Introduction
The interest for understanding the risk to both environment and human health which a chemical may have on its compound life-cycle (CLC) has been increasing over the years. For that reason, the amended Toxic Substance Control Act (TSCA) has given the U.S. Environmental Protection Agency (U.S. EPA) the authority for developing and implementing an evaluation procedure to determine whether a chemical at U.S. market exhibits an unreasonable risk to environment and human health through its manufacturing, processing, use (industrial, commercial and consumer), and disposal [1].
The end-of-life (EoL) scenarios that a chemical may have is one of the main concern areas when performing risk evaluation due to its high uncertainty level as well as the lack of studies and information for achieving some sustainable waste management goals (e.g. recycling, recovery, etc.) [2]. Currently, EoL studies consider risk and exposure during the disposal (e.g. landfilling, incineration) of chemical waste. However, an unforeseen effect is the proliferation of new chemical exposure pathways and scenarios when combining many EoL consumer products from different use (e.g. plastics) for performing industrial scale recycling and recovery and convert these as feedstocks for the manufacturing of new goods for new uses.
According to the Plan-Do-Check-Act (PDCA) cycle, ‘if you cannot measure it, you cannot manage it’. For that reason, it is recommended to identify of the most relevant sustainability indicators which help to quantify the performance of different EoL scenarios for chemical waste. Thus, the aim of this work is to provide a crucial analysis of the sustainability indicators taxonomy for assessing the chemical risk to environment and human health in EoL scenarios, for supporting an appropriate selection of a sustainable chemical waste management and risk control strategy. For doing this, a literature search strategy is performed, using Scopus as the literature search manager, a search equation, which has a combination of search terms such as end-of-life, chemical risk, environment, human health, and waste management, and terms related to waste management strategies (e.g. landfill, recycling, etc.). Other search parameters employed as a filter are the manuscripts published since 2008, which have the search terms in their title, keywords, and/or abstracts. After that, a skimming is used to select the most relevant papers according to the searching criteria parameters. Finally, an exhaustive and complete reading and evaluation is used as the last filter to select the most appropriate manuscripts (see Table 2).
Risk evaluation elements
The risk evaluation process involves different elements which are important to understand before selecting the indicators. These elements can be identified by TSCA and defined in a conceptual model when the problem formulation for risk evaluation is made. These elements are summarized in Figure 1.
Figure 1. A generic conceptual model with example of possible elements and linkages for risk evaluation (adopted from U.S. EPA [3]).In Figure 1 is represented the four elements considered in the search and identification of the sustainability indicators taxonomy for chemical risk: (a) the first one is the stressor which is defined as a physical, chemical, biological, or other entity that can cause an adverse response in a human or other organism or ecosystem [3], namely, those chemical stressors which cause some hazard risk under some conditions. (b) receptors which are the agents exposed to a chemical stressor, for instance, workers and occupational non-users at the waste management facilities, as well as general population, and aquatic and terrestrial species on the outside of the above plants. (c) exposure pathway and route which are elements establishing a relationship between the chemical stressor and the final receptor. An exposure pathway is the physical course (fate and transport) that a chemical or pollutant takes from its source to the receptor, while an exposure route is the way a chemical or pollutant enters an organism after contact, for example, ingestion, inhalation, or dermal contact [4]. (d) the final element to be considered is the hazard also known as endpoint. As it is in Figure 1, the hazard is the effect of a chemical stressor has in a susceptible receptor such as cancer.
Methodology
The literature search strategy used here was performed on Scopus as the literature search manager. The search equation was (End-of-Life. OR. Waste Management. OR. Other More Specific Search Term). AND. Chemical Risk. AND. (Environment. OR. Human Health). A more specific term in the above equation refers to a waste management alternative such as landfill, recycling, recovery, and so on. Each paper found by Scopus had to have the terms in the search equation in its title, keywords, and/or abstract, as well as published from 2008, which is the year after the U.S. EPA Science Advisory Board (SAB) provided advice on updating U.S. EPA’s exposure guidelines and enhancing risk assessment practices.3
In addition, using Scopus the manuscripts were sorted according to their relevance in descending order. After obtaining the papers, skimming these was used as a filter to determine whether they may be relevant for the scope of this work. Therefore, on the basis of the searching parameters, the selected articles were passed through the last filter, which was an exhaustive and complete reading of each manuscript to select the most appropriate studies based on the fact that the objective of these would have been to assess the chemical risk during an EoL scenario.
EoL chemical risk sustainability indicators
Table 1 shows the sustainability indicators found in the literature to estimate the chemical risk in EoL scenarios. A group of 14 indicators were employed in previous works, where 8 of these were used to conduct environmental chemical risk assessment (indicators 1e to 8e) while only 6 are employed for human health chemical risk assessment (indicators 1 h to 6 h).
Table 1. Sustainability indicators using in the literature to assess chemical risk at EoL scenarios
| N° | Indicator | Receptor | Exposure pathwaya | Exposure routesa | Type of hazarda |
|---|---|---|---|---|---|
| 1e | Marine ecotoxicity potential | Aquatic organisms | Surface water | By interaction | Acute, chronic, subchronic toxicity |
| 2e | Freshwater ecotoxicity potential | Aquatic organisms | Surface water | By interaction | Acute, chronic, subchronic toxicity |
| 3e | Terrestrial ecotoxicity potential | Terrestrial organisms | Outdoor air | By interaction | Acute, chronic, subchronic toxicity |
| 4e | Potential ecological risk index | Terrestrial organisms | Soil | By interaction | Acute, chronic, subchronic toxicity |
| 5e | Ecological risk index | Terrestrial organisms | Soil | By interaction | Acute, chronic, subchronic toxicity |
| 6e | Risk to groundwater due to the contaminant in superficial soil | Aquatic organisms | Ground water | By interaction | Acute, chronic, subchronic toxicity |
| 7e | Risk to groundwater due to the contaminant in deep soil | Aquatic organisms | Ground water | By interaction | Acute, chronic, subchronic toxicity |
| 8e | Risk assessment code | Terrestrial organisms | Soil | By interaction | Acute, chronic, subchronic toxicity |
| 1 h | Human toxicity potential | General population | Outdoor air | Inhalation |
Cancer, noncancer, genotoxicity |
| 2 h | Hazard quotient | General population, workers | Food, soil, air, dust | Ingestion, inhalation, dermal contact |
Noncancer, genotoxicity |
| 3 h | Hazard index | General population, workers | Food, soil, air, dust | Ingestion, inhalation, dermal contact |
Noncancer, genotoxicity |
| 4 h | carcinogenic risk | General population, workers | Dust, soil, food, air, surface water | Ingestion, inhalation, dermal contact | Cancer |
| 5 h | Chemical intake | General population, workers | Air, products, soil, food, water |
Ingestion, inhalation, dermal contact |
Cancer, noncancer, genotoxicity |
| 6 h | Risk index | General population, workers | Surface water. soil | Ingestion, inhalation, dermal contact | Cancer |
- a
-
The exposure pathways and routes, as well as the hazards and susceptible receptors in the table are retrieved from the reviewed literature.
Table 2. EoL usage context of sustainability indicators in literature
| Paper | Context | Risk assessment indicator | |||||||||||||
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| Environment | Human health | ||||||||||||||
| 1e | 2e | 3e | 4e | 5e | 6e | 7e | 8e | 1 h | 2 h | 3 h | 4 h | 5 h | 6 h | ||
| [5••] | Mechanical recycling, incineration for energy recovery and landfilling of waste plastic | x | x | x | x | ||||||||||
| [6•] | Polybrominated Diphenyl Ethers (PBDEs) and Alternative Halogenated Flame Retardant (AHFR) in abandoned e-waste recycling sites | x | |||||||||||||
| [7] | Heavy metals in e-waste processing sites: dismantling, burning, acid-leaching, and abandoned sites | x | x | x | x | ||||||||||
| [8] | PBDEs and heavy metals at informal e-waste recycling sites | x | x | x | |||||||||||
| [9••] | Air emissions from landfill and composting facilities | x | |||||||||||||
| [10] | Reuse and recycling of pavement systems | x | x | ||||||||||||
| [11] | PBDEs at e-waste recycling workshops | x | x | ||||||||||||
| [12••] | Typical water reclamation plants | x | x | x | x | ||||||||||
| [13] | Metals present in waste dumps from an abandoned mine | x | x | x | x | ||||||||||
| [14] | Heavy metals in abandoned mines | x | x | x | x | x | x | ||||||||
| [15] | Pyrolysis and combustion of non-metallic fraction of printed circuit boards | x | |||||||||||||
| [16] | Chemical pyrolysis of non-metallic fraction of printed circuit boards | x | |||||||||||||
| [17•] | Chemicals in recycled rubber | x | x | x | x | ||||||||||
| [18] | Heavy metals in e-waste recycling sites | x | x | x | |||||||||||
| [19] | Polycyclic Aromatic Hydrocarbons (PAHs), Persistent Organic Pollutants (POPs), and Polychlorinated Biphenyls (PCBs) in landfills | x | x | ||||||||||||
| [20] | Polychlorinated Dibenzo-p-Dioxins and Dibenzofurans (PCDD/Fs) | x | x | ||||||||||||
| [21] | Analysis of landfill soils | x | |||||||||||||
| [22] | Groundwater near a non-sanitary landfill facility | x | x | ||||||||||||
| [23] | Solid waste management by means of landfills and thermal treatment | x | x | x | x | x | |||||||||
| [24] | Heavy metals in informal e-waste recycling sites | x | x | ||||||||||||
| [25] | Aromatic compounds in landfill | x | x | x | x | ||||||||||
| [26] | POPs in waste dumping sites | x | x | ||||||||||||
| [27] | Holistic risk analysis approach in landfills | x | x | x | x | x | |||||||||
| [28] | Heavy metals in e-waste recycling sites | x | x | x | |||||||||||
| [29] | Sediments and water polluted by heavy metals from a landfill | x | |||||||||||||
| [30] | Mobile e-waste recycling plant | x | x | x | x | ||||||||||
| [31] | Air emission from a landfill | x | x | x | x | ||||||||||
| [32] | Volatile Organic Compounds (VOCs) from plastic solid wastes | x | x | x | x | ||||||||||
| [33] | Integrated waste management facility | x | x | ||||||||||||
| [34] | Landfilling and recycling of cadmium telluride thin-film photovoltaic panels | x | x | x | |||||||||||
| [35] | Solid waste landfilling | x | x | x | x | ||||||||||
| [36] | Municipal waste organic fraction treatment plant | x | x | x | x | x | |||||||||
| [37] | Municipal solid waste incineration plant | x | x | x | |||||||||||
| Number of times that the indicator was used | 1 | 1 | 1 | 2 | 4 | 1 | 1 | 1 | 1 | 25 | 18 | 17 | 18 | 7 | |
Although there are qualitative and quantitative indicators for sustainability evaluation, but from the literature review, it is possible to notice that all of the indicators used for risk assessment are quantitative, which is expected due to the high needs of objectivity associated with risk evaluation. Additionally, the indicators to assess the environmental chemical risk consider some aspects such as acute, chronic, and subchronic toxicity for both terrestrial and aquatic organisms, where the exposure pathways which were analyzed included ground and surface water, soil, and outdoor air.
As presented in Table 1, in the reviewed literature, the carcinogenic, noncancer, and genotoxicity effects that a chemical stressor may have on human health were considered in the chemical risk evaluation at EoL scenarios, as well as the exposure pathways associated with outdoor and indoor air, dust, deep and surface soil, ground and surface water, and food. Moreover, inhalation, ingestion, and dermal absorption were taken into consideration as exposure routes.
The Table 2 presents the most remarkable manuscripts which were retrieved from the literature and the sustainability indicators to estimate environmental and/or human health chemical risk employed by each