Next Article in Journal
Do Healthy City Performance Awards Lead to Health in All Policies? A Case of Taiwan
Next Article in Special Issue
The Potential Environmental Impact of PAHs on Soil and Water Resources in Air Deposited Coal Refuse Sites in Niangziguan Karst Catchment, Northern China
Previous Article in Journal
No Established Link between Repeated Transient Chokes and Chronic Traumatic Encephalopathy Related Effects. Comment on Lim, L.J.H. et al. Dangers of Mixed Martial Arts in the Development of Chronic Traumatic Encephalopathy. Int. J. Environ. Res. Public Health 2019, 16, 254
Previous Article in Special Issue
Determination of Metal Content of Waste Mobile Phones and Estimation of Their Recovery Potential in Turkey
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
IJERPH
Volume 16
Issue 6
10.3390/ijerph16061060
ijerph-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Review

Waste Mismanagement in Developing Countries: A Review of Global Issues

by
Navarro Ferronato
* and
Vincenzo Torretta
Department of Theoretical and Applied Sciences, University of Insubria, Via G.B. Vico 46, I-21100 Varese, Italy
*
Author to whom correspondence should be addressed.
Int. J. Environ. Res. Public Health 2019, 16(6), 1060; https://doi.org/10.3390/ijerph16061060
Submission received: 6 March 2019 / Revised: 20 March 2019 / Accepted: 22 March 2019 / Published: 24 March 2019
(This article belongs to the Special Issue Hazardous Waste and Human Health)
Browse Figures
Versions Notes

Abstract

:
Environmental contamination due to solid waste mismanagement is a global issue. Open dumping and open burning are the main implemented waste treatment and final disposal systems, mainly visible in low-income countries. This paper reviews the main impacts due to waste mismanagement in developing countries, focusing on environmental contamination and social issues. The activity of the informal sector in developing cities was also reviewed, focusing on the main health risks due to waste scavenging. Results reported that the environmental impacts are pervasive worldwide: marine litter, air, soil and water contamination, and the direct interaction of waste pickers with hazardous waste are the most important issues. Many reviews were published in the scientific literature about specific waste streams, in order to quantify its effect on the environment. This narrative literature review assessed global issues due to different waste fractions showing how several sources of pollution are affecting the environment, population health, and sustainable development. The results and case studies presented can be of reference for scholars and stakeholders for quantifying the comprehensive impacts and for planning integrated solid waste collection and treatment systems, for improving sustainability at a global level.

1. Introduction

Solid waste (SW) mismanagement is a global issue in terms of environmental contamination, social inclusion, and economic sustainability [1,2], which requires integrated assessments and holistic approaches for its solution [3]. Attention should be paid in developing and transition countries, where the unsustainable management of SW is common [4]. Differences should be highlighted between developing big cities and rural areas, where management issues are different, specifically regarding the amount of waste generated and the SW management (SWM) facilities available [5]. However, both suffer negative economic legislatives, political, technical and operational limitations [6].
Uncontrolled disposal generates serious heavy metals pollution occurring in the water, soil, and plants [7], open burning is cause of CO, CO2, SO, NO, PM10 and other pollutant emissions that affect the atmosphere [8], waste picking within open dump sites pose to serious health risk people working on these areas [9], release of SW in water bodies improve the marine litter globally, enhancing environmental contamination [10]. Therefore, SW mismanagement is cause of sever and various environmental and social impacts, which do not allow improvements in sustainable development.
Achieving both economic growth and sustainable development involves reduction plans of the global ecological footprint, changing the way of produce-consume-waste of goods and resources [11]. The material footprint of developing countries grew from 5 t inh−1 in 2000 to 9 t inh−1 in 2017, representing a significant growing in living standards, although its sustainable management is not still included in national regulations [12]. The principles of sustainable development were introduced within the sustainable development goals (SDGs), where 17 objectives were introduced for reducing poverty, improving social equality, decreasing environmental pollution and ameliorating city livability. In particular, the global waste management goals for improving sustainability at global level are: to ensure, by 2020, access for all to adequate, safe and affordable SW collection services; to stop uncontrolled dumping and open burning; to achieve sustainable and environmentally sound management of all wastes, particularly hazardous ones, by 2030 [13].
Many studies reported possible solutions for improving the SWM in developing countries, such as organic waste buyback programs, with compost or biogas production [14], implementation of waste-to-energy plans and technologies [15], waste-to-energy in parallel with recycling of glass, metals, and other inert [16], production of energy from biomass waste by making briquettes [17], involvement of the integration of waste pickers with legal incentives [18], among others. However, many barriers still remain for improving formal collection, treatment and final disposal [19]. Therefore, environmental contamination remains a big issue worldwide, while common solutions should be identified and implemented considering SWM patterns appropriate for each context.
Many reviews were published about SWM in developed and developing countries and about environmental contamination from waste. In particular, about char fuel production [20], management of waste electric and electronic equipment (WEEE) [21], food waste management [22] and treatment [23], recycling of used batteries [24], inclusion of the informal sector [25] and the risks that such activity pose for vulnerable informal workers [26], atmospheric pollution due to SWM [27], household hazardous waste management [28] and healthcare waste (HW) management [29], among others. The novelty of the narrative review presented in this article is its focus on the integrated assessment of these waste streams, analyzing the global issues affecting the environment and the public health, giving attention to the operational risk of the informal recycling sector. Concentration of contamination in water, air and soil are provided, as well as waste quantities and amounts dumped in developing cities or recycled by the informal sector. Results allow suggesting directions for future SWM improvements, considering its planning as an integrated system and providing examples of the consequences of its inadequate implementation.
The paper is divided in three main sections: the first analyzes the environmental impacts due to unsustainable management of municipal SW (MSW), WEEE and used batteries, waste tires, C&D waste and other hazardous and industrial wastes; the second is focused on the informal recycling, analyzing main risks due to waste picking and opportunities for its inclusion within the formal SWM system. The last section is a critical discussion of current and future challenges for improving environmental quality at global level, identifying the opportunities due to SWM selective collection and treatment systems. Finally, some suggestions are provided, according to the literature review.

2. Methods

This article reviews the open dumping and open burning of waste, main practices implemented for waste treatment and disposal in developing countries, involving many environmental and health impacts [30,31,32]. Such unsustainable practices include every waste fraction, such as MSW, HW, construction & demolition (C&D) waste, used tires, WEEE, used batteries, and industrial waste, each one spreading specific contaminant concentrations in soil, water and air environments. Waste pickers work within these sites for collecting recyclable materials that are sold in local markets. Though this informal practice allows decreasing the amounts of waste inflow into water bodies and open dumps [33,34], it is also a hazardous activity that improves health and occupational risks [35,36]. Therefore, concerning waste open burning and open dumping, the narrative review presented in this article explores environmental impacts due to unsustainable SWM, such as water, air and soil pollution, health and operation risks, global warming potential (GWP) and marine pollution. The theoretical framework of the review is schematically reported in Figure 1.
The scientific literature considered was collected from three main databases: Scopus, Web of Science and Science Direct. The keywords used for reviewing the literature were the ones that refer to the issues concerning solid waste management in developing countries, therefore combining the keywords “solid waste” and “developing countries” with: open burning, open dumping, informal recycling, health risk, environmental contamination, air-water-soil pollution, C&D, HW, WEEE, used batteries, industrial waste, marine litter. Only papers wrote in English were considered. The scientific articles were reviewed during the months of January and February 2019, analyzing only the literature from 2002 to 2019. Case studies and reviews were considered for the research, with particular focus on developing cities and contaminated area in Latin America and the Caribbean, Africa, Eastern Europe, Middle East, Asia and Oceania. Developed countries were considered only for specific case studies, such as fire of waste tires in final disposal sites and the comparison of same issues detectable worldwide, such as the marine litter in the Mediterranean Sea. Treatment technologies and collection systems were not assessed in terms of contribution of pollution and health risks.

3. Environmental and Social Issues due to SW Mismanagement

3.1. MSW open Dumping

In developing countries, the management of SW is worsened by unsustainable practices that improve the environmental contamination and the spread of diseases. In particular, the open dumping in uncontrolled sites, open burning of waste fractions and the mismanagement of the leachate produced in final disposal sites, are the main issues detectable [37]. The situation is worsened in slum areas with additional problems of high-density population, traffic, air and water pollution. Uncontrolled disposal in open spaces near water bodies are issues widespread in these contexts, which corresponds to public health issues [38]. Concerning open air final disposal, the main environmental impacts detectable are:
  • visual impacts,
  • air contamination, odors and green-house gasses (GHG) emission,
  • vectors of diseases,
  • surface water and groundwater pollution.
These issues are visible worldwide. In Banjul (Gambia) the dump site is located in a densely populated area, visible to the residents [39]. It has a negative visible impact on inhabitants and tourists visiting the country. In particular, the smoke from burning debris is the biggest issue, which covers parts of the residential areas, affecting also the life quality of the population. Indeed, the citizens are affected by the smoke from burning debris and the smell of decomposing waste. The nuisances are worst during the rainy period as the area becomes infested with flies and insects. Run off from the dump site with contaminants dissolved inflow into water bodies, while the leachate contaminates the soil and groundwater. Moreover, environmental contamination is due to the high level of fecal and total coliform that polluted the wells located near the site. The households that live around the dump site use well water for various purposes, although with high level of coliforms attributed to the proximity to the dump site [39].
In Cambodia, in the capital city Phnom Penh, where the MSW management (MSWM) system lacks regulation, households commonly burned, buried, or dumped about 361,000 tons of MSW in 2008, and 635,000 tons in 2015 [40]. In Thailand, more than 60% of the SW final disposal was carried out by open dumping. In 2004 there were 425 disposal sites, of which 330 open dumps, the majority of disposal sites received around 25 tons of waste per day, while only the landfills of Bangkok received about 4500 tons per day [41]. In the West Bank Palestinian territory, in 2005 was estimated that the MSW generated was about 2728 t per day, while in 2001 there were 133 MSW dumpsites, open burning activities at 116 sites and burial at 13 sites; 64.9% of the population was aware of the environmental issues and impacts associated with open dumpsites, and 41.6% thought that they were suffering from the final disposal sites [42]. In Abuja, the capital city of Nigeria, more than 250,000 tons of waste were generated per year in 2010. There were four major disposal sites under its management, closed in 2005 due to odors, air pollution and burning wastes at the site. Moreover, percolation of leachate from the buried waste flowed to the surface, especially during rainy seasons [43]. In Maputo, administrative center of Mozambique, with about 1,200,000 inhabitants and where about 0.5 kg of waste per inhabitants are generate daily, the MSW is transported to the official dumpsite of the city, in operation since more than 40 years. The area is of about 17 ha, with heights that achieved 15 m; open fires and auto ignition of the waste are common issues, exacerbated by the more than 500 waste pickers collecting recyclables waste at the dumpsite [44]. Therefore, SWM issues are common worldwide, with environmental burdens and hazard for the population.
The landfill leachate generates in open dump sites contains concentration of organic carbons, ammonia, chloride, heavy metals [45], as well as high concentrations of fluoride, chloride, ammonium–nitrogen, biological oxygen demand (BOD) and chemical oxygen demand (COD) [46]. For instance, the MSW dumped at Mathkal dump site (Kolkata, India), is affecting the degradation of water quality in and around dumpsite area: Cd and Ni are detectable in leachate, improving groundwater contamination; the metals Pb, Cd, Cr and Ni are characterized as toxic for drinking water, and the concentration of these components increases near an unsanitary landfill and may lead to serious toxic risks. Indeed, It has been reported that the concentration of Cr, Cd, and Mn were higher in the groundwater due to leachate, affecting the life of the population and the quality of the environment [47].
In Chennai city, the capital of Tamil Nadu, India, where more than 3200 t d−1 of SW are generated, the leaching of heavy metals in the water imposes serious health risks to humans. Heavy metal concentration of the soil samples at various depths ranges from 3.78 mg kg−1 to 0.59 mg kg−1 at a depth of 2.5 to 5.5 m, with concentration higher in the top soil up to a depth of 5.5 m (sandy clay layer). Therefore, the concentrations of heavy metals decreased with increasing soil depth, demonstrating the influence of the dumping activities [48]. In Nonthaburi dumpsite, Thailand, the concentration of heavy metals was detected in boreholes and runoff. Within the runoff and the groundwater, the concentrations of chrome, cadmium, lead, nickel and mercury, are always 10 times above the limits introduced by the World Health Organization (WHO) for drinking water [49]. In Tiruchirappalli district, India, the MSW generation is about 400–600 tons per day and it is served by an open dumping site located 12 km from the city. The leachate shows that the range of COD range to 29,880–45,120 mg L−1 and the BOD5 / COD ratio was less than 0.1. Based on the average concentration, the quantity of lead and cadmium were 5 and 11 times higher the soil contamination limits. The presence of heavy metals (Pb, Cu, Mn, and Cd) in soil sample, undetectable in the near areas, indicates that there was appreciable contamination of the soil by leachate migration [50].
In Table 1 pollutant concentrations in soil, runoff and groundwater in eight different case studies, compared with the limits imposed by international organizations for soil and water quality are reported. In the case studies reviewed, the analysis was implemented at a distance variable from 20 to 400 from the final disposal sites. Data about runoff and groundwater contamination were compared with drinking water limits since, in low-middle income areas, groundwater is the most use for drinking without adequate treatments. Results reported always a correlation between leachate and environmental contamination. Heavy metals are always the ones persistent within the samples, also 10 times more than the limits suggested by the WHO, with high concentrations of COD. So, open dumping poses surrounding population to serious health risks.
Another environmental issue due to organic waste open dump is the GWP due to waste anaerobic degradation. Methane gas is a by-product of landfilling MSW; since MSW is mainly disposed of in open dump sites, the generated methane is released directly to the atmosphere. Experimental studies indicate that the anaerobic biodegradation of MSW organic waste generates about 200 Nm3 of methane per dry tons of biomass [58]. Methane is one of the most important gas that improve the GWP, 25 times higher than CO2 [59]. Therefore, open dumps and uncontrolled landfills are direct source of GHG.
As a comparison, GHG emissions from waste landfilling were estimated per type of final disposal site: open dump, conventional landfills with energy recovery, and landfills receiving low-organic-carbon waste. The results showed that about 1000 kg CO2-eq. t−1 are generated from an open dump, 300 kg CO2-eq. t−1 from a conventional landfilling of mixed waste and 70 kg CO2-eq. t−1 for low-organic-carbon waste landfills. If compared with the emissions due to provision of energy and materials to the landfill, estimated to 16 kg CO2-eq. t−1, it can be stated that open dump cause a GWP at least 50 times higher than the total MSWM system [60]. In Beijing City, where more than 60% of the waste is disposed of in sanitary landfills, an environmental impacts assessment showed that CH4 emission is the most dominant contributor to GWP, with the annual amount of 55,000 tons; the landfills contribute the most to the impact potentials mainly due to methane emissions [61]. In India, most of the SW are disposed of by landfilling in open dump sites, generating large quantities of CH4. At national level, It was estimated that the methane emission from MSW disposal varies from 263,020 t in year 1980 to 502,460 t in year 1999 [62], increasing rapidly during the years.
Therefore, the mitigation of pollution and GHG emission can be obtained through the recovery and conversion of organic component to energy or compost. The main role is played by policy interventions, which should act through the incorporation of the waste management hierarchy considering direct and indirect impacts that would reduce the global carbon footprint [63].

3.2. Marine Litter

Open dumping cause surface water pollution due to leachate mismanagement and material uncontrolled flows. A visible impact that is affecting the seas and the oceans globally is the marine littering, which is mainly caused by plastic waste [64,65]. Marine litter is defined as manufactured or SW entering the marine environment irrespective of the source. The range and scale of impacts from marine litter are diverse [66]:
  • Environmental (ingestion, poisoning, blockage of filter, physical damage of reefs and mangroves, among others),
  • Social (loss of visual amenity, loss of indigenous values, risks to health and safety),
  • Economic (cost to tourism, cost to vessel operators, losses to fishery, costs for cleanup, animal rescue operations, recovery and disposal),
  • Public safety (navigational hazards, hazards to swimmers and divers, cuts, abrasion and stick injuries, leaching of poisonous chemicals, explosive risk).
About 80% of marine litter generation is mainly caused by the mainland, by the rivers that inflow into the seas [67]. Therefore, open dumping can be considered as the first cause of pollution of the oceans. More hazardous is the generation of micro-plastics: Once in the ocean, most plastics tend to stay at or close to the surface where the photo-chemical, mechanical and biological processes degrade larger items into smaller, less than 5 mm, forming microplastics [68]. Potentially, microplastics are ingested when present in the marine environment and tend to float on the sea surface. There, they can be ingested passively or actively by a wide range of organisms [69]. A simple scheme has been provided by do Sul et al. [69], where the definition of direct or indirect ingestion of micro-plastic, which can affect human health, is clarified (Figure 2).
A study published in 2019 reported that, in the Mediterranean Sea, microplastics are 94.6% in number and 55%wt of all plastics whereas meso-plastics represented 5.3% in abundance and 45% in weight of all plastics. In this study, only 1 macro-plastic was sampled, which represented 0.1% in abundance of all plastics and weighed five times more than all the collected plastics together [70]. It means that the amounts of micro-plastic are increasing, improving the risk of direct and indirect intake within the trophic chain, achieving human feeding. Moreover, a study conducted in the Pacific Ocean, discovered plastics from the 1960s, which means that the marine littering and the pollution of the sea is 60 years old, improving the amount of microplastics detectable into the marine environment [71].
The implementation of sound waste management collection and disposal practices, involvement of manufacturers, and behavior change are key aspects of any solution. At an intermediate stage, innovation is needed around the litter generation points: upstream, redesigning goods for reducing generation quantities; and downstream, improving collection and treatment systems. Long-term technical solutions for recovering the existing used plastics in the world’s seas should also be implemented [37]. Finally, a specific focus on low-middle income countries should be considered, since they are the main source of pollution although the generation rates are the lowest.

3.3. MSW open Burning

Waste open dumping is not the only environmental burden due to waste mismanagement. The combustion of waste with any precaution generates also contaminants, improving health risks to the population [72]. Polychlorinated dibenzo-p-dioxins (PCDDs), polychlorinated dibenzofurans (PCDFs), and polychlorinated biphenyls (PCBs) were detected in soils around dumping sites in The Philippines, India, Cambodia, and Vietnam [73]. Uncontrolled combustion, generation of methane gas, and low-temperature burning are major factors for the formation of dioxins in dumping sites. Considerable loading rates of PCDD/Fs in the dumping sites of these countries (200–4000 tons per day) were observed, ranging from 0.12–35 mg TEQ yr−1 [73].
Open dumping sites in Surabaya and Palembang, Indonesia, have concentrations of PCDD/Fs and dioxin-like polychlorinated biphenyls (DL-PCBs) in soil of about 61,000–310,000 fg TEQ g−1 (dry weight) and 6300–32,000 fg TEQ g−1, respectively. Low levels of PCDD/Fs and DL-PCBs, ranging from 75 to 98 and 0.32 fg TEQ g−1, respectively, were observed in soil for an open dumping site that included a top cover layer of soil. The difference in concentrations can be explained by the fact that open burning of waste is the source of PCDD/Fs and DL-PCBs. A sensitivity analysis implemented in this area found that the maximum emission factor could be 5,600,000 fg TEQ g−1 [74].
A controlled incineration that treated about 100,000 t of MSW per year, required for a city of about 350,000 inhabitants who generate about 0.8 kg MSW per day, generates about 40,000 fg TEQ m−3 [75], which is equal to 24 mg TEQ yr−1, considering a production of 6000 m3 of combustion gases per ton of waste burned. Therefore, open dumping can generate more quantities of dioxins per year than an incinerator, also with uncontrolled leachates, diseases vectors, odors and GHG, affecting the environment and population’s health.
In the Municipality of Huejutla, Mexico, approximately 24% of the total waste generated was burned by households, of which 90% in rural areas, where there was not an MSW collection system. This practice generates environmental contamination and contributes to the GWP by the production of black carbon (BC). It has estimated that about 8,882 tons of waste are burned per year, producing 1.97 kg BC t−1, 11.9 kg PM10 t−1, and 9.8 PM2.5 t−1 that contributed for 17.5 t BC y−1 (38,553 t CO2-eq per year), 105.7 t PM10 y−1 and 87.0 t PM2.5 y−1, for a total of 313.7 kg CO2-eq y−1 per capita. The results showed that the CO2-eq from BC emitted by waste open burning was more than 15 times larger compared to CH4 potentially released from the decomposition of equivalent amounts of combustible organic waste deposited at the dumpsite [76]. In another study, it was found that the majority of PM generated by waste open burning had smaller sizes (PM1) compared to PM2.5 and to PM10. In particular, the PM size were 0.35 µm, with about 63.0 µg m−3 generated, and 0.45 µm, with 67.8–87.7 µg m−3. Therefore, 0.45 µm had the highest peak concentration among all the compounds. The study demonstrated that the smallest-sized particles (0.35 and 0.45 µm), which represents the most hazardous for the population health, constituted the greatest percentage of total PM emissions, founding that the concentration of ultrafine particles represent another source of hazard for population health [77]. The review of the scientific literature indicated that open burning should be avoided and replaced with appropriate and sustainable technologies for reducing environmental pollution and public concerns. Know-how is required, as well as financial support for improving waste recovery and final disposal at global level.

3.4. Health and Environmental Risks due to HW Mismanagement

SW is not only municipal. There are various fractions hazardous for the environment and the population health that are generally mismanaged in developing countries. One of these fractions are the HW [78]. The term HW includes all the waste generated within health-care facilities. In addition, it includes the same types of waste originating from minor and scattered sources, including waste produced during health care undertaken at home. Between 75% and 90% of HW is comparable to MSW, so “non-hazardous” or “general HW”. The remaining 10–25% of HW is hazardous and may pose a variety of environmental and health risks [79]. Details about HW fractions is reported in Table 2.
Open dumping is the most common method of HW disposal in developing countries [80,81,82], although several authors suggest sterilizing the HW at the point of generation in order to eliminate infectious substance and improve safety management [83]. Open dumping is the lowest cost option for low income countries, although it is an uncontrolled and inadequate disposal, since the waste can be accessible to waste pickers and animals and the generation of pollutant is not monitored. In this way, HW transmits infectious pathogenic micro-organisms to the environment either via direct contact, through inhalation, ingestion, or indirect contact through the food chain. Burning is aimed to reduce the volume of waste and its infectious effect, however, uncontrolled burning activates are potential source of toxic emissions like PCDD/F, among other pollutants [84].
In the West Bank (Palestine), a study shows that 82.2% of HW is disposed of in (unsanitary) dump sites and only 17.9% of healthcare facilities dispose of their waste more than 7 times a week, the frequency recommended by the WHO. Therefore, the final disposal locations in the West Bank are uncontrolled final disposal sites, which are randomly distributed throughout the region, with poor precautions for transporting and colleting the HW [85]. In Ibadan, Nigeria, more than 60% of HW handlers did not discriminate between HW and MSW during collection and handling stages. Similarly, 66% dispose of HW with MSW at the final disposal site (open dumps). Incidences of contacting diseases are prevalent among waste handlers, compared to incidence of other hospital staff, with high incidences of viral blood infections, such hepatitis B and C. Within the open dump sites, technical and hygienic considerations are neglected or absent. For instance, several waste pickers were observed collecting HW for reselling materials considered recyclable, to pass-on to unsuspecting low-income patients. Moreover, leachate from waste disposal sites could be infiltrating and contaminating groundwater resources [86]. In Dhaka, Bangladesh, HW is collected by waste pickers who sort the waste through the bins searching for recyclables and reusable items (syringes, blades, knives, saline bags, plastic materials and metals). Scavenging activities were again observed sorting through the open dumping disposal sites, increasing the risk of diseases (Figure 3). The study reported that both scavengers and recycling operators had any knowledge of the risks from HW exposure. Employers of recycling operators did not consider occupational health and safety training for their employees. The situation was still more worrying among the marginal groups of the society [87].
The lack of appropriate HW management systems and disposal facilities in Dhaka is largely due to inadequate economic resources and legislation. This leads to the persistence of inappropriate practices such as the discharge of chemical waste into the general sewerage system or dumping into near land. HW was found to have been dumped in MSW bins, and finally disposed of on general landfill sites, which may contaminate the ground water and improve operational risks. It was observed that, during the rainy season, leachate from dumps used for HW infiltrated into water that was being used for washing and for household purposes, as well as for agriculture [88].
Therefore, in low-income countries, HW management is an environmental and social issue that spread the risk of disease and pollution. Disposal strategies involve sorting HW at the healthcare facilities, and then transporting the infectious HW to safe disposal sites, where it is treated by incineration or other technologies and the residual product landfilled. Every treatment technology has drawbacks, with incineration creating atmospheric emissions, and other treatments not able to handle all types of waste. The best way to control the impact of HW is to train healthcare workers along with the implementation of standardized HW streams and disposal bin colors, which can ensure a selective collection of the waste, improving the efficiency of treatment and final disposal [89]. Good results were obtained in San Salvador (El Salvador), where an information campaign was implemented for the employee of tertiary hospitals. Before the activity, the employees disposed of common waste in containers for infectious waste, increasing the hospital’s financial and operational burden, while after the project the quantities were halved, demonstrating the good compliance of the operators and of the activities implemented [90].

3.5. Open Dumping and Burning of WEEE and Used Batteries

Global WEEE generation has reached approximately 41 million tons in 2014, increasing at a rate of 3–5% every year [91]. The production of WEEE was correlated with the GDP, while there is no significant correlation or trend with the population. If this waste is properly recycled, it could offer an opportunity for the recovery of copper, gold, silver, palladium and other metals with an estimated value of USD 48 billion. In particular, the concertation of metals in the WEEE is significantly higher than in the natural ores that these metals are mined from (for Au it is almost 130 times higher) [91]. WEEE are classified into six different types of waste [92]:
  • Temperature exchange equipment: refrigerators, freezers, air-conditioner, heat pump,
  • Screens and monitors: televisions, monitors, laptops, notebooks, tablets,
  • Lamps: fluorescent lamps, high-intensity discharge lamps,
  • Large equipment: washing machines, clothes dryers, electric stoves, large printing machines, copying machines, photovoltaic panels,
  • Small equipment: vacuum cleaners, toasters, microwaves, ventilation equipment, calculators, radio, camera, toys, medical devices, small monitoring and control equipment,
  • Small telecommunication equipment: mobile phones, GPS, telephones.
Developing countries are producing WEEE double than developed countries. It is also estimated that the developing and developed countries will discard 400–700 million obsolete computers by 2030. Moreover, developed countries are also exporting their WEEE to developing countries for dumping, causing serious environmental and social concerns. The majority of WEEE are being sent to Africa or Asia [93]; in Figure 4 are reported the estimated flows of the waste from high income to low income countries.
WEEE is becoming a source of income for the industries and creates new jobs. However, in developing countries WEEE are mainly disposed of in open dump sites, burned without properly precautions and managed by illegal actors [95,96]. In India, Bangalore city generates 18,000 tons of WEEE per year, thousands of which are landed illegally every year [93]. In Lagos State, Nigeria, near an open dump site where WEEE and used batteries are disposed of with MSW, the heavy metal concentrations in well water and soil were investigated during the dry season [97]. Results reported that concentrations in wells were Pb 2.77 mg L−1, Cd 0.035 mg L−1, Zn 0.948 mg L−1, Cr 0.520 mg L−1 and Ni 1.45 mg L−1, while Ni concentrations in soils ranged from 35.45 mg kg−1 at a depth of 15–30 cm in the wet season to 85.43 mg kg−1 at a depth of 0–15 cm in the dry season. The elevated level of metals in the well water are correlated with the metal input from leachates resulting from the dumping of WEEE. In fact, significant levels of Pb and Ni were found in well and tap water at the residences, while the concentrations of heavy metals decreased when the sampling distances from the dumpsite increased [97]. Moreover, concentrations of lead, chrome and nickel are generally higher than the ones reviewed in studies conducted near MSW open dumps (Table 1), suggesting that the presence of high amounts of WEEE is cause of heavy metal pollution of water bodies and soils.
In Tijuana (Mexico), a study analyzed the concentrations of Cd, Cr, Cu, Pb and Ni in the soil near an open dump site where end-of-life vehicle (ELV) and WEEE are disposed of, together with the activity of waste pickers who recover the precious metals [98]. The mean concentrations found were 1.4 mg kg−1 for Cd, 4.7 mg kg−1 for Cr, 304 mg kg−1 for Cu, 74 mg kg−1 for Pb and 6 mg kg−1 for Ni. The results of the geo-accumulation index values show that the site was very polluted with Cu and Pb. The correlation analysis shows a high connection between Pb and Cu, which would be explained if the main source of the polluting heavy metals was the result of electrical wire burning to recover copper. The other two components detected within the study were Cr and Ni, related to the corrosion of junk metal objects and automobile use [98]. Again, in this case study, it is evident that the presence of WEEE is responsible of heavy metal pollution of the soil and therefore of the groundwater used for house uses. Therefore, within Table 1 results of open dumps that also contains WEEE, used batteries and ELV were reported.
Together with WEEE mismanagement, used batteries should be also mentioned. For instance, in Iran, almost 10,000 tons of household batteries were imported, most of them have been discarded in MSW without any separation and sent to sanitary landfills [99]. In addition to environmental and human health risks associated with unsafe disposal of used batteries in MSW stream, their landfilling implies the depletion of valuable resources. It is expected that more than 9000 tons of used batteries have been dumped in municipal landfills of Iran in recent decades. The most concern regarding battery disposal in MSW is directed to the high percentage of mercury, cadmium, lithium, nickel, arsenic and other toxic and heavy metals [99].
The challenges facing the developing countries in WEEE and used batteries management include the absence of infrastructure for appropriate waste management, lack of legislation dealing specifically with these waste fractions, the absence of any framework for end-of-life product take-back or implementation of extended producer responsibility (EPR) [100]. Moreover, the growing rate of WEEE amount in developing countries is destined to increase in the next future [101]: A great amount (almost 50%) of current WEEE yearly generated by developed countries continues to be illegally transferred in developing countries, volumes that remains unknown; New electric and electronic products will substitute soon the current ones, influencing both collected volumes, type of recovered materials and recycling processes; Innovative materials composing WEEE, that are currently not correctly managed during their end-of-life (ending into landfills); some electronic parts in WEEE are not again correctly disassembled or recovered [101]. In summary, many challenging issues of WEEE and used batteries management can be detected in developing countries [102]:
  • Quantity of WEEE generated is a major concern due to the lack of infrastructure,
  • Inventory assessment of WEEE does not exist,
  • Exportation of WEEE from developed countries to developing countries for recycling worsens its management,
  • Absence of knowledge regarding the toxic nature of WEEE and used batteries,
  • Portion or components of WEEE are often mixed with MSW and disposed of in open dump sites,
  • Deficient knowledge of the impacts to human health and the environment,
  • Legislation to regulate and control the import and disposal of the generated WEEE do not exist.
Environmentally sound management requires the establishment of collection, transportation, treatment, storage, recovery and disposal of WEEE. Regulatory authorities should have to provide these facilities and for the better performance there should be incentives. Communication campaigns should be oriented to the citizens, in order to improve and incentive the selecting collection of the waste, avoiding open dumping. Furthermore, incentives for municipalities that demonstrate the best results when participating in recycling initiatives should be adopting, in order to motivate the citizens in supporting local management policies and actions [103].

3.6. C&D Waste open Dumping

The term “C&D waste” is generally used to refer to the SW generated in the construction sector. More specifically, the term is defined as the waste generated from construction, demolition, excavation, site clearance, roadwork, and building renovation [104]. The main issue due to C&D waste is final disposal site landslides, which can affect the life of the population. For avoiding this impact, the volume of waste dumped in landfills should be reduced, imposing safe operating practices. In particular, 4Rs (reduce, reuse, recycle and recover) policies should be implemented, with hazardous or toxic materials that should be the primary targets [104]. As example, in 2015, a landslide in one of China’s most advanced cities, Shenzhen, killed 73 people and damaged 33 buildings, in the absence of heavy rainfall or earthquakes (Figure 5). According to China’s Ministry of Land and Resources, the landslide was triggered by the collapse of an enormous pile of C&D waste [105].
In Thailand, in 2014 the average generation of C&D waste was approximately 4,200,596 tons, which were disposed of in open dump sites. Hazardous and potentially hazardous materials were found, such as:
  • asbestos-based materials,
  • lead-based materials,
  • other materials used for construction (e.g., damp-proofing chemicals, adhesives),
  • mercury-containing electrical equipment (e.g., fluorescence lamps, thermostats),
  • chlorine fluoride carbides (e.g., air conditioners and refrigerators),
  • corrosive, flammable and toxic materials.
Hazardous waste was not separated from non-hazardous waste for proper treatment and disposal. It means that an increasing of the construction sector also contributed to the increasing of environmental pollution [106]. It has been estimated that between 2002 and 2005, an average of 1.1 million tons of C&D waste was generated per year in Thailand [107]. This constitutes about 7.7% of the total amount of waste disposed in both landfills and open dumpsites annually during the same period. Therefore, the generation of C&D waste was affected by a relevant increase. Indeed, recently, the management of C&D waste took attention due to its rapidly increasing and unregulated dumping [108]. Waste generation at a construction site may result from lack of attention being paid to the size of the products used, lack of interest of contractors, lack of knowledge about construction during design activities, and poor materials handling. Generally, 50–80% of C&D waste is reusable or recyclable, so C&D mismanagement represents a loss of valuable economic resources [107].
In Hanoi, Vietnam, processing quantities of informal and formal C&D waste recyclers were revealed [109]. However, current practices lacked appropriate C&D waste classifications and control of waste flows by private companies due to little efficiency or cost saving strategies, low attention for adding value to concrete waste recycling and lack of government legislative and financial support for industry transformation. Illegal dumping occurs in the city boundary, also due to the lack of technology, capacity and economic resources. Many construction sites mix C&D waste such as cement, bricks, steel, and plastics, disallowing the classification and recycling of these fractions [109]. In Malaysia, in the first quarter of 2015, the construction industry contributed 15.1% of the country’s GDP and provided employments to about 10% (1.4 million) of the total workforce in Malaysia. Four key issues were addressed for developing an effective C&D waste management: the increasing amount of waste, environmental impacts, illegal dumping, and lack of national support. In Malaysia, the recycling framework for improving C&D waste management is built following a three-layer approach [110]: At the micro-level, reducing wastes at the source; at meso-level, ensuring that there is a continuous effort in managing wastes, transforming the procurement methods; Finally, at the macro-level, providing monitoring, and coordinating mechanisms to ensure the practice of effective C&D waste management [110].
Therefore, for developing countries with limited financial resources, C&D waste management initiatives and sustainable construction can be achieved through effective utilization of resources, material recovery, and an improved system for waste management. However, the first objective to be achieved is the implementation of strong regulatory initiatives for construction waste management [111]. These practices can reduce the issue of the open dumping, which is worsened by the mix with MSW and informal recycling that operates in these uncontrolled areas.

3.7. Diseases Exposure due to Used Tires open Dumping and Burning

Tires that are used, rejected or unwanted are classified as ‘waste tires’, as well as tires intended to be used for retreading or recycling. This type of waste is composed of steel, rubber and textiles, and the volume depend on the use of the tires. Three main issues should be addressed concerning waste tires:
  • big volumes, which reduce the useful life of the sanitary landfill and improve the transportation costs,
  • open air burning of these materials, which contaminate the environment improving population health risks,
  • presence of disease vectors, such as insects or rodents, which live inside the holes and furrows of the tires.
In developing countries, limited data reliability on used tires availability and collection is common, as well as small activities of uncontrolled waste recovery, with cases of illegal dumping [112]. One of the most hazardous problems regards the spread of Dengue, which is currently one of the most important diseases in tropical areas. About 2.5 billion people live in areas of risk and many millions of cases occurring each year [113]. A study assessed the breeding mosquito larvae, identifying the dengue vectors distributed in Tamilnadu (India). Totally 118 water containers were inspected, among which 38 containers were recorded as positive for dengue vector. Among all type of containers analyzed, cement cistern, mud pot and used tires were positive for the mosquito larvae [113]. Therefore, the final disposal in open dump sites of waste tires should be avoided for reducing the spread of Dengue diseases in topical areas.
Another impact that affect the population health is the uncontrolled burning of waste tires. In Nepal, where the uncontrolled open-air burning of waste tires is practiced also during political agitation, a study was conducted to provide background information for assessing the environmental pollution due to tire fires [114]. The effect of the tire fires on air is a major concern, because they release potentially hazardous gases such as CO, SO2 and NO2 as well as polyaromatic hydrocarbon (PAH) and volatile organic compounds (VOC). CO is formed whenever carbon or substances containing carbon are burned with an insufficient air supply. Tire fires, apart from intense heat, give off BC with CO emission. Results of the research reported that the emission levels of CO from different type of tires were 21–49 g kg−1, SO2 emission was found to be 102–820 g kg−1, while NO2 emission was 3–9 g kg−1 [114]. These emissions can be compared with wood combustion, in order to have an indication about the pollutants of major concerns due to tires burning. Emissions of pollutants from residential wood combustion sources in wood-burning stoves are NOx—NO2 0.5 g kg−1, SOx—SO2 0.2 g kg−1, CO 83–370 g kg−1 and PM 0.6–8.1 g kg−1 while in fireplaces are of NOx—NO2 1.8 g kg−1, SOx—SO2 absent and CO 11–40 g kg−1 [115]. Therefore, it is evident that the generation of sulfur compounds generate more environmental concern in terms of quantity produced if compared with wood fire.
Open fire issues are also detectable in high-income countries, where waste tires landfills are still an issue. A large and uncontrolled fire of a tire landfill started in Toledo (Spain), and experimental analysis were implemented for measuring the potential impact at local and regional levels [116]. Outdoor and indoor measurements of different parameters were carried out at a near school, approximately 700 m downwind the burning tires. Among metals, ZnO and Co were 21 and 92 times higher than an area far from the open fire, reaching 933 µg m2, compared with 13 µg m2 in the farther zone. Increases of SO2 and PM10 levels were also detected, with sulfate concentrations of 1371 µg m2, 11 times higher than the control zone [116]. A similar study was conducted in the Iowa city landfill, (United States), where the outdoor concentrations of pollutants generated from 18 day tire fire were assessed [117]. The study estimated maximum concentrations of tire fire PM2.5 smoke at distances of 1, 5 and 10 km of 243, 55 and 26 mg m−3, respectively. SO2, PM2.5, BC, and air toxic VOC had also high concentrations if compared with areas far from the fire. In another study, where tire smoke was investigated, BC, biphenyl, benzene, benzaldehyde, PM, and CO were highly ranked hazards [117].
These environmental issues due tire open dumping and open burning should be addressed in an integrated manner, in order to avoid these practices. One suggestion provided by various authors is to introduce the EPR, to ensure environmentally effective management of end-of-life waste, following 4Rs [118]. This regulation tool wants to prevent waste formation and promote source reduction. If this is not possible, waste should be reused, recycled, and then recovered for energy, while landfilling should be avoided. Accordingly, the tire EPR system should reduce the generation of tire waste, facilitate its reuse, promote recycling and other forms of material recovery and, finally, incentive the energy recovery, although LCA studies confirmed that the material recycling of tire waste provides greater environmental benefits than energy recovery [118,119,120].

3.8. Industrial Waste open Dumping

Finally, environmental contamination due to industrial waste mismanagement should be considered, since they are mostly hazardous. There are many different types of hazardous industrial waste, as well as source of contamination, such as mine tailings, fly ash, waste from the production of chemicals (e.g., phosphoric acid), residues from coal mining, acidic waste rock, carbide slag, among others [121].
In a tanneries area located in Ranipet (India), where chromate chemicals were manufactured, a large quantity of hazardous SW was stacked in open dump sites. This practice resulted in fast migration of the contamination to the groundwater, with levels of chromium up to 275 mg L−1, 1000 times higher than the recommendations of the WHO for drinking water. The findings are of relevance for addressing the groundwater pollution due to indiscriminate disposal practices of hazardous waste [122]. A primary lead smelter operated in Santo Amaro City in Brazil, from 1960 to 1993, leaving approximately 500,000 tons of industrial waste containing 2–3% of lead and other toxic elements that contaminated the soil. The waste was deposited on the grounds belonging to the smelter, without any cover or precaution. In 2008 the average concentrations in soil were 1040 mg kg−1 for Pb, 2.73 mg kg−1 for Cd, 22 mg kg−1 for Ni, 295 mg kg−1 for Zn and 5.2 mg kg−1 for As, with a strong correlation among Cd, As and Zn. Therefore, the contamination due to heavy metals persists during 15 years, affecting the population surrounding the site, in particular the youngest [123]. In Dar es Salaam City (Tanzania), industrial waste (paints, pharmaceuticals, rubber, plastic, metal scraps, packaging materials, among others) are disposed with MSW within open dump sites. The dump of hazardous and non-hazardous wastes poses serious public health and environmental issues, since rainwater leach from the waste to the groundwater contaminating the surrounding areas [124]. Same issues regard the agriculture industries, with the production of waste related to pesticide containers and spry solutions. For example, in rural areas of Greece, farmers are used to dumping the empty containers on irrigation canals or in the field, sometimes burning or troughing them in others waste open dumps, generating river, soil and atmospheric contamination [125].
These results show that also industrial waste management is an underestimated issue and should be treated with appropriate methodologies and technologies. SW collection represent the first step, avoiding open dumping, after which a selective collection should be implemented in order to allow the recovery of valuable materials. Afterwards, incineration, chemical physical treatments, and appropriate final disposal should be implemented in function of the waste fraction generated, such as waste oils and solvents, batteries, emulsions and chemicals, sludges and refractory materials, among others [126].

4. Informal Recycling and Social Inclusion

Worldwide, there is a considerable presence of the informal sector in SWM, particularly in low-middle income cities where formal selective collection systems for recyclable materials are not still developed [127]. Informal activities tend to intensify in times of economic crises and where imported raw materials are quite expensive. However, its inclusion in formal SWM systems remain a problematic issue and considerable attention from NGOs and scholars is arising for solving such problem [37].
In Figure 6 is reported a simplified scheme that represent the selective collection chain of the informal sector [128]. The structure is of a specific case study in China, however, the structure is similar worldwide. The informal pickers collect the waste in open dump sites, bins, roads and households for segregating recyclable materials. These people can be organized or alone, with or without transportation means, and can be merchants or simply pickers. The waste is then sold to trading points that collect the waste and sell it again to formal or informal recyclers or directly to manufactures. This structure can be recognized in many case studies within the scientific literature.
Many studies were implemented and published, in order to assess how the informal sector could be included in the formal management or recognized by the local population. For instance, in Ulaanbaatar (Mongolia), the informal sector operates in t informal neighborhoods. In these areas, illegal dumping is common, and some open fields became uncontrolled disposal sites, with waste pickers working and living near these areas. In 2004, the World Bank estimated that about 5000 to 7000 informal recyclers worked in Ulaanbaatar, and today this number could be higher due to the increase in city’s population. A study in the city revealed that most waste pickers have also higher education at a university, suggesting that the activity is due to many factors (e.g., lack of work). Informal waste pickers select recyclable materials and bring them by foot to secondary dealers for obtaining an income, who then sell larger quantities to the respective recycling industries [129].
In Blantyre (Malawi), MSW is disposed of in pits, along the road-side, or in the river. Waste pickers process and transform recyclable materials reducing the amount of waste disposed at dumpsites and decreasing the use of virgin materials needed for manufacturing. However, waste pickers are rarely recognized for their contribution. The two waste categories selected by the pickers are plastic and metals. No data are available for quantifying the number of waste pickers, however it was estimated that the maximum quantity of waste selected per day was about 20–30 kg d−1 [130]. In Harare, Zimbabwe, where the quantities of waste generated within the city are not known, the informal sector operates, mainly in open dump sites. Indeed, the waste collected by the formal collection is disposed of in dumpsites, where about 220 waste pickers worked. Waste pickers required a license to enter the dumpsite and had to wait for a worker’s signal before they could start recovering materials. It was estimated that the informal recycling sector recovered about 6–10% of waste deposited at the final disposal site (about 27–50 tons per day). Competition with others pickers was considered as the major challenge for the collectors, as well as workplace health and safety and discrimination among the population [131]. In Zavidovici (Bosnia Herzegovina), where solid waste is disposed of in open dumps, informal recycling represents the main income-generating activity for a group of ethnically discriminated households. These families contribute to the recovery of iron, copper, plastics and cardboard from MSW, reducing the waste inflow into the dump sites [132]. Finally, in Iloilo City (The Philippines), where some 170 tons of waste (about 50% of the total generated) are disposed of in an open dumpsite, approximately 300 households recover recyclable materials for selling them in local markets. A pilot project with international NGOs was implemented, in order to convert the organic waste into energy through briquette production. Results of the study show that the integration of the informal sector in the production of biomass briquettes can be a good option for implementing integrated plans for including informal recyclers, especially in areas where their activity is forbidden, as in The Philippines [133].
In Table 3, seven case studies are compared in order to assess which are the number of pickers, their organization, its source of waste, the quantities and the fractions collected per day and the main issues detected by the studies. Results reported that waste pickers operate both in low income (Zimbabwe) and high-income countries (China). Mostly, informal sector collect waste from uncontrolled open dump sites and are not recognized or organized by the local municipalities. Waste pickers can collect from 14 to 60 kg of recyclable waste per day, which comprehend WEEE, MSW and HW.
Regarding the environment and the recovery of resources, the benefits are evident in many cities. In some places informal-sector service providers are responsible for a significant percentage of waste collection. In Cairo (Egypt), the informal recycling is implemented since the recyclable waste recovered are sold to the private companies, while the organic fractions are used for breeding pigs [137]; in Dhanbad Municipality (India), informal recyclers play an important role in the plastic waste management, collecting the recyclable plastic waste from landfills, rendering environmental and social benefits [138]; In Bogotá (Colombia), informal recyclers collect materials from waste, motivated by profits, due to the free-market enterprise for recycling [136]; in Nuevo Laredo (México), where migration has increased the population to over 250,000 inhabitants, unemployed informal recyclers recovered 20 kg of aluminum cans and cardboard per day, making in one day the minimum-wage of one week of a factory worker [139]. In all these international realities, the main factors that allows the activity of the informal sector is the presence of low-income communities, unemployment, lack of MSW collection and the free management of waste.
Therefore, the activity of the informal sector contributes directly to the recovery of the materials and the reduction of environmental contamination. This practice is in accordance with the circular economy (CE) principles. The objective of the CE is closing of material loops, to prevent waste from final disposal, and transforming the resulting residual streams into new secondary resources [140]. It proposes a system where 4Rs provide alternatives to the use of raw virgin materials, making sustainability more likely [141]. The CE typically includes economic processes such as “reverse logistics” or “take back” programs that recover wastes for beneficial reuse, avoiding final disposal costs, often reducing raw material costs and even generating incomes [142]. Therefore, the inclusion of the informal sector represents a key strategy for improving the CE concepts, improving social, environmental and economic sustainability [143].
The activities of the informal sector regard the degree of formalization, from unorganized individuals in dumpsites, to well organized cooperatives. Therefore, issues such as exploitation by middlemen, child labor and high occupational health risks need to be challenged for addressing sustainability [144]. Globally, SWM remains a negative economy, where individual citizens pay the cost, the financial viability of recycling is disputed, and the sector remains vulnerable to great price volatility. Most of the collection systems in developed countries are subsidized, and also result in substantial exports of recyclables in global secondary resources supply chains. Moreover, if taxes, health insurance, child schooling and training provisions, management costs and other typical costs are included within the informal waste sector, it is not clear if the sector come back to being unsustainable economically [144].
It is recognized that a door-to-door collection service of source-separated recyclables may be one of the best solutions for improving RR. Therefore, the informal sector has the opportunity to deliver important environmental benefits, becoming an active agent of behavior change. Moreover, its activity can reduce the waste inflow into water bodies, decreasing the amount of marine litter in the oceans. The inclusion of the informal recycling should be more investigated, assessing pros and cons of its activity in different realities worldwide [144].

5. Discussion

From the review, it is clear that there is a strong linkage between poor SWM and environmental/health issues. The rapid increase in population, economic growth, urbanization and industrialization improve the generation of SW at global level, boosting environmental contamination when such SW is not managed. Indeed, in many developing countries waste is scattered in urban centers or disposed of in open dump sites. The lack of infrastructure for collection, transportation, treatment and final disposal, management planning, financial resources, know-how and public attitude reduces the chances of improvement, as pointed out also by other authors [145]. In Table 4 the main source of contamination and health risks due to SW mismanagement for each waste stream are summed up.
Nevertheless, the generation of SW can be also considered a source of opportunities: generation of renewable energy, new employment, new economic advantages, private investments and improvement of population awareness about environmental issues. In developing countries, the informal sector plays the main role in recycling where plastic, glass, metal and paper have a developed market. Appropriate strategies should be introduced for supporting these activities, such as improved public awareness, enaction of specific laws and regulations and implementation of SWM infrastructures. For instance, a study conducted in Bogotá (Colombia), found that the main external requirements for including the activity of the informal sector regards the recognition of recyclers’ work, the formal alliances with the productive sector and the stabilization of the prices of recycling material [146]. Therefore, actions should be implemented both by private companies and local governments.
Support can be provided with the assistance of NGOs, private companies or international funds, for boosting the 4Rs, which included waste separation at the source involving residents, institutions, local governments and local companies. A good example was provided in Managua, Nicaragua, where over the last five years, several international cooperation projects have focused on the improvement of SWM systems creating multi-stakeholder platforms, designing and implementing joint activities for improving technical capacity and awareness, boosting the implementation of integrated and appropriated projects [147]. Therefore, some recommendations should be introduced for improving the SWM systems at global level, as also suggested by other authors [148]:
  • Improve public education and awareness among citizens and waste pickers,
  • Improve financial sustainability of the SWM systems,
  • Involve several stakeholders for improving system resilience,
  • Include safety precautions in the informal recycling sector,
  • Implement studies for assessing waste composition and characteristics.
In developing countries, in agreement with the results of a LCA study, good environmental protection can be accomplished by recycling and composting, since high amounts of organic fraction MSW are associated with environmental impacts [102], while inclusion of the informal sector is suggested due to the low economic investment required and technological simplicity [149]. Such options are in agreement with the circular economy (CE) principle, an emerging topic that has attracted research interest. However, three components should be included in the definition of CE [150]: re-circulation of resources and energy, recovering value from waste; implementation of multi-level approach; assessing the innovation introduced within the society. These principles are mainly implemented in European countries and in China, while in low income countries these activities are still under development [151]. Furthermore, another study found that the main incentive for the development of SWM in municipalities was the economy; the environment and public health are only secondary drivers [152]. CE patterns specific for developing countries should be introduced, focusing on big cities, since financial sustainability, multi-level approaches, and energy recovery are options that to date are not affordable in these contexts. Therefore, the scientific literature and research should move to this direction, providing sustainable solutions for low-middle income countries and appropriate technologies for boosting the CE.

6. Conclusions

The article presented a narrative review about environmental contamination and social issues in developing countries due to SW mismanagement. Results show that the SWM system should be considered in an integrated manner in order to cope with the reduction of the environmental footprint and to improve the targets of the SDSs. Too many times, SWM is considered as a single stream disposed in open dump sites. However, the implementation of future management plans requires the application of ad hoc collection and treatment solutions for each waste flow produced in municipal areas: MSW (organic and inorganic), HW, C&D waste, WEEE and used batteries, industrial and hazardous waste and used tires. Stakeholders and governments should know that SWM is a complex system that involves environmental, social and economic issues, which should be evaluated holistically for improving the life cycle of waste, reducing water, soil and air contamination due to open burning and open dumping, practices widespread worldwide.
Inclusion of the informal sector can be considered a viable way for improving the recycling rate and reducing the waste inflow into final disposal sites in developing countries, due to low technological requirements and economic investments. However, further investigations and efforts should be implemented for understanding the most appropriate strategy for its involvement. In Latin America various pilot project were implemented by the organization of cooperatives including waste pickers that have provided good results. However, in some areas of Asia and Africa this practice is forbidden and represents an obstacle to a formal selective collection system. Therefore, specific patterns should be implemented for each context, exploiting the activities just in place introducing the CE principles, remembering that informal recycling cannot be the only system in action; improving waste collection and selective collection coverage of municipal areas, introducing awareness and information campaigns, implementing appropriate treatment systems with regulations and control agencies, improving final disposal sites and its management, enhancing financial sustainability of the systems and introducing future management plans are all practices required for improving the integrated SWM system of a country, region, municipality or rural area.
From this review it is clear that common projects should be introduced at a global level in order to reduce the environmental contamination and health issues due to waste open dumping and burning. Authorities and the actors involved in waste management should be aware of the global issues which are affecting sustainable development, providing such information to the population for spreading awareness and its inclusion in recycling and prevention activities, also available within the scientific literature and this review. It should be specified that waste mismanagement has impacts at three levels: municipal or local impacts, such as soil and groundwater pollution, spread of diseases due to animal vectors (mosquitos, rodents) and air contamination; regional impacts, due to pollution of waterbodies used for agriculture and household purposes; global impacts, such as global warming and marine littering. Therefore, a common front should be organized for reducing these impacts globally, for improving environmental conditions and sustainable development.

Author Contributions

Conceptualization, methodology, investigation, data curation, writing—original draft preparation, and writing—review & editing, N.F.; Supervision, V.T.

Funding

This research was funded by The Rotary Foundation, grant number GG1758711 Scholarship provided by the Clubs Rotary Bassano del Grappa Castelli and Rotary Sopocachi La Paz.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Gupta, N.; Yadav, K.K.; Kumar, V. A review on current status of municipal solid waste management in India. J. Environ. Sci. (China) 2015, 37, 206–217. [Google Scholar] [CrossRef] [PubMed]
  2. Vitorino de Souza Melaré, A.; Montenegro González, S.; Faceli, K.; Casadei, V. Technologies and decision support systems to aid solid-waste management: A systematic review. Waste Manag. 2017, 59, 567–584. [Google Scholar] [CrossRef] [PubMed]
  3. Bing, X.; Bloemhof, J.M.; Ramos, T.R.P.; Barbosa-Povoa, A.P.; Wong, C.Y.; van der Vorst, J.G.A.J. Research challenges in municipal solid waste logistics management. Waste Manag. 2016, 48, 584–592. [Google Scholar] [CrossRef] [Green Version]
  4. The World Bank. What a Waste: A Global Review of Solid Waste Management; The World Bank: Washington, DC, USA, 2012. [Google Scholar]
  5. Ferronato, N.; Rada, E.C.; Gorritty Portillo, M.A.; Cioca, L.I.; Ragazzi, M.; Torretta, V. Introduction of the circular economy within developing regions: A comparative analysis of advantages and opportunities for waste valorization. J. Environ. Manag. 2019, 230, 366–378. [Google Scholar] [CrossRef]
  6. Imam, A.; Mohammed, B.; Wilson, D.C.; Cheeseman, C.R. Solid waste management in Abuja, Nigeria. Waste Manag. 2008, 28, 468–472. [Google Scholar] [CrossRef] [PubMed]
  7. Vongdala, N.; Tran, H.D.; Xuan, T.D.; Teschke, R.; Khanh, T.D. Heavy metal accumulation in water, soil, and plants of municipal solid waste landfill in Vientiane, Laos. Int. J. Environ. Res. Public Health 2019, 16, 22. [Google Scholar] [CrossRef] [PubMed]
  8. Wiedinmyer, C.; Yokelson, R.J.; Gullett, B.K. Global emissions of trace gases, particulate matter, and hazardous air pollutants from open burning of domestic wastE. Environ. Sci. Technol. 2014, 48, 9523–9530. [Google Scholar] [CrossRef] [PubMed]
  9. Gutberlet, J.; Baeder, A.M. Informal recycling and occupational health in Santo André, Brazil. Int. J. Environ. Health Res. 2008, 18, 1–15. [Google Scholar] [CrossRef]
  10. UNEP-Global. Marine Litter: A Global Challenge; UNEP: Athens, Greece, 2009; ISBN 9789280730296. [Google Scholar]
  11. Sustainable Development Goals Fund Goal 12: Responsible Consumption and Production; United Nations Dev. Program; SDG Fund: New York, NY, USA, 2016.
  12. UN. The Sustainable Development Goals Report; UN: New York, NY, USA, 2018. [Google Scholar]
  13. Wilson, D.C.; Velis, C.A. Waste management—Still a global challenge in the 21st century: An evidence-based call for action. Waste Manag. Res. 2015, 1049–1051. [Google Scholar] [CrossRef]
  14. Hettiarachchi, H.; Meegoda, J.N.; Ryu, S. Organic Waste Buyback as a Viable Method to Enhance Sustainable Municipal Solid Waste Management in Developing Countries. Int. J. Environ. Res. Public Health 2018, 15, 2483. [Google Scholar] [CrossRef]
  15. Ouda, O.K.M.; Raza, S.A.; Nizami, A.S.; Rehan, M.; Al-Waked, R.; Korres, N.E. Waste to energy potential: A case study of Saudi Arabia. Renew. Sustain. Energy Rev. 2016, 61, 328–340. [Google Scholar] [CrossRef]
  16. Sadef, Y.; Nizami, A.S.; Batool, S.A.; Chaudary, M.N.; Ouda, O.K.M.; Asam, Z.Z.; Habib, K.; Rehan, M.; Demirbas, A. Waste-to-energy and recycling value for developing integrated solid waste management plan in Lahore. Energy Sources Part B Econ. Plan. Policy 2016, 11, 569–579. [Google Scholar] [CrossRef]
  17. Sawadogo, M.; Tchini Tanoh, S.; Sidibé, S.; Kpai, N.; Tankoano, I. Cleaner production in Burkina Faso: Case study of fuel briquettes made from cashew industry waste. J. Clean. Prod. 2018, 195, 1047–1056. [Google Scholar] [CrossRef]
  18. Ghisolfi, V.; Chaves, G.D.L.D.; Siman, R.R.; Xavier, L.H. System dynamics applied to closed loop supply chains of desktops and laptops in Brazil: A perspective for social inclusion of waste pickers. Waste Manag. 2017, 60, 14–31. [Google Scholar] [CrossRef] [PubMed]
  19. Matter, A.; Ahsan, M.; Marbach, M.; Zurbrügg, C. Impacts of policy and market incentives for solid waste recycling in Dhaka, Bangladesh. Waste Manag. 2015, 39, 321–328. [Google Scholar] [CrossRef] [PubMed]
  20. Lohri, C.R.; Rajabu, H.M.; Sweeney, D.J.; Zurbrügg, C. Char fuel production in developing countries—A review of urban biowaste carbonization. Renew. Sustain. Energy Rev. 2016, 59, 1514–1530. [Google Scholar] [CrossRef]
  21. Ongondo, F.O.; Williams, I.D.; Cherrett, T.J. How are WEEE doing? A global review of the management of electrical and electronic wastes. Waste Manag. 2011, 31, 714–730. [Google Scholar] [CrossRef] [PubMed]
  22. Thi, N.B.D.; Kumar, G.; Lin, C.Y. An overview of food waste management in developing countries: Current status and future perspective. J. Environ. Manag. 2015, 157, 220–229. [Google Scholar] [CrossRef] [PubMed]
  23. Lim, S.L.; Lee, L.H.; Wu, T.Y. Sustainability of using composting and vermicomposting technologies for organic solid waste biotransformation: Recent overview, greenhouse gases emissions and economic analysis. J. Clean. Prod. 2016, 111, 262–278. [Google Scholar] [CrossRef]
  24. Bernardes, A.M.; Espinosa, D.C.R.; Tenório, J.A.S. Recycling of batteries: A review of current processes and technologies. J. Power Sources 2004, 130, 291–298. [Google Scholar] [CrossRef]
  25. Ezeah, C.; Fazakerley, J.A.; Roberts, C.L. Emerging trends in informal sector recycling in developing and transition countries. Waste Manag. 2013, 33, 2509–2519. [Google Scholar] [CrossRef] [PubMed]
  26. Brown, D.; McGranahan, G. The urban informal economy, local inclusion and achieving a global green transformation. Habitat Int. 2016, 53, 97–105. [Google Scholar] [CrossRef] [Green Version]
  27. Tian, H.; Gao, J.; Hao, J.; Lu, L.; Zhu, C.; Qiu, P. Atmospheric pollution problems and control proposals associated with solid waste management in China: A review. J. Hazard. Mater. 2013, 252, 152–154. [Google Scholar] [CrossRef] [PubMed]
  28. Inglezakis, V.J.; Moustakas, K. Household hazardous waste management: A review. J. Environ. Manag. 2015, 150, 310–321. [Google Scholar] [CrossRef] [PubMed]
  29. Ali, M.; Wang, W.; Chaudhry, N.; Geng, Y. Hospital waste management in developing countries: A mini review. Waste Manag. Res. 2017, 35, 581–592. [Google Scholar] [CrossRef]
  30. Ferronato, N.; Torretta, V.; Ragazzi, M.; Rada, E.C. Waste mismanagement in developing countries: A case study of environmental contamination. UPB Sci. Bull. Ser. D Mech. Eng. 2017, 79, 185–196. [Google Scholar]
  31. Yukalang, N.; Clarke, B.; Ross, K. Barriers to effective municipal solid waste management in a rapidly urbanizing area in Thailand. Int. J. Environ. Res. Public Health 2017, 14, 1013. [Google Scholar] [CrossRef]
  32. Vaccari, M.; Vinti, G.; Tudor, T. An Analysis of the Risk Posed by Leachate from Dumpsites in Developing Countries. Environments 2018, 5, 99. [Google Scholar] [CrossRef]
  33. Sasaki, S.; Araki, T. Estimating the possible range of recycling rates achieved by dump waste pickers: The case of Bantar Gebang in Indonesia. Waste Manag. Res. 2014, 32, 474–481. [Google Scholar] [CrossRef]
  34. Linzner, R.; Salhofer, S. Municipal solid waste recycling and the significance of informal sector in urban China. Waste Manag. Res. 2014, 32, 896–907. [Google Scholar] [CrossRef]
  35. Singh, M.; Thind, P.S.; John, S. Health risk assessment of the workers exposed to the heavy metals in e-waste recycling sites of Chandigarh and Ludhiana, Punjab, India. Chemosphere 2018, 203, 426–433. [Google Scholar] [CrossRef]
  36. Gutberlet, J.; Baeder, A.M.; Pontuschka, N.N.; Felipone, S.M.N.; dos Santos, T.L.F. Participatory research revealing the work and occupational health hazards of cooperative recyclers in Brazil. Int. J. Environ. Res. Public Health 2013, 10, 4607–4627. [Google Scholar] [CrossRef] [PubMed]
  37. Modak, P.; Wilson, D.C.; Velis, C. Waste management: Global status. In Global Waste Management Outlook; UNEP: Athens, Greece, 2015; pp. 51–79. ISBN 9789280734799. [Google Scholar]
  38. Manaf, L.A.; Samah, M.A.A.; Zukki, N.I.M. Municipal solid waste management in Malaysia: Practices and challenges. Waste Manag. 2009, 29, 2902–2906. [Google Scholar] [CrossRef] [PubMed]
  39. Sanneh, E.S.; Hu, A.H.; Chang, Y.M.; Sanyang, E. Introduction of a recycling system for sustainable municipal solid waste management: A case study on the greater Banjul area of the Gambia. Environ. Dev. Sustain. 2011, 13, 1065–1080. [Google Scholar] [CrossRef]
  40. Seng, B.; Fujiwara, T.; Spoann, V. Households’ knowledge, attitudes, and practices toward solid waste management in suburbs of Phnom Penh, Cambodia. Waste Manag. Res. 2018, 36, 993–1000. [Google Scholar] [CrossRef]
  41. Chiemchaisri, C.; Juanga, J.P.; Visvanathan, C. Municipal solid waste management in Thailand and disposal emission inventory. Environ. Monit. Assess. 2007, 135, 13–20. [Google Scholar] [CrossRef] [Green Version]
  42. Al-Khatib, I.A.; Abu Hammad, A.; Sharkas, O.A.; Sato, C. Public concerns about and perceptions of solid waste dump sites and selection of sanitary landfill sites in the West Bank, Palestinian territory. Environ. Monit. Assess. 2015, 187, 186. [Google Scholar] [CrossRef] [PubMed]
  43. Aderoju, O.M.; Dias, G.A.; Gonçalves, A.J. A GIS-based analysis for sanitary landfill sites in Abuja, Nigeria. Environ. Dev. Sustain. 2018, 1–24. [Google Scholar] [CrossRef]
  44. dos Muchangos, L.S.; Tokai, A.; Hanashima, A. Analyzing the structure of barriers to municipal solid waste management policy planning in Maputo city, Mozambique. Environ. Dev. 2015, 16, 76–89. [Google Scholar] [CrossRef]
  45. Torretta, V.; Ferronato, N.; Katsoyiannis, I.A.; Tolkou, A.K.; Airoldi, M. Novel and conventional technologies for landfill leachates treatment: A review. Sustainain 2017, 9, 9. [Google Scholar] [CrossRef]
  46. Karak, T.; Bhattacharyya, P.; Das, T.; Paul, R.K.; Bezbaruah, R. Non-segregated municipal solid waste in an open dumping ground: A potential contaminant in relation to environmental health. Int. J. Environ. Sci. Technol. 2013, 10, 503–518. [Google Scholar] [CrossRef]
  47. Babu, S.S.; Chakrabarti, T.; Bhattacharyya, J.K.; Biswas, A.K.; Kumar, S. Studies on environmental quality in and around municipal solid waste dumpsite. Resour. Conserv. Recycl. 2010, 55, 129–134. [Google Scholar]
  48. Parameswari, K.; Padmini, T.K.; Mudgal, B.V. Assessment of soil contamination around municipal solid waste dumpsite. Indian J. Sci. Technol. 2015, 8, 36. [Google Scholar] [CrossRef]
  49. Prechthai, T.; Parkpian, P.; Visvanathan, C. Assessment of heavy metal contamination and its mobilization from municipal solid waste open dumping site. J. Hazard. Mater. 2008, 156, 86–94. [Google Scholar] [CrossRef] [PubMed]
  50. Kanmani, S.; Gandhimathi, R. Assessment of heavy metal contamination in soil due to leachate migration from an open dumping site. Appl. Water Sci. 2012, 3, 193–205. [Google Scholar] [CrossRef] [Green Version]
  51. Díaz Rizo, O.; Hernández Merlo, M.; Echeverría Castillo, F.; Arado López, J.O. Assessment of metal pollution in soils from a former Havana (Cuba) solid waste open dump. Bull. Environ. Contam. Toxicol. 2012, 88, 182–186. [Google Scholar] [CrossRef] [PubMed]
  52. Ihedioha, J.N.; Ukoha, P.O.; Ekere, N.R. Ecological and human health risk assessment of heavy metal contamination in soil of a municipal solid waste dump in Uyo, Nigeria. Environ. Geochem. Health 2017, 39, 497–515. [Google Scholar] [CrossRef] [PubMed]
  53. Reyes-López, J.A.; Ramírez-Hernández, J.; Lázaro-Mancilla, O.; Carreón-Diazconti, C.; Garrido, M.M.L. Assessment of groundwater contamination by landfill leachate: A case in México. Waste Manag. 2008, 28, S33–S39. [Google Scholar] [CrossRef] [PubMed]
  54. Ashraf, M.A.; Yusoff, I.; Yusof, M.; Alias, Y. Study of contaminant transport at an open-tipping waste disposal site. Environ. Sci. Pollut. Res. 2013, 20, 4689–4710. [Google Scholar] [CrossRef]
  55. Abd El-Salam, M.M.; Abu-Zuid, G.I. Impact of landfill leachate on the groundwater quality: A case study in Egypt. J. Adv. Res. 2015, 6, 579–586. [Google Scholar] [CrossRef]
  56. Efrymson, M.E.; Will, G.W.S. Toxicological Benchmarks for Contaminants of Potential Concern for Effects on Soil and Litter Invertebrates and Heterotrophic Process. Ecotoxicol. Environ. Saf. 1997. [Google Scholar] [CrossRef]
  57. World Health Organisation. Guidelines for Drinking-Water Quality, 3rd ed.; WHO Libr. Cat. Data: Geneva, Switzerland, 2004. [Google Scholar]
  58. Themelis, N.J.; Ulloa, P.A. Methane generation in landfills. Renew. Energy 2007, 32, 1243–1257. [Google Scholar] [CrossRef]
  59. Boucher, O.; Friedlingstein, P.; Collins, B.; Shine, K.P. The indirect global warming potential and global temperature change potential due to methane oxidation. Environ. Res. Lett. 2009, 4, 0440077. [Google Scholar] [CrossRef]
  60. Manfredi, S.; Tonini, D.; Christensen, T.H.; Scharff, H. Landfilling of waste: Accounting of greenhouse gases and global warming contributions. Waste Manag. Res. 2009, 27, 825–836. [Google Scholar] [CrossRef]
  61. Zhao, Y.; Christensen, T.H.; Lu, W.; Wu, H.; Wang, H. Environmental impact assessment of solid waste management in Beijing City, China. Waste Manag. 2011, 31, 793–799. [Google Scholar] [CrossRef]
  62. Kumar, S.; Gaikwad, S.A.; Shekdar, A.V.; Kshirsagar, P.S.; Singh, R.N. Estimation method for national methane emission from solid waste landfills. Atmos. Environ. 2004, 38, 3481–3487. [Google Scholar] [CrossRef]
  63. Ramachandra, T.V.; Bharath, H.A.; Kulkarni, G.; Han, S.S. Municipal solid waste: Generation, composition and GHG emissions in Bangalore, India. Renew. Sustain. Energy Rev. 2018, 82, 1122–1136. [Google Scholar] [CrossRef]
  64. Derraik, J.G.B. The pollution of the marine environment by plastic debris: A review. Mar. Pollut. Bull. 2002, 44, 842–852. [Google Scholar] [CrossRef]
  65. Iñiguez, M.E.; Conesa, J.A.; Fullana, A. Marine debris occurrence and treatment: A review. Renew. Sustain. Energy Rev. 2016, 64, 394–402. [Google Scholar] [CrossRef] [Green Version]
  66. Cheshire, A.; Adler, E.; Barbière, J.; Cohen, Y.; Sverker, E.; Jarayabhand, S.; Jeftic, L.; Jung, R.-T.; Kinsey, S.; Kusui, E.T.; et al. UNEP/IOC Guidelines on Survey and Monitoring of Marine Litter; UNEP: Athens, Greece, 2009; ISBN 9789280730272. [Google Scholar]
  67. Andrady, A.; Law, K.L.; Wilcox, C.; Narayan, R.; Jambeck, J.R.; Geyer, R.; Siegler, T.R.; Perryman, M. Plastic waste inputs from land into the ocean. Science 2015, 347, 768–771. [Google Scholar]
  68. Andrady, A.L. Microplastics in the marine environment. Mar. Pollut. Bull. 2011, 62, 1596–1605. [Google Scholar] [CrossRef]
  69. Ivar Do Sul, J.A.; Costa, M.F. The present and future of microplastic pollution in the marine environment. Environ. Pollut. 2014, 185, 352–364. [Google Scholar] [CrossRef]
  70. de Haan, W.P.; Sanchez-Vidal, A.; Canals, M.; Party, N.S.S. Floating microplastics and aggregate formation in the Western Mediterranean Sea. Mar. Pollut. Bull. 2019, 140, 523–535. [Google Scholar] [CrossRef] [PubMed]
  71. Slat, B.; Jansen, H.; de Sonneville, J.; Arens, E.; Bolle, E.; Brugman, H.; Campbell, H.; Christiane, P.; Dekker, M.; Diamant, S.; et al. Available online: https://www.theoceancleanup.com/ (accessed on 15 January 2019).
  72. Tue, N.M.; Goto, A.; Takahashi, S.; Itai, T.; Asante, K.A.; Kunisue, T.; Tanabe, S. Release of chlorinated, brominated and mixed halogenated dioxin-related compounds to soils from open burning of e-waste in Agbogbloshie (Accra, Ghana). J. Hazard. Mater. 2016, 302, 151–157. [Google Scholar] [CrossRef] [PubMed]
  73. Minh, N.H.; Minh, T.B.; Watanabe, M.; Kunisue, T.; Monirith, I.; Tanabe, S.; Sakai, S.; Subramanian, A.; Sasikumar, K.; Viet, P.H.; et al. Open dumping site in Asian developing countries: A potential source of polychlorinated dibenzo-p-dioxins and polychlorinated dibenzofurans. Environ. Sci. Technol. 2003, 37, 1493–1502. [Google Scholar] [CrossRef]
  74. Bastian, L.; Yano, J.; Hirai, Y.; Sakai, S. ichi Behavior of PCDD/Fs during open burning of municipal solid waste in open dumping sites. J. Mater. Cycles Waste Manag. 2013, 15, 229–241. [Google Scholar] [CrossRef]
  75. Ragazzi, M.; Tirler, W.; Angelucci, G.; Zardi, D.; Rada, E.C. Management of atmospheric pollutants from waste incineration processes: The case of Bozen. Waste Manag. Res. 2013, 31, 235–240. [Google Scholar] [CrossRef] [PubMed]
  76. Reyna-Bensusan, N.; Wilson, D.C.; Smith, S.R. Uncontrolled burning of solid waste by households in Mexico is a significant contributor to climate change in the country. Environ. Res. 2018, 163, 280–288. [Google Scholar] [CrossRef] [PubMed]
  77. Barabad, M.L.M.; Jung, W.; Versoza, M.E.; Lee, Y.I.; Choi, K.; Park, D. Characteristics of particulate matter and volatile organic compound emissions from the combustion of waste vinyl. Int. J. Environ. Res. Public Health 2018, 15, 1390. [Google Scholar] [CrossRef] [PubMed]
  78. Diaz, L.F.; Eggerth, L.L.; Enkhtsetseg, S.; Savage, G.M. Characteristics of healthcare wastes. Waste Manag. 2008, 28, 1219–1226. [Google Scholar] [CrossRef] [PubMed]
  79. WHO. Safe Management of Wastes from Health-Care Activities; WHO: Geneva, Switzerland, 2014. [Google Scholar]
  80. Ali, M.; Kuroiwa, C. Status and challenges of hospital solid waste management: Case studies from Thailand, Pakistan, and Mongolia. J. Mater. Cycles Waste Manag. 2009, 11, 251–257. [Google Scholar] [CrossRef]
  81. Manga, V.E.; Forton, O.T.; Mofor, L.A.; Woodard, R. Health care waste management in Cameroon: A case study from the Southwestern Region. Resour. Conserv. Recycl. 2011, 57, 108–116. [Google Scholar] [CrossRef]
  82. Ali, M.; Wang, W.; Chaudhry, N. Management of wastes from hospitals: A case study in Pakistan. Waste Manag. Res. 2016, 34, 87–90. [Google Scholar] [CrossRef] [PubMed]
  83. Sohrab Hossain, M.; Ab Rahman, N.N.N.; Balakrishnan, V.; Puvanesuaran, V.R.; Zaidul Islam Sarker, M.; Ab Kadir, M.O. Infectious risk assessment of unsafe handling practices and management of clinical solid waste. Int. J. Environ. Res. Public Health 2013, 10, 556–567. [Google Scholar] [CrossRef] [PubMed]
  84. Hossain, M.S.; Santhanam, A.; Nik Norulaini, N.A.; Omar, A.K.M. Clinical solid waste management practices and its impact on human health and environment—A review. Waste Manag. 2011, 31, 754–766. [Google Scholar] [CrossRef] [PubMed]
  85. Al-Khatib, I.A.; Sato, C. Solid health care waste management status at health care centers in the West Bank—Palestinian Territory. Waste Manag. 2009, 29, 2398–2403. [Google Scholar] [CrossRef] [PubMed]
  86. Olomolaiye, P.; Hammond, F.; Booth, C.; Coker, A.; Sridhar, M.; Sangodoyin, A. Medical waste management in Ibadan, Nigeria: Obstacles and prospects. Waste Manag. 2008, 29, 804–811. [Google Scholar]
  87. Patwary, M.A.; O’Hare, W.T.; Sarker, M.H. An illicit economy: Scavenging and recycling of medical waste. J. Environ. Manag. 2011, 92, 2900–2906. [Google Scholar] [CrossRef]
  88. Patwary, M.A.; O’Hare, W.T.; Sarker, M.H. Assessment of occupational and environmental safety associated with medical waste disposal in developing countries: A qualitative approach. Saf. Sci. 2011, 49, 1200–1207. [Google Scholar] [CrossRef]
  89. Windfeld, E.S.; Brooks, M.S.L. Medical waste management—A review. J. Environ. Manag. 2015, 163, 98–108. [Google Scholar] [CrossRef] [PubMed]
  90. Johnson, K.M.; González, M.L.; Dueñas, L.; Gamero, M.; Relyea, G.; Luque, L.E.; Caniza, M.A. Improving waste segregation while reducing costs in a tertiary-care hospital in a lower-middle-income country in Central America. Waste Manag. Res. 2013, 31, 733–738. [Google Scholar] [CrossRef]
  91. Kumar, A.; Holuszko, M.; Espinosa, D.C.R. E-waste: An overview on generation, collection, legislation and recycling practices. Resour. Conserv. Recycl. 2017, 122, 32–42. [Google Scholar] [CrossRef]
  92. Baldé, C.P.; Wang, F.; Kuehr, R.; Huisman, J. The Global E-Waste Monitor; United Nations University (UNU-IAS): Tokyo, Japan; Bonn, Germany, 2014; ISBN 9789280845556. [Google Scholar]
  93. Garlapati, V.K. E-waste in India and developed countries: Management, recycling, business and biotechnological initiatives. Renew. Sustain. Energy Rev. 2016, 54, 874–881. [Google Scholar] [CrossRef]
  94. World Loop. World Loop, Changing the E-Waste Cycle—Illegal Flows. Available online: http://worldloop.org/e-waste/illegal-flows/ (accessed on 1 February 2019).
  95. Yang, J.; Lu, B.; Xu, C. WEEE flow and mitigating measures in China. Waste Manag. 2008, 28, 1589–1597. [Google Scholar] [CrossRef] [Green Version]
  96. Nnorom, I.C.; Osibanjo, O. Overview of electronic waste (e-waste) management practices and legislations, and their poor applications in the developing countries. Resour. Conserv. Recycl. 2008, 52, 843–858. [Google Scholar] [CrossRef]
  97. Olafisoye, O.B.; Adefioye, T.; Osibote, O.A. Heavy metals contamination of water, soil, and plants around an electronic waste dumpsite. Polish J. Environ. Stud. 2013, 22, 1431–1439. [Google Scholar]
  98. Nava-Martínez, E.C.; Flores-García, E.; Espinoza-Gomez, H.; Wakida, F.T. Heavy metals pollution in the soil of an irregular urban settlement built on a former dumpsite in the city of Tijuana, Mexico. Environ. Earth Sci. 2012, 66, 1239–1245. [Google Scholar] [CrossRef]
  99. Zand, A.D.; Abduli, M.A. Current situation of used household batteries in Iran and appropriate management policies. Waste Manag. 2008, 28, 2085–2090. [Google Scholar] [CrossRef]
  100. Osibanjo, O.; Nnorom, I.C. The challenge of electronic waste (e-waste) management in developing countries. Waste Manag. Res. 2007, 25, 489–501. [Google Scholar] [CrossRef]
  101. Cucchiella, F.; D’Adamo, I.; Lenny Koh, S.C.; Rosa, P. Recycling of WEEEs: An economic assessment of present and future e-waste streams. Renew. Sustain. Energy Rev. 2015, 51, 263–272. [Google Scholar] [CrossRef] [Green Version]
  102. Ikhlayel, M. An integrated approach to establish e-waste management systems for developing countries. J. Clean. Prod. 2018, 170, 119–130. [Google Scholar] [CrossRef]
  103. Torretta, V.; Ragazzi, M.; Istrate, I.A.; Rada, E.C. Management of waste electrical and electronic equipment in two EU countries: A comparison. Waste Manag. 2013, 33, 117–122. [Google Scholar] [CrossRef] [PubMed]
  104. Shen, L.Y.; Tam, V.W.Y.; Tam, C.M.; Drew, D. Mapping Approach for Examining Waste Management on Construction Sites. J. Constr. Eng. Manag. 2004, 130, 472–481. [Google Scholar] [CrossRef]
  105. Yang, H.; Xia, J.; Thompson, J.R.; Flower, R.J. Urban construction and demolition waste and landfill failure in Shenzhen, China. Waste Manag. 2017, 63, 393–396. [Google Scholar] [CrossRef] [PubMed]
  106. Thongkamsuk, P.; Sudasna, K.; Tondee, T. Waste generated in high-rise buildings construction: A current situation in Thailand. Energy Procedia 2017, 138, 411–416. [Google Scholar] [CrossRef]
  107. Kofoworola, O.F.; Gheewala, S.H. Estimation of construction waste generation and management in Thailand. Waste Manag. 2009, 29, 731–738. [Google Scholar] [CrossRef]
  108. Del Río Merino, M.; Gracia, P.I.; Azevedo, I.S.W. Sustainable construction: Construction and demolition waste reconsidered. Waste Manag. Res. 2010, 28, 118–129. [Google Scholar] [CrossRef]
  109. Lockrey, S.; Nguyen, H.; Crossin, E.; Verghese, K. Recycling the construction and demolition waste in Vietnam: Opportunities and challenges in practice. J. Clean. Prod. 2016, 133, 757–766. [Google Scholar] [CrossRef]
  110. Esa, M.R.; Halog, A.; Rigamonti, L. Developing strategies for managing construction and demolition wastes in Malaysia based on the concept of circular economy. J. Mater. Cycles Waste Manag. 2017, 19, 1144–1154. [Google Scholar] [CrossRef]
  111. Manowong, E. Investigating factors influencing construction waste management efforts in developing countries: An experience from Thailand. Waste Manag. Res. 2012, 30, 56–71. [Google Scholar] [CrossRef]
  112. Trulli, E.; Ragazzi, M.; Torretta, V.; Istrate, I.A.; Cioca, L.I.; Rada, E.C. Treatment and disposal of tyres: Two EU approaches. A review. Waste Manag. 2015, 45, 152–160. [Google Scholar]
  113. Yevtushenko, A.; Tolstoj-Sienkiewicz, J. Distribution of friction heat between a stationary pin and rotating ring. Arch. Appl. Mech. 2006, 76, 33–47. [Google Scholar] [CrossRef]
  114. Shakya, P.R.; Shrestha, P.; Tamrakar, C.S.; Bhattarai, P.K. Studies on potential emission of hazardous gases due to uncontrolled open-air burning of waste vehicle tyres and their possible impacts on the environment. Atmos. Environ. 2008, 42, 6555–6559. [Google Scholar] [CrossRef]
  115. Cooper, J.A. Environmental impact of residential wood combustion emissions and its implications. J. Air Pollut. Control Assoc. 1980, 30, 855–861. [Google Scholar] [CrossRef]
  116. Pandolfi, M.; García-Alonso, S.; Amato, F.; Díaz, E.; Alonso-Blanco, E.; Becerril-Valle, M.; Coz, E.; Gómez-Moreno, F.J.; Alastuey, A.; Artíñano, B.; et al. Outdoor and indoor particle characterization from a large and uncontrolled combustion of a tire landfill. Sci. Total Environ. 2017, 593–594, 543–551. [Google Scholar]
  117. Spak, S.N.; Peters, T.M.; Downard, J.; Wichman, M.D.; Mainprize, M.W.; Kostle, P.A.; Singh, A.; Beardsley, D.; Bullard, R.L.; Pooley, M.; et al. Uncontrolled combustion of shredded tires in a landfill—Part 2: Population exposure, public health response, and an air quality index for urban fires. Atmos. Environ. 2015, 104, 273–283. [Google Scholar]
  118. Park, J.; Díaz-Posada, N.; Mejía-Dugand, S. Challenges in implementing the extended producer responsibility in an emerging economy: The end-of-life tire management in Colombia. J. Clean. Prod. 2018, 189, 754–762. [Google Scholar] [CrossRef]
  119. Banguera, L.A.; Sepúlveda, J.M.; Ternero, R.; Vargas, M.; Vásquez, Ó.C. Reverse logistics network design under extended producer responsibility: The case of out-of-use tires in the Gran Santiago city of Chile. Int. J. Prod. Econ. 2018, 205, 193–200. [Google Scholar] [CrossRef]
  120. Zarei, M.; Taghipour, H.; Hassanzadeh, Y. Survey of quantity and management condition of end-of-life tires in Iran: A case study in Tabriz. J. Mater. Cycles Waste Manag. 2018, 20, 1099–1105. [Google Scholar] [CrossRef]
  121. Liu, Y.; Dong, L.; Guo, D.; Xu, Y.; Liu, J. Pollution Status and Environmental Sound Management (ESM) Trends on Typical General Industrial Solid Waste. Procedia Environ. Sci. 2016, 31, 615–620. [Google Scholar] [CrossRef] [Green Version]
  122. Rao, G.T.; Rao, V.V.S.G.; Ranganathan, K.; Surinaidu, L.; Mahesh, J.; Ramesh, G. Assessment of groundwater contamination from a hazardous dump site in Ranipet, Tamil Nadu, India. Hydrogeol. J. 2011, 19, 1587–1598. [Google Scholar] [CrossRef]
  123. Carvalho, F.M.; Tavares, T.M.; Lins, L. Soil contamination by a lead smelter in Brazil in the view of the local residents. Int. J. Environ. Res. Public Health 2018, 15, 2166. [Google Scholar] [CrossRef]
  124. Mbuligwe, S.E.; Kaseva, M.E. Assessment of industrial solid waste management and resource recovery practices in Tanzania. Resour. Conserv. Recycl. 2006, 47, 260–276. [Google Scholar] [CrossRef]
  125. Damalas, C.A.; Telidis, G.K.; Thanos, S.D. Assessing farmers’ practices on disposal of pesticide waste after use. Sci. Total Environ. 2008, 390, 341–345. [Google Scholar] [CrossRef]
  126. Yilmaz, O.; Kara, B.Y.; Yetis, U. Hazardous waste management system design under population and environmental impact considerations. J. Environ. Manag. 2017, 203, 720–731. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  127. Wilson, D.C.; Araba, A.O.; Chinwah, K.; Cheeseman, C.R. Building recycling rates through the informal sector. Waste Manag. 2009, 29, 629–635. [Google Scholar] [CrossRef]
  128. Steuer, B.; Ramusch, R.; Salhofer, S.P. Can Beijing’s informal waste recycling sector survive amidst worsening circumstances? Resour. Conserv. Recycl. 2018, 128, 59–68. [Google Scholar] [CrossRef]
  129. Uddin, S.M.N.; Gutberlet, J. Livelihoods and health status of informal recyclers in Mongolia. Resour. Conserv. Recycl. 2018, 134, 1–9. [Google Scholar] [CrossRef]
  130. Kasinja, C.; Tilley, E. Formalization of informal waste pickers’ cooperatives in Blantyre, Malawi: A feasibility assessment. Sustainain 2018, 10, 1149. [Google Scholar] [CrossRef]
  131. Nemadire, S.; Mapurazi, S.; Nyamadzawo, G. Formalising informal solid waste recycling at the Pomona dumpsite in Harare, Zimbabwe. Nat. Resour. Forum 2017, 41, 167–178. [Google Scholar] [CrossRef]
  132. Vaccari, M.; Perteghella, A. Resource recovery from waste by Roma in the Balkans: A case study from Zavidovici (BiH). Waste Manag. Res. 2016, 34, 866–874. [Google Scholar] [CrossRef]
  133. Romallosa, A.; Kraft, E. Feasibility of Biomass Briquette Production from Municipal Waste Streams by Integrating the Informal Sector in the Philippines. Resources 2017, 6, 12. [Google Scholar] [CrossRef]
  134. Black, M.; Karki, J.; Lee, A.C.K.; Makai, P.; Baral, Y.R.; Kritsotakis, E.I.; Bernier, A.; Fossier Heckmann, A. The health risks of informal waste workers in the Kathmandu Valley: A cross-sectional survey. Public Health 2019, 166, 10–18. [Google Scholar] [CrossRef]
  135. Rockson, G.N.K.; Kemausuor, F.; Seassey, R.; Yanful, E. Activities of scavengers and itinerant buyers in Greater Accra, Ghana. Habitat Int. 2013, 39, 148–155. [Google Scholar] [CrossRef]
  136. Vergara, S.E.; Damgaard, A.; Gomez, D. The Efficiency of Informality: Quantifying Greenhouse Gas Reductions from Informal Recycling in Bogotá, Colombia. J. Ind. Ecol. 2016, 20, 107–119. [Google Scholar] [CrossRef]
  137. Jaligot, R.; Wilson, D.C.; Cheeseman, C.R.; Shaker, B.; Stretz, J. Applying value chain analysis to informal sector recycling: A case study of the Zabaleen. Resour. Conserv. Recycl. 2016, 114, 80–91. [Google Scholar] [CrossRef] [Green Version]
  138. Kumar, A.; Samadder, S.R.; Kumar, N.; Singh, C. Estimation of the generation rate of different types of plastic wastes and possible revenue recovery from informal recycling. Waste Manag. 2018, 79, 781–790. [Google Scholar] [CrossRef] [PubMed]
  139. Medina, M. Serving the unserved: Informal refuse collection in Mexico. Waste Manag. Res. 2005, 23, 390–397. [Google Scholar] [CrossRef]
  140. Ghosh, S.K. Sustainable SWM in Developing Countries Focusing on Faster Growing Economies, India and China. Procedia Environ. Sci. 2016, 35, 176–184. [Google Scholar] [CrossRef]
  141. Sauvé, S.; Bernard, S.; Sloan, P. Environmental sciences, sustainable development and circular economy: Alternative concepts for trans-disciplinary research. Environ. Dev. 2016, 17, 48–56. [Google Scholar] [CrossRef] [Green Version]
  142. Fiksel, J.; Lal, R. Transforming waste into resources for the Indian economy. Environ. Dev. 2018, 26, 123–128. [Google Scholar] [CrossRef]
  143. Reike, D.; Vermeulen, W.J.V.; Witjes, S. The circular economy: New or Refurbished as CE 3.0?—Exploring Controversies in the Conceptualization of the Circular Economy through a Focus on History and Resource Value Retention Options. Resour. Conserv. Recycl. 2018, 135, 246–264. [Google Scholar] [CrossRef]
  144. Velis, C. Waste pickers in Global South: Informal recycling sector in a circular economy era. Waste Manag. Res. 2017, 35, 329–331. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  145. Srivastava, V.; Ismail, S.A.; Singh, P.; Singh, R.P. Urban solid waste management in the developing world with emphasis on India: Challenges and opportunities. Rev. Environ. Sci. Bio-Technol. 2015, 14, 317–337. [Google Scholar] [CrossRef]
  146. Pardo Martínez, C.I.; Piña, W.A. Solid waste management in Bogotá: The role of recycling associations as investigated through SWOT analysis. Environ. Dev. Sustain. 2017, 1067–1086. [Google Scholar] [CrossRef]
  147. Olley, J.E.; Ijgosse, J.; Rudin, V.; Alabaster, G. Developing a common framework for integrated solid waste management advances in Managua, Nicaragua. Waste Manag. Res. 2014, 32, 822–833. [Google Scholar] [CrossRef] [PubMed]
  148. Ziraba, A.K.; Haregu, T.N.; Mberu, B. A review and framework for understanding the potential impact of poor solid waste management on health in developing countries. Arch. Public Health 2016, 74, 55. [Google Scholar] [CrossRef] [PubMed]
  149. Ferronato, N.; Portillo Gorritty, M.; Viotti, P.; Torretta, V.; Ragazzi, M.; Guisbert Lizarazu, E.G. How to improve Recycling Rate in Developing big cities: An Integrated Approach for assessing Municipal Solid Waste Collection and Treatment Scenarios. Environ. Dev. 2019, 29, 94–110. [Google Scholar] [CrossRef]
  150. Prieto-Sandoval, V.; Jaca, C.; Ormazabal, M. Towards a consensus on the circular economy. J. Clean. Prod. 2018, 179, 605–615. [Google Scholar] [CrossRef]
  151. Geissdoerfer, M.; Savaget, P.; Bocken, N.M.P.; Hultink, E.J. The Circular Economy—A new sustainability paradigm? J. Clean. Prod. 2017, 143, 757–768. [Google Scholar] [CrossRef]
  152. Ilić, M.; Nikolić, M. Drivers for development of circular economy—A case study of Serbia. Habitat Int. 2016, 56, 191–200. [Google Scholar] [CrossRef]
Ijerph 16 01060 g001 550
Figure 1. Theoretical framework of the review: source of contamination due to SW mismanagement.
Figure 1. Theoretical framework of the review: source of contamination due to SW mismanagement.
Ijerph 16 01060 g001
Ijerph 16 01060 g002 550
Figure 2. Schematic analysis of the trophic chain of micro-plastic in the marine environment, for explaining plastic direct and indirect ingestion [69].
Figure 2. Schematic analysis of the trophic chain of micro-plastic in the marine environment, for explaining plastic direct and indirect ingestion [69].
Ijerph 16 01060 g002
Ijerph 16 01060 g003 550
Figure 3. Informal HW scavenging in Dhaka, Bangladesh [87].
Figure 3. Informal HW scavenging in Dhaka, Bangladesh [87].
Ijerph 16 01060 g003
Ijerph 16 01060 g004 550
Figure 4. Estimation of the legal and illegal WEEE flow from high-income to low-income countries at global level [94].
Figure 4. Estimation of the legal and illegal WEEE flow from high-income to low-income countries at global level [94].
Ijerph 16 01060 g004
Ijerph 16 01060 g005 550
Figure 5. C&D waste landfill landslide in Shenzhen, China [105].
Figure 5. C&D waste landfill landslide in Shenzhen, China [105].
Ijerph 16 01060 g005
Ijerph 16 01060 g006 550
Figure 6. Informal recycling chain in China, as schematically depicted by [128].
Figure 6. Informal recycling chain in China, as schematically depicted by [128].
Ijerph 16 01060 g006
Table
Table 1. Contaminants’ concentration in soil, runoff and groundwater due to open dumping in eight case studies, compared with international standard of soil contamination limits and drinking water.
Table 1. Contaminants’ concentration in soil, runoff and groundwater due to open dumping in eight case studies, compared with international standard of soil contamination limits and drinking water.
Ref.City/RegionCountryEnvironment PollutedPollutantConcentrationsLimits
[48]Chennai cityIndiaSoil (mg kg−1)Zn0.27–0.4850
Cu3.78–0.59100
Fe
[50]TiruchirappalliIndiaSoil (mg kg−1)Mn171.16500
Pb291.3>50
Cd47.7>4
[51]HavanaCubaSoil (mg kg−1)Cobalt8.420
Ni50>30
Cu252>100
Zn489>50
Pb276>50
[52]UyoNigeriaSoil (mg kg−1)Pb9.9–11.850
Zn137–146>50
Ni11.8–12.6 30
Cr3.6–4.1>1
Cd9.05–12.2>4
Mn91.2–94500
[49]NonthaburiThailandRunoff (mg L−1)Mn0.49>0.4
Cr0.99>0.05
Cd0.01>0.003
Pb0.1>0.01
Ni0.5>0.07
Zn1.324
Cu0.632
Hg0.95>0.002
[50]TiruchirappalliIndiaGroundwater (mg L−1)Cd0.16–1.04>0.003
Cu0.6–2.72
Mn0.2–1.8>0.4
Pb0.8–5.1>0.01
[53]MexicaliMexicoGroundwater (mg L−1)BOD54.3–6.5 20 *
COD23.5–188>120 *
Na600>200
SO4-1000>300
[54]SepangMalaysiaGroundwater (mg L−1)BOD5128–142>120
COD2698–2891>120
Cl123.8–127.7>5
Ni0.44–0.65>0.07
As0.06–0.07>0.01
Pb0.04–0.08>0.01
[55]Alexandria(Landfill)EgyptGroundwater (mg L−1)Ni0.007–0.1520.07
Pb0.002–0.0090.01
Cr0.006–0.058>0.05
Mn0.039–0.673>0.4
Cd0.001–0.051>0.003
Zn0.001–0.3434
Note: Soil contamination limits [56], Drinking water limits [57], * water release after wastewater treatment.
Table
Table 2. Categories of HW as reported by the WHO [79].
Table 2. Categories of HW as reported by the WHO [79].
Waste CategoryDescription and Examples
Sharp wasteUsed or unused sharps (e.g., needles, syringes with attached needles, knives, blades, broken glass).
Infectious wasteWaste suspected to contain pathogens and that poses a risk of disease transmission (e.g., waste contaminated with blood and other body fluids).
Pathological wasteHuman tissues, organs or fluids, body parts, fetuses, unused blood products.
Pharmaceutical wastePharmaceuticals that are expired or no longer needed.
Chemical wasteWaste containing chemical substances (e.g., laboratory reagents, film developer, disinfectants that are expired or no longer needed, broken thermometers with mercury).
Radioactive wasteWaste containing radioactive substances (e.g., unused liquids from radiotherapy or laboratory studies).
Non-hazardous or general HWWaste that does not pose any biological, chemical, radioactive or physical hazard.
Table
Table 3. Comparison of the waste pickers’ activity among seven different countries worldwide.
Table 3. Comparison of the waste pickers’ activity among seven different countries worldwide.
Ref.CityCountryNo. of Waste PickersOrganization/
Formalization		Source of RecyclablesKg d−1 Per Waste PickerWaste FractionsIssues
[134]KathmanduNepal7000–15,000NoCity streets/
landfill		60Plastic
bottles,
plastic
bags, paper, glass,
iron, HW		Illnesses, lack of financial resilience,
occupational risks
[130]BalantyreMalawiN.A.NoOpen dumps in urban areas20–30PET,
HDPE,
LDPE,
metals		Negative public
perception, lack of
capital, fluctuation
of the price
[131]HarareZimbawe220LicensedOpen dumps70Plastic,
paper,
rubber,
metals,
glass,
tires		Competition with others waste pickers safety issues, discrimination, climate conditions
[129]UlaanbaatarMongolia5000–7000NoDumpsites,
public
areas,
streets		N.A.Plastics, cansAlcohol addiction, no ID card,
homeless, discrimination, diseases
[128]BeijingChina150,000Prohibited by regulationHouseholds,
public bins,
small enterprises		14–16WEEE, paper, metals, plasticsMinimum wage standards, discrimination
[135]Great Accra regionGhanaN.A.NoLandfills,
open dump
sites		N.A.Metals, plastics, PET, WEEEHealth hazards,
cuts & injuries, insects bites, lack of respect, unstable prices
[136]BogotáColombia20,000CooperativesTrash bags, public bins25Plastics,
metals,
paper,
glass		Lack of public acceptance, health, cleanness of operation.
Note: (No.) number, (N.A.) not available.
Table
Table 4. Environmental and health risks due to waste open burning and open dumping for different waste streams.
Table 4. Environmental and health risks due to waste open burning and open dumping for different waste streams.
Waste StreamPollutants and HazardsEnvironmental and Health Risks
MSW open dumping
  • Leachates with high concentrations of heavy metals, BOD, COD, SO42−, NH3,
  • Anaerobic digestion of organic fractions with generation of landfill gases, mainly composed of methane,
  • Disease vectors living in the areas.
  • The leachate generated is released to the soil, polluting groundwaters mainly used for drinking and household purposes. The risks concern the health the population through direct and indirect (agriculture) intake.
  • The generation of methane and other GHGs increases global warming, the risk of local fires and the pollution of the atmosphere surrounding the final disposal sites.
  • The breeding of animals around the disposal sites and the presence of rodents and insects increases the risks of diseases transferring to the population through bites and direct contact with the animals.
  • The uncontrolled disposal causes the release of waste fractions, mainly plastics, into water bodies, contaminating the rivers, lakes and then the oceans and the seas, causing the phenomena of the marine littering.
MSW open burning
  • Generation of PCDD/F and cancerogenic compounds, PM, BC, CO, CO2, NO, and other GHG and hazardous compounds.
  • The emissions due to uncontrolled waste fires produce significant amounts of contaminants that affect the health of the population. Respiratory illnesses, especially in children, are common in areas with open burning practices. The generation of BC, CO, CO2 and other GHG, affects the GWP, more than the anaerobic degradation of organic waste.
HW
  • Open dumping of sharp and infectious waste,
  • Burned HW generates PCDD/F and other hazardous compounds.
  • The presence of sharps and infectious waste in open dump sites increases the risks to waste pickers that operate in the area. Indeed, recyclable materials are scavenged by informal recyclers, that are not aware of the issues due to HW. Moreover, these fractions can be targets for animal disease vectors. Finally, the open dumping of HW creates bacterial resistance, that affects the performance of antibiotics for human uses.
  • Burned HW is a source of PCDD/F that directly affect the health of the population living near sites, increasing the risk of cancer and respiratory diseases.
WEEE and used batteries
  • The open dumping of the waste generates leachates with high heavy metals concentrations,
  • The open burning generates hazardous compounds like PCDD/F, BC and PM.
  • Open WEEE dumping generates leachates rich in heavy metals. Waste picking is also done on these fractions to collect precious metals. These practices affect the health of the pickers that operate in the dumping sites, due to the presence of Hg, Pb, Cd and Mn, all hazardous metals. Picking of WEEE leads to waste burning for the recovery of the metals.
  • Uncontrolled WEEE burning affects the quality of the air and the atmosphere due to the generation of high amounts of PM, BC and PCDD/F, affecting both the health of the populations surrounding the site and increasing the GWP.
C&D waste
  • Landslides due to waste uncontrolled dumping,
  • Presence of hazardous materials within the waste, such as asbestos, lead, mercury and sharp waste.
  • The main issue is the risk of landslides that can affect populated areas. The huge amounts of waste produced by C&D activities reduce the useful life of final disposal sites and their density, increasing the risk of land collapses.
  • The presence of hazardous materials can be a source of pollution due to the leachates generated at the final disposal sites or directly for the waste pickers operating collecting recyclable materials. Pb and Hg waste can affect the health of the population due to respiratory, skin and other illnesses.
Waste tires
  • The open dumping causes the presence of mosquitos and the risk of fire injections,
  • Open burning generates contaminants for the atmosphere, such as BC and SOx.
  • Open dumping of waste tires is an area of mosquito growth, especially in tropical areas, where dengue, malaria, yellow fever, among other diseases, is common. The presence of waste tires in open dump sites increases the risk of contraction of these illnesses. Moreover, the presence of this highly combustible waste fraction, can be a cause of fires.
  • Open burning of waste tires induces high generation of PM, BC and SO, increasing the GWP and the acid rain phenomenon due to the presence of sulphates in the atmosphere which generate H2S in contact with water, increasing environmental pollution. Moreover, the generation of PM, containing heavy metals increases health issues in the populations that live near the areas, also affecting the air indoor.
Industrial waste
  • Generation of hazardous leachates mainly composed of heavy metals.
  • The presence of heavy metals affects the health of citizens, especially the children, which intake can be less than an adult in terms of concentrations assumed per day, boosting the health effects. The presence of heavy metals is persistent and affects the soil and groundwater quality, with possible intake by direct ingestion (e.g., food and water).

Share and Cite

MDPI and ACS Style

Ferronato, N.; Torretta, V. Waste Mismanagement in Developing Countries: A Review of Global Issues. Int. J. Environ. Res. Public Health 2019, 16, 1060. https://doi.org/10.3390/ijerph16061060

AMA Style

Ferronato N, Torretta V. Waste Mismanagement in Developing Countries: A Review of Global Issues. International Journal of Environmental Research and Public Health. 2019; 16(6):1060. https://doi.org/10.3390/ijerph16061060

Chicago/Turabian Style

Ferronato, Navarro, and Vincenzo Torretta. 2019. "Waste Mismanagement in Developing Countries: A Review of Global Issues" International Journal of Environmental Research and Public Health 16, no. 6: 1060. https://doi.org/10.3390/ijerph16061060

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop