Pharmaceutical market, environmental public policies and water quality: the case of the São Paulo Metropolitan Region, Brazil

Aragão, Rafaela Barbosa de Andrade; Semensatto, Décio; Calixto, Leandro Augusto; Labuto, Geórgia

doi:10.1590/0102-311x00192319

Abstract:

Water pollution has been an increasing concern for the authorities responsible for planning and executing public policies. In this qualitative research, we have discussed the most sold pharmaceuticals in the São Paulo Metropolitan Region, Brazil, and compared public policies focused on pharmaceuticals and environmental issues among countries/regions. For that, data provided by Close-Up International related to the sales of medicines in the São Paulo Metropolitan Region between April/2016 and April/2017 were collected and processed to identify and quantify the pharmaceutical products. The 300 most sold medicines in the São Paulo Metropolitan Region fall in 26 therapeutic classes, which include 159 drugs. The most sold pharmaceutical products group is nonsteroidal anti-inflammatory drugs (NSAIDs) representing approximately 44.3% of the total. The ten most sold pharmaceuticals sum up 1200 tons. Dipyrone is the first place in mass representing around 488 tons, followed by metformin with around 310 tons commercialized. Public policies focused on pharmaceuticals in the environment still need adjustments to improve reinforcement, even in developed countries. There is no international standard on how to conduct the issue, each country adopting the public policy that best matches to the local. Brazil, despite having some legislation that approaches the theme, still lacks effective public policies and stakeholder awareness. In this aspect, the need for improvement of the reverse logistics system, consumer orientation to the adequate disposal of unused/expired medicines, and the adoption of the unit-dose system as a therapeutic strategy is evident.

Keywords:
Water Pollution; Environmental Monitoring; Environmental Health; Environmental Policy; Health Policy

Resumo:

A poluição da água tem preocupado cada vez mais as autoridades responsáveis pelo planejamento e execução das políticas públicas no Brasil. Esta pesquisa qualitativa discute os produtos farmacêuticos mais vendidos na Região Metropolitana de São Paulo, Brasil, e compara as políticas públicas focadas em produtos farmacêuticos e questões ambientais, entre países e regiões. Foram coletados e processados os dados fornecidos pela Close-Up International sobre vendas de medicamentos na Grande São Paulo entre abril de 2016 e abril de 2017, para identificar e quantificar esses produtos. Os 300 medicamentos mais vendidos na Grande São Paulo pertencem a 26 classes terapêuticas e incluem 159 fármacos. Os produtos farmacêuticos mais vendidos pertencem ao grupo dos anti-inflamatórios não esteroides (AINES), representando aproximadamente 44,3% do total. Os dez produtos farmacêuticos mais vendidos somam 1.200 toneladas. A dipirona liderou o ranking em termos de massa, com cerca de 488 toneladas, seguida pela metformina, com 310 toneladas comercializadas. As políticas públicas focadas nos produtos farmacêuticos e sua presença no meio ambiente ainda requerem ajustes, mesmo nos países desenvolvidos. Não existe uma norma internacional para lidar com essa questão, e cada país adota a política pública mais adequada para o contexto local. O Brasil já dispõe de alguma legislação sobre o tema, mas ainda faltam políticas públicas efetivas e uma melhor conscientização dos atores envolvidos. Portanto, há uma necessidade evidente de melhorar o sistema de logística reversa, com orientação dos consumidores em relação ao descarte adequado dos medicamentos não utilizados ou vencidos e a adoção do sistema de dose unitária como estratégia terapêutica.

Palavras-chave:
Poluição da Água; Monitoramento Ambiental; Saúde Ambiental; Política Ambiental; Política de Saúde

Resumen:

La contaminación del agua ha sido una creciente preocupación para las autoridades responsables de planificar y ejecutar políticas públicas. Esta investigación cualitativa trata sobre los productos farmacéuticos más vendidos en la Región Metropolitana de São Paulo, Brasil, y además compara las políticas públicas centradas en cuestiones farmacéuticas y ambientales entre países/regiones. En este sentido, los datos proporcionados por Close-Up International, relacionados con las ventas de medicinas en la Región Metropolitana de São Paulo entre abril/2016 y abril/2017, se recogieron y presentaron para identificar y cuantificar los productos farmacéuticos. Las 300 medicinas más vendidas en la Región Metropolitana de São Paulo se incluyeron en 26 clases terapéuticas, que incluyeron 159 medicamentos. El grupo de productos farmacéuticos más vendido es el de los medicamentos antiinflamatorios no esteroides (AINE), representando aproximadamente un 44,3% del total. Los 10 productos farmacéuticos más vendidos llegaron a alcanzar las 1.200 toneladas. La dipirona está en primer lugar, alrededor de 488 toneladas, a la que le sigue la metformina con cerca de 310 toneladas comercializadas. Las políticas públicas centradas en productos farmacéuticos y medioambiente todavía necesitan ajustes para mejorar su fortalecimiento, incluso en los países desarrollados. No existe un estándar internacional sobre cómo gestionar este asunto, cada país adopta las políticas públicas que mejor se ajustan a su entorno. Brasil, a pesar de contar con algo de legislación que se centra en esta cuestión, todavía adolece de políticas públicas efectivas, así como una falta de sensibilización de los agentes responsables. En este aspecto, es evidente la necesidad de mejorar el sistema de logística inversa, así como la orientación al consumidor para desechar adecuadamente las medicinas no usadas/caducadas, y la adopción de un sistema de dosis unitarias como estrategia terapéutica.

Palabras-clave:
Contaminación del Agua; Monitoreo de Ambiente; Salud Ambiental; Política Ambiental; Política de Salud

Introduction

Access to quality water has been recognized by the United Nations as an essential right in realizing all other human rights (Resolution n. 64/292). Worryingly, however, the quality of water bodies has been deteriorating as a result of misuse of natural resources, causing scarcity, both in terms of quantity and quality ¹1. Hoekstra AY, Mekonnen MM, Chapagain AK, Mathews RE, Richter BD. Global monthly water scarcity: blue water footprints versus blue water availability. PLoS One 2012; 7:e32688.. This situation requires urgent attention not only from environmental professionals but also from those in the health sciences ²2. Bartram J, Cairncross S. Hygiene, sanitation, and water: forgotten foundations of health. PLoS Med 2010; 7:e1000367..

Pharmaceuticals drugs are a particular group of pollutants that since the 1970s have aroused interest of the scientific community due to the growing frequency and concentration of both pharmaceuticals and metabolites in water, sediments and aquatic organisms ³3. Gavrilescu M, Demnerová K, Aamand J, Agathos S, Fava F. Emerging pollutants in the environment: present and future challenges in biomonitoring, ecological risks and bioremediation. N Biotechnol 2015; 32:147-56.. Such compounds are emerging pollutants, and most lack any ecotoxicological information or environmental regulation, despite the potential to cause many adverse effects on biota, including humans ⁴4. Geissen V, Mol H, Klumpp E, Umlaufd G, Nadale M, van der Ploeg M, et al. Emerging pollutants in the environment: a challenge for water resource management. International Soil and Water Conservation Research 2015; 3:57-65.. Although some of them are degradable, their constant input into water bodies results in similar behavior to that of persistent substances and can cause a variety of impacts on aquatic life and health ⁵5. Grenni P, Ancona V, Caracciolo AB. Ecological effects of antibiotics on natural ecosystems: a review. Microchem J 2018; 136:25-39..

The projected growth in global medicine use was expected to increase by 4.5 trillion doses by 2020, an addition of 24% from 2015 ⁶6. IMS Institute for Healthcare Informatics. Global medicines use in 2020: outlook and implications. Parsippany: IMS Institute for Healthcare Informatics; 2015.. The IMS Institute for Healthcare Informatics (New Jersey, United States) also points out that global medication spending was expected to rise by 29-32% by 2020, with an estimated 50% of the world’s population consuming more than one dose per person per day. It was forecast that global absolute pharmaceutical spending would increase from USD 182 billion in the period 2010-2015 to USD 349 billion in the period 2016-2020, i.e., an expansion of 91.8%. Concerning Brazil, the prognosis indicated that consumption would reach 2.82 doses per person per day by 2020 (an increase of 38%). The consequence of this global and national increase in pharmaceutical production and consumption is the potential greater quantity of these substances being released into the environment than it currently is. Some papers presented relatively accurate predictions of pharmaceuticals drugs concentration in wastewater treatment plant (WWTP) influents/effluents and surface water based on sales and consumption data ⁷7. Azuma T, Nakada N, Yamashita N, Tanaka H. Evaluation of concentrations of pharmaceuticals detected in sewage influents in Japan by using annual shipping and sales data. Chemosphere 2015; 138:770-6.^,⁸8. Oosterhuis M, Sacher F, ter Laak TL. Prediction of concentration levels of metformin and other high consumption pharmaceuticals in wastewater and regional surface water based on sales data. Sci Total Environ 2013; 442:380-8.^,⁹9. Pereira AMPT, Silva LJG, Lino CM, Meisel LM, Pena A. A critical evaluation of different parameters for estimating pharmaceutical exposure seeking an improved environmental risk assessment. Sci Total Environ 2017; 603:226-36.. Thus, it is reasonable to infer that the higher sales and consumption are, the higher the concentration of pharmaceuticals drugs in the environment.

As in other regions of the world, concentrations of different types of pharmaceuticals drugs have been found in the water and sediment of the Billings and Guarapiranga reservoirs, which receive untreated sewage, despite supplying together drinking water to 6.4 million people in the São Paulo Metropolitan Region ¹⁰10. Almeida GA, Weber RR. Fármacos na Represa Billings. Saúde & Meio Ambiente 2006; 6:7-12.^,¹¹11. Cotrim MEB, Martins EAJ, Furusawa HA, Shihomatsu HM, Monteiro LR, Lebre DT, et al. Qualidade ecológica da Represa Guarapiranga: água e sedimentos superficiais: multitraçadores ambientais - metais, elementos-traço, interferentes endócrinos, HPAs e fármacos. In: Bicudo C, Bicudo DC, organizadores. 100 anos da Represa Guarapiranga: lições e desafios. Curitiba: Editora CRV; 2017. p. 309-82.. The water collected and distributed from these reservoirs only goes through conventional treatment systems, which only makes a negligible reduction in concentrations ¹²12. Goswami L, Kumar RV, Borah SN, Manikandan NA, Pakshirajan K, Pugazhenthi G. Membrane bioreactor and integrated membrane bioreactor systems for micropollutant removal from wastewater: a review. Journal of Water Process Engineering 2018; 26:314-28..

In this work, we have presented an overview of pharmaceutical sales in the São Paulo Metropolitan Region, which in its turn may indicate their potential release into local water bodies. Furthermore, we have compared the public policies associated with unit-dose systems (UDS) and disposal and reverse logistics employed in Brazil and other countries and regions in order to offer recommendations to improve public policies in planning and execution.

Material and methods

São Paulo Metropolitan Region

The São Paulo Metropolitan Region consists of 39 cities (Figure 1) with an estimated population of 21.5 million in 2018, according to the Brazilian Institute of Geography and Statistics (IBGE). The São Paulo Metropolitan Region has robust economic activity with its regional Gross Domestic Product (GDP) of ~USD 250 billion. Nevertheless, the region presents several inequalities in terms of the proportion of health units (hospitals, emergency units, clinics, diagnosis centers), GDP per capita and the proportion of households served by sanitation facilities (Table 1). If, on the one hand, the proportion of health units and GDP per capita indirectly expresses the potential of the population of each city to access medicine, on the other hand, the proportion of the population served by the sanitation facilities denotes the potential for load of pharmaceuticals and their metabolites released into local aquatic ecosystems via untreated sewage. These numbers indicate that regional management of potential pharmaceutical loads in water bodies is challenging and quite heterogeneous among municipalities.

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Figure 1
Cities of the São Paulo Metropolitan Region, Brazil.

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Table 1
List of cities that form the São Paulo Metropolitan Region, Brazil, organized by population size.

Source of data and analysis

We have analyzed a set of secondary data obtained from scientific, technical, legal, and legislative literature. Close-Up International provided, under our request, a list of the 300 most marketed medicines in the São Paulo Metropolitian Region from April/2016 to April/2017, in which the masses (kg) of pharmaceuticals drugs circulating in the region were calculated based on the information on the medicine, the dosage form (tablet, suspension etc.), quantity by package, and the dose. As some pharmaceuticals drugs are made up of more than one medicine, we ascertained the mass of each one by adding up the masses of all medicines with the pharmaceuticals drugs in question. Close-Up International’s information considers wholesale and retail marketing in drugstores and by public and private sector hospitals. In Brazil, over-the-counter drugs are sold solely in drugstores; thus, data used in this work encompasses the whole market regarding over-the-counter drugs. Data did not include veterinary drugs, dermatological ingredients, and medicines traded in unregulated markets.

Following the survey and the standardization of the masses, we then organized the pharmaceuticals according to their respective therapeutic classes, based on the 2010 national therapeutic form 2010 of the Brazilian Ministry of Health ¹³13. Ministério da Saúde. Formulário terapêutico nacional 2010: Rename 2010. 2ª Ed. Brasília: Ministério da Saúde; 2010. and the guide to generic medicines ¹⁴14. Agência Nacional de Vigilância Sanitária. Guia de medicamentos genéricos. Brasília: Agência Nacional de Vigilância Sanitária; 2001.. As in some cases the same pharmaceutical may cover two or more therapeutic classes, we have adopted the class indicated in the pharmaceutical specialty dictionary ¹⁵15. EPUC. Dicionário de especialidades farmacêuticas. 44ª Ed. Rio de Janeiro: Editora de Publicações Científicas; 2016..

Comparisons on public policies were based on the analysis of the regulations on the UDS, the disposal and reverse logistics of unused/expired medicines in the United States, Canada, European Union and, Brazil. The inclusion of Canadian information stems from the fact that this country presents the broadest management plan for chemicals, which includes pharmaceutical drugs, an interesting aspect for comparative assessments.

Results

The 300 most sold medicines in the São Paulo Metropolitan Region fall into 26 therapeutic classes and 159 pharmaceuticals drugs, totaling 1,499 tons (Supplementary Material: http://cadernos.ensp.fiocruz.br/static//arquivo/suppl-e00192319_1464.pdf). Of this total, 1,200 tons (~85%) refer to only ten substances (Table 2). The therapeutic class with the highest sold mass is nonsteroidal anti-inflammatory drugs, representing 44.3%, followed by antidiabetics, electrolytes/nutrition, and anti-hypertensives, accounting for 20.8%, 6.7%, and 4.5% respectively. It is important to emphasize the lack of information on the pharmacokinetics and toxicological behavior of metabolites for most listed substances. It represents a critical data gap for the environmental monitoring and control of these substances in the environment. Thus, the present data might help to define which pharmaceuticals should be prioritized, in terms of potential input load into natural ecosystems and drinking water, for the development of studies regarding their impacts on biota, environment, and humans. Of the ten pharmaceuticals with the largest mass marketed, only four contain information regarding the percentage of excretion in its unaltered form in their respective leaflets.

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Table 2
Ranking of the 10 most sold pharmaceutical drugs at the São Paulo Metropolitan Region, Brasil, between April/2016 and April/2017, after processing data provided by Close-Up International.

Hormones are not among the top sold medicines in terms of mass because of their typical low dosage and concentration, although they exert significant impacts on organisms and ecosystems. Data on sales at the São Paulo Metropolitan Region reveal that 11 hormones were traded in the region during the period analyzed, dominated by dienogest and estradiol, which together account for 85% of the total mass of traded hormones (Table 3).

Antimicrobials account for 26.14 tons, which represents 1.74% of the total mass of pharmaceuticals drugs traded. Cephalexin, amoxicillin and, ciprofloxacin add up to 72% of the mass of antimicrobials here listed.

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Table 3
Mass of hormones more commercialized at the São Paulo Metropolitan Region, Brazil, between April/2016 and April/2017, after processing data provided by Close-Up International.

Discussion

Dipyrone is broadly consumed in Brazil, although it is banned in some countries because of its relationship with agranulocytosis and other blood dyscrasias ¹⁶16. Pamplona JH, Oba ET, Silva TA, Ramos LP, Ramsdorf WA, Cestari MM, et al. Subchronic effects of dipyrone on the fish species Rhamdia quelen. Ecotoxicology and Environmental Safety 2011; 74:342-9.. Its original form and metabolites are easily found in wastewater from sewage treatment plants in many cities, as such, it is no surprise that is the pharmaceutical with the highest concentration reported in Latin America among many emergent pollutants ¹⁷17. Peña-Guzmán C, Ulloa-Sánchez S, Mora K, Helena-Bustos R, Lopez-Barrera E, Alvarez J, et al. Emerging pollutants in the urban water cycle in Latin America: a review of the current literature. J Environ Manage 2019; 237:408-23.. A prioritization ranking for environmental monitoring of emergent pollutants in aquatic environments positioned dipyrone in a group of low toxicity, but high exposure potential scores ¹⁸18. Santos CEM, Nardocci AC. Prioritization of pharmaceuticals in drinking water exposure based on toxicity and environmental fate assessment by in silico tools: an integrated and transparent ranking. Comput Toxicol 2019; 9:12-21.. Such level of exposure is a function of the high consumption due to its low cost and strong analgesic effect, which is enhanced by the possibility of purchasing over-the-count drugs ¹⁹19. Martínez-Bueno M, Gomez M, Herrera S, Agüera A, Fernández-Alba A. Occurrence and persistence of organic emerging contaminants and priority pollutants in five sewage treatment plants of Spain: two years pilot survey monitoring. Environ Pollut 2012; 164:267-73.. Dipyrone and its metabolites caused toxic effects in fish, mostly DNA damage, reaching the ultrastructural level, in concentrations from 50ng.L^-1¹⁶16. Pamplona JH, Oba ET, Silva TA, Ramos LP, Ramsdorf WA, Cestari MM, et al. Subchronic effects of dipyrone on the fish species Rhamdia quelen. Ecotoxicology and Environmental Safety 2011; 74:342-9.. In most of the cities that form the São Paulo Metropolitan Region, the sewage systems do not serve a significant part of inhabitants (Table 1); thus, untreated sewage flows to the main reservoirs that supply the population within the São Paulo Metropolitan Region: Guarapiranga and Billings ²⁰20. Semensatto D, Asami T. Além dos índices numéricos: a qualidade da água da Represa Guarapiranga ao longo do tempo. In: Bicudo C, Bicudo DC, editors. 100 anos da Represa Guarapiranga: lições e desafios. Curitiba: Editora CRV; 2017. p. 383-400.. The sewage collected is subjected to conventional physical-chemical treatments, which do not remove satisfactorily dipyrone or its metabolites, the last recognized as more persistent and toxic; removal from water ranges from 45% to 68% (4-formylaminoantipyrine: 4-FAA and 4-methylaminoantipyrine: 4-MAA, respectively) ¹⁹19. Martínez-Bueno M, Gomez M, Herrera S, Agüera A, Fernández-Alba A. Occurrence and persistence of organic emerging contaminants and priority pollutants in five sewage treatment plants of Spain: two years pilot survey monitoring. Environ Pollut 2012; 164:267-73.. Hence, taking into account the considerable mass of this active component sold at the São Paulo Metropolitan Region, we can infer that the exposure level for local biota is potentially high.

Metformin is the most prescribed drug for anti-diabetic treatment worldwide for type-2 diabetes (non-insulin-dependent) ²¹21. Gong L, Goswami S, Giacomini KM, Altman RB, Klein TE. Metformin pathways: pharmacokinetics and pharmacodynamics. Pharmacogenet Genomics 2012; 22:820-7.. In Brazil, metformin dominates the oral hypoglycemic market with a market share of 57.5% of this class of pharmaceuticals drugs in 2012 ²²22. Lu CY, Emmerick ICM, Stephens P, Ross-Degnan D, Wagner AK. Uptake of new antidiabetic medications in three emerging markets: a comparison between Brazil, China and Thailand. J Pharm Policy Pract 2015; 8:1-8.. Metformin was freely distributed to patients through the Farmácia Popular Program, a program launched in 2004 that was discontinued in 2018.

Prevalence of type-2 diabetes in Brazil has grown, with obesity as the main risk factor, reaching 11.2% in São Paulo in 2013 ²³23. Almeida-Pititto B, Dias ML, Moraes ACF, Ferreira SRG, Franco DR, et al. Type 2 diabetes in Brazil: epidemiology and management. Diabetes Metab Syndr Obes 2015; 8:17-28., and it is inferred that type-2 diabetes costed USD 1,844 per patient in 2010 in São Paulo ²⁴24. Borges NB, Ferraz MB, Chacra AR. The cost of type 2 diabetes in Brazil: evaluation of a diabetes care center in the city of São Paulo, Brazil. Diabetol Metab Syndr 2014; 6:122.. It was discussed that the government should enforce policies for the prevention of diabetes and its secondary complications to tackle the rising costs for the public health system, which in our view may consequently reduce the load of metformin in the environment. However, prescriptions of metformin are expected to rise because it has been successfully tested as an anticancer agent ²⁵25. Vancura A, Bu P, Bhagwat M, Zeng J, Vancurova I. Metformin as an anticancer agent. Trends Pharmacol Sci 2018; 39:867-78. and weight loss drug both for diabetic and non-diabetic individuals ²⁶26. Seifarth C, Schehler B, Schneider HJ. Effectiveness of metformin on weight loss in non-diabetic individuals with obesity. Exp Clin Endocrinol Diabetes 2012; 121:27-31., also being used for treatment of polycystic ovaries and excreted in its original form through urine ²¹21. Gong L, Goswami S, Giacomini KM, Altman RB, Klein TE. Metformin pathways: pharmacokinetics and pharmacodynamics. Pharmacogenet Genomics 2012; 22:820-7.. Despite metformin and its biodegraded product granylurea being recognized as recalcitrant in surface water ⁸8. Oosterhuis M, Sacher F, ter Laak TL. Prediction of concentration levels of metformin and other high consumption pharmaceuticals in wastewater and regional surface water based on sales data. Sci Total Environ 2013; 442:380-8., it remains poorly monitored in the environment and only a few papers report its occurrence and fate ²⁷27. Briones RM, Sarmah AK, Padhye LP. A global perspective on the use, occurrence, fate and effects of anti-diabetic drug metformin in natural and engineered ecosystems. Environ Pollut 2016; 219:1007-20.. Metformin acts as an endocrine disruptor and inhibits the growth of organisms, namely fish, Daphnia, algae, earthworm and humans ²⁸28. Niemuth NJ, Klaper RD. Emerging wastewater contaminant metformin causes intersex and reduced fecundity in fish. Chemosphere 2015; 135:38-45.^,²⁹29. Guo J, Sinclair CJ, Selby K, Boxall ABA. Toxicological and ecotoxicological risk-based prioritization of pharmaceuticals in the natural environment. Environ Toxicol Chem 2016; 35:1550-9., although its ecological risk is classified as low ³⁰30. Moermond CTA, Smit CE. Derivation of water quality standards for carbamazepine, metoprolol, and metformin and comparison with monitoring data. Environ Toxicol Chem 2016; 35:882-8..

Revised data about metformin in the environment revealed that the maximum concentration ever found was 248µg/L in raw water in the United States; surface water concentrations of metformin are also related to the population age structure and local sewage contributions ²⁷27. Briones RM, Sarmah AK, Padhye LP. A global perspective on the use, occurrence, fate and effects of anti-diabetic drug metformin in natural and engineered ecosystems. Environ Pollut 2016; 219:1007-20.. To date, there is no data about the concentration of metformin or granylurea in water and wastewater from the São Paulo Metropolitan Region. However, these two compounds may be present in most water bodies and urban reservoirs of the São Paulo Metropolitan Region, taking into account the relationship between prescription levels and concentration in the environment ²⁷27. Briones RM, Sarmah AK, Padhye LP. A global perspective on the use, occurrence, fate and effects of anti-diabetic drug metformin in natural and engineered ecosystems. Environ Pollut 2016; 219:1007-20., not to mention the fact that a proportion of untreated sewage flows directly into water bodies and WWTPs do not remove these compounds completely ³¹31. Straub JO, Caldwell DJ, Davidson T, D’Aco V, Kappler K, Robbinson PF, et al. Environmental risk assessment of metformin and its transformation product guanylurea. I. Environmental fate. Chemosphere 2019; 216:844-54..

Paracetamol (acetaminophen) is an analgesic broadly consumed in Brazil as an alternative to dipyrone and ibuprofen. It was found in the superficial waters, influent and effluent of WWTPs in many countries ¹⁹19. Martínez-Bueno M, Gomez M, Herrera S, Agüera A, Fernández-Alba A. Occurrence and persistence of organic emerging contaminants and priority pollutants in five sewage treatment plants of Spain: two years pilot survey monitoring. Environ Pollut 2012; 164:267-73.^,²⁹29. Guo J, Sinclair CJ, Selby K, Boxall ABA. Toxicological and ecotoxicological risk-based prioritization of pharmaceuticals in the natural environment. Environ Toxicol Chem 2016; 35:1550-9.^,³²32. Chen Y, Vymazal J, Březinová T, Koželuhc M, Kulec L, Huang J, et al. Occurrence, removal and environmental risk assessment of pharmaceuticals and personal care products in rural wastewater treatment wetlands. Sci Total Environ 2016; 566/567:1660-9.. Paracetamol was found in Brazil in raw water (0.01-1,222.6ng.L^-1) and drinking water (< 0.20-453.6ng.L^-1) ³³33. Lima D, Tonucci M, Libânio M, Aquino S. Fármacos e desreguladores endócrinos em águas brasileiras: ocorrência e técnicas de remoção. Eng Sanit Ambient 2017; 22:1043-54.. Its presence was reported in the São Paulo Metropolitan Region in 74% (n = 42) of superficial water samples collected at Guarapiranga Reservoir but without any significant concentration ¹¹11. Cotrim MEB, Martins EAJ, Furusawa HA, Shihomatsu HM, Monteiro LR, Lebre DT, et al. Qualidade ecológica da Represa Guarapiranga: água e sedimentos superficiais: multitraçadores ambientais - metais, elementos-traço, interferentes endócrinos, HPAs e fármacos. In: Bicudo C, Bicudo DC, organizadores. 100 anos da Represa Guarapiranga: lições e desafios. Curitiba: Editora CRV; 2017. p. 309-82.. The excretion rate is 80.9% and its removal from water and wastewater varies between 95% and 100% ¹⁹19. Martínez-Bueno M, Gomez M, Herrera S, Agüera A, Fernández-Alba A. Occurrence and persistence of organic emerging contaminants and priority pollutants in five sewage treatment plants of Spain: two years pilot survey monitoring. Environ Pollut 2012; 164:267-73.^,³²32. Chen Y, Vymazal J, Březinová T, Koželuhc M, Kulec L, Huang J, et al. Occurrence, removal and environmental risk assessment of pharmaceuticals and personal care products in rural wastewater treatment wetlands. Sci Total Environ 2016; 566/567:1660-9.. Paracetamol is often ranked in intermediary positions in the lists for environmental monitoring ¹⁸18. Santos CEM, Nardocci AC. Prioritization of pharmaceuticals in drinking water exposure based on toxicity and environmental fate assessment by in silico tools: an integrated and transparent ranking. Comput Toxicol 2019; 9:12-21.^,²⁹29. Guo J, Sinclair CJ, Selby K, Boxall ABA. Toxicological and ecotoxicological risk-based prioritization of pharmaceuticals in the natural environment. Environ Toxicol Chem 2016; 35:1550-9., despite its high frequency in samples and high concentration. Additionally, its active metabolite N-acetyl-p-benzoquinone imine is considered potentially toxic to the liver and kidneys ³⁴34. Mazaleuskaya LL, Sangkuhl K, Thorn CF, FitzGerald GA, Altman RB, Klein TE. PharmGKB summary: pathways of acetaminophen metabolism at the therapeutic versus toxic doses. Pharmacogenet Genomics 2015; 25:416-26..

Phenylephrine and chlorpheniramine are poorly mentioned and have never been reported in environmental matrices in Brazil, probably because they are MEOCS (Matthew Effect Orphaned Chemicals) ³⁵35. Daughton CG. The Matthew Effect and widely prescribed pharmaceuticals lacking environmental monitoring: case study of an exposure-assessment vulnerability. Sci Total Environ 2014; 466/467:315-25.. Phenylephrine is a nasal decongestant used in single- and multiple-ingredient over-the-counter drugs ³⁶36. Gelotte CK. An open-label, randomized, four-treatment crossover study evaluating the effects of salt form, acetaminophen, and food on the pharmacokinetics of phenylephrine. Regul Toxicol Pharmacol 2018; 95:333-8.. However, some papers classified phenylephrine as a drug of abuse, considering that it is a metabolite of the stimulant ephedrine ³⁷37. Robles-Molina J, Gilbert-López B, García-Reyes JF, Molina-Díaz A. Monitoring of selected priority and emerging contaminants in the Guadalquivir River and other related surface waters in the province of Jaén, South East Spain. Sci Total Environ 2014; 479/480:247-57.^,³⁸38. Estévez E, Cabrera MC, Molina-Díaz A, Robles-Molina J, Palacios-Díaz MP. Screening of emerging contaminants and priority substances (2008/105/EC) in reclaimed water for irrigation and groundwater in a volcanic aquifer (Gran Canaria, Canary Islands, Spain). Sci Total Environ 2012; 433:538-46.. Its removal was inferred by 55% after sewage was submitted to pre-treatment for solid removal, primary treatment to eliminate suspended material, activated sludge biological treatment and final clarification ³⁹39. Martínez-Bueno M, Uclés S, Hernando MD, Fernández-Alba A. Development of a solvent-free method for the simultaneous identification/quantification of drugs of abuse and their metabolites in environmental water by LC-MS/MS. Talanta 2011; 85:157-66.. There is a lack of information about the toxicity, despite it may be moderate ⁴⁰40. Madden JC, Enoch SJ, Hewitt M, Cronin MTD. Pharmaceuticals in the environment: good practice in predicting acute ecotoxicological effects. Toxicol Lett 2009; 185:85-101..

Losartan is an anti-hypertensive that became an affordable treatment and increased its market share in Brazil from < 5% to 53% in ten years ⁴¹41. Silva RM, Chaves GC, Chaves LA, Campos MR, Luiza VL, Bertoldi AD, et al. Farmácia Popular Program: pharmaceutical market analysis of antihypertensive acting on the renin-angiotensin system medicines. Ciênc Saúde Colet 2017; 22:2501-12.. It is present in waters in many places in Latin America, including São Paulo Metropolitan Region ¹¹11. Cotrim MEB, Martins EAJ, Furusawa HA, Shihomatsu HM, Monteiro LR, Lebre DT, et al. Qualidade ecológica da Represa Guarapiranga: água e sedimentos superficiais: multitraçadores ambientais - metais, elementos-traço, interferentes endócrinos, HPAs e fármacos. In: Bicudo C, Bicudo DC, organizadores. 100 anos da Represa Guarapiranga: lições e desafios. Curitiba: Editora CRV; 2017. p. 309-82.^,¹⁷17. Peña-Guzmán C, Ulloa-Sánchez S, Mora K, Helena-Bustos R, Lopez-Barrera E, Alvarez J, et al. Emerging pollutants in the urban water cycle in Latin America: a review of the current literature. J Environ Manage 2019; 237:408-23.^,⁴²42. Pereira CDS, Maranho LA, Cortez FS, Pusceddu FH, Santos AR, Ribeiro DA, et al. Occurrence of pharmaceuticals and cocaine in a Brazilian coastal zone. Sci Total Environ 2016; 548/549:148-54.^,⁴³43. Starling MCV, Amorim CC, Leão MMD. Occurrence, control and fate of contaminants of emerging concern in environmental compartments in Brazil. J Hazard Mater 2019; 372:17-36.. Losartan seems to have low toxicity ⁴⁴44. Cortez FS, Souza LS, Guimarães LL, Almeida JE, Pusceddu FH, Maranho LA, et al. Ecotoxicological effects of losartan on the brown mussel Perna perna and its occurrence in seawater from Santos Bay (Brazil). Sci Total Environ 2018; 637/638:1363-71., but potentially bioaccumulates and can generate cyanide ions by reaction with sodium hypochlorite in WWTP ⁴⁵45. Adachi A, Okano T. Generation of cyanide ion by the reaction of hexamine and losartan potassium with sodium hypochlorite. J Heal Sci 2008; 54:581-83..

Ibuprofen was one of the pharmaceuticals with the highest frequency in drinking water and presented the highest concentration of all in Latin America ¹⁷17. Peña-Guzmán C, Ulloa-Sánchez S, Mora K, Helena-Bustos R, Lopez-Barrera E, Alvarez J, et al. Emerging pollutants in the urban water cycle in Latin America: a review of the current literature. J Environ Manage 2019; 237:408-23.^,⁴³43. Starling MCV, Amorim CC, Leão MMD. Occurrence, control and fate of contaminants of emerging concern in environmental compartments in Brazil. J Hazard Mater 2019; 372:17-36.. The minimum and maximum concentrations varied in Brazilian raw water (0.02-4,155.5ng.L^-1) and drinking water (< 0.66-16.9ng.L^-1) ³³33. Lima D, Tonucci M, Libânio M, Aquino S. Fármacos e desreguladores endócrinos em águas brasileiras: ocorrência e técnicas de remoção. Eng Sanit Ambient 2017; 22:1043-54.. Despite its high frequency, ibuprofen is a low priority for monitoring ¹⁸18. Santos CEM, Nardocci AC. Prioritization of pharmaceuticals in drinking water exposure based on toxicity and environmental fate assessment by in silico tools: an integrated and transparent ranking. Comput Toxicol 2019; 9:12-21.; it may cause adverse effects in some organisms and its presence in WWTP effluent represents a high potential of environmental risk ³²32. Chen Y, Vymazal J, Březinová T, Koželuhc M, Kulec L, Huang J, et al. Occurrence, removal and environmental risk assessment of pharmaceuticals and personal care products in rural wastewater treatment wetlands. Sci Total Environ 2016; 566/567:1660-9.. Advanced oxidation process (AOP) removed > 90% of Ibuprofen from water in laboratory experiments ³³33. Lima D, Tonucci M, Libânio M, Aquino S. Fármacos e desreguladores endócrinos em águas brasileiras: ocorrência e técnicas de remoção. Eng Sanit Ambient 2017; 22:1043-54..

Natural and synthetic hormones can undergo interconversion through their metabolization by aerobic and anaerobic organisms, which also contributes to environmental pollution in densely populated urban centers ⁴⁶46. Adeel M, Song X, Wang Y, Francis D, Yang Y. Environmental impact of estrogens on human, animal and plant life: a critical review. Environ Int 2017; 99:107-19..

Dienogest is prescribed as a next-generation oral contraceptive. It undergoes rapid direct photolysis and forms complex products with pH between 2 and 7 ⁴⁷47. Pflug NC, Hankard MK, Berg SM, O’Connor M, Gloer JB, Kolodziej EP, et al. Environmental photochemistry of dienogest: phototransformation to estrogenic products and increased environmental persistence via reversible photohydration. Environ Sci Process Impacts 2017; 19:1414-26.. Complete and facile photodegradation of dienogest occurs in sunlit surface water, although it might be environmentally persistent through product-to-parent reversion and formation of bioactive transformation products ⁴⁷47. Pflug NC, Hankard MK, Berg SM, O’Connor M, Gloer JB, Kolodziej EP, et al. Environmental photochemistry of dienogest: phototransformation to estrogenic products and increased environmental persistence via reversible photohydration. Environ Sci Process Impacts 2017; 19:1414-26.. Data about dienogest occurrence in wastewater and surface water is rare because analytical methods to detect it in such matrices have only been developed recently ⁴⁸48. Golovko O, Šauer P, Fedorova G, Kroupová HK, Grabic R. Determination of progestogens in surface and waste water using SPE extraction and LC-APCI/APPI-HRPS. Sci Total Environ 2018; 621:1066-73.. Only a few papers reported the presence of dienogest in environmental matrices, but ecotoxicological effects remain unknown ⁴⁹49. Liu Z-H, Ogejo JA, Pruden A, Knowlton KF. Occurrence, fate and removal of synthetic oral contraceptives (SOCs) in the natural environment: a review. Sci Total Environ 2011; 409:5149-61.. Considering that dienogest is the most sold hormone in terms of mass within the São Paulo Metropolitan Region, it ought to be assessed and monitored in water bodies to evaluate possible environmental/health risks.

Antimicrobials are a therapeutic class that arouses great concern due to their environmental impacts ⁵⁰50. Michael I, Rizzo L, McArdell CS, Manaia CM, Merlin C, Schwartz T, et al. Urban wastewater treatment plants as hotspots for the release of antibiotics in the environment: a review. Water Res 2013; 47:957-95.. Although its commercialized mass is small in comparison to other pharmaceuticals drugs, it is important to note that this specific group must be observed carefully, as there are several environmental and human risks associated with its inappropriate use and disposal.

Public policies: United States, European Union, Canada and Brazil

Monitoring pharmaceutical programs in water bodies

Most countries do not execute continuous drug monitoring programs in drinking water because of the high cost, low availability of technologies and analytical methods and lack of laboratory infrastructure ⁵¹51. World Health Organization. Pharmaceuticals in drinking-water. Geneva: World Health Organization; 2012.. Therefore, most of the available data on the occurrence of pharmaceuticals drugs in water bodies and drinking water comes from academic projects carried out to develop, test and adjust methods of detection and analysis of drugs in the environment.

The U.S. Environmental Protection Agency (EPA) established the Unregulated Contaminant Monitoring Rule (UCMR), which is in its fourth edition, in order to publish once every five years a list of up to 30 unregulated contaminants that public water systems must monitor ⁵²52. United States Environmental Protection Agency. The fourth unregulated contaminant monitoring rule. Washington DC: United States Environmental Protection Agency; 2016.. The 2016 edition did not mention any pharmaceutical drug, but the former edition registered seven hormones: 17-β-estradiol, 17-α-ethinyl estradiol, 16-α-hidroxiestradiol, equilin, estrone, testosterone, and 4-androstene-3,17-dione. During the years covered by the UCMR, toxicological essays and ecological risk assessments are carried out based on concentrations reported in monitoring. Depending on the results, EPA includes the contaminant on the Candidate Contaminant List (CCL) or removes it from the monitoring list. The CCL prioritizes the contaminants to be assessed in terms of toxicological effects. After the publication of the CCL, the EPA decides on at least five contaminants present in the list to undergo regulation. If a contaminant fulfills all the criteria, EPA publishes the Maximum Contaminant Level Goal and the National Primary Drinking Water Regulation. Even though these mechanisms are essential to regulate emerging contaminants, they are not enough to meet the demand for monitoring drugs in water bodies.

The European Union follows the Directive 2013/29/EU, which requires a “watch list” to be created by the European Commission with the contaminants to be monitored. Depending on the results, a prioritization list includes the contaminants that are often detected in water with concentrations that can cause effects on human health and ecosystems. The most recent list released in 2018 followed the analysis of the Joint Research Centre ⁵³53. Loos R, Marinov D, Sanseverino I, Napierska D, Lettieri T. Review of the 1st Watch List under the water framework directive and recommendations for the 2nd Watch List. Luxembourg: Publications Office of the European Union; 2018.. The European Commission is developing strategic approaches to tackle pharmaceuticals in the environment, but each State-Member regulates the pharmaceuticals and the maximum levels within its territory ⁵⁴54. European Commission. European Union strategic approach to pharmaceuticals in the environment. Brussels: European Comission; 2019.. The Strategy Micropoll implemented in Switzerland is a good example of how to tackle the pollution caused by micropollutants, such as pharmaceuticals ⁵⁵55. Metz F, Ingold K. Politics of the precautionary principle: assessing actors’ preferences in water protection policy. Policy Sci 2017; 50:721-43..

In 2006, the Government of Canada launched the Chemicals Management Plan (CMP) to reduce the risks of chemicals to human health and the environment. The plan provides the basis to formulate national public policies and includes investments to advance research and environmental monitoring, including pharmaceuticals and personal care products. Since then, assessments have included over 4,300 chemical priorities under the CMP; more than 2,700 substances have been assessed, and over 130 were concluded to be toxic ⁵⁶56. Zidek A, Macey K, Mackinnon L, Patel M, Poddalgoda D, Zhang Y. A review of human biomonitoring data used in regulatory risk assessment under Canada’s Chemicals Management Program. Int J Hyg Environ Health 2017; 220:167-78..

Brazilian national legislation does not regulate the pharmaceuticals in drinking water and the environment. The monitoring initiatives come from academics and some environmental agencies, such as the São Paulo State Environmental Company (CETESB). Brazil still lacks an official prioritization list of pharmaceuticals to be assessed and monitored in water, so the present paper contributes by clarifying this situation and offering information for accomplishing this task.

Unit-dose systems

The rational use of medicines assumes that patients will receive the appropriate drugs for their clinical needs, in doses that meet their requirements and for an adequate period at the lowest cost for them and their community ⁵⁷57. World Health Organization. Promoting rational use of medicines: core components WHO policy perspectives on medicines. Geneva: World Health Organization ; 2002.. The United States, Canada, and Europe adopt UDS, which significantly reduce losses, costs, and prescription errors ⁵⁸58. Mieiro DB, Oliveira EBC, Fonseca REPD, Mininel VA, Zem-Mascarenhas SH, Machado RC. Strategies to minimize medication errors in emergency units: an integrative review. Rev Bras Enferm 2019; 72:307-14.. The principle is always the same: patients purchase medicines in the exact prescribed dosage and period; hospitals deliver the unit-doses according to the patient’s requirements.

Brazilian patients often acquire more medicines than prescribed because packages are sold either sealed, in primary (blister packaging), or secondary packaging (cartons), which impedes fractioning. Despite national regulation intended to establish the possibility of fractioning packages to provide the unit-doses, drugstores have not adopted the UDS. Excessive dispensing reached up to 200% for azithromycin and most of the medicines were distributed up to 30% in excess by the pharmacy of a public health unit at the São Paulo Metropolitan Region ⁵⁹59. Murakami I, Ribeiro-Neto LM, Silva AM. A importância do fracionamento de medicamentos para o SUS: um estudo piloto. Rev Bras Farm 2012; 93:221-4.. These numbers indicate the significant increase of costs for the public health system, the imminent risk of self-medication, and the potential load of pharmaceuticals in the environment, which in its turns will generate ecological impacts and externalities for users of the public water supply by increasing treatment costs, that could be all avoided by the UDS.

Pharmaceuticals disposal and reverse logistics

The United States has not implemented a national program for reverse logistics of pharmaceuticals. Initiatives are limited to the local scale and for those the U.S. Food and Drug Administration (FDA) has established three ways of disposing of pharmaceuticals in domestic usage that are no longer needed ⁶⁰60. U.S. Food and Drug Administration. Where and how to dispose of unused medicines. Washington DC: U.S. Food and Drug Administration; 2019.: (i) take-back programs, not available in the whole country; (ii) flushing down the sink or toilet (especially when harmful to others and where take-back is not available) and; (iii) disposal in household trash, except those on the FDA flush list.

In Europe, the European Federation of Pharmaceutical Industries and Associations (EFPIA) outlines the majority of reverse logistics programs for pharmaceuticals ⁶¹61. Hiratuka C, Vargas MA, Fracalanza P, Rosandiski EN, Corazza RI, Oliveira ALR. Logística reversa para o setor de medicamentos. Brasília: Associação Brasileira de Desenvolvimento Industrial; 2013.. Directive 2004/27/CE establishes that State-Members will ensure the creation of adequate collection systems for medicines that are unused or have expired. In 2013, 19 of 27 State-Members have implemented collection systems in their territories, with some national variations ⁶¹61. Hiratuka C, Vargas MA, Fracalanza P, Rosandiski EN, Corazza RI, Oliveira ALR. Logística reversa para o setor de medicamentos. Brasília: Associação Brasileira de Desenvolvimento Industrial; 2013.. More than half of the collection programs are supported by the pharmaceutical industry, with drugstores as the main collection point ⁶²67. Health Care Without Harm. Unused pharmaceuticals where do they end up? A snapshot of European collection schemes. Brussels: Health Care Without Harm; 2013..

Canada does not have national regulation regarding the collection of unused/expired medicines ⁶¹61. Hiratuka C, Vargas MA, Fracalanza P, Rosandiski EN, Corazza RI, Oliveira ALR. Logística reversa para o setor de medicamentos. Brasília: Associação Brasileira de Desenvolvimento Industrial; 2013.. Most Canadian provinces base their collection systems on the ability to ensure safety for consumers and children, reduce costs, improve therapeutic results, and diminish potential environmental impacts ⁶³63. Daughton CG. Cradle-to-cradle stewardship of drugs for minimizing their environmental disposition while promoting human health. II. Drug disposal, waste reduction, and future directions. Environ Health Perspect 2003; 111:775-85.. In the case that collection systems are not available, the Government of Canada recommends disposal of the unused/expired medicines in the household trash. Nevertheless, they do not recommend flushing any medicines down sinks or toilets.

In 2018, the Brazilian Health Regulatory Agency (Anvisa) regulated the practices in managing health systems residues (HSR) when health institutions (hospitals, ambulatories, clinics, etc.), drugstores and medicine distributors dispose of pharmaceuticals drugs (Resolution n. 222/2018). The resolution states that medicines that do not pose radiological, chemical, or biological risks must be dealt with through reverse logistics. Although other national regulations try to implement reverse logistics for pharmaceuticals, they are ineffective.

Regulations and programs to monitor pharmaceuticals in the environment vary among countries, as do the disposal and management of health residues. However, it seems that Brazil lacks initiatives and specific regulation when compared to other countries. Thus, we offer eight recommendations in order for Brazil to minimize the potential environmental/health impacts caused by the inadequate disposal of pharmaceuticals drugs (Box 1).

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Box 1
Suggestions of public policies to be implemented in Brazil regarding pharmaceuticals drugs in environment.

Final considerations

The presence of pharmaceuticals drugs in the environment has been repeatedly reported throughout the world in scientific and technical literature. For some pharmaceuticals drugs , there is concrete evidence pointing to their environmental/health impacts, although the effects of the vast majority of these substances remain unknown. As analytical methods, techniques and equipment have developed in recent years, new information on the spread and impact of pharmaceuticals drugs in the environment has helped to better plan of actions and implementation of public policies around the world.

The type and amount of medicine sold in the São Paulo Metropolitan Region indicate the pharmaceuticals drugs that can potentially accumulate in water bodies, especially urban reservoirs. The prioritization of pharmaceuticals drugs both in terms of detection and monitoring in the environment and the water requires the integration of mass sold data with other chemical and environmental attributes of such substances.

Public policies related to the consumption, disposal and reverse logistics of medicines are critical. Several countries envisage mechanisms to minimize the load of pharmaceuticals into the environment, varying only in specific operational details. In Brazil, national regulations already address this issue. However, the deficit of coverage in the sanitation network compounded by the lack of information of agents working with medicines on how to correctly dispose of it (from users and health professionals to distribution chains and sales) results in ineffective enforcement of existing regulations and greater exposure to environmental/health risks. In addition to possible improvements in legal texts, it is necessary to invest in campaigns to raise awareness of the problem, especially aimed at health professionals involved in dispensing and marketing medicines. If properly instructed, these agents will be able to disseminate the correct medical disposal guidelines to patients and consumers. Besides, it is essential to hold the pharmaceutical industry to account, from the recognition that its products are pollutants and the establishment of an effective reverse logistics structure to supporting the development of techniques and methods of detection, monitoring and remediation of pharmaceuticals, metabolites, and pharmaceuticals degradation products in the environment. In this sense, pharmaceutical industries should help finance the costs of the analytical methods required to assess and monitor pharmaceuticals in the environment by independent organizations.

Finally, the adoption of the UDS may contribute to reducing the environmental impacts of pharmaceuticals, with the additional benefit of minimizing risks of intoxication, self-medication, and consequent reduction in costs. This model has proven to be highly efficient in several countries. If Brazil overcomes this barrier, it could reduce water treatment and monitoring costs and increase the safety of drinking water for the population.

Acknowledgments

The authors are grateful to Close-Up International for providing pharmaceutical sales data, to São Paulo State Research Foundation (FAPESP) for granting (2016/06271-4 and 2019/04319-8), and to Daniel Colman for revising the text.

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³³
Lima D, Tonucci M, Libânio M, Aquino S. Fármacos e desreguladores endócrinos em águas brasileiras: ocorrência e técnicas de remoção. Eng Sanit Ambient 2017; 22:1043-54.
³⁴
Mazaleuskaya LL, Sangkuhl K, Thorn CF, FitzGerald GA, Altman RB, Klein TE. PharmGKB summary: pathways of acetaminophen metabolism at the therapeutic versus toxic doses. Pharmacogenet Genomics 2015; 25:416-26.
³⁵
Daughton CG. The Matthew Effect and widely prescribed pharmaceuticals lacking environmental monitoring: case study of an exposure-assessment vulnerability. Sci Total Environ 2014; 466/467:315-25.
³⁶
Gelotte CK. An open-label, randomized, four-treatment crossover study evaluating the effects of salt form, acetaminophen, and food on the pharmacokinetics of phenylephrine. Regul Toxicol Pharmacol 2018; 95:333-8.
³⁷
Robles-Molina J, Gilbert-López B, García-Reyes JF, Molina-Díaz A. Monitoring of selected priority and emerging contaminants in the Guadalquivir River and other related surface waters in the province of Jaén, South East Spain. Sci Total Environ 2014; 479/480:247-57.
³⁸
Estévez E, Cabrera MC, Molina-Díaz A, Robles-Molina J, Palacios-Díaz MP. Screening of emerging contaminants and priority substances (2008/105/EC) in reclaimed water for irrigation and groundwater in a volcanic aquifer (Gran Canaria, Canary Islands, Spain). Sci Total Environ 2012; 433:538-46.
³⁹
Martínez-Bueno M, Uclés S, Hernando MD, Fernández-Alba A. Development of a solvent-free method for the simultaneous identification/quantification of drugs of abuse and their metabolites in environmental water by LC-MS/MS. Talanta 2011; 85:157-66.
⁴⁰
Madden JC, Enoch SJ, Hewitt M, Cronin MTD. Pharmaceuticals in the environment: good practice in predicting acute ecotoxicological effects. Toxicol Lett 2009; 185:85-101.
⁴¹
Silva RM, Chaves GC, Chaves LA, Campos MR, Luiza VL, Bertoldi AD, et al. Farmácia Popular Program: pharmaceutical market analysis of antihypertensive acting on the renin-angiotensin system medicines. Ciênc Saúde Colet 2017; 22:2501-12.
⁴²
Pereira CDS, Maranho LA, Cortez FS, Pusceddu FH, Santos AR, Ribeiro DA, et al. Occurrence of pharmaceuticals and cocaine in a Brazilian coastal zone. Sci Total Environ 2016; 548/549:148-54.
⁴³
Starling MCV, Amorim CC, Leão MMD. Occurrence, control and fate of contaminants of emerging concern in environmental compartments in Brazil. J Hazard Mater 2019; 372:17-36.
⁴⁴
Cortez FS, Souza LS, Guimarães LL, Almeida JE, Pusceddu FH, Maranho LA, et al. Ecotoxicological effects of losartan on the brown mussel Perna perna and its occurrence in seawater from Santos Bay (Brazil). Sci Total Environ 2018; 637/638:1363-71.
⁴⁵
Adachi A, Okano T. Generation of cyanide ion by the reaction of hexamine and losartan potassium with sodium hypochlorite. J Heal Sci 2008; 54:581-83.
⁴⁶
Adeel M, Song X, Wang Y, Francis D, Yang Y. Environmental impact of estrogens on human, animal and plant life: a critical review. Environ Int 2017; 99:107-19.
⁴⁷
Pflug NC, Hankard MK, Berg SM, O’Connor M, Gloer JB, Kolodziej EP, et al. Environmental photochemistry of dienogest: phototransformation to estrogenic products and increased environmental persistence via reversible photohydration. Environ Sci Process Impacts 2017; 19:1414-26.
⁴⁸
Golovko O, Šauer P, Fedorova G, Kroupová HK, Grabic R. Determination of progestogens in surface and waste water using SPE extraction and LC-APCI/APPI-HRPS. Sci Total Environ 2018; 621:1066-73.
⁴⁹
Liu Z-H, Ogejo JA, Pruden A, Knowlton KF. Occurrence, fate and removal of synthetic oral contraceptives (SOCs) in the natural environment: a review. Sci Total Environ 2011; 409:5149-61.
⁵⁰
Michael I, Rizzo L, McArdell CS, Manaia CM, Merlin C, Schwartz T, et al. Urban wastewater treatment plants as hotspots for the release of antibiotics in the environment: a review. Water Res 2013; 47:957-95.
⁵¹
World Health Organization. Pharmaceuticals in drinking-water. Geneva: World Health Organization; 2012.
⁵²
United States Environmental Protection Agency. The fourth unregulated contaminant monitoring rule. Washington DC: United States Environmental Protection Agency; 2016.
⁵³
Loos R, Marinov D, Sanseverino I, Napierska D, Lettieri T. Review of the 1st Watch List under the water framework directive and recommendations for the 2nd Watch List. Luxembourg: Publications Office of the European Union; 2018.
⁵⁴
European Commission. European Union strategic approach to pharmaceuticals in the environment. Brussels: European Comission; 2019.
⁵⁵
Metz F, Ingold K. Politics of the precautionary principle: assessing actors’ preferences in water protection policy. Policy Sci 2017; 50:721-43.
⁵⁶
Zidek A, Macey K, Mackinnon L, Patel M, Poddalgoda D, Zhang Y. A review of human biomonitoring data used in regulatory risk assessment under Canada’s Chemicals Management Program. Int J Hyg Environ Health 2017; 220:167-78.
⁵⁷
World Health Organization. Promoting rational use of medicines: core components WHO policy perspectives on medicines. Geneva: World Health Organization ; 2002.
⁵⁸
Mieiro DB, Oliveira EBC, Fonseca REPD, Mininel VA, Zem-Mascarenhas SH, Machado RC. Strategies to minimize medication errors in emergency units: an integrative review. Rev Bras Enferm 2019; 72:307-14.
⁵⁹
Murakami I, Ribeiro-Neto LM, Silva AM. A importância do fracionamento de medicamentos para o SUS: um estudo piloto. Rev Bras Farm 2012; 93:221-4.
⁶⁰
U.S. Food and Drug Administration. Where and how to dispose of unused medicines. Washington DC: U.S. Food and Drug Administration; 2019.
⁶¹
Hiratuka C, Vargas MA, Fracalanza P, Rosandiski EN, Corazza RI, Oliveira ALR. Logística reversa para o setor de medicamentos. Brasília: Associação Brasileira de Desenvolvimento Industrial; 2013.
⁶⁷
Health Care Without Harm. Unused pharmaceuticals where do they end up? A snapshot of European collection schemes. Brussels: Health Care Without Harm; 2013.
⁶³
Daughton CG. Cradle-to-cradle stewardship of drugs for minimizing their environmental disposition while promoting human health. II. Drug disposal, waste reduction, and future directions. Environ Health Perspect 2003; 111:775-85.

Publication Dates

Publication in this collection
23 Nov 2020
Date of issue
2020

History

Received
02 Oct 2019
Reviewed
29 Mar 2020
Accepted
27 Apr 2020

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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Guo J, Sinclair CJ, Selby K, Boxall ABA. Toxicological and ecotoxicological risk-based prioritization of pharmaceuticals in the natural environment. Environ Toxicol Chem 2016; 35:1550-9.

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Straub JO, Caldwell DJ, Davidson T, D’Aco V, Kappler K, Robbinson PF, et al. Environmental risk assessment of metformin and its transformation product guanylurea. I. Environmental fate. Chemosphere 2019; 216:844-54.

[32] ³²
Chen Y, Vymazal J, Březinová T, Koželuhc M, Kulec L, Huang J, et al. Occurrence, removal and environmental risk assessment of pharmaceuticals and personal care products in rural wastewater treatment wetlands. Sci Total Environ 2016; 566/567:1660-9.

[33] ³³
Lima D, Tonucci M, Libânio M, Aquino S. Fármacos e desreguladores endócrinos em águas brasileiras: ocorrência e técnicas de remoção. Eng Sanit Ambient 2017; 22:1043-54.

[34] ³⁴
Mazaleuskaya LL, Sangkuhl K, Thorn CF, FitzGerald GA, Altman RB, Klein TE. PharmGKB summary: pathways of acetaminophen metabolism at the therapeutic versus toxic doses. Pharmacogenet Genomics 2015; 25:416-26.

[35] ³⁵
Daughton CG. The Matthew Effect and widely prescribed pharmaceuticals lacking environmental monitoring: case study of an exposure-assessment vulnerability. Sci Total Environ 2014; 466/467:315-25.

[36] ³⁶
Gelotte CK. An open-label, randomized, four-treatment crossover study evaluating the effects of salt form, acetaminophen, and food on the pharmacokinetics of phenylephrine. Regul Toxicol Pharmacol 2018; 95:333-8.

[37] ³⁷
Robles-Molina J, Gilbert-López B, García-Reyes JF, Molina-Díaz A. Monitoring of selected priority and emerging contaminants in the Guadalquivir River and other related surface waters in the province of Jaén, South East Spain. Sci Total Environ 2014; 479/480:247-57.

[38] ³⁸
Estévez E, Cabrera MC, Molina-Díaz A, Robles-Molina J, Palacios-Díaz MP. Screening of emerging contaminants and priority substances (2008/105/EC) in reclaimed water for irrigation and groundwater in a volcanic aquifer (Gran Canaria, Canary Islands, Spain). Sci Total Environ 2012; 433:538-46.

[39] ³⁹
Martínez-Bueno M, Uclés S, Hernando MD, Fernández-Alba A. Development of a solvent-free method for the simultaneous identification/quantification of drugs of abuse and their metabolites in environmental water by LC-MS/MS. Talanta 2011; 85:157-66.

[40] ⁴⁰
Madden JC, Enoch SJ, Hewitt M, Cronin MTD. Pharmaceuticals in the environment: good practice in predicting acute ecotoxicological effects. Toxicol Lett 2009; 185:85-101.

[41] ⁴¹
Silva RM, Chaves GC, Chaves LA, Campos MR, Luiza VL, Bertoldi AD, et al. Farmácia Popular Program: pharmaceutical market analysis of antihypertensive acting on the renin-angiotensin system medicines. Ciênc Saúde Colet 2017; 22:2501-12.

[42] ⁴²
Pereira CDS, Maranho LA, Cortez FS, Pusceddu FH, Santos AR, Ribeiro DA, et al. Occurrence of pharmaceuticals and cocaine in a Brazilian coastal zone. Sci Total Environ 2016; 548/549:148-54.

[43] ⁴³
Starling MCV, Amorim CC, Leão MMD. Occurrence, control and fate of contaminants of emerging concern in environmental compartments in Brazil. J Hazard Mater 2019; 372:17-36.

[44] ⁴⁴
Cortez FS, Souza LS, Guimarães LL, Almeida JE, Pusceddu FH, Maranho LA, et al. Ecotoxicological effects of losartan on the brown mussel Perna perna and its occurrence in seawater from Santos Bay (Brazil). Sci Total Environ 2018; 637/638:1363-71.

[45] ⁴⁵
Adachi A, Okano T. Generation of cyanide ion by the reaction of hexamine and losartan potassium with sodium hypochlorite. J Heal Sci 2008; 54:581-83.

[46] ⁴⁶
Adeel M, Song X, Wang Y, Francis D, Yang Y. Environmental impact of estrogens on human, animal and plant life: a critical review. Environ Int 2017; 99:107-19.

[47] ⁴⁷
Pflug NC, Hankard MK, Berg SM, O’Connor M, Gloer JB, Kolodziej EP, et al. Environmental photochemistry of dienogest: phototransformation to estrogenic products and increased environmental persistence via reversible photohydration. Environ Sci Process Impacts 2017; 19:1414-26.

[48] ⁴⁸
Golovko O, Šauer P, Fedorova G, Kroupová HK, Grabic R. Determination of progestogens in surface and waste water using SPE extraction and LC-APCI/APPI-HRPS. Sci Total Environ 2018; 621:1066-73.

[49] ⁴⁹
Liu Z-H, Ogejo JA, Pruden A, Knowlton KF. Occurrence, fate and removal of synthetic oral contraceptives (SOCs) in the natural environment: a review. Sci Total Environ 2011; 409:5149-61.

[50] ⁵⁰
Michael I, Rizzo L, McArdell CS, Manaia CM, Merlin C, Schwartz T, et al. Urban wastewater treatment plants as hotspots for the release of antibiotics in the environment: a review. Water Res 2013; 47:957-95.

[51] ⁵¹
World Health Organization. Pharmaceuticals in drinking-water. Geneva: World Health Organization; 2012.

[52] ⁵²
United States Environmental Protection Agency. The fourth unregulated contaminant monitoring rule. Washington DC: United States Environmental Protection Agency; 2016.

[53] ⁵³
Loos R, Marinov D, Sanseverino I, Napierska D, Lettieri T. Review of the 1st Watch List under the water framework directive and recommendations for the 2nd Watch List. Luxembourg: Publications Office of the European Union; 2018.

[54] ⁵⁴
European Commission. European Union strategic approach to pharmaceuticals in the environment. Brussels: European Comission; 2019.

[55] ⁵⁵
Metz F, Ingold K. Politics of the precautionary principle: assessing actors’ preferences in water protection policy. Policy Sci 2017; 50:721-43.

[56] ⁵⁶
Zidek A, Macey K, Mackinnon L, Patel M, Poddalgoda D, Zhang Y. A review of human biomonitoring data used in regulatory risk assessment under Canada’s Chemicals Management Program. Int J Hyg Environ Health 2017; 220:167-78.

[57] ⁵⁷
World Health Organization. Promoting rational use of medicines: core components WHO policy perspectives on medicines. Geneva: World Health Organization ; 2002.

[58] ⁵⁸
Mieiro DB, Oliveira EBC, Fonseca REPD, Mininel VA, Zem-Mascarenhas SH, Machado RC. Strategies to minimize medication errors in emergency units: an integrative review. Rev Bras Enferm 2019; 72:307-14.

[59] ⁵⁹
Murakami I, Ribeiro-Neto LM, Silva AM. A importância do fracionamento de medicamentos para o SUS: um estudo piloto. Rev Bras Farm 2012; 93:221-4.

[60] ⁶⁰
U.S. Food and Drug Administration. Where and how to dispose of unused medicines. Washington DC: U.S. Food and Drug Administration; 2019.

[61] ⁶¹
Hiratuka C, Vargas MA, Fracalanza P, Rosandiski EN, Corazza RI, Oliveira ALR. Logística reversa para o setor de medicamentos. Brasília: Associação Brasileira de Desenvolvimento Industrial; 2013.

[62] ⁶⁷
Health Care Without Harm. Unused pharmaceuticals where do they end up? A snapshot of European collection schemes. Brussels: Health Care Without Harm; 2013.

[63] ⁶³
Daughton CG. Cradle-to-cradle stewardship of drugs for minimizing their environmental disposition while promoting human health. II. Drug disposal, waste reduction, and future directions. Environ Health Perspect 2003; 111:775-85.

City	Inhabitants (2010)	Health units (2009)	Health units/10,000 inhabitants	GDP per capita - USD (2016)	Households served by sanitation facilities in 2017 (%)
São Paulo	11,253,503	2,541	2.3	14,849.99	95.7
Guarulhos	1,221,979	242	2.0	10,503.63	87.7
São Bernardo do Campo	765,463	308	4.0	13,332.55	95.9
Santo André	676,407	299	4.4	9,432.21	98.7
Osasco	666,740	177	2.7	27,800.23	89.1
Mauá	417,064	78	1.9	7,938.44	94.5
Mogi das Cruzes	387,779	140	3.6	8,743.39	85.3
Diadema	386,089	77	2.0	8,291.29	93.3
Carapicuíba	369,584	36	1.0	3,439.37	79.5
Itaquaquecetuba	321,770	37	1.1	4,746.14	67.6
Suzano	262,480	86	3.3	8,553.21	93.4
Taboão da Serra	244,528	44	1.8	7,873.50	97.9
Barueri	240,749	107	4.4	46,246.73	98.2
Embu das Artes	240,230	25	1.0	9,843.94	71.8
Cotia	201,150	55	2.7	12,238.02	51.0
Itapevi	200,769	28	1.4	13,955.80	62.4
Ferraz de Vasconcelos	168,306	21	1.2	3,982.24	81.8
Francisco Morato	154,472	23	1.5	2,101.01	41.9
Itapecerica da Serra	152,614	29	1.9	5,929.10	29.2
São Caetano do Sul	149,263	165	11.1	21,767.37	99.6
Franco da Rocha	131,604	24	1.8	4,335.34	62.7
Ribeirão Pires	113,068	50	4.4	6,491.23	72.9
Santana de Parnaíba	108,813	12	1.1	17,080.83	41.1
Jandira	108,344	17	1.6	7,403.98	74.8
Poá	106,013	27	2.5	9,857.84	99.1
Caieiras	85,529	31	3.6	7,258.80	73.9
Mairiporã	80,956	30	3.7	4,538.34	21.9
Arujá	74,905	25	3.3	14,446.77	68.6
Cajamar	64,114	18	2.8	46,490.06	89.1
Embu-Guaçu	62,769	9	1.4	4,083.01	36.8
Santa Isabel	50,453	14	2.8	5,810.00	46.7
Rio Grande da Serra	43,974	13	3.0	3,078.49	51.5
Vargem Grande Paulista	42,997	10	2.3	9,167.20	32.7
Juquitiba	28,737	12	4.2	3,733.51	13.9
Biritiba Mirim	28,575	5	1.7	6,104.27	47.8
Guararema	25,844	2	0.8	12,954.15	46.0
Pirapora do Bom Jesus	15,733	5	3.2	3,898.05	50.3
Salesópolis	15,635	4	2.6	3,036.52	51.6
São Lourenço da Serra	13,973	5	3.6	3,333.90	28.3
Total	19,682,975	4,831	2.5	10,632.58	89.5

Active principle	Commercialized mass (kg)	Drug class	Excretion in unaltered form (%)
Dipyrone	488,445	Nonsteroidal anti-inflammatory drugs	*
Metformin	310,067	Antidiabetics	100
Paracetamol	94,881	Nonsteroidal anti-inflammatory drugs	3.5-5.0
Phenylephrine	57,202	Nasal decongestant	-
Chlorpheniramine	56,666	Anti-allergy and antihistamines	-
Losartan	42,337	Antihypertensives	4.0
Sodium bicarbonate	41,709	Antacids	*
Citric acid	39,895	Antacids	*
Ibuprofen	37,110	Nonsteroidal anti-inflammatory drugs	1.0
Zinc	33,747	Electrolytes and nutrition	*

Active ingredient	Mass sold (kg)
Dienogest	1,564.92
Estradiol	1,339.44
Drospirenone	127.88
Testosterone	126.64
Ciproterone	67.56
Ethynilestradiol	58.63
Levonorgestrel	56.46
Noretisterone	54.07
Levotiroxine	14.16
Desogestrel	4.90
Gestodene	0.95
Total	3,415.62

Saúde Pública

Saúde Pública

Pharmaceutical market, environmental public policies and water quality: the case of the São Paulo Metropolitan Region, Brazil

Mercado farmacêutico, políticas públicas ambientais e qualidade da água: o caso da Região Metropolitana de São Paulo, Brasil

Mercado farmacéutico, políticas públicas ambientales y calidad del agua: el caso de la Región Metropolitana de São Paulo, Brasil

Abstract:

Resumo:

Resumen:

Introduction

Material and methods

São Paulo Metropolitan Region

Source of data and analysis

Results

Discussion

Public policies: United States, European Union, Canada and Brazil

Monitoring pharmaceutical programs in water bodies

Unit-dose systems

Pharmaceuticals disposal and reverse logistics

Final considerations

Acknowledgments

References

Publication Dates

History