Abstract
Environmental pollutants can result in a variant of acne called 'chloracne'.Chloracne is caused by systemic exposure to certain halogenated aromatic hydrocarbons 'chloracnegens', and is considered to be one of the most sensitive indicators of systemic poisoning by these compounds.Dioxin is the most potent environmental chloracnegen. Most cases of chloracne have resulted from occupational and non-occupational exposures, Non-occupational chloracne mainly resulted from contaminated industrial wastes and contaminated food products. Non-inflammatory comedones and straw-coloured cysts are the primary clinical manifestation of chloracne. Increasing of cysts in number is a signal of aggravation of chloracne. Generalized lesions can appear on the face , neck, trunk, exterimities, genitalia , axillary and other areas. Course of chloracne is chronic. Severity of chloracne is related to dosage of exposed chloracnegens, chloracnegenic potency and individual susceptibility. Histopathology of chloracne is characterized mainly by hyperplasia of epidermal cell, while follicular and sebaceous gland are taken placed by keratinized epidermal cell. The pathogenesis of chloracne maybe related to the imbalance of epidermal stem cell. Chloracne appears to be resistant to all tested forms of treatment. The only way to control chloracne is to prevent exposure to chloracnegens.
Introduction
Althought technological progress has created great benefits for human being, at the same time a lot of industrial by-products and chemical wastes have been produced. Health of human being has been affected by these enviromental pollutants greatly.Citation1 The skin is the largest organ in the human body and one of its main functions is to protect the body from noxious substances. Environmental pollutants are related to skin diseases such as contact dermatitis, chemical depigmentation and also chloracne.Citation2 Acne vulgaris is generally considered to be a disorder of adolescence, but environmental pollutants can result in a variant of acne called chloracne, a typical enviromental skin disease, which is characterized by acnelike eruption of comedones (blackheads and whiteheads), cysts and pustules that occurs following systemic absorption of chemical ‘chloracnegens’.
Etiology of Chloracne
Chloracne results from environmental exposure to certain halogenated aromatic hydrocarbons and is considered to be one of the most sensitive indicators of systemic poisoning by these compounds. Chloracne was first described in 1887 by Von BettmanCitation3 and by Herxheimer in 1889,Citation4 who suggested that it was caused by chlorine exposure and hence called ‘chloracne’ based on the similarity of its clinical features with acne vulgaris. From then on, a number of chloracnegenic chemicals have been identified, such as chlorinated phenols, chloronaphthalenes, polychlorinated biphenyls (PCBs), and other polychlorinated compounds, which include polyhalogenated dibenzofurans, polychlorinated dibenzo-p-dioxins, and chlorinated azo- and azoxybenzenes.Citation5 All chloracnegenic compounds are known to share certain structural features including molecular planarity and two benzene rings with halogen atoms occupying at least three of the lateral ring positions. The position of the halogen substitutions appears to be critical, as it is known that substitutions leading to molecular nonplanarity dramatically diminish chloracnegenic activity.Citation2
Dioxin is a great family of halogenated aromatic hydrocarbons, which consists of tricyclic aromatic compounds, and hydrogen atoms can be substituted by up to eight chlorines, thus permitting about 75 isomers. Dioxins is ragarded to be class 1 carcinogen and endocrine disruptors, and also is the most potent environmental chloracnegen among chloracnegens. 2,3,7,8-Tetrachlorodibenzop-dioxin (TCDD) with four chlorine atoms in lateral positions is the most biologically active isomer, and is also the most toxic substances knownCitation6 (). Chloracne is the most consistent manifestation of dioxin intoxication, and considered to be its reliable “hallmarker.”Citation7
Dioxins or other chloracnegens are absorbed into human body by direct contact, inhalation or ingestion. Generally the average concentration of TCDD in normal people is less than 10 ppt,Citation8 while it is over several hundreds of ppt in patient with chloracne.Citation9 Dioxin is stable and highly lipophilic, and its half-life in the human body is about 7∼11 years.Citation10
Etiology of Chloracne
Most cases of chloracne have resulted from occupational and non-occupational exposures (environmental exposures). Non-occupational chloracne mainly resulted from contaminated industrial wastes, and contaminated food products.
In a study of 109 workers who had been engaged in the production of pentachlorophenol, chloracne among them had been noted since 1974. The prevalence of chloracne was 73.4% (80/109) in total and 95.2% (20/21) in a trichlorobenzene (TCB) tank area where dioxin and dibenzofurans levels were thousands of ppm.Citation11 Another survey in 3,538 workers of a factory exposure to TCDD, 11% were found to have chloracne.Citation12
In addition, a widely publicized example was the accident occurred at a chemical plant near Seveso of Italy in 1976. Two kilograms of TCDD were discharged into the atmosphere during an explosion and and 135 cases of chloracne were diagnosed among polluted 2,000 inhabitants (6.7%), most of them (88%) are children under 14-years-old, while healthy control is 0.1%.Citation9 Another famous accident is the widespread ingestion of tainted rice cooking oil contaminated with PCBs in Yucheng in Taiwan, 17.5% have chloracne and healthy control is 1.3%;Citation13 Examination of the skin in a group of 288 Vietnamese veterans with a remote (17–22 years) history of exposure to the herbicide known as Agent Orange revealed persistent chloracne lesions in 11.5% of these subjects.Citation14
Clinical Features of Chloracne
Usually after exposure to chloracnegens, the first onset of chloracne is erythema or oedema on the face, then develop into non-inflammatory comedones and straw-colored cysts in a few days, occasionally pustules, non-infectious abscesses and scar can be seen.Citation15
The distribution of the lesions of chloracne is characteristic. In the earlier time skin lesions appear on the face and neck, and later extend to trunk, exterimities, genitalia or other areas. Generally comedone appear more often on face and neck, especially the below and to the outer side of the eye (the so-called malar crescent) and in the postauricular triangles. The ear lobes, suboccipital hairline and groin are often involved. The cysts often appear on neck, shoulders, chest-back, penis, scrotum and axillary. The nose, perioral skin and supraorbital regions are usually spared. Increasing of cysts in number is a signal of aggravation of chloracne. Other skin lesions include decreased sebum secretion with skin xerosis, pigmentation, porphyrinopathy, hirsutism, skin thickening, palmoplantar hidrosis and palmoplantar hyperkeratotic. Citation15–Citation17
Since chloracne is not only a skin disease but a systemic intoxical disease, so sometimes accompanied by other systemic symptoms such as fatigue, anorexia, neuropathy, impotence, dysfunction of liver function, hyperlipemia, anaemia, arthritis, thyromegaly and ophthalmitis.Citation1
Chloracne is characterized by chronicity, which is because of that the chloracnegens are highly lipophilic and can remain in body fat for longer period. Normally from exposure to chloracnegens to the onset of clinical symptoms about 2–4 weeks, but after cessation of exposure it needs at least 2–3 yeas to recover, sometimes over 15–30 years.Citation13,Citation18 The severity of chloracne is related to intensity and duration of exposure, relative ‘chloracnegenic potency’ of the specific compound and individual susceptibility.Citation7 Study showed that children (<8-years-old) and people with light hair color maybe more susceptible to the chloracnegens.Citation8
Histopathology of Chloracne
HambrickCitation19 studied the histopathologic features of lesions of chloracne in different stages of evolution in human volunteers, and described that in early lesions of chloracne the epithelial cells of the outer root sheath forming the wall of the proximal portion of the infundibulum and the sebaceous duct appeared increased in number, resulting in dilatation of the proximal infundibulum. The walls of the sebaceous glands were thickened and merged with the infundibular wall. Hyperplasia of the epidermal cells, with incomplete keratinization, was manifested by a thick parakeratotic cell layer surrounding a mass of keratinized epidermal cells, which began the proximal filling of the infundibulum. In later stage lesions, almost all pilosebaceous units were involved. There was a definite diminution in the sebaceous glands, with reduced numbers of cells and reduced size of sebaceous lobules, which otherwise had a normal appearance. Still later stage lesions consisted of small comedones, with almost all vellus hair follicles showing thickening of the outer root sheath, dilated infundibula filled with sebum, and absence of sebaceous lobules. The maximum infundibular dilatation occurred proximally, resulting in either bottle-shaped formations, with the neck near the surface, or columnar funnels along the entire length of the infundibular structure.Citation19–Citation21
Chloracne is easy to be diagnosed by history of exposure to chloracnegens, characteristic clinical manifestations and histopathology, and high serum concentration of chloracnegens. Chloracne has acneiform comedo and cyst, but different from acne vulgaris in etiology, pathogenesis, clinical features, histopathology and treatment ().
Pathogenesis of Chloracne
The exact cellular and molecular pathogenesis of chloracne is still unclear. Since the major effect induced by chloracnegens in different skin structures is alteration of cellularity that results in prominent hyperplastic or hypoplastic responses. This indicates different epithelial structures in the skin respond to chloracnegens differentially: epidermis and infundibulum, which is characterized by epidermal-like type of differentiation undergo prominent hyperplasia, while sebaceous and sweat glands lose their secretory activity and are replaced by keratinizing cells.Citation22
Earlier views ever thought that SGs are replaced by keratinized epithelial cells because SGs undergo squamous metaplasia and keratinization in patients with chloracne.Citation23 Recently Panteleyev and BickersCitation22 produced a hypothesis to explain the pathogenesis of chloracne based on epidermal stem cell theory that chloracnegeninduced transformation of the pilosebaceous unit is driven by activation and accelerated exit of cells from the stem cell compartment coupled with a shift from a pilosebaceous differentiation pattern to an epidermal one. This may result in imbalance in early multipotent cells commitment and their preferential differentiation along an epidermal lineage with consequent diminution of SG and lower HF portion along with prominent epidermal/infundibular hyperplasia and hyperkeratinization. This process maybe controlled by a serious signal pathway of aryl hydrocarbon receptor(AhR), β-catenin, c-Myc, Indian Hedgehog (IHH) expressed in the cells.Citation24,Citation25
Treatment
Although some individual reports showed that retinoids, corticosteroid, dermabrasion and light electrodesiccation maybe useful in the treatment of chloracne, but actually chloracne appears to be resistant to all tested forms of treatment. So the only way to manage chloracne is to prevent exposure to chloracnegens.Citation26 Once exposure happens, affected individuals should be removed from exposure sites and try to eliminate accumulated chloracnegens from the body. Recently a study found that a synthetic dietary fat substitute known as olestra can combine with chloracnegens and accelerate their fecal excretion,Citation27 further study also showed that combined dietary olestra and caloric restriction causes a 30-fold increase in the rate of excretion of labelled compound,Citation28 which maybe a perspective theray method in the future.
Figures and Tables
Figure 1 Chemical structure of 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD).
Table 1 Differential diagnosis of acne vulgaris and chloracneCitation22
References
- Pelclova D, Urban P, Preiss J, et al. Adverse health effects in humans exposed to 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD). Environ Health 2006; 21:15 - 17
- English JS, Dawe RS, Ferguson J. Environmental effects and skin disease. Br Med Bull 2003; 68:129 - 142
- Bornemann W. Ueber die histologie der chloracne. Arch Derm Res 1902; 62:75 - 90
- Herxheimer K. Uber chloracne. Munch Med Wochenschr 1899; 46:278
- Tindall JP. Chloracne and chloracnegens. J Am Acad Dermatol 1985; 13:539 - 558
- Schwetz BA, Norris JM, Sparschu GL, et al. Toxicology of chlorinated dibenzo-pdioxins. Environ Health Perspect 1973; 5:87 - 99
- Suskind RR. Chloracne, “the hallmark of dioxin intoxication”. Scand J Work Environ Health 1985; 11:165 - 171
- Link B, Gabrio T, Zoellner I, et al. Biomonitoring of persistent organochlorine pesticides, PCDD/PCDFs and dioxin-like PCBs in blood of children from South West Germany (Daded-Wuerttembergs) from 1993 to 2003. Chemosphere 2005; 58:1185 - 1201
- Baccarelli A, Pesatori AC, Consonni , et al. Health status and plasma dioxin levels in chloracne cases 20 years after the Seveso, Italy accident. Br J Dermatol 2005; 152:459 - 465
- Wolfe WH, Michalek JE, Miner JC, et al. Determinants of TCDD half-life in veterans of operation ranch hand. J Toxicol Environ Health 1994; 41:481 - 488
- Cheng WN, Coenraads PJ, Hao ZH, et al. A health survey of workers in the pentachlorophenol section of a chemical manufacturing plant. Am J Ind Med 1993; 24:81 - 92
- Piacitelli L, Marlow D, Fingerhut M, et al. A retrospective job exposure matrix for estimating exposure to 2,3,7,8-tetrachlorodibenzo-p-dioxin. Am J Ind Med 2000; 38:28 - 39
- Guo YL, Yu ML, Hsu CC, Rogan WJ. Chloracne, goiter, arthritis and anemia after polychlorinated biphenyl poisoning: 14-year follow-Up of the Taiwan Yucheng cohort. Environ Health Perspect 1999; 107:715 - 719
- Panteleyev AA, Roumak VS, Stepanova LV, Poznyakov SP, Bocharov BV. Clinical and ultrastructural characterization of human skin after exposure to dioxin-contaminated defoliants. 1991; Proceedings of Joint Russian-Vietnam Tropical Centre Moscow 300 - 304
- Zugerman C. Chloracne. Clinical manifestations and etiology. Dermatol Clin 1990; 8:209 - 213
- Jensen NE. Chloracne: three cases. Proc R Soc Med 1972; 65:687 - 688
- Geusau A, Jurecka W, Nahavandi H, et al. Punctate keratoderma-like lesions on the palms and soles in a patient with chloracne: a new clinical manifestation of dioxin intoxication?. Br J Dermatol 2000; 143:1067 - 1071
- Kerger BD, Leung HW, Scott P, et al. Age- and concentration-dependent elimination half-life of 2,3,7,8-tetrachlorodibenzo-p-dioxin in Seveso children. Environ Health Perspect 2006; 114:1596 - 1602
- Hambrick GW. The effect of substituted naphthalenes on the pilosebaceous apparatus of rabbit and man. J Invest Dermatol 1957; 28:89 - 103
- Panteleyev AA, Thiel T, Rosenbach T, et al. Christiano Acne chlorina and acne vulgaris—casual likeness or causal homology?. Arch Dermatol Res 2000; 292:577 - 581
- Pastor MA, Carrasco L, Izquierdo MJ, et al. Chloracne: histopathologic findings in one case. J Cutan Pathol 2002; 29:193 - 199
- Panteleyev AA, Bickers DR. Dioxin-induced chloracne—reconstructing the cellular and molecular mechanisms of a classic environmental disease. Exp Dermatol 2006; 15:705 - 730
- McConnell EE, Moore JA. Toxicopathology characteristics of the halogenated aromatics. Ann N Y Acad Sci 1979; 320:138 - 150
- Loertscher JA, Sattler CA, Allen-Hoffmann BL. 2,3,7,8-Tetrachlorodibenzo-p-dioxin alters the differentiation pattern of human keratinocytes in organotypic culture. Toxicol Appl Pharmacol 2001; 175:121 - 129
- Huelsken J, Vogel R, Erdmann B, et al. beta-Catenin controls hair follicle morphogenesis and stem cell differentiation in the skin. Cell 2001; 105:533 - 545
- Gawkrodger DJ. Chloracne: causation, diagnosis and treatment. J Dermatol Treat 1991; 2:73 - 76
- Geusau A, Tschachler E, Meixner M, et al. Olestra increases faecal excretion of 2,3,7,8-tetrachlorodibenzo-p-dioxin. Lancet 1999; 354:1266 - 1267
- Redgrave TG, Wallace P, Jandacek RJ, Tso P. Treatment with a dietary fat substitute decreased Arochlor 1254 contamination in an obese diabetic male. J Nutr Biochem 2005; 16:383 - 384