish voivodeships (NUT2 level). The lowest average values of 300 hospitalizations per 100 000 inhabitants were noted in the Pomorskie voivodeship, while the highest (over 700 admissions) were in Podkarpackie, Swietokrzyskie, Lubelskie, and Lodzkie. Moreover, the dynamics concerning changes in HF hospitalizations in 20122019 also differed. In all voivodeships, HF hospitalizations ratios per 100 000 inhabitants increased while the highest rise was observed in Podlaskie Voivodeship where the registered growth rate was 102%.

The standardized hospitalization rates for HF can be described by a smaller range (from 1.17 to 3.87) as presented on the counties distribution map (Figure 2). On average the highest coefficients were noted in districts of eastern Poland, mainly in the Podkarpackie and Lubelskie voivodeships, while the lowest were in Pomorskie, Zachodniopomorskie, and Dolnoslaskie. The average value of the ratios in the studied sub-periods decreased from 1.12 to 1.10, and this drop was complemented by a decrease in the regional variation (Figure 2).

Figure 2. Standardized hospitalization ratio for heart failure in 20122019 in Polish counties

Most economic variables were highly varied in particular regions in Poland. Working age population share stands out amongst them. The descriptive statistics for these variables are presented in Table 1. An increase in the number of physicians by 10 per 10 000 population and healthcare expenditure of 100 PLN per capita resulted in a 3.5% (–0.035; 95% CI, –0.06 to –0.01; P = 0.002) and a 3% (–0.029, 95% CI, –0.04 to –0.013; P <0.001) decrease in hospitalizations, respectively. For each new ambulatory healthcare facility per 10000 population, there was a 3% (–0.031; 95% CI, –0.048 to –0.014; P <0.001) decrease in hospitalizations. One percentage point increase in the proportion of green areas and an increase in working age population resulted in a 2.7% (–0.027; 95% CI, –0.042 to –0.01; P = 0.049) and 1.5% (–0.015; 95% CI, –0.033 to –0.003; P = 0.01) decrease in hospitalizations, respectively. However, an increase in vehicles by 1000 inhabitants and an increase of 1 percentage point in the unemployment rate were associated with a 6% increase in HF hospitalizations (0.064; 95% CI, 0.0080.121; P = 0.026) and 1% (0.008; 95% CI, 0.0010.011; P = 0.04) increase in hospitalizations, respectively (Figure 3). Air pollution appears to be an important determinant of hospitalizations for HF. An increase in the PM2.5 and P10 by 10 µg/m3 at a voivodeship resulted in a county increase in HF hospitalizations by 7.5% (0.075; 95% CI, 0.0130.137; P = 0.017) and 6% (0.060; 95% CI, 0.0120.108; P = 0.015), respectively.

Table 1. Explanatory variables descriptive statistics in Polish counties in 2012–2019

Variable

Mean in Poland

County minimum

County maximum

Coefficient of dispersion

Coefficient of variation

Healthcare services

Physicians, 10 per 104 inhabitants

38.54

2.00

202.6

0.72

0.34

Health expenditure per capita, 100 PLN per capita per year

20.95

6.23

194.6

0.64

0.24

Ambulatory healthcare facility, per 104 inhabitants

4.70

1.93

12.3

0.33

0.2

Socio-economic conditions

Gross domestic product at constant prices, PLN per capita

30 626

13 579

130 731

0.39

0.21

Industrial sales, PLN per capita

22 779

0.00

207 222

0.95

0.6

Investment, PLN per capita

3 205

176

27 583

0.94

0.49

Unemployment, %

3.7

2.7

16

0.94

0.49

Employment in agriculture, % of total employment

11.49

0.36

79.06

0.69

0.58

Employment in services, % of total employment

57.97

15.2

86.8

0.35

0.24

Municipal own income, PLN per capita

1347

0.00

7586

0.65

0.27

Environmental conditions

Industrial wastewater discharged, persons per km²

1.21

0.00

194

9.6

2.94

Bicycle tracks density, km/10 000 km2

716

0.00

1700

1.48

1.4

Forests density, %

29.4

0.00

72.2

0.92

0.84

Protected area density, ha per km²

0.30

0.00

1.00

0.74

0.58

Vehicles, per 1000 inhabitants

576

187

1042

0.14

0.09

Population density, persons per km²

123

17.7

3899.3

1.46

0.88

Figure 3. Effect of healthcare services, socioeconomic conditions, and environmental conditions on hospital admissions due to heart failure in 20122019 in Poland. The data are presented as semi-elasticity with 95% confidence intervals (CI). The graph shows only variables with P-value less than 0.2

Discussion

To our knowledge, this is the first nationwide study that focuses on the impact of socioeconomic and environmental factors, such as air pollution, on HF. Many previous studies reported a correlation between socioeconomic status and CVD risks [11, 12]. Variation in the burden of HF is also likely caused by other-than-traditional factors. Among them, there are environmental and socioeconomic factors, whose importance has been confirmed in our analysis.

The main findings indicate that environmental factors affect the frequency of hospitalizations for HF. Residents of areas with high environmental pollution caused by a high density of vehicles density of forests and green areas, air pollution, and low greenery were far more likely to experience HF-related hospitalizations. On the other hand, patients with low socioeconomic status compounded by a lower number of physicians and lower healthcare facilities density or healthcare expenditures were far more likely to experience hospitalizations for HF.

As our results show, despite progress made in pharmacological therapy in the last decade, HF-related hospitalizations are on the rise in Poland, especially in the Podlaskie voivodeship. It is related to an aging society, higher prevalence of comorbidities, lack of properly organized pre-hospital care, and an improvement in the treatment of acute cardiovascular diseases [13]. Our study revealed that an increase in the number of medical doctors, healthcare expenditure, and healthcare associated with a decrease in hospitalizations for HF. In the available literature, lower physician concentration was associated with a greater chance of readmission and a higher mortality rate due to cardiovascular disease (CVD) [14–16]. The ESC Guidelines emphasize that self-management programs are extremely important in the therapy of HF as they reduce the risk of hospitalization or death [17]. Several studies show the great effectiveness of patient education in reducing readmission rates and mortality [18, 19]. The experts from the Polish Cardiac Society point out that to this date there is no such program in Poland [20]. The latest ESC Guidelines on HF, experts’ opinion, and results such as ours, should prompt the government to implement systemic changes such as increasing financial funding for healthcare in poverty-stricken areas, and establishing a national registry of HF. Introducing self-management programs, such as health insurance, does not mean equal access to the healthcare system.

Living in areas with a higher share of surrounding residential greenery has turned out beneficial to people’s health [21, 22]. There are multiple ways to explain this phenomenon. For instance, residents of these neighborhoods tend to engage more in physical activity [23]. Moreover, living in green spaces might improve mental health and reduce detrimental environmental exposures to air pollutants, noise, and heat [24, 25]. In our study, we observed a connection between the density of green areas and a decrease in HF-related hospitalizations [26]. Plans et al. [27] showed that a greater density of green spaces had a positive impact on cardiovascular risk factors, but only in the female population.

Table 2. Mean concentration of air pollutants in 16 voivodeships in years 2012–2019

Air pollutant

Mean yearly concentration, µg/m3

Mean 8-year concentration, µg/m3

2012

2013

2014

2015

2016

2017

2018

2019

Dolnoslaskie

PM2.5 (SD)

25.52 (5.2)

25 (4.4)

23.15 (4.5)

21.28 (4.3)

22.34 (4)

21.21 (1.1)

21.65 (1.4)

17.34 (2.3)

22.19 (2.55)

PM10 (SD)

31.7 (16.8)

28.43 (8.8)

34.21 (11.3)

32.73 (9.9)

30.85 (7.6)

30.53 (3)

31.02 (4.9)

25.35 (2.8)

30.6 (2.7)

NO2 (SD)

14.14 (11.8)

13.93 (11.7)

16.27 (11.7)

16.83 (11.5)

16.21 (10.9)

16.02 (10.3)

15.9 (9.8)

15.36 (8.6)

15.58 (1.04)

Kujawsko-pomorskie

PM2.5 (SD)

17.74 (3.7)

17.08 (4.3)

21.47 (2.1)

20.01 (2.8)

19.63 (3.9)

18.94 (3.8)

22.12 (3.9)

17.55 (4)

19.3 (1.85)

PM10 (SD)

29.54 (8)

28.33 (8.4)

33.02 (4.7)

31.53 (4.4)

29.5 (5.3)

29.53 (5.2)

31.27 (3.9)

25.43 (3.1)

29.75 (2.31)

NO2 (SD)

16.83 (9.8)

18.89 (8.4)

16.33 (8.7)

17.34 (8.3)

16.69 (7.4)

16.31 (7.9)

16.79 (7.9)

14.44 (6.3)

16.69 (1.24)

Lubelskie

PM2.5 (SD)

21.3 (2.5)

21.41 (2.5)

23.9 (4.2)

25.39 (4.3)

23.14 (2.8)

23.15 (2.3)

22.5 (2.9)

18.1 (2.7)

22.36 (2.17)

PM10 (SD)

30.77 (5.4)

29.86 (3.2)

31.86 (3.1)

32.58 (4.4)

28.53 (2.6)

30.43 (3.4)

28.86 (3.3)

23.83 (2.9)

29.6 (2.72)

NO2 (SD)

15.73 (5.2)

15.19 (5)

13.75 (6)

13.24 (6.6)

12.45 (6.1)

12.19 (6.8)

12.85 (7.4)

11.82 (4.5)

13.39 (1.41)

Lubuskie

PM2.5 (SD)

19.67 (4.8)

20.67 (4.5)

21.31 (4.9)

19.45 (2.2)

19.96 (1.8)

19.88 (2.3)

19.54 (2.8)

16.16 (3.6)

19.6 (1.51)

PM10 (SD)

27.59 (9.1)

26.38 (7.9)

29.16 (6.3)

26.03 (5.1)

27.84 (4.1)

26.44 (5.5)

28.46 (5.1)

23.07 (3.5)

26.88 (1.89)

NO2 (SD)

13.12 (7.1)

13.08 (6.6)

13.32 (7.4)

13.65 (7.1)

13.46 (6.9)

14.03 (6.3)

13.99 (6.3)

12.21 (5.6)

13.36 (0.59)

Lodzkie

PM2.5 (SD)

29.27 (9.2)

27.74 (6.8)

27.68 (8.1)

25.11 (4.7)

23.33 (3.9)

26.63 (4.7)

25.67 (3.6)

22.18 (3.5)

25.95 (2.38)

PM10 (SD)

40.66 (9.3)

40.23 (7.9)

39.47 (7.6)

35.31 (8.1)

36.51 (5.9)

36.7 (4.8)

35.6 (4.4)

30.44 (3.8)

36.86 (3.35)

NO2 (SD)

19.98 (14.1)

19.23 (13.4)

19.81 (12.2)

20.57 (12.3)

21.3 (12)

19.9 (12.4)

19.55 (12.6)

17.16 (12.5)

19.69 (1.2)

Malopolskie

PM2.5 (SD)

38.35 (4.7)

32.94 (5.6)

31.55 (6.6)

27.64 (6.2)

29.3 (3.5)

30.31 (4.9)

28.59 (5.5)

23.24 (3.1)

30.23 (4.38)

PM10 (SD)

47.83 (9.8)

43.09 (8.9)

40.02 (9.5)

42.07 (10.7)

36.31 (7.5)

39.64 (6.1)

38.78 (7)

32.38 (6.4)

40.01 (4.6)

NO2 (SD)

26.86 (14.6)

25.73 (15.8)

23.59 (14.6)

24.86 (15.7)

27.61 (13.9)

26.42 (14.1)

25.73 (14.2)

24 (14.1)

25.6 (1.38)

Mazowieckie

PM2.5 (SD)

26.88 (2)

25.3 (3.4)

26.51 (2.5)

24.88 (1.4)

23.35 (2.4)

23.85 (3.3)

23.38 (1.6)

19.04 (2.7)

24.15 (2.47)

PM10 (SD)

35.61 (4.9)

32.21 (4.6)

33.14 (4.7)

33.16 (5.1)

30.79 (5.2)

31.37 (5.9)

32.84 (6.4)

25.72 (5.3)

31.85 (2.87)

NO2 (SD)

21.27 (8.8)

22.67 (13.3)

21.89 (11.7)

22.85 (13)

21.26 (13.1)

20.65 (11.7)

19.8 (10.7)

18.73 (10.5)

21.15 (1.4)

Opolskie

PM2.5 (SD)

27.01 (2.1)

27.92 (3.2)

25.86 (3.6)

22.85 (2.4)

23.28 (2.6)

23.49 (3.4)

23.08 (3.3)

18.17 (3.1)

23.98 (3.03)

PM10 (SD)

36.56 (4.9)

36.38 (4.7)

37.4 (4.5)

34.07 (4)

33.14 (3.3)

33.82 (4.7)

34.11 (4.3)

27.98 (3.5)

34.19 (2.94)

NO2 (SD)

18.27 (4.9)

16.89 (5.6)

17.38 (4.7)

18.07 (4.9)

16.07 (4.4)

15.88 (4.4)

16.29 (4.5)

13.76 (6.7)

16.6 (1.44)

Podkarpackie

PM2.5 (SD)

29.31 (4)

25.75 (3.2)

23.99 (1.3)

24.56 (1.7)

23.15 (1.9)

24.12 (0.9)

23.45 (1.1)

19.88 (2.8)

24.3 (2.64)

PM10 (SD)

37.51 (9)

34.06 (6.7)

31.83 (3)

32.48 (3.9)

29.02 (2.6)

30.04 (4.9)

30.42 (4.6)

24.63 (3.8)

31.24 (3.79)

NO2 (SD)

18.36 (5)

18.63 (5.4)

14.36 (4.6)

13.56 (5.1)

12.98 (4.7)

13.24 (4.7)

12.85 (4.6)

14.94 (6.6)

14.88 (2.34)

Podlaskie

PM2.5 (SD)

26.72 (7.1)

22.54 (6.5)

21.16 (4.7)

21.2 (5.9)

19.14 (6)

16.47 (6)

18.95 (5.3)

14.37 (5.8)

20.06 (3.77)

PM10 (SD)

26.33 (4.7)

24.09 (5.7)

27.59 (4.8)

27.45 (5.2)

22.83 (3.6)

21.16 (3.7)

24.57 (3.7)

19.3 (4.1)

24.16 (2.96)

NO2 (SD)

10.75 (5.3)

9.49 (5.1)

10.38 (5.5)

10.27 (4.5)

9.86 (4.9)

9.83 (4.1)

10.88 (5.1)

9.73 (4.1)

10.15 (0.5)

Pomorskie

PM2.5 (SD)

21.07 (7.9)

18.21 (10)

21.97 (8.8)

17.88 (7.5)

17.05 (8.7)

17.46 (9.1)

19.07 (6.8)

13.47 (6.1)

18.29 (2.61)

PM10 (SD)

24.45 (7.2)

22.19 (6.9)

27.22 (7.4)

23.36 (6.3)

23.44 (7.8)

21.18 (4.3)

26.34 (5.2)

21.26 (4.2)

23.69 (2.21)

NO2 (SD)

15.58 (5.2)

14.51 (4.7)

14.38 (5)

13.75 (4.5)

13.75 (4.4)

13.57 (4.3)

15.1 (4.5)

13.33 (4.2)

14.25 (0.8)

Slaskie

PM2.5 (SD)

33.36 (2.2)

31.69 (1.9)

31.04 (3.7)

27.65 (2.3)

27.91 (5.1)

29.48 (3.5)

29.86 (2.5)

23.51 (3.1)

29.31 (3.03)

PM10 (SD)

47.58 (5.7)

43.14 (4)

43.48 (5.8)

40.3 (4.5)

38.92 (5.5)

40.75 (4.6)

40.66 (4.9)

33.38 (5.3)

41.03 (4.09)

NO2 (SD)

25.18 (9)

24.49 (8.9)

23.54 (10.9)

24.47 (11.8)

23 (11.2)

24.04 (11.1)

24.36 (11.1)

22.89 (11.4)

24 (0.81)

Swieto- krzyskie

PM2.5 (SD)

29.83 (7.3)

25.96 (4.4)

25.73 (4.1)

22.94 (3)

21.29 (2.8)

23.3 (4.6)

24.1 (5.2)

18.79 (2.1)

23.99 (3.31)

PM10 (SD)

36.16 (8.7)

31.61 (5.7)

33.1 (6.4)

31.79 (5.6)

29.27 (4.3)

32.57 (5.7)

33.13 (5.6)

26.96 (3.9)

31.84 (2.74)

NO2 (SD)

23.09 (6.8)

16.93 (5.2)

13.75 (5.5)

18.06 (6)

16.7 (5.1)

13.6 (5.8)

15.78 (7.6)

16.74 (6)

16.83 (2.98)

Warminsko-mazurskie

PM2.5 (SD)

17.09 (5.4)

15.63 (3.7)

16.9 (3.4)

16.29 (2.7)

15.01 (5.4)

16.26 (3.3)

17.71 (3.4)

13.83 (4)

16.09 (1.26)

PM10 (SD)

22.7 (7)

22.7 (5.5)

24.24 (6)

24.13 (5.6)

24.99 (4.5)

24.7 (4.5)

26.99 (5.3)

19.71 (3.6)

23.76 (2.14)

NO2 (SD)

10.63 (5.5)

10.78 (6.4)

11.08 (6.1)

10.46 (7)

10.94 (6)

11.07 (5.1)

11.41 (4.8)

9.1 (5.7)

10.69 (0.7)

Wielko- polskie

PM2.5 (SD)

28.42 (7)

25.97 (6.8)

27.25 (5.7)

26.51 (6.7)

26.85 (5.9)

25.28 (4)

23.75 (3.6)

20.76 (3.7)

25.61 (2.37)

PM10 (SD)

32.72 (4.8)

30.94 (6)

34.34 (5.4)

32.04 (4.9)

31.02 (4.7)

29.59 (4.2)

30.86 (3.9)

26.56 (3.2)

31 (2.27)

NO2 (SD)

15.47 (6.1)

15.07 (11.1)

16.05 (10.9)

16.67 (7.1)

16.82 (9.6)

15.82 (8.9)

16.81 (8.7)

15.62 (4.8)

16.05 (0.66)

Zachodniopomorskie

PM2.5 (SD)

15.87 (3.7)

15.15 (6)

19.76 (3)

16.29 (2.7)

16.36 (3.2)

17.27 (2.7)

18.28 (2.3)

14.53 (1.9)

16.71 (1.71)

PM10 (SD)

24.3 (6.3)

23.9 (7.3)

26.87 (4.1)

23.9 (4.1)

23.36 (3.4)

23.6 (3.3)

25.52 (2.3)

20.78 (1.8)

24.04 (1.75)

NO2 (SD)

17.71 (11.7)

18.82 (11.6)

18.63 (11.3)

17.68 (7.4)

18.64 (10)

16.17 (9.3)

17.8 (9.1)

13.74 (8.1)

17.39 (1.7)

Figure 4. Effect of air pollution on hospital admissions due to heart failure in 20122019 in Poland. The data are aggregated to 16 voivodeships of Poland and presented as semi-elasticity with 95% confidence intervals

As our study demonstrated, a risk factor that significantly increases the number of HF-related hospitalizations is the number of vehicles per 1000 inhabitants. Air pollution is a well-established trigger for CVD incidence. Interestingly enough, vehicle exhaust is not the only source of car smog, as is commonly believed. The contribution of tire, brake, and road deposits to overall particle emission increases each year and has become a real problem [28]. Shah et al. [29] in their meta-analysis suggest that air pollutants, such as PMs, carbon monoxide, sulfur dioxide, and NO2, have a harmful impact on the circulatory system and increase morbidity and mortality due to HF. Another recent systematic review based on robust evidence indicates that chronic exposure to the abovementioned air pollutants has a negative impact on cardiovascular morbidity and mortality [30]. More recent studies seem to agree with the aforementioned systemic review [31, 32]. Moreover, an experimental study designed by Phipps et al. [33] showed that exposure to traffic-generated smog might cause increased activity of the renin-angiotensin system leading to CVD and obesity. In light of this information, we believe that implementing transport infrastructure layouts and transport policies that mitigate air pollution should become a top priority. For the time being, patients, especially those from a high-risk group, need to take preventive measures.

When analyzing the role of healthcare structure in the treatment of HF, it is impossible to ignore the importance of palliative care (PC) and its impact on patients’ life. In Poland, only 1.5% of patients with reported PC contact were referred due to CVD in 2019 [34]. Sobański et al. emphasize the role of PC in pain and depression management in patients with HF, which contributes not only to improvement in quality of life but also to a better prognosis and reduced readmission rate in patients with HF [36, 37].

Our article shows that in the group of economic and sociological factors, unemployment rate and agriculture share were found to be significant in affecting HF-related hospitalizations. The unemployment rate broadly characterizes the poverty level of the selected studied regions. Its high value is closely related to the occurrence of more diseases in the area [38]. The number of people employed in agriculture sheds light on the characteristics of the economic structure and specialization. Rural areas are often poorer, and thus access to health facilities is more difficult [39].

The only purely sociodemographic factor in this group is the working-age population. This indicator is directly related to the age dependency ratio and the problem of an aging population. Areas with a low working-age population tend to be less efficient due to limited human capital value. Research confirms that working-age population share and reduction in the number of depended children are associated with an increase in GDP per capita, with similarly positive effects on poverty reduction [40].

Considering all factors, public health policies should focus also on urban planning interventions to increase green spaces, reduce traffic-related air pollution, and on the sustainable development of the country.

Limitations

There are several limitations to our study. First of all, our research does not take into account some of the most common medical factors affecting the frequency of hospitalization for HF Secondly, we were unable to assess individual exposure of patients to environmental factors since we had no information on the exact residence of patients. We could not separate analyzed hospitalizations into those caused by HF de novo and acute decompensated HF. In our study, we analyzed the 20122019 period. It would certainly be very interesting to assess the impact of the COVID-19 pandemic on this issue, as some studies show that the SARS-CoV-2 virus increased the risk of myocarditis, acute and chronic HF. However, there is no data on HF-related hospitalizations in Poland in 20202022 yet [41, 42].

Conclusions

The number of HF-related hospitalizations has been increasing in the last decade. This trend is most noticeable in regions with low socioeconomic development and poor medical facilities. Our study indicates that health policy measures including environmental and socioeconomic instruments may result in positive health outcomes. Additional analyzes are needed to compare the impact of socioeconomic and environmental factors against the impact of healthcare alone.

Article information

Conflict of interest: None declared.

Funding: The study was financed from the funds of the National Science Center granted under contract number UMO-2021/41/B/NZ7/03716.

Open access: This article is available in open access under Creative Common Attribution-Non-Commercial-No Derivatives 4.0 International (CC BY-NC-ND 4.0) license, which allows downloading and sharing articles with others as long as they credit the authors and the publisher, but without permission to change them in any way or use them commercially. For commercial use, please contact the journal office at kardiologiapolska@ptkardio.pl.

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Polish Heart Journal (Kardiologia Polska)