key: cord-0723082-nyccdahw authors: Franch-Pardo, Ivan; Napoletano, Brian M.; Rosete-Verges, Fernando; Billa, Lawal title: Spatial analysis and GIS in the study of COVID-19. A review date: 2020-10-15 journal: Sci Total Environ DOI: 10.1016/j.scitotenv.2020.140033 sha: 58bb53128f1760c6d725c8980cb36d1950d57cf0 doc_id: 723082 cord_uid: nyccdahw This study entailed a review of 63 scientific articles on geospatial and spatial-statistical analysis of the geographical dimension of the 2019 coronavirus disease (COVID-19) pandemic. The diversity of themes identified in this paper can be grouped into the following categories of disease mapping: spatiotemporal analysis, health and social geography, environmental variables, data mining, and web-based mapping. Understanding the spatiotemporal dynamics of COVID-19 is essential for its mitigation, as it helps to clarify the extent and impact of the pandemic and can aid decision making, planning and community action. Health geography highlights the interaction of public health officials, affected actors and first responders to improve estimations of disease propagation and likelihoods of new outbreaks. Attempts at interdisciplinary correlation examine health policy interventions for the siting of health/sanitary services and controls, mapping/tracking of human movement, formulation of appropriate scientific and political responses and projection of spatial diffusion and temporal trends. This review concludes that, to fight COVID-19, it is important to face the challenges from an interdisciplinary perspective, with proactive planning, international solidarity and a global perspective. This review provides useful information and insight that can support future bibliographic queries, and also serves as a resource for understanding the evolution of tools used in the management of this major global pandemic of the 21 Century. It is hoped that its findings will inspire new reflections on the COVID-19 pandemic by readers. • Data processed with GIS and spatial statistics are important to study COVID-19. • Decision making is the principle objective of COVID-19 studies with GIS. • Geographical aspects of the study of COVID-19 can be grouped into five categories. • COVID-19 requires an interdisciplinary approach with a global perspective. • Health geography has a critical perspective that can help vulnerable populations. a b s t r a c t a r t i c l e i n f o Six months have passed since Chinese authorities identified a deadly new coronavirus strain, SARS-CoV-2 (January 7, 2020); four months since the WHO declared a pandemic (March 11, 2020) . During this time, scientific papers on the 2019 coronavirus disease Science of the Total Environment 739 (2020) 140033 have been numerous, addressing global awareness (primarily at national levels) and covering a significant range of disciplines including medicine, mathematics and social sciences. Among these disciplines, this paper focuses on the geographical dimensions of the disease. This thematic aspect of COVID-19 requires analysis that adopts an interdisciplinary approach, and geography is one of the few disciplines that purports to offer a synthetic approach to the interplay between the biophysical and human variables (Turner, 2002) , by approaching the environment from a holistic perspective with a focus on the forms and processes that concur in a geographical space (Sauer, 1925) . Other disciplines define the physical, historical and social characteristics and processes, but geography situates these in a spatial, territorial, locational and landscape perspective (Pattison, 1964) . The complex reality of the environment-society dialectic (sensu Schnaiberg and Gould, 1994) must be understood in the context of the integrative approach of geography. Medical geography specializes in the application of concepts, methods and quantitative techniques to address spatial issues in disease and medicine (Meade, 2014) . Within this, health geography focuses geographical concepts and categories on the population and demographic aspects concerning health. According to Kearns and Moon (2002) , health geography has a predominantly utilitarian perspective and analyses the territory technically, although it incorporates structuralist approaches, such as cultural and sociological vision of social welfare, a sense of 'place' for people, and a critical stance. The COVID-19 pandemic is full of unknowns, and many of them have a spatial dimension that lead to understanding the phenomenon as geographical and potentially mappable. Thus from health science, the research needs include the ability to cross variables of different kinds to interpret the COVID-19 phenomenon, its spatial analysis and spatiotemporal dimensions, its geographical impact on decision-making and everyday life, and predictive modelling of the evolution of the disease. For these reasons, the use of geospatial and statistical tools has become particularly relevant with the declaration of COVID-19 as a global pandemic. The aim of this study is to review the implementation of geographical and geo-spatial analysis in understanding locations and the distribution patterns of COVID-19. The study seeks to highlight current geospatial-analytical methods in the interpretation of the environmental effects and consequences of COVID-19, to understand its sociodemographic implications and role of big data mining and web based spatial analysis and representation. The review summarizes studies and research on COVID-19 phenomena in the context of geography. It can also be a useful resource in understanding the geographical consequences and effectiveness of the containment of the disease. There are already various reviews on COVID-19, but they have not approached the issue from a geographical perspective. Tobaiqy et al. (2020) discussed the different therapies used in COVID-19 patients, while the use of artificial intelligence and big data to study and mitigate effects of the virus was discussed by Pham et al., 2020 , and systematisation of ongoing data science activities in this area was done by Latif et al. (2020) . The review here of different works dealing with geographical phenomena of COVID-19 should inspire new reflections for the readers, and help connect between themes and tools. We have reviewed 63 scientific articles found in the Google Scholar, Scopus, ScienceDirect and PubMed search engines, and by following the references in the works we read. The keywords we used to find these articles were 'COVID-19', 'coronavirus' (limited to 2020) or 'SARS-CoV-2', together with different conjugations of the words 'GIS', 'spatiotemporal', 'spatial analysis', 'geospatial', 'geography', 'map' and 'mapping'. The time interval dates from 27 January 2020 (first identified spatial study) to 1 May 2020 (date of the last study reviewed prior to writing and sending this paper for review). Based on the authors' experience and understanding of geographical phenomena and processes, the articles were evaluated in terms of their depth of analysis, leaving aside those that only provided a simple representation of certain details in the form of a map and did not offer relevant contributions in the field of spatial analysis. The review does not include works that take on the spatial dimension abstractly and whose spatial analysis are conceptual. In this, Wallace's (2020) lead is followed in avoiding empiricism while emphasizing a degree of analytical and empirical vigour-Thus it is important to recognise that not all the vital information necessary to address the outbreak can be readily quantified and mapped. The temporal variable, although not always central, was also present in most of the work reviewed. Research papers were categorized into five general groups and summarized in terms of the most substantial works on themes developed, significant methodologies, and the most relevant results. The first group, of spatiotemporal analysis and disease mapping, refers to studies of the temporal pattern of the COVID-19 phenomenon together with its geographical expansion. After discussing this, we describe the other categories we posited based on the major themes covered: health and social geography, environmental variables, data mining, and web-based mapping. This grouping, derived from the main themes of the papers that we reviewed, integrates all the different studies and adequately summarizes the topics covered, although some works fall into more than one category (Table 1) . One of the most important properties of epidemics is their spatial spread, "a characteristic which mainly depends on the epidemic mechanism, human mobility and control strategy" (Gross et al., 2020: 2) . We can use GIS and spatial statistics to respond to this, and also to help mitigate the epidemic through scientific information, find spatial correlations with other variables, and identify transmission dynamics (Xiong et al., 2020) . One of the first works, as well as one of the most cited, that makes use of GIS for the spatial analysis of COVID-19 is that of Guan et al. (2020) . They extracted data on 1099 patients with laboratory-confirmed COVID-19 cases from Chinese hospitals until January 29, 2020, and proceeded to characterize the profile of the average patient: mean age, gender, symptoms and their spatiotemporal characteristics-i.e., identification of the rapid spread of the disease throughout mainland China, distribution of patients by province, characteristics between residents of Wuhan and non-residents, history of direct contact with wildlife and non-residents of Wuhan who visited the city or who had contact with citizens there (72.3%). The work is important because the early date of its publication (February 28) allowed the clinical characteristics of the affected patients to be more precisely defined. Also in China, around the same time, Chen et al. (2020b) , using a Bayesian spatial-temporal model, determined the distribution of COVID-19 cases and their correlation with the migration of the Wuhan population in the early stages of the epidemic, which is of great importance for early warning and prevention of future outbreaks. Huang et al. (2020) , weeks later (COVID-19 moves very fast, while the onset of symptoms are delayed by an average of two weeks, allowing many things happen in a short time), analysed the epidemiological characteristics of COVID-19, the control measures taken, their effects with respect to the pandemic, and its spatiotemporal distribution. One enotable result was the identification of a significant number of people who entered Wenzhou from Hubei Province, which explains why this city was the first outside the epicentre where confinement was adopted. These first geographic analyses also mapped the information to more precise administrative levels (counties, provinces), something that was to be reproduced in other countries such as the USA (Dong et al., 2020) , Iran (Arab-Mazar et al., 2020) , later South Korea (Rezaei et al., 2020) , Brazil (Dagnino et al., 2020) , Israel (Rossman et al., 2020) , Italy (Giuliani et al., 2020) , Spain (Orea and Álvarez, 2020), Table 1 Grouping of reviewed studies by geospatial theme, date of first publication, country or region studied, provenance of the information used and brief description. Argentina (Buzai, 2020) , Mexico (Santana Juárez, 2020), India (Saha et al., 2020) and Pakistan (Sarwar et al., 2020) . Returning to the spatiotemporal analyses carried out in China, Gross et al. (2020) agree that the spread of the disease originated in the Hubei migration prior to confinements. With more information on the dynamics of the virus, in this work they drew imaginary lines connecting vertices representing the epicentres of the virus, specific provinces, cities and locations scattered around the world. The distances and the intensities of the epicentres are very irregular; the virus propagation adopts the flight of Levy, a tendency to fractal movement typical of human mobility. With pertinent mathematics, future scenarios could be modelled. In the work of Zhang et al. (2020) , an attempt was made to determine whether the pattern of spatial-temporal behaviour is related to SARS 2003, and came up with negative results owing to changes in social Online questionnaire aimed at the geographical identification of possible symptoms Gao et al. (2020) 4/9 USA Data mining Mobility pattern analysis using mobile data at the county level. Web cartographic viewer and demographic factors, local government containment strategies, and differences in the dynamics of transmission between these two coronaviruses. Later, Tang et al. (2020) analysed the changing patterns in the different geographical areas of the country, with the temporal evolution of the COVID-19 epidemic. They used Poisson's segmented model and attempt to provide further explanations for what is happening in real time. Su et al. (2020) combined efforts to understand the transmission dynamics, focusing on the main Chinese metropolitan areas. They used the reported data of infected people in a time interval, plus the daily travel intensity index with Baidu Maps data for those dates, in order to calibrate the level of restrictions and estimate the proportion of the population in quarantine. It is a study based on the Chinese experience, but its purpose is to help large urban agglomerations in other regions of the world that have to go through the same thing. In Israel, an online questionnaire was carried out to identify possible symptoms and, with this, to follow up with infected persons over time (Rossman et al., 2020: 3) . In the interpretation of the data, differences in the proportion of reported symptoms in participants from different cities and different neighbourhoods that are geographically close to each other are revealed, which could suggest the ability to detect changes at a high geographical resolution. The GIS analyses carried out in the USA, where containment efforts have been belated and relatively lax (in comparison with China, South Korea, and Taiwan), have very diverse themes, as we will see throughout the other sections. Desjardins et al. (2020) used prospective space-time statistics to identify active and emerging COVID-19 groups at the county level. The prospective approach is an important surveillance tool for controlling disease outbreaks as they develop (Kulldorff and Kleinman, 2015 cited in Desjardins et al., 2020) and its main strength is the ability to add updated COVID-19 counts and re-execute the statistics to identify new emerging groups. It also tracks previously detected groups to determine whether they are growing or shrinking in magnitude. Doing so can help determine whether current mitigation and isolation techniques are effective in slowing the spread of COVID-19, and suggests that they could be used more widely in public health departments. In other works, such as that of Gao et al. (2020) , the daily evolution of human mobility in US counties was mapped, allowing monitoring of changes in population trends based on the different measures adopted by respective governments. Likewise, in the web map viewer of Dong et al. (2020) , the figures for the number of people infected and killed by COVID-19 are shown at a national level, but for the USA the information is available at a county level. In Spain, one month after the declaration of a national emergency and mandatory confinement, Orea and Álvarez (2020) analysed by province the effectiveness of these measures with respect to the spread of the pandemic. The result is favourable, with the emphasis on those provinces that are closest to the main epicentres of the COVID-19, where the state of emergency seems to have allowed the vicious circle of contagion to be broken. Also at the provincial level, but in Italy, Giuliani et al. (2020) modelled the spatial-temporal dynamics of COVID-19 contagion and victims. As in Spain, the local distribution is very heterogeneous. Its main foci are in the north, but it has been progressively infiltrating the southern provinces. There is strong evidence that the strict control measures implemented in some provinces effectively break the cycles of infection and limit the spread to nearby areas. They also mention that planning to contain the spread of COVID-19 must take into account the peculiarities of local territories, but there must also be control measures at the national level to avoid delaying or losing control of the disease's spread as a whole. For Pakistan, Sarwar et al. (2020) are developing an open and userfriendly GIS to detect, collect and analyse outbreak data in the country. In addition to the uses mentioned in the other papers referred to, GIS Pakistan can be useful for accurate spatial segmentation (larger scale of detail) of areas at epidemic risk and appropriate level of prevention, assessment of population flow and distribution, concerns about the adequacy of health services and constant monitoring of information. They encourage public authorities to use this tool to locate the most affected regions and take appropriate action. The works of De Kadt et al. (2020) and Gibson and Rush (2020) in South Africa explore the challenges of establishing health control measures in developing countries where there are entire neighbourhoods in extreme poverty. De Kadt et al. (2020) produced two maps for the city of Gauteng. One is the risk factor index for maintaining social distance and preventive hygiene, which is not as feasible for all people in all communities (Gibson and Rush, 2020) . Thus, they compile six risk factors that can be considered impediments to achieving basic hygiene and social distancing: crowded living conditions; sharing of water and sanitation services; dependence on public health services; limited access to communication tools; and dependence on public transport. The second map is the index of risk factors that increase social and health vulnerability during an outbreak or wider quarantine. This map responds to the concern about how the social distancing measures taken by the South African government and its reaction to an outbreak will impact poorer communities. Gibson and Rush (2020) , following their GIS study, state that social distancing is unfeasible (apart from enclosure) in certain informal settlements of the more than 146,000 households located in Cape Town, which are densely populated, with houses in close proximity to each other, and with a severe lack of sanitation infrastructure. Here the intrinsic link between widespread poverty and disease susceptibility faced by communities in the Global South, and thus the need to address the structural drivers of this poverty in the global political-economy, becomes apparent (Davis, 2020; Zeilig and Cross, 2020) . In Ghana, a malaria-endemic country, Kuupiel et al. (2020) tested the geographical accessibility of inhabitants to Point of Care (POC) tests for Glucose-6-Phosphate Dehydrogenase (G6PD) deficiency. Specifically in their upper east region, they identify 100 Rural Primary Health and the health centres where G6PD tests are provided. Considering the spatial distribution of the population and other means of public transport, plus topographic determining factors (relief, road network, rivers), they used near function analysis tools to measure which areas and how much of the population have good geographic access to these services and which ones have shortcomings. According to the authors, this information is very relevant for the treatment of COVID-19 because there are a number of antimalarial drugs that, reportedly, are useful in its treatment (Gao et al. 2020 , cited in Kuupiel et al., 2020 . On a global scale, Padula and Davidson (2020) related the concentration of nurses (more than half the world's healthcare workers) to the mortality of COVID-19 by country. The paper shows an association between high numbers of nurses and reduced mortality rates of COVID-19. The key to addressing current and future outbreaks of COVID-19, or for that matter, any infectious disease outbreak of this magnitude, is to prepare a versatile and highly skilled nursing workforce. In the USA, Jella et al. (2020) identified the geographical distribution of orthopaedic surgeons aged 65 years or more (age-group considered more vulnerable to the disease) to compare their distribution with other specialties and with those diagnosed with COVID-19. The objective was to determine the potential risk of orthopaedic surgeons during the pandemic of COVID-19. From their results, they highlight that the highest numbers occur in the states most severely affected by COVID-19: New York, New Jersey, California and Florida. Lakhani (2020a) carried out a spatial analysis of the Australian city of Melbourne, at a time of extraordinary vigilance over older people The city was spatially analysed to identify the areas that offer the greatest difficulties in accessing health services, where populations over 65 years of age are concentrated and which require medical assistance at home and, finally, the location of hospitals and pharmacies. This type of study is proposed for other issues related to COVID-19, such as studying how rural areas in different countries are being managed (Lakhani, 2020b) , especially when they are located in remote conditions (Bocco, 2016) . Allcott et al. (2020) analysed the relationship between the governing political party in each US county, social behaviour with respect to containment measures, and confirmed cases of COVID-19. Large partisan gaps in social distancing behaviour were revealed. There is a strong correlation between counties with weaker social distancing responses and those with higher percentages of Republican voters. Stronger social distancing responses are also observed in counties with more COVID-19 confirmed cases. From the discussion, it appears that messages from political leaders and the media about the severity of COVID-19 could substantially affect North Americans' responses to the pandemic. Also in the USA, Kuchler et al. (2020) studied the correlation between Facebook friendships and COVID-19 cases in two administrative entities heavily hit by COVID-19: an American county (Westchester County, NY) and an Italian municipality (Lodi, Lombardy). They were looking to see if the Facebook friendship links of these two points with other cities have a correlation with COVID-19 infections, assuming that such friendship indicates a higher probability of physical interaction. The results indicate that a social connectivity index can help epidemiologists predict the spread of communicable diseases. Remote sensing tools are very useful for the spatial study of diseases. In addition to the atmospheric information obtained by satellites (as we see in the next section), vegetation, sea surface characteristics and changes in land cover can influence the spread of diseases. Recently, Minetto et al. (2020) measured changes in economic activity since containment measures were adopted in different parts of the world (Munich, Phoenix, Moscow, Wuhan, North Korea). They used recent and pre-COVID-19 satellite images to identify the change in vehicle volume at regular points, ship traffic at ports, and aircraft at gates. Coccia (2020) analysed the geo-environmental and demographic characteristics of 55 Italian cities and their relationships with the dynamics of COVID-19. The study identified, for each city, its distance from the sea, latitude, population density, air pollution levels (PM10 or ozone), climatic variables of these months (average temperature, relative humidity, predominant wind speed, rainy and foggy days), and spatial-temporal characteristics of COVID-19 and of infected people. The work found a probable association between the accelerated diffusion of COVID-19 and high air pollution, specific meteorological conditions (e.g. low wind speed) and the cities farthest from the sea. The author appeals to environmental and sustainability sciences to prevent future epidemics. Oto-Peralías (2020), in Spanish provinces, used geographical variables (latitude, longitude, average temperature and rainfall for the months under study, average altitude and amplitude, insularity, coastal province, distance from Madrid-the Spanish epicentre) and socioeconomic variables (GDP, population and age groups, density, urban agglomerations, labour sector, flights, pollution) to explain the large disparity of infected people (by number of inhabitants) between the provinces and tried to determine if there is an indicator that could be correlated. He found interesting correlations with temperature and distance from Madrid. The observed temperature correlation contradicts hopes that the summer heat will stop the coronavirus, even if it minimizes its transmission efficiency. Mollalo et al. (2020) , for the USA, used 35 explanatory factors, of socio-economic (average income, inequality, unemployment, insurance, etc.), behavioural (smoking), environmental (road density, pollutants, air quality, temperature, precipitation), topographical (altitude, altitudinal range, slope) and demographic (over 65 years, race, sex, number of doctors and nurses, hospitals) attributes. These variables were processed using a family of spatial regression and autoregressive models. The authors conclude that environmental factors are not shown to have a substantial influence on the incidence of COVID-19, as is the case in other studies (e.g. Ma et al., 2020) . However, a combination of four variables-average household income, income inequality, percentage of nurse practitioners, and percentage of black womencould explain a relatively high variability in disease incidence in the continental United States. The first projection of the global dispersion of COVID-19 was proposed by Bogoch et al. (2020) in January 2020 from air passenger transport, who identified Thailand, Taiwan, Japan and South Korea as the main sources of dispersion. Additionally, taking into account previous studies conducted to predict the spread of influenza (Viboud et al., 2006; Lowen et al., 2007; Tamerius et al., 2011; Lowen et al., 2018) and SARS-CoV (Tan et al., 2005; Casanova et al., 2010; Chan et al., 2011) from climate variables, two publications attempting to predict the potential spread of COVID-19 appeared in early March 2020. One of them, with a global scope, considered the temperature at two meters above the surface, relative humidity, specific humidity and absolute humidity (Sajadi et al., 2020) , and the other, with a national scope, using data from the 100 Chinese cities with more than 40 cases recorded in January, used air temperature and humidity . Sajadi et al. found very different results to those reported by Bogoch et al. (2020) , since they identified that between March and April the main areas at risk of virus dispersion were Manchuria, Central Asia, the Caucasus, Eastern Europe, Central Europe, the British Isles, the northeast and middle east of the USA, and British Columbia (Sajadi et al., 2020) , a result that agrees somewhat with the main areas of expansion of the virus at an international level. Wang et al. found that high temperatures and high relative humidity seemed to reduce the transmission of the virus, consistent with similar behaviour reported for influenza transmission . In late March, another paper appeared that explored the association between deaths from COVID-19 and daytime temperature ranges and relative humidity in Wuhan, the epicentre of the pandemic . This paper was the first to link recorded deaths to climate factors. These three articles have marked different geographical approaches to investigate the potential for distribution or affectation of the virus using climatic factors at the global, regional/national and local levels. During the month of April, several works appeared analysing this relationship between climatic factors and the virus's dispersion potential, which can be grouped into three geographical approaches: global (Hasan and Mahfujul Haque, 2020; Bariotakis et al., 2020) , regional/national De Ángel Solá et al., 2020; Ahmadi et al., 2020a; Ahmadi et al., 2020b; Qi et al., 2020; Gupta et al., 2020) and local (Bashir et al., 2020; Tosepu et al., 2020) . Geospatial big data refers to spatial data sets exceeding the capacity of current computing systems (Lee and Kang, 2015) . Having information on human mobility patterns from mobile phones, or the registration of global flight networks, is fundamental to epidemiological modelling (Chen et al., 2020a; Chen et al., 2020b; Buckee et al., 2020) . Using big data, researchers can attempt to quantify the scale of an event before it has occurred, thereby facilitating appropriate and timely policies, at least for authorities willing to act on the data provided. Such studies could help us to understand a pandemic's behaviour in terms of outbreak tracking, disease treatment and future vaccine manufacture and distribution (Pham et al., 2020) . In the case of COVID-19, the disease is characterized by a long incubation period, high infectivity, and difficulty in detection, which has contributed to the rapid outbreak and development of the epidemic. This situation has led to calls for GIS and big data technology to enable rapid responses and analysis, rapid provision of information on the dynamics of the epidemic and an understanding of the rules of its development to provide timely support for prevention and control decisions and interventions . In the case of China, point out that GIS has played a key role by rapidly aggregating big data from multiple sources, quickly visualizing epidemic information, spatially tracking confirmed cases, predicting regional transmission, spatially segregating epidemic risk and level of prevention, balancing and managing supply and demand for material resources and socio-emotional guidance and elimination of panic, which provided strong spatial information support for decision making, formulating measures and evaluating the effectiveness of prevention and control of COVID-19 cases. In relation to applied cases for COVID-19, Chan et al. (2020) used the worldwide data that Google provided with (anonymous) mobility reports of its users describing the changes in mobility for various geographies in different types of locations, including shopping and recreation, supermarkets, shops and pharmacies, parks, transit stations, workplaces and private residences. They propose to offer this information to the scientific community for future research. , using data from Chinese public institutions, analysed the spatial representation of the disease, material, population and social psychology on three scales: individual (spatial monitoring of the epidemic and spatial-temporal mobility of those infected), group (population flow and spatial distribution) and regional (spatial risk segmentation, geographical supply and demand for medical resources). The article highlights its innovative process for data acquisition through big data technology feeding into GIS. For the USA, Warren and Skillman (2020) and Gao et al. (2020) used anonymous data on mobile device locations to measure population mobility by day. The resulting geospatial statistics were used to predict levels of disease spread and evaluate the effectiveness of health policy strategies for containment. Chen et al. (2020a) and Chen et al. (2020b) , on the other hand, developed a mathematical model that characterizes infections by state and incorporates interstate traveller inputs and outputs. The modelling reveals that stopping interstate travel when the disease is already widespread makes little difference-it is akin, to use an old English proverb, to closing the stable door after the horse has bolted. This model could also be used to determine the resources needed before state policies on social distancing can be safely lifted. Allcott et al. (2020) , as mentioned in Section 2.3, analysed the relationship between the governing party in each U.S. county, social behaviour with respect to containment measures, and confirmed cases of COVID-19. This paper used GPS data from SafeGraph, adding GPS pings from numerous mobile applications to measure pedestrian traffic patterns at a collection of points of interest: retail stores, restaurants, cinemas, hospitals, and other locations. For each point, SafeGraph reports its geographic location and the total number of visitors. Social network data is also being used to measure and understand the geographic structure of social networks (Bailey et al., 2018) . Particularly in the work of Kuchler et al. (2020) , mentioned in 2.3, the authors claim that measuring the geographic structure of social networks can be useful for epidemiologists in predicting the spread of communicable diseases, as they presented in their study in Westchester County (NY, USA), and the Lodi municipality (Lombardy, Italy). Web map viewers are playing a very important role in the dissemination and provision of (official) information on COVID-19. They are very effective for the spatial representation of the pandemic and its evolution, both for specialised and non-specialised Internet users. Boulos and Geraghty (2020) reviewed the different web mapping applications on COVID-19 available in January and February. Since then, more viewers have been created; each country has its own viewer, often with detailed information at the provincial or local level. Themes have also become more diversified, as in three cases: a map of changes in population mobility in US counties, 1 a map of information from Israeli population surveys, 2 and a map of New York City sidewalks indicating their suitability for social distancing. 3 However, the most widely referenced viewer, the one with the most international information compiled, and the first to go online out is that of Dong et al. (2020) , from John Hopkins University. 4 Numerous papers reviewed here have used their information or cited them (Ahmadi et al., 2020a; Ahmadi et al., 2020b; Buzai, 2020; Desjardins et al., 2020; Kuchler et al., 2020; Mollalo et al., 2020; Padula and Davidson, 2020; Sajadi et al., 2020a) . Several media outlets around the world also refer to this platform. Numerous subsequent national viewers, generated for their respective territorial domains, have been based on Dong et al. (2020) , following their web design and the ArcGIS online platform and its map bases. Regarding this last point, in relation to the web mapping platforms available for the visualization of geographic information, it is worth mentioning that other works used free platforms such as openstreetmap (Iacus et al., 2020; Rossman et al., 2020; Minetto et al., 2020) . The news media also are constantly using maps to present COVID-19 information to their audiences. International, national and local news organizations are developing their own personalized maps with international information, plus information corresponding to their country. Powerful media outlets mapping their information include The New York Times, 5 South China Morning Post, 6 El Pais, 7 Yomiuri shimbun, 8 Le Monde, 9 and the BBC, 10 all of which have their sections highlighted with eloquent interactive maps and graphics, and receive large numbers of daily visits. These days, a geographical axiom has been alluded to which, paradoxically, does not apply to the COVID-19 pandemic: "all objects (on the earth's surface) are related to each other, but the relationships are more intense with the closer objects than with the more distant ones" (Tobler, 1970: 236) . The falsification of this axiom indicates the need to adapt it to today's interconnected world. Already in 2015 Escolano modified the axiom as follows: "all objects (on the earth's surface) are related to each other, but the relationships are more intense among the better connected objects regardless of their proximity" (Escolano, 2015: 51) . For the current case of COVID-19, Kost (2020) states that "everything is related to everything else, and mobility compresses spatial things" (Kost, 2020: 9) , or, in the words of Giuliani, "the phenomenon external to an area of interest affects what goes on inside" (Giuliani et al., 2020: 3) . Tobler's (1970) premise, although effective in its message and true in some senses, does not conform to the geography of the 21st century. From the reflections in this review, we posit that, in order to face COVID-19, it is necessary to approach the issues from an interdisciplinary perspective, with proactive measures, international solidarity and collaboration, and a global perspective (from De Ángel Solá et al., 2020 ; Coccia, 2020; Holmes et al., 2020; Segal et al., 2020) . Unfortunately, at the political level, contradictions have emerged and been reported in the media, particularly where pundits and analysts acritically accept the inherent conflict between economic interests and public health. For example, in an international case, US companies are demanding Mexico exercise greater laxity in its preventive measures so that the commodity chains of US companies dependent on workers in Mexico's maquiladoras are not disrupted (Hernández Navarro, 2020; Corchado and Olivares, 2020) . The generation of information is one of the keys to confronting COVID-19. There are proposals worth mentioning, such as the international consortium Coronavirus Census Collective 11 (Segal et al., 2020) where they are integrating information from multiple sources, including surveys, diagnostic laboratory test results, geospatial statistics, and real-time data. These efforts will likely be referenced in future events, just as we are currently building on previous pandemic work. COVID-19 as an object of study is a thematic polyhedron where geographical variables are present in several of its facets. An important part of the study of the COVID-19 pandemic is based on geographical data, which are then processed through GIS and spatial statistical tools. But the most pressing issue is that these studies contribute to better social mobilization, decision-making, and planning, especially by helping to: -provide a large number of methods on the dynamics of spatial transmission that enable effective feedback to public health officials, decision makers, and affected communities (Desjardins et al., 2020) ; -improve estimations of the number of infections, detection of possible new outbreaks, and thus facilitate more successful interventions in public health (Coccia, 2020) ; -improve the locations of health services and controls, points of care, and facilitate access, which translates into an improvement in patient outcomes, time, and material resources (Kuupiel et al., 2020) ; -understand and map human movement, and formulate appropriate scientific, policy, and social measures Mollalo et al., 2020) ; and -predict the spatial spread and temporal trends of the outbreak, which is essential for health services (Giuliani et al., 2020) . Regarding the last point, we expect that the future will bring a greater volume of information, with geospatial data increasing at least 20% each year (Lee and Kang, 2015) , and hopefully increased accessibility. GIS developers must work towards opening up their online applications, and designing software applications that operate with big data in a user-friendly way while responding to privacy and other social concerns, more than is currently the case. For data integration, historical data tracking and dynamic mapping of spatial-temporal variables at multiple scales would be invaluable . Predictive modelling is becoming one of the vocations of spatialtemporal analysis, mainly referring to climate analysis and its effects on the expansion of COVID-19. As the pandemic has developed, more complex and refined predictive models of virus spread have also been generated. At a global level, there is a very important jump from the work of Wang et al. (2020) , which used two variables-air temperature and relative humidity-to the work presented by Bariotakis et al. (2020) in which 19 bioclimatic parameters were analysed. Sophisticated works with more accumulated variables (Mollalo et al., 2020; Baker et al., 2020) conclude that, although the climate and geography are factors that can modulate the transmission of SARS-CoV-2, these are not determining factors in the trajectory of the pandemic. In terms of nation-states, both as objects of study and the places of origin of the authors, China and the USA have carried out the most analysis on their territorial domains, especially in relation to big data-almost all the papers come from there. In the rest of the categories, many Chinese papers have been oriented towards spatial-temporal analysis under different statistical models, and those from the USA, on the other hand, have a greater emphasis on inter-disciplinary analyses. The intervention of other countries in GIS studies of COVID-19 has been extended as it has evolved chronologically. Iran, Israel, South Africa, Australia, Brazil, South Korea, Italy, Spain and India could represent this second grouping, with more than one work. Although valuable work has been done in Africa (Gibson and Rush, 2020; Kuupiel et al., 2020) , Latin America and the Caribbean (De Ángel Solá et al., 2020; Buzai, 2020) and in South Asian countries (Sarwar et al., 2020) , work here is clearly insufficient. COVID-19 is full of many unknowns, and in these regions of the world intersecting social issues could multiply the effects of the pandemic. Health geography that uses GIS to respond to needs at the local, neighbourhood and village level, is shown to have a very strong applicability. We believe that research in health geography should be expanded in terms of topics and areas of study, for its ability to map health infrastructures and their accessibility, and for territorial planning in terms of location and allocation of health services (Cicalò and Valentino, 2019) . We suggest that research in health geography and COVID-19 has the potential to be applied in more subjects and in more regions of the world that need studies of this type. In short, more experiences are needed in this regard. The management of public space in cities after the pandemic is another of the great challenges that we will face in the near future (Honey-Roses et al., 2020) . In addition to the spatial analysis applications summarized in this work, participatory GIS is seen as a very useful application in post-coronavirus urban planning, through the inclusive participation of the population that inhabits these places. Such an application is helpful in identifying which spaces are social priorities, context-sensitive place-based information, social sustainability and social, economic and environmental dynamics that affect a specific community (Samuelsson et al., 2020) . With regard to access to information, the availability of information from the WHO, public institutions in different countries, the JHU and large platforms such as Google, Baidu or Facebook, who have made their information available to the public, is proving to be fundamental to the proliferation of academic work and efforts to coordinate responses to the outbreak. It is important to note that 76% of the works consulted have used official data on SARS-CoV-2 infections. In addition, 20% have used information data mining obtained from cell phones (geolocation, payments, points of connection), flights or social networks. To a lesser extent, 10% of the works have been based on the socio-economic characteristics of the population and its urban structure, and some specific cases that have worked through polls, participatory GIS and satellite images (Table 1) . Regarding software, for GIS more than half of the works that refer to the software used mention ArcGIS, followed by R, QGIS, Kosmo and GeoJSON. For statistics, those referred to are R, SPSS, ERA5, WinBUGS, Geomathematics and SaTScan. We expect that GIS development will increase, both for private platforms and free ones. The web map viewers appear to have been successful at disseminating information to the public and specialists, becoming a tool that improves data transparency and helps authorities to communicate important information and generates greater sensitivity in public opinion (Cicalò and Valentino, 2019; Boulos and Geraghty, 2020) . Many countries have their own viewers within their official websites. As a criticism, we could comment that some are unnecessarily complex and not very intuitive, and in others it takes too long to load the cartography, which causes the tool to lose effectiveness. Behind this comment lies the observation that web map viewers are becoming a fad that, in some cases, is unnecessary where a static image at an appropriate resolution could work perfectly well to communicate spatial information. 11 https://coronaviruscensuscollective.org Regarding cartographic design, as already noted in February (Field, 2020) , we continue to identify cases with inadequate use of COVID-19 information in their maps, due to the incorrect use of choropleth thematic mapping technique, conformal projections where the area is a datum considered in the interpretation of the information, or the dispensable use of 3D tools. Ultimately, a map is only as helpful as the data, assumptions, representations and interpretations that go into it. This work is an addition to recent reviews on COVID-19 that offers a geographical perspective. It is a compendium that identifies the themes and analyses that are being carried out with GIS and spatial-statistical tools. We believe that compiling this information can streamline efforts for future, more effective bibliographic inquiries. It can also serve as support for the evolution in the use of these tools in the following months and inspire new reflections for the readers, connecting between themes and tools. We have delimit a state of the art five months after the start of the phenomenon, where each week seems like a year on a human scale. To date, spatiotemporal analysis and disease mapping, health and social geography, environmental variables, data mining, and webbased mapping have been the most recurrent topics. COVID-19 studies with GIS could be valuable tools in decisionmaking and, more importantly, social mobilization and community responses. Health geography also has a critical social perspective that is highly relevant, so that political decisions can be accountable to all sectors of society, hopefully minimising the regularity with which marginalised populations are sacrificed or left unprotected. Understanding the spatial-temporal dynamics of COVID-19 is critical to its mitigation, which is why such work is being done in all regions of the world. This is due in large part to the opening up of large volumes of information by public institutions, international organizations and private companies with geospatial information. 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