Ozone for Swimming Pools

InfoTrac Web: Health Reference Center-Academic. Full content for this article includes table, graph, table and illustration. Source: Archives of Environmental Health, May-June 1990 v45 n3 p175(5). Title: Plasma chloroform concentrations in swimmers using indoor swimming pools. Author: Gabriella Aggazzotti, Guglielmina Fantuzzi, Pier Luigi Tartoni and Guerrino Predieri Abstract: Chloroform (CHCl3) is produced by chemical reactions when sodium hypochlorite (NaOCl) interacts with organic molecules in chlorinated swimming pool water. Chloroform levels build up both in the water and in the air of indoor swimming pools where the vapors are contained. The level of concentration in these situations is conditioned on may factors, including the number of persons using the pool, the level of turbulence produced by the swimmers and water circulators, and the ventilation of the building. Although visitors and swimmers who do not do vigorous exercise inhale chloroform, the maximum uptake is reserved for swimmers who breath under the stress of exertion for extended periods of time. Although chloroform is classified as a carcinogen on the basis of animal research, little is known about the epidemiologic implications for humans. This study evaluates the level of chloroform in the air and water of three different swimming pools, which were measured at 18 different times. The blood of 127 volunteers (81 males and 46 females), who frequently attended the pools, was also collected and analyzed. Similarly, the blood of 40 volunteers (controls), who had no know occupational exposure to chloroform, was also collected. The local drinking water supply was free of chloroform. None of the controls had chloroform levels greater than the detection level of the equipment. The blood of all 127 exposed volunteers had measurable levels of chloroform. Analysis showed that the blood chloroform level in this group was strongly correlated with the level of chloroform in the air and water, the number of swimmers in the pool, time spent swimming, and intensity of their exercise. (Consumer Summary produced by Reliance Medical Information, Inc.) Subjects: Chloroform - Toxicology Swimming pools - Health aspects Pollutants - Measurement Chloroform - Measurement Pollutants - Toxicology Chloroform - Physiological aspects Electronic Collection: A9405815 RN: A9405815 Full Text COPYRIGHT 1990 Heldref Publications Plasma Chloroform Concentrations in Swimmers Using Indoor Swimming Pools CHLOROFORM ([CHCI.sub.3]) is present in indoor swimming pools as a consequence of water chlorination with sodium hypochlorite (NaOCI). As a lipophilic volatile substance, [CHCI.sub.3] can be released from water into environmental air, where its concentration depends on several factors, among which the most important are the number of swimmers in the water and the turbulence caused by their movements. [1-4] Chloroform in air can be inhaled by swimming pool visitors, but is mainly inhaled by agonistic swimmers who breathe under stress for a long time directly at the surface of the water. Chloroform is a class 2B carcinogen with sufficient evidence in experimental animals but inadequate epidemiological evidence. [5] Thus, it is advisable to look for biological markers of exposure in humans. Very little information is available on [CHCI.sub.3] metabolism in humans, and no byproducts have been found in human fluids. In addition, few studies have reported on the level of [CHCI.sub.3] in human blood, and many difficulties have been encountered when determining the actual level of human exposure via inhaled air and drinking water in various circumstances. [6-10] Because indoor swimming pool visitors are exposed to [CHCI.sub.3] during a precise period of time at a known environmental concentration, they form an available population to obtain more detailed information about nonoccupational exposure to [CHCI.sub.3]. The aims of this study were to evaluate the level of [CHCI.sub.3] in blood of exposed (indoor swimming pools visitors and swimmers) and nonexposed subjects, and to verify if individual and/or environmental variables can influence blood [CHCI.sub.3] concentration. Materials and methods Sampling. Three indoor swimming pools in Modena were visited on 18 occasions from November 1987 to April 1988. During every visit, the [CHCI.sub.3] concentration was determined in pool water and in environmental air within the breathing zone of all subjects at the swimming pool. A total of 127 volunteer subjects (81 males and 46 females) who regularly attended a swimming pool were examined. Informed consent was obtained from each person. Blood samples were collected from each subject at the time he or she was ready to leave the swimming pool environment. Data were gathered from each subject about the possibility of exposure outside the swimming pool (e.g., occupational expoure or handling of solvents at home while engaged in hobby activities). The type of activity practiced in the swimming pool was recorded; therefore, all subjects were classified into three main groups: (1) agonistic swimmers (n = 102) who trained for competitions every day, (2) nonagonistic swimmers (n = 16) who attended swimming courses twice a week, and (3) visitors (n = 9) who were present but who did not swim. Every subject was asked about the frequency of attendance and length of time spent at the swimming pool during a week. The length of the swimming session was determined, and the lapse of time between the end of the sport activity and the blood sampling was registered for swimmers only. A control group of 40 volunteers who had no known occupational and environmental exposure and who never attended an indoor swimming pool were examined to evaluate [CHCI.sub.3] in blood. Modena is supplied with drinking water treated with chlorine dioxide ([CIO.sub.2]) and is free from [CHCI.sub.3] and other halogenated organic compounds. However, we analyzed drinking water samples before, during, and after this study to confirm the absence of [CHCI.sub.3]. Blood was drawn by a physician at the swimming pool (from 1 to 40 min) after exposure ceased (i.e., 1-40 min after exposure). A [5-cm.sup.3] volume of blood was drawn from a cubital vein with a [10-cm.sup.3] syringe and immediately placed in a capped disposal tube that contained the anticoagulant [K.sub.3] EDTA. The tubes were shaken gently, chilled on ice, and kept cold until analyzed. The samples were centrifuged for 10 min at 1000 g) as soon as possible; plasma was then drawn using an Eppendorf micropipette and transferred into [3.7-cm.sup.3] borosilicate glass vials with hole caps sealed with Teflon-faced silicon-rubber septa (Supelco). During each session, three air samples were collected at the same level above the water surface, i.e., 150 cm in height at the edge of the pool, and three samples of water were obtained at three different points in the pool at a depth of 20 cm near the edge of the pool. Environmental air samples were collected within the breathing zone. Environmental air and water samples were collected in screw-capped [40-cm.sup.3] glass vials with silicone-faced septa. Immediately prior to sampling, vials that were to be used for water collection received 5 mg of sodium thiosulfate to quench residual chlorine reactions. Septa and screw caps were washed in water, acetone, n-pentane, and then dried at 105 [+ or -] 1 [degrees] C for 4 h. Vials and all pieces of glassware were washed in water, acetone, n-pentane, and were then placed in a muffle furnace at 400 [+ or -] 5 [degrees] C for 2 h to purge any volatile contaminants. Determination of [CHCI.sub.3] in plasma. Analyses were performed on the plasma aliquots. Samples were analyzed by a head-space gas chromatographic technique, in accord with a previous report, using a glass steel column packed with 10% OV-1 on Chromosorb WAW. [11] Determination of [CHCI.sub.3] in wateer. Samples were analyzed by a head-space gas chromatographic technique. An autosample DAN-NI HSS 3950 and a VAR-IAN 3400 gas chromatograph equipped with a [sup.63.Ni] electron-capture detector and a VOCOL capillary column (length = 30 m, ID = 0.53 mm, film thickness = 30 [micrometer] [SUPELCO]) were used. The carrier gas (He) flow rate was 8 ml/min; make-up gas, 20 ml/min; initial column temperature 50 [degrees] C (1 min); final temp, to 100 [degrees] C (7 min at 6 [degrees] C/min); injector temperature, 150 [degrees] C, detection temperature, 260 [degrees] C; detector ECD, range 10, attenuation 32. Calibration was performed by the external standard method. This method is preferred by most workers when studying the presence of [CHCI.sub.3] in waters by head-space gas chromatography [12-13]. Precision, calculated from 5 duplicate determinations on 5 different days, was 2.8% (coefficient of variation [CV]). The detection limit was calculated during 30 different series of [CHCI.sub.3] determinations of blank value (vials with [CHCI.sub.3]-free water). The mean blank concentration was 2.9 nmol/l and had a standard deviation of 0.3 nmol/l. Based on 2.5 times the standard deviation, the detection limit was 0.8 nmol/l. Determination of [CHCI.sub.3] in environmental air. Samples were injected directly into the gas chromatograph using a gas-tight syringe (Hamilton). Calibration was performed by the external standard method. Precision, calculated as before, was 3.5% as C.V. The detection limit was calculated during 30 different series of [CHCI.sub.3] determinations of blank value (vials with environmental air). The mean blank concentration was 41.9 [nmol/m.sup.3], with a standard deviation of 3.4 [nmol/m.sup.3]. Based on 2.5 times the standard deviation, the limit of detection was 8.4 [nmol/m.sup.3]. Quantitative analysis was performed by Chromato-Integrator Merck Hitachi D2000. The identity of [CHCI.sub.3] was confirmed by gas chromatography-mass spectrometry (GC-MS). We examined both standard samples of [CHCI.sub.3] in n-pentane and standard examples of [CHCI.sub.3]-fortified human plasma at increasing concentrations (i.e., 0.8-8 376 [micrometer]ol/l) after extraction with n-pentane. The identification of [CHCI.sub.3] is based on retention times measured on a total ion-current chromatogram and on mass chromatograms of the molecular ion and the most significant fragments of [CHCI.sub.3] (m/z 47-50, 82-87, and 117-124). [11] Statistical analyses. The correlations between parameters were evaluated by Spearman's rank correlation coefficient. As the distribution of parameters after log-transformation was not closer to Gaussian, no-log transformation was applied before using the parametric tests. Linear and multiple regression analyses were performed, and the linearity of the regression model was controlled. Moreover, to evaluate the ifluence of some parameters on [CHCI.sub.3] content in plasma, the analysis of covariance was performed. Differences among mean values were evaluated by the Student-Newman-Keuls test. These tests were always checked with regard to the homogeneity of variance according to the Cochran and Bartlett Tests. Results Concentrations of [CHCI.sub.3] in water samples and environmental air samples (mean values of three samples) in indoor swimming pools during each sampling session are given in Table 1. As the three air samples collected during every session at different points at the same level above the water surface were very similar, the mean value was considered as representative of the environmental concentration. Mean values of [CHCI.sub.3] in plasm samples collected during the same session are also reported. Although no plasma sample from the 40 nonexposed control subjects showed [CHCI.sub.3] levels [is greater than] 0.8 nmol/l (detection limit), all samples taken from the 127 exposed subjects showed [CHCI.sub.3] values ranging from 0.8 nmol/l to 25.1 nmol/l. Levels of [CHCI.sub.3] in pool waters ranged from 142 to 394 nmol/l. Mean levels of [CHCI.sub.3] in environmental air ranged from 553 to [ 5 445 [nmol/m.sup.3], depending on the level of [CHCI.sub.3] and the number of swimmers in the pool. Figure 1 shows the distribution of [CHCI.sub.3] in 127 plasma samples. The geometric mean was 6.9 nmol/l, and the median was 7.5 nmol/l. Of interest is that 53.3% of the samples showed levels from 0.8 to 8.0 nmol/l, whereas 13% of samples showed a [CHCI.sub.3] concentration [is greater than] 16.0 nmol/l. Table 2 shows the correlation coefficients between some variables. The [CHCI.sub.3] level in plasma was significantly correlated to four variables: (1) concentration in water, (2) time spent swimming, (3) number of swimmers, and (4) most significant of all, [CHCI.sub.3] concentration in environmental air. No significant correlation was found between [CHCI.sub.3h in plasma and the time since exposure ceases. As expected, mean [CHCI.sub.3] values in environmental air were correlated to mean levels in water and the number of swimmers. Unexpectedly, the mean level of [CHCI.sub.3] in water correlated to the number of swimmers. Perhaps this finding is due to the fact that swimmers contribute to the total amount of organic substance that is responsible for [CHCI.sub.3] and another trihalomethanes in pool water when continuous chlorination with NaOCI is performed. Chloroform levels in plasma are also influenced by the variable "intensity of the sport activity." When covariance analysis was applied, the plasma concentration was considered as a dependent variable, whereas [CHCI.sub.3] values in environmental air and intensity of the sport were considered independent parameters. Chloroform in air was accounted for as a covariate and intensity of the sport as a factor. The total explained variance by this statistical model was 67.43%: 61.69% accounted for [CHCI.sub.3] in environmental air (F = 232.97; p [is less than] .001), whereas 5.74% accounted for intensity of the sport (F = 10.83, p [is less than] .001). The Student-Newman-Keuls test at p [is less than] .050 showed significant differences in [CHCI.sub.3] mean plasma levels of agonistic swimmers (10.3 [+ or -] 5.7 nmol/l) v. nonagonistic swimmers (3.4 [+ or -] 1.3 nmol/l) and v. visitors (2.5 [+ or -] 1.7 nmol/l); however, absolute differences are small. Sessions where [CHCI.sub.3] mean values in environmental air exceeded 1 700 [nmol/m.sup.3] 7mean plasma [CHCI.sub.3] value = 13.7 [+ or -] 5.5 nmol/l) were considered, and multiple regression analysis was performed accounting for temporal variables (i.e., time spent at the swimming pool, time spent swimming, time since cessation of exposure). A positice association was found between [CHCI.sub.3] in plasma and the time (min) spent swimming ([R.sup.2] adjusted = 0.229; F = 12.45; p = .001), whereas no correlation was found between the time spent at the swimming pool and time since exposure ceased. Discussion Very few studies report [CHCI.sub.3] levels in blood of nonoccupationally exposed individuals. Recently, Hajimiragha et al. [9] reported values that ranged from [is less than] 0.1 to 1.7 [mu]g/l ([is less than] 0.8 to 14.2 nmol/l) in samples from 39 subjects who had no occupational exposure to [CHCI.sub.3], whereas increased levels were found in 6 occupationally exposed subjects, e.g., drycleaners and pressers. In our study, plasma [CHCI.sub.3] in nonexposed subjects was never measured at a level that exceeded 0.8 nmol/l; however, plasma [CHCI.sub.3] levels were evident in all exposed subjects. Exposure via drinking water could be excluded because water in Modena does not contain [CHCI.sub.3]; similarly, other recognized possibilities of exposure could be excluded. Therfore, [CHCI.sub.3] in blood is most probably related to exposure in an indoor swimming pool environment. [CHCI.sub.3] in water results from chlorination with NaOCI when organic substance is present in pool water. According to the haloform reaction, [CHCI.sub.3] is released in environmental air, where its concentration is dependent on the level of organic substance in water and the number of swimmers who produce turbulence. [1-4] Whether swimmers or visitors, individuals at the indoor swimming pool inhale [CHCI.sub.3] during the time spent in this environment. However, the greatest amount of [CHCI.sub.3] is inhaled by those who swim for a long time under physical stress. The inhaled [CHCI.sub.3] is rapidly absorbed in the lung, and the total amount is directly proportional to the concentration of the inspired air, the duration of exposure, the blood/air Ostwald solubility coefficient, the solubility in the various body tissues (very high for fat tissue), and the intensity of physical activity (increased pulmonary ventilation rate and cardiac output). [14-15] Therefore, all these factors can influence the level of [CHCI.sub.3] in blood. Our study showed that the [CHCI.sub.3] concentration in blood varies with water and environmental air values, number of swimmers, length of the time spent swimming, and the intensity of the sport activity. No significant correlation with time since cessaton of exposure was found, perhaps because many individual variables can influence the kinetics of [CHCI.sub.3] absorption, distribution, and clearance. Some of these variables are difficult to control in this type of study, e.g., total fat tissue content of the body and the pulmonary ventilation in exposed subjects. Chloroform exposure in indoor swimming pools represents an additional source that must be accounted for when exposure levels for the general population are considered. As reported previously, [CHCI.sub.3] is classified as a carcinogenic substance as a result of tests with animals. For this reason, more information about human exposure to [CHCI.sub.3] is required. Swimming pools visitors represent a special population to be studied to acquire more information about [CHCI.sub.3] intake, uptake, and elimination because environmental conditions are well known and defined. Blood sampling represents a first step to evaluate [CHCI.sub.3] exposure. However, satisfactory biological monitoring will have to include other biological measurements, e.g., breath (alveolar air) sampling. Studies are in progress on the kinetics of [CHCI.sub.3] after exposure at low levels by taking samples of blood and alveolar air from exposed subjects at different moments after the end of exposure. References [1] Beech AJ, Diaz R, Ordaz C, Palomeque B. Nitrates, chlorates and trihalomethanes in swimming pool water. Am J Public Health 1980; 70:79-181. [2] Lahl U, Batjer, Duszeln JV, Gabel B, Stachel, B, Thiemann W. Distribution and balance of volatile halogenated hydrocarbons in the water and air of covered swimming pools using chlorine for water disinfection. Wat Res 1981; 15:803-14. [3] Chambon P, Taveau M, Morin M, Chambon R, Vial J. Survey of trihalomethane levels in Rhone-Alps water supplies. Wat Res 1983; 17:65-69. [4] Aggazzotti G, Predieri G. Survey of volatile halogenated organics (VHO) in Italy. Levels of VHO in drinking waters, surface waters and swimming pools. Wat Res 1986; 20:959-63. [5] International Agency for Research on Cancer. IARC Monographs on the evaluation of the carcinogenic risk of chemicals to humans. Some halogenated hydrocarbons. Chloroform. Lyon International Agency for Research on Cancer. October 1979; 401-27. [6] Peoples AJ, Pfaffenberger D, Shafik TM, Enos HF. Determination of volatile purgeable halogenated hydrocarbons in human adipose tissue and blood serum. Bull Environ Contam Toxicol 1979; 23:244-49. [7] Pfaffenberger CD, Peoples AJ. Long-term variation study of blood plasma levels of chloroform and related purgeable compounds. J Chromatogr 1982; 239:217-26. [8] Wallace LA, Pellizzari E, Hartwell T, et al. Personal exposure to volatile organic compounds. I. Direct measurements in breathing zone air, drinking water, food and exhaled breath. Environ Res 1984; 35:393-319. [9] Hajimiragha H, Ewers U, Jansen-Rosseck R, Brockhaus A. Human exposure to volatile halogenated hydrocarbons from the general environment. Int Arch Occup Environ Health 1986; 58:141-50. [10] Monster AC. Biological markers of solvent exposure. Arch Environ Health 1988; 43:90-93. [11] Aggazzotti G, Predieri G, Fantuzzi G, Benedetti A. A head-space gas chromatographic analysis for determining low levels of chloroform in human plasma. J Chromatogr 1987; 416:125-30. [12] Lukacovic L, Mikulas M, Vanko A and Kiss G. application of headspace gas chromatography to the determination of chlorinated hydrocarbons in waste waters. J Chromatogr 1981; 207:373-77. [13] Otson R, Polley GL, Robertson JL. Chlorinated organics from chlorine used in water treatment. Wat Res 1986; 20:775-79. [14] Sato A and Nakajima T. A structure activity relationship of some chlorinated hydrocarbons. Arch Environ Health 1979; 3412:69-75. [15] United States Environmental Protection Agency. Health assessment document for chloroform. EPA/600/ 884/004F. Washington, DC: Office of Health and Environmental Assessment, September 1985.