The International Journal of Coal Science & Technology is a peer-reviewed open access journal. It focuses on key topics of coal scientific research and mining development, serving as a forum for scientists to present research findings and discuss challenging issues.
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Published: 11 February 2021
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International Journal of Coal Science & Technology Volume 8, 179-198, (2021)
1.
Department of Energy and Mineral Engineering, G3 Center and EMS Energy Institute, The Pennsylvania State University, University Park, USA
There is a growing concern in mining community about the contribution of nano-particulates to miner’s health. Despite the health influence of respirable dusts and associated lung diseases have been recognized for decades in the mining industry, the nano-scale particulates accompanying with complicated physiochemical properties and their enormous contribution in quantity have been drawing attentions only in recent a few years because of the advancement of nano-science discipline. In this review, we examine the current regulations of dusts exposure and the dominant mass-based monitoring methods to point out the ignorance of nano-particulates in mining industry. The recognized mining-related nano-particulates sources are summarized to identify the mechanically generated finer particulates including particles and aerosols. In addition, the mechanism of adverse health impact on miner with exposure to nano-scale particulates is discussed in a detail to emphasize their substantial detriment as a potential respiratory hazard. Characterization of the complex physiochemical properties of nano-particulates are then summarized and discussed because these properties could be different from regular respirable dusts due to their dramatically increased surface area and particulate counts. The intent of this review is to demonstrate the potential of adverse health effect of nano-particulate on the mine personals throughout the mining cycle and to identify the research gaps of the mine nano-particulate characterization and quantification. We suggest that further understanding of the mining induced nano-particulate properties and their pathogenesis are critical for the future engineering control measure to mitigate the potential health threat for future miners.
Dust can be broadly defined as small solid particles resulting from the breakage of solids. The adverse health impact of dust exposure for miners during operation has been recognized as a paramount issue in mining industry since early 1900s (NIOSH 2019). Sufficient proofs have been studied about their relationship with lung diseases (Cohen et al. 2016; Blackley et al. 2018; Doney et al. 2019; Moreno et al. 2019). When suspended in air, smaller airborne particles of dust can be a great risk to the miners’ respirable system. It has been proved that the smaller the aerodynamic diameter of the inhaled dust particle, the more likely it will be deposited more deeply in the respirable tract (Prata 2018; Gasparotto et al. 2018; Gianoncelli et al. 2018; Entwistle et al. 2019; Graczyk and Riediker 2019). A dramatic increase of the prevalence of progressive massive fibrosis among working underground coal miners in central Appalachia has been observed in the past decade although stringent regulations have been proposed by MSHA and NIOSH, as shown in Fig. 1 (Blackley et al. 2018; Doney et al. 2019; Hall et al. 2019). The 2018 National Academic of Sciences (NAS) report about mine dust explosion indicted that changes in mining practices, conditions, and technologies during the past decades might have led the changes of the typical dust-size distribution of both silica and coal dusts, which could result in the changes of disease epidemiology (Coal et al. 2018). Comprehensive investigation of the new challenges related to dusts monitoring, distribution and characterization were recommended. Throughout the international communities, occupational exposure limits (OELs) have been established to provide the guidance on hazardous airborne contaminant concentrations that mine workers can be exposed to during their working lifetime by various global organizations, including United State National Institute for Occupational Safety and Health (NIOSH 2011), Australia Queensland Government, Organization for Economic Co-operation and Development (OECD 2017), International Organization for Standardization (ISO 2014) and several other institutions, organizations and governmental agencies. In the mining industry, there are two types of primary dusts during the extraction and processing: respirable mine dust (RMD) and silica dust (generally referring to the rock particle with quarts concentration of more than 5%). Specifically, for the coal mining, the respirable mine dusts are termed as respirable coal mine dusts (RCMDs). The different compositions in coal dust as well as its byproducts (e.g. nitrogen dioxide, sulphur dioxide, ash and soot) and waste are considered serious exposure hazards for mine workers due to their mobilization and bioaccumulation in human tissues and toxic effect, which can induce DNA damage in different organisms, indicating the need for biomonitoring (Kabata-Pendias 2000; Menezes et al. 2013; Menezes et al. 2015). Sufficient proofs have been studied about their relationship with lung diseases.
The proposed and recommended OELs for mining industry are listed in Table 1 by various mining countries. The OELs of RCMD range from 1 mg/m3 to 6 mg/m3, while OELs of silica dusts from 0.1 mg/m3 to 20 mg/m3. These OELs are measured by a gravimetric sampling method with airborne particles filter collection. Mass concentration is used for these countries to assess the OELs that they believe the workers can be exposed during a certain time period at the low risk of adverse health effects.
Country | Total production in 2015 | Underground mining | Dust/DPM exposure limits | Required monitoring devices | Sampling methods | ||
---|---|---|---|---|---|---|---|
Rank | Thousand short tons | Est. percent of total production (%) | Typical method | ||||
People’s Republic of China | 1 | 4,376,984 | 90 | Longwall | Depending on a silica content ranging from 5% to 50%, exposure limits are between 6 and 1 mg/m3 for RCMD and between 20 and 2 mg/m3 for total coal mine dust | Personal gravimetric sampler | Gravimetric method |
United States | 2 | 896,941 | 34 | Room-and-pillar, longwall | RCMD exposure limit is 1.5 mg/m3. Quartz exposure limit is 0.10 mg/m3. DPM exposure limit: 0.16 mg/m3 (measured as TC) | Personal gravimetric sampler | Gravimetric method |
India | 3 | 643,720 | 10 | Room-and-pillar, longwall | RCMD exposure limit is 2 mg/m3, when the silica content is less than 5%. When the silica concentration is 5% or more, the exposure limit is calculated as 10 divided by the percent silica content in the RCMD | Monitoring device approved by the Indian government | Gravimetric method |
Australia | 4 | 560,714 | 20 | Longwall | New South Wales: Exposure limits is 1.5 mg/m3 (effective on Feb 1, 2021) for RCMD, 0.05 mg/m3 for quartz, and 0.1 mg/m3 (effective on Feb 1, 2021) for DPM | Personal gravimetric sampler | Gravimetric method |
Queensland: Exposure limits is 3 mg/m3 for RCMD with a quartz content less than 5%, 10 mg/m3 for the inhalable fraction, and 0.10 mg/m3 for quartz | Personal gravimetric sampler | Gravimetric method | |||||
Republic of South Africa | 7 | 256,876 | 50 | Room-and-pillar, some longwall | Exposure limit is 2 mg/m3 for RCMD with a quartz content less than 5%. If the quartz content is greater than 5%, an exposure limit for quartz is 0.1 mg/m3 | Personal gravimetric sampler | Gravimetric method |
Germany | 8 | 203,613 | 3 | Longwall | Limiting cumulative exposure for a 2-year, 220-shift exposure would be an estimated dose accumulated from an average exposure of 4.0 mg/m3. DPM exposure limit: 0.1 mg/m3 for general surface working place and 0.3 mg/m3 for underground non-coal mines | Area gravimetric sampler | Gravimetric method Does based method |
Poland | 9 | 149,147 | 53 | Longwall | Exposure limits is 1 mg/m3 for RCMD containing free crystalline silica from 2 to 50%, 4 mg/m3 for total dust | Personal gravimetric sampler | Gravimetric method |
It is commonly believed that dust size is critical for the assessment of the adverse effect on human health. Only dust particle with a smaller diameter can become suspended in the air stream for a long period of time which pose a great risk to the respiratory system with continuous inhaled. Particles ranging from ~ \(60 \upmu \rm{m}\) to ~\(2000 \upmu \rm{m}\) can only reach heights up to approximately 3 feet above the ground surface, while particles with a diameter less than \(60 \upmu \rm{m}\) can be suspended in air for long periods of time (NIOSH 2019). Therefore, by quantifying the mass concentration of dust particles smaller than \(60 \upmu \rm{m}\) has been widely applied in mining industry to assess the severity of dust hazards to miners’ health with a strong assumption that dust particles with various diameters cause a same risk of adverse health effects on workers. In fact, it is a really wide sized range for the dusts less than \(60 \upmu \rm{m}\), and the size-dependent health effect should be paid more attention for future characterization and pathogenesis of dusts on miners’ respirable system.
In recent years, nano-dust and their aggregates or agglomerates (NOAA) have obtained significant attention due to their potential influence on health in work environment. The studies have indicated that nano-scale particles pose a higher risk of human health due to their specific characterizations, such as highly developed surface area per unit weight or volume, which may cause a larger lung deposited surface area (LDSA) with a different toxicology compared to the same mass concentration of dust with relatively large size (Arias-Andres et al. 2018; Johnson et al. 2019; Zhao et al. 2019). The definition of the nanoscale, given by International Organization for Standardization (ISO) and European Committee for Standardization (CEN), is a size range from approximately 1 to 100 nm (Definition of a nanomaterial) (Commission 2017). A related term, ultrafine particles (UFPs) was also introduced in 2013 Health Eating Index (HEI), referring the fraction of ambient particulate matter (\({\mathrm{PM}}_{0.1}\)), containing airborne particles of nanoscale size with a diameter less than 0.1 \(\mathrm{\upmu \rm{m}}\). At the active mine extraction sites or the processing plants, the continuously coal/rock cutting and breakage can produce a wide range of dust particles including nano-sized dusts (Sarver 2018). These nano-sized dusts existing in mining environment throw into a question that the current OELs in assessing dust hazard using a mass concentration instead of a number concentration. Because the total mass of the nanoparticles contained in the aerosol may constitute only its percentage, but their number can reach over 80% of the total particles (Oberbek 2019). A better understanding of the formation, transformation, and adverse health impacts of nano-scale dusts would contribute to the protection of miners’ health and future regulation formulation.
This review tries to summarize the state of knowledge on the evidence of nano-dust hazards in mining industry and their fate and effects in organisms after inhalation by discussing existing literatures regarding nano-dust characterization. Five sections address exposure, health effects, and characterizations in the following order: (1) current regulations; (2) health impacts of nano-scale dusts; (3) Mining related nano-dust sources; (4) surface characterization and size distribution; and (5) coating effect with DPM.
In mining operations, no matter surface or underground mining (Fan and Liu 2019a, b), dust is generated in obvious ways. Anytime an operation is cutting, blasting, transporting, refining, or processing a dry material, there is a great likelihood that dusts can be generated (Fan and Liu 2017; NIOSH 2019; Zhao et al. 2020). The dust generated will easily be liberated into the confined working environment, forming a dust cloud if its concentration is high and with proper sizes. This type of dust cloud, obviously, is a great health threat to mining operation personnel. In addition, high dust levels can impede visibility and thus directly affect the safety of workers. In most cases, however, exposure to dust clouds can be prevented through administrative controls (such as increasing waiting time before getting access to the operational regions) and engineering controls (such as suppression and prevention from water sprays), because large-size particulates (60–2000 \(\upmu \rm{m}\)) only can suspend in the air for a very short time before settling down on the ground according to EPA (1996). Therefore, these dusts generally have been mitigated before interacting with workers. Particulates with size less than 60 \(\mathrm{\upmu \rm{m}}\) can suspend in the air for a long time before creeping down. It is expected that the smaller the dust size is, the longer suspending time for the corresponding dusts. Therefore, nano-dusts can easily suspend in the air for hours and be transmitted to locations far away from its original sources. The possible mining related nano-dust sources are summarized in Fig. 2. Proofs of existence of nano-dusts in mining related operations have been reported.
Drilling and blasting are the two primary mining operations involving displacement of air around the operational regions. Both are notorious sources of nano-dusts with the fragmentation of the rocks. Surface mine drilling is accomplished using both rotary and percussion drilling methods. In particular, dry drilling achieves penetration through rock and cleanness of cuttings using pneumatic power. Fines particulates will be delivered to the air around the drill holes and become a risk of dust exposure. Generally, wet drilling by using moisture air and installing shroud around the drill are the primary dust control methods applied in fields. However, the water suppression effect with nano-sized particulate and the leakage between the shroud and complicated working surfaces are still skeptical by researchers (Zimmer et al. 1987; Organiscak and Page 2005). Droplet size is critical in dust suppression. Only with the size similar to the size of nano-particulate, the water spray system can be applied with a high efficiency. There are two difficulties for the water suppression of nano-particulates: the formation of nano-scale droplets and the polydisperse of size distribution. While blasting seemingly generates large amount of dust, the operation occurs infrequently enough that it is not considered to be a significant contributor to particulate less than 10 µm (Muleski 1991; Richards and Brozell 2001). The investigation of the dust size distribution for both soot and minerals with primary blasting in limestone quarries well demonstrated the existence of nano-scale dusts (Jones et al. 2003). The image analysis-based quantity percentage is shown in Fig. 3. Although underground blasting is confined in an enclosed environment, setting off the blast in underground operations generally occurs off-shift when miners are evacuated, and ventilation is used to clear the mine for hours. There is less likelihood for dusts accumulation under this circumstance, but secondary dust sources should be paid more attentions, such as the following loading and hauling operations. In addition, mineral processing on surfaces with pneumatic powers (e.g. bag filling) can also be the potential nano-dust sources because of the continuous air blowing around dust sources. The root causes for the airborne dusts with these processes are that small particles of insufficient weight are picked up by excessive air currents. Generally, dust collection system should be properly designed, and PPEs are suggested for workers within these processes to reduce inhaled respirable dusts.
Mining processes such as cutting, crushing, mucking, hauling and so on are primarily related to the breakup and transport of rock blocks, where new dusts formed due to mechanical forces or existing dusts become airborne due to disturbances. The mechanical breakup forms dusts due to the inherent nature of size-reduction and segregation processes. Relative dust emission rates are different from different mineral processing equipment. The general principle summarized, as one would expect, is that emissions increase as the size of the material processed decreases. It is recommended that the readers can refer EPA-estimated particulate emissions for crushed stone operations for more data. Worker exposure may be managed through engineering controls to coat, suppress, or enclose the dust sources, or by isolating the worker from the dust sources. However, it was evident that the improvement in cab collection efficiency is limited for nano-scale dusts and more protection should be focused on the nano-scale dusts. Figure 4 demonstrates the limited cab collection efficiency for nano-scale dusts as marked in red. Also, the protection factor (the average outside respirable dust concentration divided by the inside cab dust concentration) is high for the nano-scale dusts as measured by GRIMM Particle monitors (Gresh et al. 1994). The potential second dust sources during loading and hauling of “mucks” can liberate existing dusts, which have been attached on the surface of broken rocks, via using LHD (load-haul-dump) vehicles and muckers. Local ventilation and water applications to the muck pile are the primary means of dust control. But for different types of rocks, the dust control effectiveness varies. For example, water suppression cannot be efficiently applied in coal mines due to its hydrophobic nature. Different types and application ratios of additives have been studied for suppression and prevention of hydrophobic dusts (Blazek 2003; Organiscak 2013). Details about of this is beyond the scale of this review.
Different types of conveyors can be used in mines for transporting materials, from raw unprocessed ore to fully processed products. A conveyor and its transfer points are well known to generate significant amount of respirable dusts. Fugitive emission is the most common dust source related to material transportation with a conveyor belt. Spillage results from uncontained or improperly loaded material, and carryback comes from materials falling to discharge from the belt as it is transferred or discharged from the conveyor belt, can become airborne via interacting with the ventilation airflow currents (NIOSH 2019). Proper design and selection of the conveyor equipment accompanying with the enclosed system by considering the transfer distance, property of materials to be transferred, can effectively control the dusts emission towards the working environment. In addition, more attentions should be put on the transfer points, where sufficient airborne dusts can be generated due to the air induction resulting from the materials falling through air, which imparts momentum to the surrounding air. Due to this energy transfer, a stream of air always travels with the falling material and the excessive airflow can pick up the dusts of insufficient weight and make it suspend in air for a long time. The same mechanism of dusts generation in the storage bin, bucket elevator, and other processes where material falling occurs. Combination use of water prevention and suppression systems before, during and after the transfer point is critical to reduce airborne dusts during these processes.
Open areas with exposed product are another dust source in mining process and around surface plants. Stockpiles are the most common region generating dust cloud in a large scale during the material loading, moving and unloading from the stockpiles. Wind fence is normally installed to prevent the dust emission and transmission and contain the operation in a relatively enclosed region. Haul road dust emission control is a significant issue at surface sites as well due to the fugitive dust. It is proved that the dust contribution from the haul truck is 78%–97% of total respirable dusts at surface site, which is highly possible to cause overexposure of mine personnel (Cole and Zapert 1995; Amponsah-Dacosta and Annegam 1998; Reed et al. 2001). Rather than a fixed dust source, the mobile vehicles is a moving dust source, which may have an influence with a large scale. Another concern for the dust source from open areas is the unpredicted wind direction and flowrate, which may have a dominant control on the dust emission and its plume. Therefore, the speed control of haul trucks itself should be considered for dust control. Material wetting is also applied to maintain the respirable dusts stick on the ore surfaces and prevent it becoming airborne.
The size distribution could be dramatically different from the mining-related dust sources due to the different break-up mechanisms of rock during the operation (Smith 1986; Jiang et al. 2016; Yang et al. 2020). Although, with current studies, it keeps largely unknown of the nano-scale fraction of dusts formed in various mining cycles and operations, adamant evidences have shown that the nano-scale dusts can exist in all of these operations, and the number fraction of nano-scale dusts could possess absolute advantage in the total number quantity. The size distribution of samples of mine dust from 50 coal mines in the 10 MSHA bituminous districts shown that the average weight contribution of dusts under 200 mesh (< 75 \({\upmu \rm{m}}\)) could be \(\left( {30 \pm 5} \right)\) %, and the nano-scale dusts among them are believed to have a dominant quantity contribution (Cashdollar 1996; Sapko et al. 2007). An investigation of total suspended particulates in an India surface coal mine revealed that the weight percentages lying within different size ranges were a function of mining activity. The finer dusts would suspend in the air for a longer time and being transported to a further distance. Particle size analysis by Cascade Impactor indicated that at two monitored stations the size range 0–2 μm had a weight percentage as high as of 48.2% and 54.5% (Ghose and Majee 2007). An example shown in Fig. 5 is the dust size distribution versus volume with various drilling operations measured in the lab by Yang et al. (2020). Different curves represent different drilling operation with various rotation speeds and penetration rates as listed in the table. Two obvious volume peaks occurred for the majority curves, indicating the large volume of dusts with large-scale size of ~ 100 \(\mathrm{\upmu \rm{m}}\) and small-scale size of ~ 500 nm. It is easy to convert this volume percentage to number percentage by assuming the dust shape as a sphere. The number counts of small-scale dusts could be 6 magnitudes larger than that of the large-scale dusts. Similar results were also observed in Fig. 7, which sample was collected from an underground mine. The big fraction of the small-scale dusts should be paid more attentions while characterizing the health effects of mining-related dusts rather than only focus on the mass concentration, which is primarily dominant by the large-scale dusts in mining industry.
Item | Z1 | Z2 | Z3 | Z4 | Z5 |
---|---|---|---|---|---|
Rotation (r/min) | 600 | 900 | 1250 | 1750 | 2600 |
Item | T1 | T2 | T3 | T4 | T5 |
Penetration (mm/s) | 0.75 | 0.85 | 1.0 | 1.2 | 1.5 |
Numerous factors influence miners’ health of exposure to mining-inducted nano-dust. The hazard posed by inhaled nano-dusts in mining industry depends on their abundance and particle sizes, properties such as chemical composition, solubility, shape, and surface area, which all play a role in the associated health effects, as shown in Fig. 6 (Entwistle et al. 2019; Liu and Liu 2020). Surface area of particles can exponentially increase with the decreasing particle size, reflecting the increased physical and chemical activities of nano-particles (Fig. 6b). A schematic represent of a typical dust size distribution of the number concentration, surface area concentration, and mass concentration in underground mines is shown in Fig. 7, indicating that although nano-particulates contribute a micro fraction of the total mass, their number contribution is significant. Small-scale particulates could suspend in the working environment for a longer time and transmit to a further location with directional airflow in underground. Therefore, these small-scale particulates are highly likely to be inhaled by miners. Dust exposure can span a wide range of particles sizes in mining industry with health effects depending upon the region of deposition in the lung. For this reason, the size distribution of dusts existing in the working environment should be evaluated. Three dust fractions are defined, namely inhalable, thoracic and respirable fractions. There has been international agreement that OELs for dusts should normally be specified as one of the above fractions. The relationship between dust size and its deposition are given by ACGIH in 1999 (Table 2), indicating that the nano-scale dusts are completely respirable and can be fully deposited in the lung or transport into bloodstream.
Aerodynamic diameter (\({\mu m}\)) | Inhalable fraction (%) | Thoracic fraction (%) | Respirable fraction (%) |
---|---|---|---|
0 | 100 | 100 | 100 |
1 | 97 | – | 97 |
2 | 94 | 94 | 91 |
3 | – | – | 74 |
4 | – | 89 | 50 |
5 | 87 | – | 30 |
6 | – | 80.5 | 17 |
7 | – | – | 9 |
8 | – | 67 | 5 |
9 | – | – | – |
10 | 77 | 50 | 1 |
With above discussion, a fully characterization of the size less than 1 micro should be focuses on for mining resulted dusts. We can acknowledge the value of mass centration as shown in green curve in Fig. 7, but the pathogenesis study will be benefit much more from the red and blue curves. Establishment of the relation of mass to number and surface area through characterization would be the key to better understand the potential transmission and pathogenesis mechanisms by inhalation of nano-scale dusts.
Numerous techniques have been applied to characterize the dust size distribution, shape and chemical compositions such as SEM–EDX, TEM–EDX, XRD (X-ray Diffraction), DLS (Dynamic Light Scattering), SAXS (Small-angle X-ray Scattering), AFM (Atomic Force Microscopy), FTIR (Infrared Spectroscopy and Atomic Force Macroscopy), etc. Both SEM–EDX and TEM–EDX are equipped with energy dispersion X-ray, allowing the analysis of the mineral composition. They are well established for chemical identification of particles (Kasahara et al. 1993; Kasparian et al. 1998; Carpenter et al. 2002; Deboudt et al. 2010; Cvetković et al. 2012) and determination of size and shape parameters (Kasparian et al. 1998; Wang and Luo 2009). They have been specifically applied to investigate mine dust mineralogy and particle size (Denee 1972; White and DeNee 1972; Huggins and Meyers 1986). Detailed guidance on the use of SEM–EDX for analysis of particulate samples is proposed by the US EPA (Environmental Protection Agency) (De 2004). SAXS is an uncomplicated bulk nanostructural quantification technique, particularly sensitive to the smaller end of the nanoscale. It has been reported that the results from SAXS have repeatedly been demonstrated to agree well with findings from electron microscopy. A round robin experiment for inter-laboratory comparison of SAXS results was conducted by Brian et al. (2017). To assess the practical precision and accuracy, indicating that SAXS is a suitable method for revealing particle size distribution in the sub −20 nm region (at minimum). Dynamic light scattering is a technique tool to diagnose particle size distribution in solution or colloidal suspensions, where the photon correlation spectroscopy (PCS) was applied to calculate the autocorrelation function and deduce the particle size information. Similar technique such as real-time cloud and aerosol spectrometer (CAS) light-scattering measurements was also applied to characterize the dust cloud using a light-scattering theory for irregular particles- ray tracing with diffraction on facets (RTDF) (Hesse et al. 2009), which is considering diffraction at facet in addition to diffraction at the projected cross section applied in dynamic light scattering, and therefore describes the size-dependence better (Barone et al. 2017). The surface topography and chemical property such as functional groups can be assessed through AFM and FTIR. AFM is powerful tool to investigate the three-dimension surface tomography, friction (Fujihira and Morita 1994; Frisbie and Rozsnyai 1994), magnetism (Martin and Wickramasinghe 1987; DiCarlo and Scheinfein 1992), surface charge (Sugawara et al. 1994; Yoo et al. 1997), rigidity (Maivald et al. 1991; Persch et al. 1993) and capacitance (Neubauer et al. 1996) by moving a tiny probe contacting with the particle surface. FTIR is unique among all the chemical characterization techniques because it is nondestructive and capable of identifying the molecular level chemistry through the identification of the vibrational signatures related to specific types of chemical bonds (Painter et al. 1981; Liu et al. 2016). In addition, and providing important information on molecular structure, especially the chemical functional groups of organic compounds coated on the particle surfaces.
After recognizing that the size and particle counts are critical for the characterization of the nano-particulates, we would like to review the influence of these factors on the transmission, deposition and interaction with organ tissues of nano-particulates. Despite occupational improvements within the mining industry, mine dusts, and associated potential toxic elements (PTEs) generating in mining activities, is one such hazard related cause of adverse health effects on mine workers. Understanding the exposure pathways is critical, as is the source, transport pathway, nature of exposure (e.g. duration, activity) and exposure route (i.e. by inhalation, ingestion or dermal/topical adsorption) (Entwistle et al. 2019). Rather than the well-known health effects of accumulated respirable dusts in human lungs, such as diseases of coal worker pneumoconiosis (black lungs), silicosis, chronic obstructive pulmonary diseases, etc., with an accumulative dust mass concentration only in lungs, nano-dusts may have more complicated mechanisms of adverse health effects on human health with its specific characterizations in a ultra-small scale. A better understanding of the mechanisms that lead to adverse health impacts, toxicity, and evolving biomonitoring of nano-dusts in mining community are pivotal for future understanding of the pathogenesis of the dust on the human lung.
The mechanisms, the efficiency and the pattern of dust deposition in the lung is known to be determined by the aerodynamics and thermodynamics of dust particles from a physical perspective. Apparently, the nano-sized particles can behave in a more complex way as inhaled. Figure 8 demonstrates the fractional deposition of inhaled particles. The particulates of 10–100 \(\mathrm{nm}\) are primarily deposited in the alveolar region where the gas exchange occurs. Rather than only interact with lung cells, nano-sized dusts are of particular concern as they may translocate and be transported by mechanism such as macrophage-mediated clearance (Kreyling 1990; Kreyling et al. 2012), interstitial-lymphatic clearance (Semmler-Behnke et al. 2014) and the blood circulation (Kreyling et al. 2017; Graczyk and Riediker 2019) to distance sites and organs. The predominant mechanism for dust clearance from peripheral lungs is uptake by lung surface macrophages and transport to the larynx. Varying amounts of circulated nano-dusts in human body can be excreted quickly by different routes, usually through the liver, kidney or gastrointestinal tract, and sometimes in sweat, skin cells and hair loss (Baker 2012). However, the deposited nano-dusts can be a potential hazard for human health. Therefore, a much broader list of human diseases can be influenced by inhaled nano-dusts, including cardiovascular, respiratory, liver, neurological, gastro-intestinal, kidney and mental health (Stewart and Hursthouse 2018). In addition, mining-induced dusts can be troublesome on impact with the skin and eyes. Under certain conditions in certain mine locations considerable irritation due to the facial impaction of coarse particles has been reported (Gibson and Vincent 1980; Sun et al. 2007). However, few studies have investigated the impacts of nano-scale dusts. The limited researches conducted in the lab indicates that the small-scale coal dust explore plays an important role in the development of dry eyes, that were attributed not only to the mechanical injury of coal dust but also its toxicity, which induced the development of xerophthalmia (Sun et al. 2007; 2009). More studies should be conducted focusing on the skin and eyes impact due to nano-scale dusts in the industry working environment.
One noteworthy property of nano-dusts causing attention is their high toxicity and their capacity to bioaccumulate. The continuous inhalation of nano-dusts in the working environment with high dust concentration is hazardous and a silent risk factor to a healthy worker that may lead to oxidative stress, oxidative damage, acute pro-inflammatory response and damage to macromolecules such as lipids (lipid peroxidation), proteins, carbohydrates and nucleic acids (DNA) (Schins and Borm 1999; Silva 2016; León-Mejia et al. 2018). In addition to the well-known lung diseases, liver is reported as a vulnerable target organ since the translocated nano-dust can easily reach micro live vasculature and hepatocytes through bloodstream (Mani 2007; Bourdon et al. 2012; Kim et al. 2014). Biomonitoring tests in the lab demonstrated that Obese rats are more vulnerable to coal-dust inhalation induced adverse health effects, which may induce organ specific pathologies or even aggravate existing diseases where obesity is present (Gasparotto et al. 2018). One group of lung and liver histology comparison with coal dust inhalation has been summarized in Fig. 9, indicating the adverse influence of nano-scale dusts on organ cells. Accumulating evidences suggested that inhaled nano-dusts have a considerable impact on health and disease of the CNS (Central Nervous System) (Block et al. 2012). It is reported that nanoparticles can accumulate in the nasal regions, where they are then transported along sensory axons of the olfactory nerve directly to the CNS (Oberdörster et al. 2005; Oberdörster and Elder 2009). Dust exposure has also been associated with autism, attention deficit/hyperactivity disorders and neurodegenerative diseases—although evidence of causation has not been established (Kioumourtzoglou et al. 2015; Casanova et al. 2016; Heusinkveld et al. 2016; Cacciottolo et al. 2017; Liu and Liu 2020).
The toxicity mechanisms are clearly related to chemical and physical compositions of nano-dusts and molecular mechanisms driving the body defense or possible related diseases. The micro particles inside the tissues may undergo complex metabolic transformations and the surface properties can be modified by removal and deposition of chemical elements, metals and salts, or by adsorption of macro-molecules such as proteins (Gianoncelli et al. 2018). Numerical studies of particle characterizations has been reported from different part of the world, as discussed in Sect. 2. However, a very few sparse tests have been reported related to lung tissue chemical analysis by using different technologies, including PIXE (particular-induced X-ray emission), SEM (Scanning Electron Microscopy), TEM-EDS (Transmission Electron Microscopy – Energy Dispersive X-ray Spectroscopy), \(\mu\) FTIR (Fourier Transform Infra-Red), SR-\(\mu\) XRF (Synchrotron Radiation XRF). The application of PIXE was firstly reported in 1981 by Robaye et al. involving multiple procedures involving freeze-drying (Pascolo et al. 2015), low temperature ashing and dissolution that completely destroys the tissues itself. Then it is improved by Annegarn et al. and widely used in biomonitoring region for dust induced adverse health effects (Annegarn et al. 1988; Ogasawara et al. 2011; Chino et al. 2015; He et al. 2017). It is believed that SEM and TEM have a higher spatial resolution for this purpose, however, they are more feasible for dust characterization because the lower detection sensitivity that limit the information can be obtained from the tissues. Another reason why SRF is proposed for tissue chemical analysis is the relatively easy sample preparation and single particle can be discriminated in the heterogeneous aggregates. Recently, Alessandra et al. applied SR-\(\mu\) XRF spectromicroscopy to track the dust inside histological samples of lung tissue and investigate the chemical nature at nanometer spatial resolution. They found XRF can quantify important elements in nano-deposits providing information on the presence of highly toxic material. Using the same technique, Zhang et al. found that the bioavailable iron contained in coal can induce an increment of ferritin in the cells and stimulate lipoperoxidation via free radical production and eventually induce cell death (Ackerman et al. 1999). Similar results obtained by McCunney et al. suggested that the main active compound of coal inducing pneumoconiosis is iron (McCunney et al. 2009). Another advanced imaging technique widely applied is micro Fourier Transform Infra-Red (μ FTIR) spectroscopy. Basing on the adsorption of IR radiation by molecules and molecular groups at specific frequency, μ FTIR approaches are sensitive, label-free and non-damaging analytical tools for the characterization of biomolecules, revealing the vibrational pattern of the investigated samples (Pascolo et al. 2015). The well-known IR adsorption profile of fundamental components of biological tissues such as protein, nucleic, carbohydrates etc. also benefits the application of this technique. The demonstration of results acquired from different techniques are shown in Table 3.
Method | Demonstration of results | Description |
---|---|---|
PIXE (Yasuo et al. 2011) | Peaks of each element and element map for peak line 1. a Peak line 1 indicates all elements in the beamed area and peak line 2 indicates the spectrum of the gated area. b The intensity of metals in lung tissue is shown by gray to white bars | |
μXRF (Lorella et al. 2016) | μXRF analyses of asbestos bodies and anthracosis in human lung tissue. The images show the XRF maps of Fe, Ca, and Zn acquired at 7.2 keV over the area (100 μm × 100 μm) depicted in the visible light image (acquisition time 300 ms/pixel) | |
μFTIR (Lorella et al. 2015) | μFTIR Imaging of lung tissues with anthracosis and asbestosis. Upper row: a c Optical picture of the lung tissue sample, showing asbestos bodies; b d Chemical image of the 1720–1490 cm−1 spectral region e Second derivative of the average vibrational spectrum of selected points on the asbestos bodies and surrounding tissues (line thickness is proportional to standard deviation) |
Although various techniques can be applied to quantify the surface composition of nano-scale dusts. Attention to details is required while selecting the proper techniques to quantify the surface toxicity. For instance, both SEM and TEM-EDS are adequate for particulate analysis with specific surface elementals attachment, while μXRF and μFTIR can be applied to map the elemental distribution in tissues. Therefore, choosing the proper technique is vital for acquiring accurate surface toxicity of nano-particulates.
In mining industry, the materials, in general, have been weathered and subjected to a wide range of environmental conditions that have modified the original ore and gangue materials. In such contexts, the dusts generated are potentially different in their reactivity and hazard from the originally mined sources. Nano-particulates released into the working environment are highly likely to interact with other pollutants, which is also being released in the same environment. An important aspect of nanotoxicity is the modification of physiochemical characteristics of nano-particulates’ surface functionary by coating, aggregating, chemical transforming and more (Lee et al. 2014). Parallels can be drawn with the coal mining industry where changes in specific dust characteristics have been invoked to explain resurgence in diseases such as black lung in the Appalachians (Arnold 2016). As demonstrated in Fig. 10, the nano-particulate or aerosol generally formed by an elemental carbon/silica core accompanying with very complicated surface coatings, including organic carbons species, adsorbed soluble and vaporous hydrocarbons, hydrated sulphates and nitrates, reactive metals and more (Stone et al. 2017).
DPMs (diesel particulate matters) released from diesel powered equipment in underground mining has been identified as a hazard in the past decades. An improved understanding of the physiochemical property change—the interactions between combustion induced aerosols and mechanical generated particulates in complexed underground conditions—would be a substantial contribution to prevent miners from exposing to such hazards.
The formation and transformation of DPMs normally includes several stages: combustion, cooling-dispersion-dilution, and particle growth, accompanying with three modes of particulates—nucleation, accumulation and coarse modes—as shown in Fig. 11. Diesel aerosols are, in general, one order of magnitude smaller than other respirable particulates generated in mines through mechanical processes. Their sizes range from \(\mathrm{nm}\) to \(\mathrm{\upmu \rm{m}}\). Most of the diesel aerosols behavior similar to the gaseous components in underground with a long residence time in the ventilation air. However, the particulates of nucleation mode (less than 0.1 μm), the primary components of which is elemental carbon produced due to incomplete combustion, would be rapidly deposited by Brownian diffusion. These particulates are readily to collide with adjacent particulate to coagulate into large particulates. While particulates go to the region of tailpipe with lower temperature and pressure, they continuously grow due to condensation and coagulation with other semivolatile or volatile organic compounds. The coagulation and evaporation process rapidly diminishe the particulate number of the nucleation mode. With the aging of emitted particulates in air, the particle growth continues via chemical reaction and physical adsorption, and consequently form particulates of accumulate and coarse modes. While the size is larger than 1 μm, the sedimentation is dominant, and the corresponding residence time shortens. It is reported that particulates between 30 nm to 1 μm tend to have longer atmospheric lifetime because they are less likely to be deposited in either way as shown in Fig. 11 (Kwon et al. 2020).
In addition, the electrical forces a charged airborne dust particle can experience may be of considerable practical importance to lung deposition after inhalation and toxicity alternation. Dust particles could carry varying electric charges after pulverization depending on the characteristics of individual mines. The factors affecting the sign and magnitude of charges on coal dust particles include moisture content, ambient humidity, dust components (e.g., mineral level, sulfate level), process method, and particle size (Johnston et al. 1985; Page 2000; Tessum and Raynor 2017). It is reported that the respirable particles can carry on the order of 102–106 charges per particle that could cause a different dispersion patten in air after it is generated. Most importantly, the surface charge may alternate the surface chemical characteristics through the complex interaction with DPMs in the air that could increase its toxicity. Previous studies demonstrated that the negatively charged dusts would react strongly with scavenger receptors on alveolar macrophages and would activate the generation of reactive oxygen species (ROS) and inflammatory cytokines (Lapp and Castranova 1993; Castranova 1998; Jardin and Wallaert 2012). Since the nano particles tend to deposit more and deeper in the lung, future studies should be conducted focusing on investigating the deposition mechanism of highly-charged nano-dusts and its interaction with lung fluids.
Despite the intensive toxicity by interacting with nano-dusts, DPM itself, as another primary contaminant with nano-scale size in underground, especially in metal, non-metal mines, can cause a severe concern due to its adverse health effects on human body. A substantial body of research addressing the adverse health effect of the DPM and the underlying toxicological mechanisms have been studied, indicating that the long-term or short-term exposure in the environment with high DPM concentration, such as in underground, is responsible for causing respiratory mortality and morbidity (Donaldson 2005; Pope and Dockery 2006; Ayres et al. 2008).
A high number of animal studies starting from 1950s have been carried out to demonstrate that the long-term and short-term exposure to high-concentration DMP concentrations contributes to the increasing risk of lung tumour (Chang and Xu 2017). As the concentration of DPM is larger than 2.5 mg/m3, all animal studies except for one study have shown a lung tumour response in rats, indicating its positive relationship with DPM exposure (Heinrich et al. 1986). However, Ping et al. summarized in a review paper that although sufficient evidences have been collected in rats test, none of the hamster studies showed the same increasing trend as rats in the risk of lung tumours and only one study involved monkeys, but no lung tumours were found in monkeys after long-term DPM exposure (Chang and Xu 2017). Therefore, it is suggested that more studies should be carried out focusing on the cohort and occupational studies relevant to the potential carcinogenicity of DPM on human bodies. Some epidemiological studies for different job titles have been reported by IARC providing a strong evidence that the DPM exposure could increase the risk of lung tumour for human beings (IARC 2013). The systematic studies of the adverse health effect on coal miners with respect to DPM exposure was reported by NIOSH in 1986 with the title of “Evaluation of the potential health effects of occupational exposure to diesel exhaust in under-ground coal mines”, demonstrating a strong association between lung cancer and exposure to DPM. Similar study was carried out at 8 U.S. non-metal mines to evaluate the potential influence of DPM exposure on the lung health of 12,315 miners (Attfield et al. 2013). Positive correlation between lung tumour and DPM exposure time was also revealed in this study since the DPM level is generally higher in underground than other industries. Although few studies have been carried out in underground, strong evidences have been found to demonstrate the adverse health effect of DPM exposure. Since the generation source and the mechanism of adverse health effect could be different for DPM compared to nano-scale dusts, more studies should be carried out to further unveil the pathological mechanism and the potential control methodologies for DPM exposure in underground.
Despite nano-particulates are massless and weightless and may invisible in mining environment, their considerable number quantity and dramatically surface area are pivotal to their toxicity and adverse impact on health after being deposited in miners’ respiratory tract and transmitted to circulation system. Further studies will be required to answer a few different questions: (1) nano-scale dusts generation sources and rates; (2) their transport and deposition behavior in the prevailing mine environment; (3) pathogenesis and its relation with dust characterization; and (4) effective mitigation methods including monitor and suppression techniques. Number quantity-based monitoring methods should be proposed in mining industry rather than only employing mass-based monitoring. Numerous lab technologies have been developed to quantify the size distribution of collect samples, further studies will be required on mapping the residence time of nano-particulates in a large scale, in particular, considering the environmental moisture and aging of DPMs in underground.
The niche-targeting regulations should be discussed based on the scientific evidence of the mine nano-particulates. Current mass-based regulations of respirable dusts generally consider only the particulates larger than 1 \(\mathrm{\mu m}\) because the weight accumulation of particulates less than 1 \(\mathrm{\mu m}\) is negligible among mechanical generated dusts. A considerable number of nano-particulates and aerosols could be generated through diesel-powered equipment. The combination effects of DPM and existing dusts should be carefully considered while formulating new regulations of respiratory hazard exposure.
Mining operation related nano-dust sources have been summarized in this review. However, the specific particulates properties and size distribution could be dramatically different with various mining related process and ore properties. Various types of dusts should be collected in different coal mines and M/NM mines adjacent to different operations. Size distribution and surface functionary characterization are needed to be conducted in the lab. It is necessary to build up the mining operation-based database of dust properties, that would contribute to the dust control and operation optimization.
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