The coastline of Eastern Andalusia concentrates the main protected horticultural production area of the Andalusian autonomous community. Since 2001, the Junta de Andalucía has been mapping greenhouses on the Eastern Andalusian coast (regions of Campo de Dalías, Campo de Níjar and Bajo Andarax and Bajo Almanzora in Almería, La Costa in Granada and Vélez-Málaga in Málaga). Although most of the greenhouse surface in the provinces of Almería, Granada, and Málaga is found in the five regions studied since 2001 (96% according to SigPac), in 2017 it was decided to extend the study to other regions where it was detected the presence of greenhouses. Specifically, the study is extended to the Alto Andarax, Campo Tabernas, and Río Nacimiento regions in Almería, Alhama, Las Alpujarras, and Baza in Granada and Centro-Sur or Guadalhorce in Malaga. In this way, since 2017, the studied area would include more than 99% of the protected surface in the set of the three provinces according to SigPac data. The area of greenhouses estimated for the year 2019 in the regions studied amounted to 35,946 has registered an increase of 457ha (1.3%) compared to 2018. By provinces, in Almería 32,048ha have been estimated, 434ha more than the last year. In Granada, 3122ha have been estimated, 22ha more than last year. In Malaga, 776ha have been estimated, 1ha more than last year.3

According to the 2019 mapping of crops under plastic in Huelva, the area mapped as cultivation under plastic would amount to 16,611ha. It has been estimated that 14,616ha would correspond to the surface under plastic while the rest would correspond mainly to corridors of the exploitation and roads. If we compare these estimates with the results of the previous season, an increase in the area under plastic is observed of 796ha (6%). Since 2004, the area under plastic in Huelva has increased by 103% (7419ha). The municipalities of Moguer and Almonte concentrate almost half of the estimated total area under plastic (42%). They are followed in the amount of estimated protected area by the municipalities of Lepe, Lucena del Puerto, and Cartaya, which exceed 1000ha. At the opposite extreme, in Punta Umbría and San Juan del Puerto, they do not reach 10ha. Gibraleón followed by Lepe, Cartaya, and Almonte are the municipalities with the greatest increase in area. Another nine municipalities increase their surface to a lesser degree, between 10 and 50ha. The rest of the municipalities analyzed maintain their surface quite stable with variations that do not reach 10ha.4

As in the previous campaign, a small percentage of the area estimated as protected crop corresponds to areas where the plastic was not yet spread on January 12 and has been detected in the image of February 11.4

In Cádiz, seven municipalities have been studied: Chipiona, Sanlúcar de Barrameda, Medina-Sidonia, Conil de la Frontera, Jerez de la Frontera, Arcos de la Frontera and Rota (96% of the area of protected crops in the province according to the census), estimating a protected area of 888ha compared to 919ha in 2014, 3.4% less. Sanlúcar de Barrameda and Chipiona account for most of the greenhouses (78%). In all municipalities except Conil de la Frontera, the estimated protected area has decreased slightly. In Arcos de la frontera, traveling macro-tunnel-type structures have been detected. In Seville, seven other municipalities have been studied: Los Palacios y Villafranca, Lebrija, Las Cabezas de San Juan, Aznalcázar, Alcalá de Guadaira, Utrera and El Cuervo de Sevilla (79% of the area of protected crops according to census), estimating a Protected area of 292ha compared to 261ha in 2014, 11.7% more. Los Palacios and Villafranca, followed by Lebrija, are the two municipalities with the highest presence of greenhouses (72%). The increase in area is especially concentrated in Los Palacios and Villafranca. In Aznalcázar, traveling macro-tunnel-type structures have been detected.8

Pesticides are widely used throughout the world due to their benefits for the agriculture sector, improving crop production, and in public health for the control of vector-borne diseases. In Spain, the use of pesticides as plant protection is 73,286 tons in its latest study in 2018.9

Long-term use of pesticides in areas of intensive use for agriculture contributes to environmental pollution; therefore, residential proximity to pesticide-treated farmland can pose a risk to human health.10

The purpose of our study is to determine, through a case–control study, if there is a relationship between environmental exposure to pesticides and the appearance of ALS in southern Spain.

The areas studied correspond to municipalities in Andalusia (Southern Spain), which were classified into two groups (high versus low exposure to the use of pesticides) according to the agronomic criteria provided by the Andalusian Council of Agriculture, in particular tons of pesticides used, and a land area dedicated to intensive agriculture in plastic-covered greenhouses.11

Intensive agriculture areas with a large number of hectares (ha) of a greenhouse, and therefore with high use of pesticides, were considered high exposure. In contrast, areas with a low number of greenhouse hectares or dedicated only to extensive agriculture (and therefore with low use of pesticides) were classified as low exposure to pesticides. The exhibition included the entire autonomous community of Andalusia, distinguishing in the provinces of Seville, Huelva, Cádiz, Málaga, Granada and Almería between high and low exposure, and Córdoba and Jaén being classified as the entire province of low exposure according to the cartography for 2018 due to its low number of greenhouse hectares.4,8,10,11

Regarding the main groups of phytosanitary products used during the study period according to the phytosanitary marketing survey in 2018 were fungicides and bactericides (52%: inorganic, carbamates and dithiocarbamates, benzimazoles, imidazoles and triazoles, morpholines, microbiological or botanicals), herbicides (23%: triazines and triazinones, carbamates and bicarbamates, urea, uracil or sulfonylure, others), molluscicides, growth regulators and others (16%: growth regulators, molluscicides and others), insecticides and acaricides (9%: pyrethroids, microbiological/botanical origin, others).9

For our population sample, we selected the 519 individuals diagnosed with Amyotrophic Lateral Sclerosis according to the Minimum Basic Data Set (CMBD) for the year 2018 in Andalusia, which we later divided into high and low exposure.

Of the individuals with ALS diagnoses, 194 people lived in high pesticide use areas and 325 people lived in low pesticide use areas. Of those 519 patients, 269 are men (51.4%) and 254 women (48.6%). The average age is 63, 79+12.77, with ages between 21 and 92 years (Table 1).

We selected the “cases” group through the computerized registry of the Andalusian Public Health Service, called the Basic Minimum Data Set (CMBD), among the patients diagnosed with ALS during the 3-year study period and in turn we divided them among those who lived in an area of intensive agriculture in greenhouses (high exposure) and those who did not (low exposure). The CMBD is a registry that collects coded clinical data on patients from admission to discharge from a public hospital, with data on their health status as the main diagnosis, as well as other secondary diagnoses, and other data such as age, sex and the place of residence.

The diagnosis of Amyotrophic Lateral Sclerosis (ALS) was defined according to the tenth revision of the International Classification of Diseases (ICD-10) of the World Health Organization, in force during the study period. The codes used to obtain the data for Amyotrophic Lateral Sclerosis (ALS) in the CMBD according to the ICD-10 were G12.21, in section G10-G14.

We select the “control” group through Andalusian population that lived in the same study areas as the cases, according to the INE for the period of time studied, and was composed of 3.335.482 people without a diagnosis of ALS in the high-exposure area and 5.048.601 people no diagnosis of ALS in the low-exposure zone, as of January 1, 2018.

In data analysis, frequencies and percentages were calculated for the variables sex and age in the sample obtained from cases of Amyotrophic Lateral Sclerosis, as well as the means and standard deviations of these variables. For the calculation of the prevalence rate, as well as the risk of developing Amyotrophic Lateral Sclerosis, they were calculated for areas of high and low exposure to pesticides through the Odds Ratios (OR) test, with an interval of 95% confidence (CI). The level of statistical significance was established at p<0.05. The data were analyzed with the statistical program SPSS 24.0 for the analysis of frequencies and percentages, and Epidat 3.1 for the calculation of OR using a 2×2 contingency table (Table 2).