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Review

Bioaccumulation and Biotransformation of Chlorinated Paraffins

by
Liujun Chen
1,2,
Bixian Mai
1,3 and
Xiaojun Luo
1,3,*
1
State Key Laboratory of Organic Geochemistry and Guangdong Key Laboratory of Environmental Resources Utilization and Protection, Guangzhou Institute of Geochemistry, Chinese Academy of Sciences, Guangzhou 510640, China
2
University of Chinese Academy of Sciences, Beijing 100049, China
3
Guangdong-Hong Kong-Macao Joint Laboratory for Environmental Pollution and Control, Guangzhou Institute of Geochemistry, Chinese Academy of Sciences, Guangzhou 510640, China
*
Author to whom correspondence should be addressed.
Toxics 2022, 10(12), 778; https://doi.org/10.3390/toxics10120778
Submission received: 3 November 2022 / Revised: 6 December 2022 / Accepted: 8 December 2022 / Published: 12 December 2022
(This article belongs to the Special Issue Fate, Bioaccumulation and Risk Assessments of Persistent Organic Pollutants (POPs))
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Abstract

:
Chlorinated paraffins (CPs), a class of persistent, toxic, and bioaccumulated compounds, have received increasing attention for their environmental occurrence and ecological and human health risks worldwide in the past decades. Understanding the environmental behavior and fate of CPs faces a huge challenge owing to the extremely complex CP congeners. Consequently, the aims of the present study are to summarize and integrate the bioaccumulation and biotransformation of CPs, including the occurrence of CPs in biota, tissue distribution, biomagnification, and trophic transfer, and biotransformation of CPs in plants, invertebrates, and vertebrates in detail. Biota samples collected in China showed higher CP concentrations than other regions, which is consistent with their huge production and usage. The lipid content is the major factor that determines the physical burden of CPs in tissues or organs. Regarding the bioaccumulation of CPs and their influence factors, inconsistent results were obtained. Biotransformation is an important reason for this variable. Some CP congeners are readily biodegradable in plants, animals, and microorganisms. Hydroxylation, dechlorination, chlorine rearrangement, and carbon chain decomposition are potential biotransformation pathways for the CP congeners. Knowledge of the influence of chain length, chlorination degree, constitution, and stereochemistry on the tissue distribution, bioaccumulation, and biotransformation is still scarce.

1. Introduction

Chlorinated paraffins (CPs), known as poly-chlorinated n-alkanes (PCAs), are produced by the chlorination of different n-alkanes with the formula CnH2n+2−mClm. They are divided into short-chain (SCCPs, C10–13), medium-chain (MCCPs, C14–17), and long-chain CPs (LCCPs, C ≥ 18) according to the lengths of their carbon chain. Recently, very-short-chain CPs (vSCCPs, chain lengths below 10) have been reported in wildlife and human samples [1,2]. CPs have the advantages of low volatility, flame retardancy, good electrical insulation, and low cost. Consequently, CPs have been used as plasticizers, flame retardants, and additives in metal cutting fluids, adhesives, coatings, rubber, and sealants with a global CP production of more than two million tons per year [3,4].
CPs are highly persistent in the environment, are bioaccumulative and toxic to animals and humans, and have a high probability of undergoing long-range environmental transport. SCCPs were designated as persistent organic pollutants (POPs) and listed in annex A of the UN Stockholm Convention in 2017. This regulation has resulted in a limit in the use and production of SCCPs. A substantial amount of research has reported the occurrence of CPs in abiotic media such as sediment [5], soils [6], and airs [7], as well as in the biota [8]. Nevertheless, the understanding of the environmental behavior, fate, and potential risks is still scarce because of the extremely complex CP congeners and the difficulties regarding accurate quantification.
Some reviews on CPs have been produced in the last ten years, and most of them focused on analysis method, environmental distribution, and toxicity [9,10,11,12]. The data on CPs in organisms have increased over the last decade, and studies on the trophic transfer of CPs in both aquatic and terrestrial food webs has increased substantially in recent years [13,14]. The concerns regarding the biotransformation of CPs have also been continuously increasing. Thus, the aim of the present study is to compile our present knowledge on the bioaccumulation and biotransformation of CPs in biota and identify knowledge gaps, i.e., to some further research needs. The review is based on data retrieved from studies primarily on chlorinated paraffins in biology (published between 1982 and 2022). We searched the databases Web of Science and CNKI as well as websites from national and international organizations such as the U.S. EPA, the World Health Organization (WHO), and the EU. The search strategy was based on the following keywords: chlorinated paraffin, occurrence, tissue distribution, bioaccumulation, biotransformation, and metabolism. We consulted 627 references in total, and based on the objectives of this review, 115 were selected and classified into 5 major categories: (i) Occurrence of CPs in organisms, including aquatic biota, terrestrial biota, humans and human foodstuffs samples (68 references); (ii) Tissue distribution of CPs in organisms (9 references); (iii) Bioaccumulation of CPs in organisms (25 references); (iv) Biotransformation of CPs in organisms, including plants, invertebrates, and vertebrates (22 references).

2. Occurrence of CPs in Organisms

Data on CPs in biota were mostly obtained from China from 2010 onwards (Table 1). This is plausible considering that China has been the largest global producer and consumer of CPs since 2007, producing up to 1,000,000 metric tons in 2009 [15], and CP contamination has become a major environmental concern in China. A precise comparison of CP concentrations among different regions or countries is difficult since the samples were collected in different periods and the species differed between different studies. Additionally, the concentrations were expressed using different units (ng/g dw, ng/d ww, ng/d lw, etc.). Generally, CP concentrations in aquatic organisms from China were several orders of magnitude higher than those from other regions or countries (Table 1). Relatively high CP concentrations were found in aquatic organisms collected from e-waste recycling sites such as those in Qingyuan and Taizhou, China [13,16,17]. SCCPs have also been reported at relatively high concentrations in mollusks from the Liaohe estuary [18] and fish from Liaodong Bay [19] (Table 1).
Data on CPs in terrestrial biota are all from China. Similar to aquatic organisms, high SCCP concentrations were also detected in terrestrial biota collected from e-waste recycling areas [16]. Surprisingly, CP concentrations in plants and animals collected from Tibet, China, were also comparable with those in the e-waste recycling area [14,51,52], indicating high CP pollution in this area, although the intensity of anthropogenic activities in this area was thought to be lower.
SCCPs and MCCPs have been detected in human tissues including fingernails, hair, blood, cord serum, the placenta, and breast milk from different countries [55,56,57,58,59,60,61,62,63,64,65,79,80]. Human foodstuffs, including aquatic food, meat, baby food, noodles, green tea, cereals and beans, milk, rice seeds, and oil food, from China and Europe were also found to contain SCCPs and MCCPs [46,66,67,68,69,70,71,72,73,74,75,76,77,78]. Concentrations of SCCPs in the foodstuffs were generally higher than concentrations of MCCPs, with the exception of oil-based vitamin E dietary supplements collected in Germany [78]. However, the concentrations of MCCPs were similar to or more than the concentrations of SCCPs in most of the human tissues samples, indicating a higher bioaccumulation of MCCPs than SCCPs in humans.
Earlier studies focused more on SCCPs in aquatic species; however, research on vSCCP, MCCPs, and LCCPs in terrestrial species or humans has increased in recent years [2,22,44]. LCCPs were first detected in human blood samples in China with median concentrations of 150 ng/g lw, which were lower than those of SCCP (3500 ng/g dw) and MCCPs (740 ng/g dw) [61]. Since then, LCCPs were detected in marine organisms from the Baltic Sea (nd: 130 ng/g dw) [34], Greenland and Iceland (<0.41–930 ng/g dw) [1], aquatic and terrestrial organisms from Germany (nd: 2400 ng/g dw) [44], plants from Beijing, China (27–561 ng/d dw) [54], and cereal and legume samples from China (48.1–664 ng/g dw) [59]. Compared with SCCPs and MCCPs, the concentrations of LCCPs in the abovementioned samples were on the same order of magnitude as those of SCCPs and MCCPs. vSCCPS were initially quantified in aquatic biota samples from the Yangtze River Delta in China with high levels (2.6–8400 ng/g lw) [2] compared to those of vSCCPs in bivalves and marine mammals from Greenland and Iceland (<0.12–34 ng/g lw) [42] and those in biota from Germany (nd: 65 ng/g lw) [44]. vSCCPs were also detected in fish and mosses from Liaodong Bay and the Antarctic at relatively low levels (3.4–153 ng/g dw) [22].

3. Tissue Distribution of CPs in Organisms

Several in vivo exposure experiments investigated the tissue distribution of CPs in organisms [81,82,83]. Lipid content was the main factor in determining the physical burden of CPs in organ tissue. The high concentrations of SCCPs (based on wet weight) were in the abdominal fat and the feces, and the low concentrations were in the blood, meat, and bile fluid when broiler chickens were exposed to SCCP (60% Cl) via diet. An exposure experiment using laying hens obtained similar results [82]. The amount of SCCP deposited in the leg meat was higher than that in breast meat due to the higher fat content of leg meat compared to breast meat in both broiler and laying chickens. An experiment using rat exposure to SCCPs, MCCPs, and LCCPs revealed that approximately 57.0–76.5% of CPs were deposited in the liver, 23.1–42.4% of CPs in the fat, while approximately 0.3–1.4%, 0.01–0.04%, and 0.002–0.022% CPs were in the blood, kidneys, and lungs, respectively [83]. The same dependence on the lipid content was also observed in field fish samples. Sun et al. (2017) [13]. found concentrations of SCCPs (based on wet weight) in snakehead and mud carp in the order liver > gill > kidney > skin > muscle, and the SCCP concentrations in the tissue were positively correlated with the content of lipids in tissues (p < 0.001). However, when the concentration was expressed based on lipid, the muscle SCCP concentrations were the highest among all tissues in the laying chicken [84]. Sun et al. (2020) found similar results in chicken collected from an e-waste recycling site [49]. The concentrations of SCCPs were in the order muscle (6200 ng/g lw) > fat (2400 ng/g lw) > liver (1100 ng/g lw). This tissue distribution was due to the low lipid content in muscle and metabolism of SCCPs in the liver.
The deposition of CPs in tissue was also related to carbon chain and degree of chlorination. Mézière et al. (2021) [84] conducted an experiment using laying hens exposed to different degrees of chlorination (low %Cl and high %Cl) SCCPs, MCCPs, and LCCPs to investigate the accumulation and distribution of CPs in biota after ingestion. All C10–C36 CPs were detected in the liver. However, differences were observed in CP distribution: LCCPs with high %Cl were retained in the liver, while LCCPs with low %Cl circulated through the serum and were distributed in the different compartments but were mostly excreted through the eggs; SCCPs and MCCPs were found in all tissues at similar levels. SCCPs with low %Cl were detected at lower levels compared to SCCPs with high %Cl and MCCP, implying a higher biodegradation potential for SCCPs with low %Cl compared to CPs with higher %Cl. Du et al. (2020) [85] analyzed the vSCCPs, SCCPs, MCCPs, and LCCPs in different tissues of terrestrial short-tailed mamushi (Gloydius brevicaudus) and the semiaquatic red-backed rat snake (Elaphe rufodorsata) from the Yangtze River Delta of China. The tissue distribution of total CPs content (ww) in the two snakes was in the order fat (44–1300 ng/g ww) > muscle (39–550 ng/g ww) > liver (41–490 ng/g ww). vSCCPs (C6–9) and SCCPs (C10–13) were preferentially distributed in the snake liver, while fat was an important storage compartment for MCCPs (C14–17) and LCCPs (C > 18).
The tissue distribution of CPs also exhibited the specific homologues for specific tissues. In the studies of CPs in chicken, Sun et al. (2020) [49] observed that the concentration ratio of muscle to liver of CPs decreased with increased log KOW, while the concentration ratio of fat to liver increased with increasing log KOW. This result indicated that the fat prefers to accumulate high log KOW homologues compared to the liver and muscle. Muscles that preferred to deposit SCCP with lower log KOW compared to liver were also found in fish samples [13]. The difference in the lipid component was responsible for this tissue distribution. The proportions of neutral lipids (triglycerides) to total lipids in the abdominal adipose tissue, liver, and muscle of chickens were 98%, 52%, and 32%, respectively, while the proportions of polar lipids (phospholipids) to lipids were 1.7%, 46%, and 65%, respectively [63,86]. It is likely that SCCPs with higher log KOW have a stronger affinity with neutral lipids than polar lipids.

4. Bioaccumulation of CPs in Organisms

Bioaccumulation is the process of accumulation of chemicals in an organism from the environment through diet, skin absorption, or respiration that occurs when the chemical concentration in the organism exceeds that of the surrounding environment or diet after reaching equilibrium [87]. The bioaccumulation potential of chemicals for evaluation comprises the bioaccumulation factor (BAF), bioconcentration factor (BCF), biomagnification factor (BMF), and trophic magnification factor (TMF). Generally, the chemical is considered to be bioaccumulative when BAF/BCF > 5000, BMF/TMF > 1 [88].
Numerous laboratory and field studies showed that CPs had bioaccumulation potential. The values for the logBAF of ∑SCCPs and ∑MCCPs were estimated as 2.70–4.45 and 2.25–3.64, respectively, for aquatic insects from Qingyuan at an e-waste recycling site [20], 1.48 for soil–vegetation of ∑SCCPs from the Arctic [35], 4.5–6.05 for fish of ∑SCCPs from Liaodong Bay [19,23], and 2.04–3.79 for marine organisms of ∑SCCPs from the East China Sea [27]. Following the administration of 14C-labeled CPs in bivalve blue mussels (Mytilus edulis), the values for the BAF of MCCPs (C16, 34% Cl) and SCCPs (C12, 69% Cl) were estimated at 7000 and 13,900, respectively, indicating that SCCPs with short carbon chains and high chlorination had strong bioaccumulation [89]. The log BCF values of five different CPs (Cereclor S45:MCCP 45% Cl; Cereclor 50LV: SCCP 50% Cl; Huels 70C:SCCP 70% Cl; CP-42: 42% Cl, C10–C17, C21–C31; CP-52: 52% Cl; C9–C29) in Daphnia magna were assessed as 6.7–7.0 (Lkg lipid−1). All the CPs tested were bioaccumulative in D. magna [90].
The BMF of ∑SCCPs for oyster–mangrove crab (2.4) from the Pearl River Estuary [25], Ngas–Agas (1.9) from Antarctica [35], and prey species–finless porpoises (3.1–6.7) and prey species–Indo-Pacific humpback dolphins (11–38) from Hong Kong [21] were all >1, indicating the biomagnification of SCCPs in these marine food chains. In juvenile rainbow trout that were exposed to CPs (C10H15.3Cl6.7, C14H23.3Cl6.7 and C18H31.4Cl6.6), the BMFs for ∑SCCPs ranged from 0.9 to 2.8, demonstrating that these CPs had the potential to biomagnify [91]. In an e-waste recycling pond in South China, the BMF values for ∑SCCPs and ∑MCCPs for fish–water snakes were 2.9 and 2.95, respectively, indicating biomagnification [17]. The mean BMFs of vSCCPs, SCCPs, MCCPs, and LCCPs in the food chain (black-spotted frog–red-backed rat snake) were 2.2, 1.9, 1.8, and 1.7, respectively, indicating the potential for biological magnification. This was the first study to address the biomagnification potential of vSCCPs and LCCPs [85]. On the other hand, biodilution was also reported in both marine and freshwater food chains. For examples, the BMFs of SCCPs and MCCPs for fish–bird in an e-waste recycling pond were 0.08 and 0.1, respectively [17]. The BMFs of ∑SCCP were 0.46 for gammarid–cod from Ny-Ålesund in the Arctic [36], and were 0.282 and 0.212, respectively, for plant–plateau pika, as well pika–eagle from the Tibetan plateau [14].
The varied trophodynamic behavior of CPs was also reported in previous studies. Trophic magnifications of SCCPs were observed in an aquatic food web from Dianshan Lake in Shanghai (TMF: 1.19–1.57) [30], marine food web from the East China Sea (TMF: 3.98) [27], and zooplankton–shrimp–fish food web (TMF: 2.38) [19] and fish food web (2.57) [23] from the Liaodong Bay Sea. The TMF of SCCPs and MCCPs in a marine food web from Hong Kong (TMF: 4.29 and 4.79, respectively) [21] and in a terrestrial food web dominated by insects from an e-waste recycling site in southern China (TMF: 2.08 and 2.45, respectively) indicated trophic magnification [13]. The TMF of SCCPs and MCCPs in the invertebrates–forage fish–lake trout food webs from Lake Michigan and Lake Ontario were 0.97 ± 0.33 and 1.2 ± 0.51, respectively, which is in the margin of trophic magnification and trophic dilution [92]. The lake trout had lower SCCP concentrations than several of their prey on a lipid basis, which did not support the biomagnification of CPs. Meanwhile, the trophic dilution of CPs in food webs was also reported. The TMF of SCCPs in an aquatic food web from an e-waste recycling site was 0.17 [13]; the TMF values of SCCPs and MCCPs in a freshwater food web from France were <1 [93]; the TMF of SCCPs in mollusks from Bohai was 0.396; and the TMF of SCCPs in plant–pike–eagle food chain from the Tibetan plateau was 0.392 [14].
The biomagnification and biodilution of CPs in both aquatic and terrestrial food webs were reported in different regions and in different food webs. The structure of food webs; size of organisms collected; food habits; biotransformation of SCCPs in organisms; treatment method for any outliers; and even environmental parameters such as water temperature, dissolved organic matter, and suspended particles may have all contributed to the differences obtained [19,94,95].
Both the chlorine content and the carbon chain length determine the physicochemical properties of CPs [96]. Therefore, both may affect the bioaccumulation capacity of CPs. In a laboratory exposure experiment, pumpkin seedlings were exposed to four kinds of SCCPs: 1,2,5,6,9,10-C10H16Cl6 (HexCD), 1,1,1,3,8,10,10,10-C10H14Cl8 (OctaCD), 1,1,1,3,10,11-C11H18Cl6 (HexCU), and 1,1,1,3,12,13- C13H22Cl6 (HexCT). The cumulative amounts of OctaCD, HexCT, HexCU, and HexCD in pumpkin were 59.9%, 40.5%, 33.4%, and 23.6% of the parent SCCP, respectively, showing that bioaccumulation increased with the carbon chain length and chlorination degree in plants [97]. The soil–vegetation BAFs of SCCP in the Arctic support this finding. BAFs increased with increasing content carbon and chlorine, and the number of carbon atoms was the primary factor regarding the bioaccumulation of SCCPs [36]. Fisk et al. [91] observed that the BMFs of CP congeners (C10Cl6.7, C14Cl6.6, and C18Cl6.7) in juvenile rainbow trout increase with increasing carbon chain length in a given chlorination content. The BMF of SCCP congeners in a food chain (tapertail anchovy–Bombay duck) collected in the Pearl River Estuary showed significant positive correlations with both number of carbon and chlorine atoms of SCCP congeners [26]. All these results indicate that both the length of carbon chain and the chlorine content affect biomagnification of CPs in organisms.
However, some field monitoring provided inconsistent results. The BMFs of SCCP congeners in the food chain Agas–Ngas from Antarctica decreased from 2.3 for C10 to 0.8 for C13 [35]. Houde et al. (2008) [92] also observed that BMFs in a food web from Lake Michigan decreased with the increasing carbon chain length of SCCP congeners. In aquatic organisms collected from a large sewage treatment plant in Beijing, the BMF of SCCP homologues exhibited significant correlation with chlorine content while no significant correlation was found between the BMF and carbon chain length [94]. The correlation between bioaccumulative potential and chlorine content but not between carbon chain length were also found in other food chains/webs, such as bivalves–sediments from Bohai Sea [24], and fish–water snake, fish–waterbird food [17], and insect-dominated terrestrial food webs in an e-waste site in South China [50]. These results imply that chlorination degree rather than carbon length affects the bioaccumulative potential of CP congeners.
The low bioaccumulative potential with low chlorine content of these CPs may be due to the metabolization of low-chlorine-content CPs, which were more easily compared to CPs with higher chlorine content. The carbon chain length has positive and negative effects on the bioaccumulation of CPs. On the one hand, the lipophilicity of CP congeners increases with the increasing carbon chain length, which is beneficial to bioaccumulation. On the other hand, the molecular sizes of CP congeners increase with the increasing carbon chain length, which reduces the bioaccumulative potential of CP congeners. This could explain the inconsistent results of the observed effects of carbon chain on the bioaccumulation of CP congeners.

5. Biotransformation of CPs in Organisms

The biodilution and trophic dilution of CPs in food chains/webs were reported in both aquatic and terrestrial ecosystems. These abnormal trophic transfer behaviors were highly suspected to be related to the biotransformation of CPs in high-trophic-level organisms. The biotransformation of CPs was investigated in the early 1980s [98]. More studies on biotransformation of CPs have been conducted recently since SCCPs were listed as emerging POPs.

5.1. Biotransformation of CPs in Plants

Li et al. [99] conducted a series studies on biotransformation of CPs in plants. 1,2,5,5,6,9,10-C10H15Cl7 was found to produce dechlorination products (C10H17Cl5 and C10H16Cl6 (14.7%) and chlorine rearrangement products (C10H15Cl7) in pumpkin plant (Figure 1). Further research on biotransformation of CPs (1,2,5,6,9,10-C10H16Cl6, HexCD; 1,1,1,3,8,10,10,10-C10H14Cl8, OctaCD; 1,1,1,3,10,11-C11H18Cl6, HexCU; 1,1,1,3,12,13-C13H22Cl6, HexCT) in pumpkin and soybean seedling indicated that dechlorination, chlorine rearrangement, and carbon chain decomposition products were detected (Figure 1). The biotransformation rate of SCCPs was higher in soybean than in pumpkin seedlings, which may be due to the higher fat content of soybean seedlings than pumpkin seedlings [97]. To verify that airborne chlorodecanes were converted by reactive phytogenic volatile organic compounds (PVOCs), the PVOCs of pumpkin collected in sealed glass bottle reacted with 1,1,1,3,8,10,10-C10H14Cl8 in a concentration of 96.4 ng/µL under illumination for 10 days, while the reaction control group did not contain PVOCs. Dechlorination, chlorine rearrangement, and carbon chain decomposition products were detected with or without PVOCs: C10Cl5–8, C9Cl6–8, and C8Cl7–8. The PVOCs of pumpkin seedlings promoted these transformations to a certain extent. In the absence of PVOCs, CPs may react with OH radicals in the atmosphere [100]
Chen et al. (2020) [101] investigated the biotransformation of CPs (1,2,5,6,9,10-C10H16Cl6 and 52% MCCPs) using suspension rice cell culture exposure systems. In total, 79.53% of 1,2,5,6,9,10-C10H16Cl6 and 40.70% of 52%-MCCP were metabolized by suspension rice cells, respectively. Forty and 25 metabolic products for 1,2,5,6,9,10-C10H16Cl6 and 52%-MCCP, respectively, were identified, including (multi-) hydroxylation, dechlorination, –HCl– elimination metabolites, (hydroxylation-) sulfation, and glycosylation conjugates. A comprehensive metabolic molecular network and potential degradation pathway were proposed. The results of the abovementioned study improved our understanding of the transformation behaviors of CPs in plant.

5.2. Biotransformation of CPs in Invertebrates

Degradation of CPs by microorganisms was firstly reported in the 1980s. Omori and Kodama (1987) [102] isolated four bacterial strains (HK-3, HK-6, HK-8, and HK-10) from soil. In the presence of n-hexadecane, cometabolic dechlorination of chlorinated paraffins was observed. The cometabolic dechlorination of CP-150 (C15.4H25.4Cl5.6, 50% Cl) by the mixture of these four bacteria reached 51% in 36 h.
Allpress and Gowland (1999) [103] isolated a bacterium, a species of Rhodococcus, later designated isolate S45-1, from a stream in Sheffield, UK. Isolate S45-1 was able to utilize chlorinated paraffins with chain lengths of between 10 and >20 as sole source of carbon and energy. The degradation product was identified as γ-butyrolactone (Figure 2). The pathway postulated for the formation of γ-butyrolactone involved initial attack at the nonhalogenated site by oxygenase, followed by chain shortening via β-oxidation, resulting in the formation of 4-chlorobutyric acid. Chemical lactonization of 4-chlorobutyric acid then leads to γ-butyrolactone formation, which is subsequently slowly catabolized to 4-hydroxybutyric acid and succinic acid, which allows entry to the tricarboxylic acid cycle. This is the first report of microbial utilization of chlorinated paraffins as sole source of carbon and energy. However, when the degree of chlorination was 58.5% (Cereclor S58) or greater, the growth of bacterium was inhibited.
In addition to Gram-positive bacteria, SCCPs were also degraded by Gram-negative bacteria, such as Pseudomonas. These bacteria were considered aerobic and abundantly distributed in soil, water, animals, and humans. Pseudomonas sp. strain 273 metabolized CPs with a good dechlorination effect, but similar to the strain screened by Allpress and Gowland (1999) [103], whose bacterial dechlorination cycle needed 20 days or even longer. Pseudomonas 273 strain could easily degrade monochlorinated alkanes whose chlorine atoms were located on primary carbons, and before β-oxidation, the chlorine atoms substituted at the end of SCCPs had to be dehalogenated enzymatically. However, the oxygenolytic dehalogenase enzymes produced by Pseudomonas strain 273 cannot metabolize SCCPs with chlorine atoms substituted in a vicinal arrangement [104].
Lu (2013) [105] isolated a bacterial strain identified as Pseudomonas sp. N35 from soil. This bacterial strain can utilize SCCPs as a sole source of carbon and energy. A total of 57.5% of chloride was released into the medium as chloride ions in pure culture within 20 days. Bioaugmentation resulted in 73.4% removal of SCCPs in the sludge microcosm after 30 days of treatment.
Heeb et al. (2019) [106] isolated several Sphingomonadacea strains which can convert hexachlorocyclohexanes (HCHs) from HCH dump site. The dehydrohalogenase expressed by such bacteria (also called as LinA2) can catalyze the HCl elimination reaction, which converts CPs to chlorinated olefins. However, not all SCCP congeners can be transformed by the bacterial enzyme LinA2. About 20–40% of the exposed CP material was reactive and readily converted by LinA2 within 24 h, while about 60–80% of the given CP material was not, or only slowly, converted by LinA2. In a subsequent study, Heeb and his colleagues [107,108] reported that under the catalysis of LinB enzyme, dehalohydroxylation reactions of CPs resulted in mono- and dihydroxylated products, and in mono- and diolefinic compounds that resulted in corresponding hydroxylated products. However, the LinB enzyme cannot catalyze HCl elimination to form alkenes. Conversion decreased with increasing degree of chlorination, while the effect of carbon chain length was less pronounced.

5.3. Biotransformation of CPs in Vertebrates

In the 1980s, studies of CPs metabolism were mostly performed with radioactive 14C-labeled CPs. Darnerud et al. (1982) [98] conducted a series of in vivo experiment to investigate the metabolism of CPs in animals. C57B1 mice were exposure to 14C-labeled chloroalkanes (i.e., C12H16.2Cl9.8, 68.5% chlorination; C20H20.1Cl5.9, 55.9% chlorination; and C12H25Cl1, 17.4% chlorination) via intravenous injection. After 12 h, 8%, 32%, and 52% of SCCP was exhaled through the respiratory system in the form of 14CO2, indicating that SCCPs were metabolized into metabolites in mice and CO2 was the final product. The exhaled amount of 14CO2 decreased with the increase of the degree of chlorination, implying that low-chlorination CP congener was readily to be metabolized. In the latter study, mice were transferred to an all-glass metabolism cage to monitor the exhaled air 14CO2 after the same administration above. After adding the cytochrome P-450 inhibitor piperonyl butoxide, the degradation rate decreased by 84%, which was positively correlated with the degree of chlorination, indicating that SCCPs with a high degree of chlorination were more dependent on cytochrome P-450 for degradation [109]. In carp, after intra-arterial (i.a.) injection of 14C-labeled chloroalkane (C16, 34% Cl), about 6% of dose was excreted as 14CO2 in 96 h. The metabolic rate in carp was lower than that of mice and quails (40% metabolized within 8 h) [110].
After gavage of 14C-labeled chloroalkane (C16H30.7Cl3.3, 34.1% Cl and C12H20.1Cl5.9, 55.9% Cl) to Japanese quail, radioactivity was highest in tissues with high metabolic activity and high cell turnover rate, and in bile and urine. About 40% and 20% of dose was excreted as 14CO2 in 8 h, respectively [111]. After oral and intravenous injection of 14C-labeled chloroalkane (C16H20.6Cl13.4, 69% Cl) to quail and C57B1 mice, about only 1% of dose was excreted as 14CO2 in 8 h. Obviously, the formation of 14CO2 was negatively correlated with the degree of chlorination of CPs [112].
Åhlman et al. (1986) [113] identified potential metabolites of polychlorinated hexadecane (14C-PCHD; 65% chlorine by wt) in rat. A uniformly 14C-labeled reagent was injected into the portal vein in bile-duct-cannulated rats (5–6 mg/kg) and the bile was collected for two or three days. The radioactivity was separated by ion-exchange chromatography into two major fractions: one acidic, the other amphoteric. N-acetylcysteine (mercapturic acid) and glutathione conjugation were found, which were produced by PCHD.
Dong et al. (2020) [83] reported the pharmacokinetic modeling for chlorinated paraffins in rats and humans via in vivo and in vitro exposed SCCP, MCCP, and LCCP to rat and liver microsomes. The metabolic rates of ∑SCCPs, ∑MCCPs, and ∑LCCPs were 1.31 × 10−6, 2.54 × 10−6, and 3.55 × 10−6/h in rat and 1.31 × 10−6, 2.54 × 10−6, and 3.55 × 10−6/h in humans. The metabolic rates of CPs were extremely slow and increased with the increased carbon chain length of CPs.
However, unlike the results of Dong et al. (2020) [83], an in vitro experiment using human liver microsomes conducted by He et al. (2021) [114] indicated that CPs were extensively and rapidly metabolized after incubation with human microsomes. After the incubation with CYP (Cytochrome P450) for two hours, a decrease of 85%, 98%, and 73% for SCCPs, MCCPs, and LCCP, relative to their negative controls, were observed. After Phase I and Phase II transformation, concentrations of different groups of CPs decreased by more than 70%, suggesting a rapid transformation of CPs by HLMs (human liver microsomes). The biotransformation products included vSCCPs, OH-CPs, CO-CPs, and COOH-CPs. Potential transformation pathway of CPs was C–C bone cleavage and ketones were potential products of biotransformation for CPs, especially for long-chain CPs (C > 17).
Lin et al. (2022) [115] reported the metabolism of SCCP in chicken and human via incubation of 1,2,5,5,6,9,10-heptachlorodecane (HeptaCD) to chicken and human liver microsomes. Two metabolites, monohydroxylated hexachlorodecane (HO-HexCD) and monohydroxy heptachlorodecane (HO-HeptaCD), were detected in human liver microsomal assays, while only one metabolite (HO-HexCD) was identified in chicken liver microsomal assays. After 1 h incubation, concentration of HeptaCD in chicken liver microsomes decreased by approximately 13%, but by 50% in human liver microsomes, indicating that the metabolic rate in human liver microsomes were higher than those in the chicken. The result of Lin et al. (2022) [115] confirmed that CP were extensively and rapidly metabolized after incubation with human microsomes. The number of metabolites in Lin et al. was lower than that found in He et al. (2021) [114], which could be due to the difference in experiment condition and the extraction method.
The metabolism of SCCPs 1-chlorodecane by cytochrome P450 enzymes was simulated to use a simplified model of active site of CYPs, a density functional theory. In this theory, 1-chlorodecane can be easily metabolized by CYPs in either low-spin or high-spin state, but hydroxylation was more major than dichlorination due to the energy barrier. The main metabolic products were 10-chloro-1-decanol, 10-chloro-decan-5-ol, and 1-chorodecanol with a rate constant of 42.3−1/h by CYPs in the human body [116].

6. Conclusions and Perspectives

In this article, the current studies on bioaccumulation and biotransformation of CPs in biota and humans were briefly reviewed. CPs including vSCCPs, SCCPs, MCCPs, and LCCPs are widely distributed in various biota, including humans, worldwide. The bioaccumulation and biotransformation of CPs are directly related to carbon chain and chlorination degree. However, our knowledge on the effects of chain length, chlorination degree, constitution, and stereochemistry on the bioaccumulation and biotransformation are still scarce. There are several issues relating to CPs, which should be considered research priorities:
There is an urgent need for relevant data on MCCPs and LCCPs. SCCPs have been regulated as POPs since 2017, while MCCPs and LCCPs remain unclassified (UNEP, 2017) [117]. Recent studies indicated that MCCPs, LCCPs, and vSCCPs were ubiquitous in the environment and they were also detected in biota samples. The concentrations of MCCPs and LCCPs were comparable or on the same order of magnitude with those of SCCPs. Some studies also reported the biomagnification or trophic magnification of MCCPs and LCCPs in aquatic and terrestrial food chains/webs. Considering the substantial amount of MCCPs and LCCPs produced compared to SCCPs, more concerns should be paid to MCCPs and LCCPs in further studies.
Future work is needed to study the bioaccumulation and influencing factors (such as the tissue distribution, degradation, and transformation) of CPs in aquatic and terrestrial food webs. Similar to other lipophilicity POPs, the lipid content of tissue plays a key role in the bioaccumulation and tissue distribution of CPs. However, the effects of the carbon chain length and chlorination degree on the bioaccumulation and tissue distribution are unclear. Inconsistent results on the biomagnification and trophic magnification of CPs were obtained according to available data. There is sufficient evidence to support the biotransformation of CPs by microorganisms, plants, and animals. However, knowledge gaps still exist. The knowledge on species-specific bioaccumulation and biotransformation is still scarce. Investigations on the biotransformation of CPs are still in the early stages. No field monitoring studies have been conducted to detect the metabolites of CPs. How and to what extent the species-specific biotransformations affect the bioaccumulation and trophic transfer of CPs are unknown.
Further investigation on the mechanisms of the toxicity of CPs are required. The bioaccumulative potential, toxicity, and biotransformation pathway vary for different CP congeners. Not all CPs are equally persistent towards biotransformation, and not all CP isomers are bioaccumulating and equally toxic. The effects of chain length, chlorination degree, constitution, and stereochemistry on the bioaccumulation, biotransformation, and the toxicity are unclear. Therefore, one can question whether a cut based on carbon chain length is a sufficient criterion for regulation or whether other criteria are needed to assess and classify medium- and long-chain CPs as well.
As CP metabolites are identified, the toxicity of CP metabolites needs to be evaluated and studied. Potential CP metabolite candidates, which may resemble chlorine-containing aliphatic molecule species, had adverse biological effects in earlier studies. Molecular biological methods can be used to conduct in-depth toxicological studies on CP metabolites at the molecular, gene, and cell levels.
It is necessary to explore the molecular mechanism of microbial degradation and possible phytoremediation of CPs among different biological species to determine the key process of the biological metabolism to reduce the occurrence of CPs in the environment.

Author Contributions

Conceptualization: X.L.; data analysis: X.L. and L.C.; writing—original draft preparation: L.C.; writing—review and editing: X.L., L.C. and B.M.; supervision, funding acquisition, and project administration: X.L. and B.M. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the National Nature Science Foundation of China grant number [42277267,41877386] and Guangdong Foundation for the Program of Science and Technology Research (Nos. 2020B1212060053 and 2019B121205006). This is contribution No. IS-3282 and SKLOGA202004 from GIGCAS.

Institutional Review Board Statement

No applicable.

Informed Consent Statement

No applicable.

Data Availability Statement

No applicable.

Conflicts of Interest

The authors declare no conflict of interest.

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Toxics 10 00778 g001 550
Figure 1. The transformation pathways of 1,2,5,5,6,9,10-C10H15Cl7, 1,1,1,3,6,12,13-C13H22Cl6, and 1,1,1,3,8,10,10,10-C10H14Cl8 mediated by pumpkin seedling, rice cell, soybean, and PVOCs, respectively. Values in the brackets are the transformation ratios of parent compound to the daughter compounds. The dotted arrow with the question mark is the pathway which possibly occurs but is not able to be detected by GC/ECNI-LRMS.
Figure 1. The transformation pathways of 1,2,5,5,6,9,10-C10H15Cl7, 1,1,1,3,6,12,13-C13H22Cl6, and 1,1,1,3,8,10,10,10-C10H14Cl8 mediated by pumpkin seedling, rice cell, soybean, and PVOCs, respectively. Values in the brackets are the transformation ratios of parent compound to the daughter compounds. The dotted arrow with the question mark is the pathway which possibly occurs but is not able to be detected by GC/ECNI-LRMS.
Toxics 10 00778 g001
Toxics 10 00778 g002 550
Figure 2. The transformation pathways of 1-chlorotetradecane, SCCPs (C6–16, Cl: 14–61% w/w), SCCPs (C10–13, Cl: 56% w/w), and octachlorotridecanes mediated by Rhodococcus sp. S45-1, Pseudomonas sp. Strain 273 and N35, and bacterial enzyme LinB of Sphingobium indicum, respectively. E2 are the reactions of abiotic and biotic elimination, which are not catalyzed by LinB.
Figure 2. The transformation pathways of 1-chlorotetradecane, SCCPs (C6–16, Cl: 14–61% w/w), SCCPs (C10–13, Cl: 56% w/w), and octachlorotridecanes mediated by Rhodococcus sp. S45-1, Pseudomonas sp. Strain 273 and N35, and bacterial enzyme LinB of Sphingobium indicum, respectively. E2 are the reactions of abiotic and biotic elimination, which are not catalyzed by LinB.
Toxics 10 00778 g002
Table
Table 1. Levels of CPs in the aquatic biota, terrestrial biota, humans, and human foodstuffs samples.
Table 1. Levels of CPs in the aquatic biota, terrestrial biota, humans, and human foodstuffs samples.
SiteOrganismsSCCPs MCCPs Reference
Mean/MedianRangeMean/MedianRange
Aquatic biota
Qingyuan, ChinaFish and invertebrates 1700–95,000 a [13]
Qingyuan, ChinaFish, snake, bird eggs 1200–250,000 a 2300–200,000 a[17]
Qingyuan, ChinaInsects 52–410 c 40–740 c[20]
Guiyu, ChinaCatfish30,800 a11,400–70,400 a [16]
Hong Kong, ChinaFishes801 ± 253 a280–1940 a1820 ± 934 a502–4770 a[21]
Crustaceans422 ± 162 a202–694 a593 ± 306 a205–1190 a
Mollusks328 ± 79 a259–506 a603 ± 132 a464–874 a
Liao Estuary, ChinaMollusks66,500 a28,100–120,400 a [18]
Liaodong Bay, ChinaFish968 b53.3–2907 b [22]
Liaodong Bay, ChinaInvertebrates and fish20,100 a2300–76,500 a [19]
Liaodong Bay, ChinaFish 376.3–8596 a 22.37–5097 a[23]
Bohai Sea, ChinaBivalves1710.5 b476.4–3269.5 b [24]
Pearl River Estuary, ChinaMarine organism 870–36,000 a [25]
Pearl River Estuary, ChinaMarine organism 210–21,000 a [26]
East China SeaMarine organism 155 ± 215 c12.8–1819 c [27]
South China SeaFinless porpoises2800 a570–5800 a5100 a670–11,000 a[28]
Humpback dolphins5500 a920–24,000 a13,000 a1400–56,000 a
Bohai Sea, ChinaMollusk1410 b64.9–5510 b [8]
ChinaFarmed crabs543 a82–1760 a nd–680 a[29]
Dianshan Lake, ChinaWild aquatic organisms 10,000–1,300,000 a [30]
Taiwan, ChinaFreshwater Fish nd–2,320,000 a [31]
Hainan, ChinaCoral/800 a184–7410 a/1490 a305–14,800 a[32]
ChinaFish of the Pearl Real Delta16,000 ± 12,000 a3000–41,000 a [33]
Farmed freshwater fish5900 ± 8100 a220–51,000 a
Fish of the Yangtze River Delta3000 ± 1600 a900–7300 a
Baltic SeaMarine organisms nd–220 a nd–390 a[34]
AntarcticFish and mosses262 b69.0–504 b [22]
AntarcticFish 1500 ± 500 a [35]
Ny-Ålesund and London Island, Svalbard, ArcticAlgae, gammarids, and cod178.9 b [36]
Persian Gulf, IranianLarak coral tissue112 b28.5–200 b65.9 b15.5–136 b[37]
FranceFish/728 a63–1492 a/4430 a99–11,300 a[38]
AntarcticHumpback whales nd–46 a [39]
Northern EuropeFish and seabird 28–880 a 14–3700 a[40]
North Baltic SeaLiver of fish 19–286 c 25–260 c[41]
Greenland and Iceland and SwedenBivalves marine mammals <5.2–570 a <8.6–270 a[42]
NorwayHerring gull blood and eggs 5–200 c 3–630 c[43]
GermanAquatic and terrestrial organisms nd–350 a nd–1800 a[44]
Greenland, DenmarkBird and marine mammals 220–2200 c [10]
South KoreaBlack-tailed gull eggs 1180–2931 a 694–2023 a[45]
Terrestrial biota
Taizhou, ChinaApple snail314 b137–821 b [46]
Guiyu, ChinaChicken eggs 2300–6800 a [47]
Goose eggs nd–150,000 a
Guiyu, ChinaPigeon7600 a4700–11,000 a [16]
Qingyuan, ChinaBird species 620–17,000 a [48]
Qingyuan, ChinaChicken 460–13,000 a [49]
Qingyuan, ChinaInsect 2200–9000 a 990–11,000 a[50]
Birds 6100–48,000 a 2000–33,000 a
Frogs and toads 8100–24,000 a 4600–17,000 a
Tibetan, Chinatree bark 2900–7000 a 1800–5700 a[51]
needle 2400–6400 a 1600–5000 a
lichen 1400–6100 a 700–4000 a
moss samples 1500–5300 a 900–4000 a
Tibetan, ChinaPlants4300 ± 2830 a [14]
Plateau pika1870 ± 1090 a
Eagle723 ± 536 a
Tibetan, ChinaChicken and goose eggs 3098–6999 a [52]
ChinaMature maize plant381 b119–61,999 b551 b77.6–52,930 b[53]
Beijing, ChinaPlants127 ± 116 b13–593 b289 ± 148 b21–785 b[54]
GermanFauna sample (mussels, fish, birds, earthworms, and roe deer)
Flora sample (tree shoots and leaves)		 nd–350 a nd–1800 a[44]
Greenland, DenmarkBlack guillemot eggs
Glaucous gull liver
Ringed seal blubber
Polar bear adipose tissue		 220–2200 c [10]
South KoreaBlack-tailed gull (Larus crassirostris) eggs 1180–2931 a 694–2023 a[45]
Humans and human foodstuffs
Beijing, ChinaMaternal serum 21.7–373 c 3.76–31.8 c[55]
Cord serum 8.51–107 c 1.33–12.9 c
ChinaBreast milk in urban and rural areas/393 a
/525 a		131–808 a
139–1543 a		/472 a
/576 a		94–1714 a
211–1089 a		[56]
Henan, ChinaHuman placentas593 a98.5–3771 a316 a80.8–954 a[57]
ChinaHair/239 b19.2–877 b/325 b16.9–893 b[58]
Nails/154 b57.7–355 b/233 b61.0–476 b
ChinaCereal samples343 c 51.6–981 c213 c[59]
Legume samples328 c 47.1–801 c184 c
Jinan, ChinaHuman serum/13,800 a1670–42,700 a/15,200 a1350–38,900 a[60]
ChinaHuman blood/3500 a370–35,000 a/740 a130–3200 a[61]
ChinaMaternal serum,/117,100 d /38,900 d [62]
Cord serum,/70,000 d /25,600 d
Placenta/30.3 c /19.0 c
Breast milk/82,600 d /26,100 d
ChinaHuman milk/303 a /35.7 a [63]
China,
Korea,
Japan		Breast milk nd–54 a
nd–20 a
nd–20 a		 [64]
South ChinaMaternal 3280–10,400 d 1300–5500 d[65]
cord blood 890–4130 d 890–1690 d
placenta 3.18–9.12 c 1.91–4.89 c
Taizhou, ChinaPaddy seeds17.6 b4.9–55.1 b [46]
Jinan, ChinaFood samples69.3 ± 74.4 c8.27–268 c [66]
ChinaAquatic food samples1472 c215–4200 c80.5 c9.0–586 c[67]
ChinaCooking oil <9–7500 c [68]
ChinaCooking oil nd–16,055 c nd–11,612 c[69]
ChinaMeat 129 ± 4.1 c15.7–469 c5.7 ± 0.59 c0.3–23.8 c[70]
ChinaInfant formulas,7.95 c2.32–54.2 c 1.67–20.9 c[71]
Cereals4.26 c2.73–8.81 c 1.21–8.24 c
Purees4.66 c1.33–8.43 c 0.53–5.41 c
ChinaFood samples nd–120 c nd–100 c[72]
ChinaGreen tea55.7 b4.99–717 b33.5 b2.55–543 b[73]
ChinaNoodle1200 c59–3000 c140 c12–520 c[74]
Seasoning1400 c160–3300 c160 c8–650 c
Noodle soup560 d160–1500 d540 d19–1500 d
ChinaRaw milk1470 a130–5770 a170 a6.8–800 a[75]
GermanInfant food nd–190 a Nd–32 a[76]
EuropeBaby food nd–3765 a [77]
GermanVitamin E supplements3810 and–61,100 a15,200 and–151,000 a[78]
UKHuman milk /180 a49 to 820 a/21 a6.2 to 320 a[79]
CzechHuman serum/370 a150–2600 a/360 a200–2110 a[80]
a: Unit is ng/g lw, b: ng/g dw, c: ng/g ww, d: ng/L, nd: no detect. /data: indicated median.
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Chen, L.; Mai, B.; Luo, X. Bioaccumulation and Biotransformation of Chlorinated Paraffins. Toxics 2022, 10, 778. https://doi.org/10.3390/toxics10120778

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Chen L, Mai B, Luo X. Bioaccumulation and Biotransformation of Chlorinated Paraffins. Toxics. 2022; 10(12):778. https://doi.org/10.3390/toxics10120778

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Chen, Liujun, Bixian Mai, and Xiaojun Luo. 2022. "Bioaccumulation and Biotransformation of Chlorinated Paraffins" Toxics 10, no. 12: 778. https://doi.org/10.3390/toxics10120778

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Chen, L., Mai, B., & Luo, X. (2022). Bioaccumulation and Biotransformation of Chlorinated Paraffins. Toxics, 10(12), 778. https://doi.org/10.3390/toxics10120778

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