Abstract
Spatial analysis can help measure the spatial accessibility of health services with a view to improving the allocation of health care resources. The objective of this study was to analyze the spatial distribution of COVID-19 detection rates and health care resources in Brazil’s Amazon region. We conducted an ecological study using data on COVID-19 cases and the availability of health care resources in 772 municipalities during two waves of the pandemic. Local and global Bayesian estimation were used to construct choropleth maps. Moran’s I was calculated to detect the presence of spatial dependence and Moran maps were used to identify disease clusters. In both periods, Moran’s I values indicate the presence of positive spatial autocorrelation in distributions and spatial dependence between municipalities, with only a slight difference between the two estimators. The findings also reveal that case rates were highest in the states of Amapá, Amazonas, and Roraima. The data suggest that health care resources were inefficiently allocated, with higher concentrations of ventilators and ICU beds being found in state capitals.
Key words: COVID-19; Spatial analysis; Ecological studies; Mechanical ventilators; Intensive care units
Resumo
O método de análise espacial permite mensurar a acessibilidade espacial dos serviços de saúde para alocação dos recursos de forma eficiente e eficaz. Diante disso, o objetivo deste estudo foi analisar a distribuição espacial das taxas de COVID-19 e dos recursos de saúde na Amazônia Legal. Estudo ecológico realizado com casos de COVID-19 e os recursos de saúde nos 772 municípios em dois picos da pandemia. Utilizou-se o método bayesiano global e local para elaboração de mapas coropléticos, com cálculo do índice de Moran para análise da dependência espacial e utilização do Moran map para identificação dos clusters da doença. Os índices de Moran calculados para os dois períodos demonstraram autocorrelação espacial positiva dessa distribuição e dependência espacial entre os municípios nos dois períodos, sem muita diferença entre os dois estimadores. Evidenciaram-se maiores taxas da doença nos estados do Amapá, Amazonas e Roraima. Em relação aos recursos de saúde, observou-se alocação de forma ineficiente, com maior concentração nas capitais.
Palavras-chave: COVID-19; Análise espacial; Estudos ecológicos; Ventiladores mecânicos; Unidades de terapia intensiva
Introduction
Brazil is the only country in the world with a population of over 100 million with a universal health care system1. This system, which for decades has helped reduce inequalities in access to health care, was overwhelmed during the pandemic as Brazil was among the countries hardest hit by COVID-19, leading Latin America to be declared the epicenter of the pandemic in May and June 20202.
Despite having an extensive primary care network, Brazil faced the largest health and hospital system collapse in the country’s history during the pandemic. Adult COVID-19 intensive care unit (ICU) bed occupancy rates in the country’s public health system, the Sistema Único de Saúde (SUS) or Unified Health System, in March 2021 were greater than or equal to 80% in 24 states and the Federal District, with 15 states having rates of at least 90%3.
Between 17% and 35% of non-vaccinated patients hospitalized with COVID-19 need to be admitted to an ICU, mainly due to hypoxemic respiratory failure. In addition, between 29% and 91% of COVID-19 patients who have hypoxemic respiratory failure need invasive ventilatory support4-6.
The SARS-CoV-2 virus is highly transmissible and most individuals are susceptible to infection7. The spread of the virus is a complex process influenced by demographic characteristics, population mobility, and the environment, meaning that transmissibility varies greatly between countries and regions and over time5.
Despite having a low population density, Brazil’s Amazon region in the North of the country had a high concentration of COVID-19 cases8. The Amazon is a multifaceted and socially and environmentally diverse region with populous cities intermingled with sparsely populated areas isolated from large urban centers. The region also has a large concentration of traditional and indigenous peoples living in remote rural areas, including riverine, fishing, and Quilombola communities. The Amazon is also characterized by social, economic, and health disparities, combined with rapid population and economic growth and high-income concentration, and a large proportion of the population suffer from poor living conditions9.
Manaus, capital of the state of Amazonas, was surprised by a sharp rise in the number of cases and deaths in April 202010, putting considerable pressure on the city’s health services. Geographical barriers have been used as a justification for difficulties in developing interiorized actions and providing access to the three tiers of health care across the Amazon11.
Mapping patterns in the distribution of the disease and physical health care resources can therefore help to understand the current dynamics of access to care and identify areas that are most vulnerable to the pandemic. This understanding can help support the implementation of measures to control the spread of the virus, prevent local outbreaks, and guide resource allocation, improving the accessibility of intensive care for critically ill patients. In light of the above, the aim of the present study was to analyze the spatial distribution of COVID-19 detection rates and the availability of health care resources in Brazil’s Amazon region.
Materials and methods
We conducted an ecological study using data on the distribution of COVID-19 detection rates and health care resources (COVID-19 ICU beds and mechanical ventilators) in Brazil’s Amazon region.
The units of analysis were the 772 municipalities in the Amazon region, which is made up of the states of Acre, Amapá, Amazonas, Mato Grosso, Pará, Rondônia, Roraima, Tocantins and part of Maranhão. The Amazon covers an area of 5,015,067.75 km² (58.9% of the country) and population density is low across most of the region12.
We used data on cases of COVID-19 detected during the period 25 February 2020 (date of the first recorded case) to 31 March 2021, considering the cumulative total of cases up to July 2020 and up to March 2021. These periods were chosen because they include two peaks of the pandemic in Brazil, as can be seen on the graph of cases per epidemiological week on the World Health Organisation’s website13.
The number of COVID-19 cases per municipality of residence was extracted from the Ministry of Health coronavirus platform on 10 April 202114. These data are constantly updated and corrected. In this regard, the municipality where the cases is notified is not always the same as the municipality of residence, with the latter being corrected after the completion of the investigation process. A total of 1,860,217 cases were recorded during the study period, including 559,349 up to the first peak in July 2020.
To calculate the municipal case detection rates, we used 2020 population estimates published by the Brazilian Institute of Geography and Statistics15.
We calculated cumulative crude municipal case detection rates (number of cases divided by total population multiplied by 100,000) and smoothed rates using the global Bayesian estimator, which calculates the weighted average between the local and regional rate, and local Bayesian estimator, which considers the spatial effects of estimates in neighboring municipalities16.
The estimators reduce random rate fluctuations and can indicate priority areas for health actions (where rates are more pronounced even after smoothing) and, in the case of the local Bayesian estimator, take into account trends in neighboring areas. For the local Bayesian estimator, we considered first-order neighbors, i.e. only immediate neighbors. Choropleth maps were created to visualize the distribution of rates, graduating values using natural breaks.
Moran’s I was calculated to determine the spatial dependence in the distribution of the global and local Bayesian rates. The index ranges between -1 and +1, with positive values indicating spatial dependence and negative values indicating negative spatial correlation. Values close to 0 indicate no spatial autocorrelation. A neighborhood contiguity matrix was created adopting a 5% significance level.
A Moran scatter plot of the detection coefficient calculated using the local Bayesian estimator was used to determine spatial patterns. A Moran map was used to identify statistically significant clusters of areas with high values with neighbors with high values (Q1 - high-high pattern), areas with low values with neighbors with low values (Q2 - low-low pattern), and transition areas (Q3 - high-low pattern and Q4 - low-high pattern).
The data on mechanical ventilators and COVID-19 ICU beds were collected from the National Register of Health Establishments (CNES)17. The number of beds and mechanical ventilators was represented using proportional circles placed over the municipality’s administrative center. This information was superimposed over the Moran map to compare numbers with case clusters.
Data processing, georeferencing, spatial analysis, and mapping were performed using Excel 2013, GeoDa 1.18.0, and QGIS 3.18.1. Pearson’s chi-squared test was used to determine the correlation between variables in the two waves adopting a 95% confidence level. Pearson’s chi-squared test and the descriptive analyses were performed using SPSS.
The study did not require ethical approval as it was conducted using secondary data available in the public domain.
Results
The total number of COVID-19 cases/100,000 population rose from 1.99 during the first wave (up to 31 July 2020) to 6.62 cases/100,000 population in the second wave (up to 31 March 2021). Table 1 shows the data for the first and second wave.
Local and global Moran’s I were 0.44 (p = 0.001) and 0.43 (p = 0.001) during the first wave and 0.46 (p = 0.001) and 0.45 (p = 0.001) in the second. The values indicate that the distribution displays positive spatial autocorrelation and spatial dependence between municipalities in both periods, with only a slight difference between the two estimators.
Figures 1 and 2 present the distribution of the cumulative crude COVID-19 detection rates and smoothed rates for both periods. The maps show that there was only a slight variation between crude and smoothed rates in both waves.
In the first wave, the municipalities with a detection coefficient of more than 3,000 cases/100,000 population were concentrated in the state of Amapá, the northwest and mid-south of Amazonas, and the east and south and sparsely populated areas of Pará. The lowest detection rates (less than 1,000 cases/100,000 population) occurred mainly in Mato Grosso, Tocantins, the west of Rondônia, and the north and southeast of Pará (Figure 1). The only municipality not to have recorded cases of the disease was Mateiros in Tocantins.
The cumulative detection rate rose sharply in the second wave. The highest crude detection rates (more than 8,000 cases/100,000 population) were concentrated in Amapá, the south and northeast of Pará, and the north and southeast of Amazonas, while the lowest detection rates (less than 4,000 cases/100,000 population) were found in Maranhão and the northeast of Pará. All municipalities recorded cases of the disease in this period (Figure 2).
Figure 3 shows the distribution of mechanical ventilators superimposed over the Moran map of the smoothed rates in the first and second waves, revealing that ventilators were concentrated in state capitals in both periods.
Moran map of municipal COVID-19 case detection coefficients and distribution of the number of mechanical ventilators in the Amazon region, Brazil, 2020 and 2021.
In the first wave, although some state capitals such as Manaus (1,040), Cuiabá (847), and Belém (829) show a high concentration of ventilators, the findings show regions with statistically significant high-high patterns and a low number of ventilators. An example of this pattern is Pará, where the number of ventilators was greater in regions without high detection rates and high-high clusters (Novo Progresso/Itaituba and Parauapebas/Canaã dos Carajás) had a small number of ventilators. Various critical regions therefore had a shortage of ventilators (Figure 3) and none of the regions with a high-high pattern had a high number of available ICU beds (Figure 4).
Moran map of municipal COVID-19 case detection coefficients and distribution of number of ICU beds in the Amazon region, Brazil, 2020 and 2021.
Also with regard to the first wave, regions with a statistically significant low-low pattern were concentrated mainly in Tocantins, which had a medium number of ventilators and ICU beds, and the northwest and northeast of Mato Grosso, which had low numbers of ventilators and ICU beds (figure 3 and 4).
In the second wave, Amazonas continued to experience high-high patterns in the north and southeast, with these patterns expanding to the southeast and northeast of the state. Case patterns and the availability of ventilators remained the same in Amapá, while the situation in Pará changed, with high-high patterns being concentrated in the southeast and northeast. In Roraima, a high-high pattern continued to be found in the south of the state and rates increased in the central region. In Acre, the municipalities Feijó, Assis Brasil and Sena Madureira showed a high-high pattern in the second wave, with only the latter having ventilators (two). In Rondônia, the region surrounding the capital Porto Velho, also showed the same pattern, but with a high concentration of ventilators and ICU (figure 3 and 4).
Low-low patterns were concentrated in the northeast of Pará and in Maranhão in the second wave, with both regions having a high concentration of ventilators and ICU beds (figures 3 and 4). It is important to highlight that ventilators and ICU beds are made available to patients living in the municipalities and in adjacent municipalities located in the same health region.
The results of Pearson’s chi-squared test showed a significant correlation between variations in COVID-19 detection rates and number of ventilators (0.267) and ICU beds (0.359) across health regions, showing a positive correlation between allocation of mechanical ventilators and ICU beds and a rise in detection rates between the two periods (p < 0.05).
Discussion
The findings show that detection rates and the number of ventilators and ICU beds increased by 332%, 14.54%, and 35%, respectively, between the two periods and the presence of spatial dependence in the distribution in both periods. Municipalities in the bordering states of Amapá, Amazonas, and Roraima had high-high patterns of detection in both periods.
The overwhelming majority of countries have not carried out enough testing to provide good quality COVID-19-related health indicators18. In Brazil, access to tests is unequal, with poorer regions such as the Amazon having lower testing capacity19.
The initial spread of COVID-19 and deaths in Brazil was not driven by population age structure and pre-existing health conditions but rather patterns of socioeconomic vulnerability20-21. The North of the country was the region with the highest vulnerability to COVID-1922, which is corroborated by the high COVID-19 detection rates in the Amazon Region and sharp increases between waves.
The spread of the virus in the state of Amazonas was driven by the proximity of regions and the macro-regional urban hierarchy, in conjunction with the presence of international ports, the Manaus Free Trade Zone, and a vast river network, which is the region’s main means of passenger and freight transport. These elements contributed to the interiorization of the spread of COVID-1923, which may explain the case distribution patterns observed in this study.
Another study reported high-high patterns in both reference periods in Amapá. At the end of May 2020, the state accounted for the third-highest percentage of overall COVID-19 cases in the North yet had the country’s highest incidence rate24. These numbers may be explained by the fact that the state borders French Guiana, which had the highest cumulative incidence rate in Latin America in November 2021, with 14,941.98 cases/100,000 population25. The relationship between cases in French Guiana and Amapá could be an interesting topic for future research.
Regarding the availability of health care resources, the findings reveal several regions with high-high patterns and low numbers of ventilators and ICU beds. Although some of the health services in municipalities in the same health region are integrated, heavy demand combined with poor geographic accessibility can result in unequal access to complex care. Our findings are corroborated by a study conducted by Bezerra et al. (2020)26, which revealed that access to healthcare across Brazil is uneven and unequal.
Another study in Brazil reported that the smoothed COVID-19 mortality rate was higher in the North region, where a greater shortage of hospital resources was observed21. In the same study, COVID-19 deaths were positively correlated with socioeconomic vulnerabilities and negatively associated with hospital resources21. Moreira (2020)27 concluded that health regions with the highest mean mortality rates were located in regions with shortages of ICU beds and mechanical ventilators.
A survey conducted in April 2020 showed that Amapá and Roraima had the lowest health care infrastructure indices. The same study reported a concentration of low-low clusters in Amazonas and Pará, suggesting weak health system capacity, especially in critical situations with heavy demand26.
Despite its size, the overwhelming majority of the state of Amazonas’ ICUs are located in the capital, Manaus, meaning that a collapse in this city’s health system reverberates across the entire state. The same can be said of Amapá and Roraima, meaning that municipalities in the region are directly dependent on the capital’s health care infrastructure.
Inequalities in access to health care in Amazonas are driven by low population densities and the state’s vast size, with huge river basins covered with tropical forest and a precarious transport network28. As a result, COVID-19 patients from remote areas experience major difficulties in getting to regional centers that provide medium- and high-complexity care services23. In addition, the increase in the number of mechanical ventilators (14.54%) and adult COVID-19 ICU beds (35%) between the first and second wave found by this study was not proportional to the rise in detection rates (332%).
The prospect of recurring COVID-19 outbreaks in Brazil is real. It is recommended that countries adjust and coordinate their COVID-19 response based on increasingly detailed data (PAHO, 2020)29. The use of georeferenced data and geographic information systems can help inform decision-making, speeding up response and improving the effectiveness of public health actions. It is therefore hoped that this study can contribute to more effective health care resource allocation that takes into account more vulnerable areas.
This study has some limitations that are inherent to ecological studies, including the fact that it is not possible to determine the relationship between exposure and outcome at individual level. In addition, testing in Brazil is performed mainly on symptomatic people, meaning that underreporting is possible, especially given low testing rates in remote areas and among vulnerable communities where access to health services and information is poor. Case incidence data should therefore be treated with caution. Although data are updated daily, gaps in information may occur as local and state health departments have the autonomy to correct information on the place of residence after the investigation of the notification. In addition, created for epidemiological surveillance purposes, the federal government information system was updated on various occasions during the pandemic and the information was inputted by people who were not involved in the study, meaning that the data are subject to error. Despite the above, our findings provide important insights into the distribution of COVID-19 cases during the two waves.
Conclusion
Our findings indicate the presence of positive spatial autocorrelation in the distributions of COVID-19 cases and spatial dependence between municipalities in both periods. The results also reveal that case rates were highest in the states of Amapá, Amazonas, and Roraima. In addition, the data indicate that health care resources were inefficiently allocated, with higher concentrations of ventilators and ICU beds being found in state capitals.
Spatial analysis allowed us to measure the spatial accessibility of health services, providing important inputs to inform public policies and help promote the efficient and effective allocation of health care resources.
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Publication Dates
-
Publication in this collection
06 Jan 2023 -
Date of issue
Jan 2023
History
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Received
30 Mar 2022 -
Accepted
05 Aug 2022 -
Published
07 Aug 2022