Open-access Relationship between acetaldehyde concentration in mouth air and tongue coating volume

Abstract

Objective  Acetaldehyde is the first metabolite of ethanol and is produced in the epithelium by mucosal ALDH, while higher levels are derived from microbial oxidation of ethanol by oral microflora such as Candida species. However, it is uncertain whether acetaldehyde concentration in human breath is related to oral condition or local production of acetaldehyde by oral microflora. The aim of this pilot study was to investigate the relationship between physiological acetaldehyde concentration and oral condition in healthy volunteers.

Material and Methods  Sixty-five volunteers (51 males and 14 females, aged from 20 to 87 years old) participated in the present study. Acetaldehyde concentration in mouth air was measured using a portable monitor. Oral examination, detection of oral Candida species and assessment of alcohol sensitivity were performed.

Results  Acetaldehyde concentration [median (25%, 75%)] in mouth air was 170.7 (73.5, 306.3) ppb. Acetaldehyde concentration in participants with a tongue coating status score of 3 was significantly higher than in those with a score of 1 (p<0.017). After removing tongue coating, acetaldehyde concentration decreased significantly (p<0.05). Acetaldehyde concentration was not correlated with other clinical parameters, presence of Candida species, smoking status or alcohol sensitivity.

Conclusion  Physiological acetaldehyde concentration in mouth air was associated with tongue coating volume.

Acetaldehyde; Tongue; Bacteria; Cross-sectional studies


INTRODUCTION

Although metabolism of alcohol by aldehyde dehydrogenase (ALDH) principally occurs in the liver4, alcohol metabolism is also known to be carried out in other areas of the body. For example, acetaldehyde is produced in the epithelium by mucosal ALDH2, while higher levels are derived from microbial oxidation of ethanol by oral microflora such as Candida species9,10,12,17,23. Thus, the effects of acetaldehyde on the oral cavity can be local, and oral hygiene may be linked to local production of acetaldehyde by oral microflora.

Acetaldehyde is known to be carcinogenic and to cause mutations in DNA25. Long-term exposure to acetaldehyde, even at physiological concentrations, may affect cell activity and cause mutations in DNA. For example, physiological concentrations of acetaldehyde (220 ppb) influence cell proliferation in rabbit aortic myocytes after long-term exposure27. Therefore, physiological concentrations of acetaldehyde in oral cavity might affect cell activity in both humans and animal models.

Only one study has reported data on physiological concentrations of acetaldehyde in human breath (0.4-1.6 ppb) in a small number of subjects (n=20)5. However, the relationship between physiological concentrations of acetaldehyde in human breath and oral condition is uncertain. Thus, we hypothesized that physiological concentrations of acetaldehyde in human breath are related to oral condition or local production of acetaldehyde by oral microflora. The aim of this study was to investigate the physiological concentrations of acetaldehyde in human mouth air and the relationship between these concentrations and oral condition.

MATERIAL AND METHODS

Participants

At the Dental Clinic of Okayama University Hospital, sixty-five volunteers (51 males and 14 females, aged from 20 to 87 years old; mean age 44.0±22.7 years) without respiratory, digestive system, otorhinolaryngologic or liver disease and not undergoing any antibiotic or other antimicrobial therapy participated in the present study, when the dentists asked the patients to participate the research. The recruitment period was from October 2013 to August 2014. The study was approved by the Ethics Committee of Okayama University Graduate School of Medicine, Dentistry and Pharmaceutical Sciences (No. 1461, August 28, 2012). Written consent was obtained from all participants.

Measurement of acetaldehyde

We used the Sensor Gas Chromatograph SGEA-P2 (FIS Inc., Itami, Japan). The system consists of pump, filter, flow control, column, detector (semiconductor gas sensor) and sample injection area (manual injection with a syringe). As a high-sensitivity semiconductor gas sensor is used as a detector, ppb level measurement is possible. Using a syringe, injection of sample gas (5 mL) starts the measurement automatically. Measurement was completed in 8 minutes. The monitor uses ambient air as a carrier gas, and a high-pressure gas cylinder is not necessary. To assess the reproducibility of the portable monitor, 100-10,000 ppb acetaldehyde was used for calibration. Measurement was performed in duplicate. Both intra- and inter-assay coefficients of variation were below 5%.

Participants were advised to abstain from food or drink and to refrain from their standard oral hygiene practice on the morning of the day of measurements. Participants were also instructed to refrain from eating strong smelling foods for at least 48 h, from using strong perfumes for 24 h, from smoking for 24 h and from drinking alcohol for 12 h prior to measurements. Actual measurements were conducted in the morning, between 8 and 9 am. Participants kept their mouths closed for 3 min prior to measurement of mouth air with a syringe19 (Figure 1). During collection, participants breathed through their nose. As acetaldehyde is highly volatile, we avoided air contamination in the oral cavity as much as possible. Sample gas in the syringe was then injected immediately and measured.

Figure 1
Collection of acetaldehyde. Participants kept their mouths closed for 3 min. The syringe was tightly held between lips to avoid contamination of the oral cavity with outside air

We also investigated acetaldehyde concentration changes after tongue coating removal in 6 participants (5 males and 1 female, aged from 27 to 65 years old; mean age, 39.8±18.4 years) with a tongue coating status score of 3. In addition, the diurnal variation [morning (between 8:00 and 9:00), noon (between 12:00 and 1:00) and evening (between 17:00 and 18:00)] in another 6 participants (5 males and 1 female, aged from 27 to 41 years old; mean age, 30.2±5.4 years) was examined.

Oral examination

Probing pocket depth (PPD) and clinical attachment level (CAL) were determined at six sites (mesiobuccal, midbuccal, distobuccal, mesiolingual, midlingual and distolingual) on all teeth using a color-coded probe (Hu-Friedy, Chicago, IL, USA). Sites that bled upon gentle probing (25 g probing force) were recorded, and the proportion of sites with bleeding on probing (BOP) was measured in each participant. The plaque control record (PCR) was measured using erythrosine staining, and was recorded with respect to their relative location to the gingival margin at four sites (mesial, distal, buccal and lingual) around each tooth22. Tongue coating status was assessed according to distribution area as follows: score 0: none visible; 1: less than one third of the tongue dorsum surface covered; 2: less than two thirds; 3: more than two thirds18. All clinical procedures were performed by four trained and calibrated dentists (A. Y., T. M., T. T. and D. E.). Intra- and inter-examiner agreement for the oral examination (tongue coating status, PPD and CAL) was good, as evaluated by kappa statistics of more than 0.8.

Detection of Candida species

We used a CHROMagar Candida medium (Kanto Chemical Corp., Inc., Tokyo, Japan) (pH 6.1) to detect Candida albicans (C. albicans), Candida tropicalis (C. tropicalis) and Candida krusei (C. krusei)21. The medium comprised (per liter) peptone (10 g), glucose (20 g), agar (15 g), chloramphenicol (0.5 g) and Chromogenic ix (2 g), and was prepared in accordance with the manufacturer’s instructions. All samples wiped from the surface of buccal mucosa and tongue dorsum using a sterilized dental mirror were plated on the medium for 48 hours at 37°C. Production of color and morphology, as described by the manufacturer, were recorded and photographs were recorded; i.e, green colonies of C. albicans, steel blue colonies of C. tropicalis and rose colored colonies of C. krusei21.

Assessment of alcohol sensitivity

We used the ethanol patch test (ASK Human Care Inc., Tokyo, Japan) to assess participant genotypes28. Briefly, a patch plaster fixed on adhesive tape was attached to the inner surface of the arm for 20 minutes, and was removed in accordance with the manufacturer’s instructions. A patch area with erythema after removal was judged to be positive and alcohol sensitivity was considered to be high (ALDH2*1/*2 or *2/*2), while in the case of a negative reaction, sensitivity was considered to be low (ALDH2*1/*1).

Questionnaire

In addition to age, sex and general condition, the questionnaire included the following items: smoking, alcohol consumption and daily frequency of tooth brushing. Because smoking status14 can affect acetaldehyde production, we investigated smoking status, which was characterized as “never”, “past” and “current”11. Information regarding drinking frequency [never; less than 5 days a week (light); 5 or more days a week, less 360 mL a day (moderate); 5 or more days a week, 360 mL or more a day (heavy)], mean amount of alcohol consumption per occasion and type of alcoholic beverage, which included beer, sake, wine, whisky and shochu (distilled alcoholic beverage made from wheat or sweet potatoes) was obtained26. We calculated average daily alcohol consumption by multiplying the mean amount of alcohol consumption per occasion by drinking frequency. Alcohol content was estimated to be 20 g for a bottle of beer (500 mL), 22 g for a cup of sake (180 mL), 20 g for a glass of whisky (60 mL), 50 g for a cup of shochu (180 mL) and 12 g for a glass of wine (120 mL)1. To assess oral health behavior, participants were asked to state their daily frequency of toothbrushing26.

Statistical analysis

Data analysis was performed using the Statistical Package for Social Science (SPSS version 19) (IBM, Tokyo, Japan). Chi-square test (or Mann-Whitney U test) was performed to compare variables between male and female and to compare acetaldehyde concentration in mouth air between two groups, i.e., male vs. female, Candida species positive vs. negative, low alcohol sensitivity vs. high, nonsmoker vs. smoker, or once a day vs. more than once a day (for toothbrushing frequency)26. The association between acetaldehyde concentration and other parameters were analyzed using Spearman correlation coefficient. Wilcoxon signed rank test was used to compare acetaldehyde concentration in mouth air between before and after tongue coating removal and diurnal variation in acetaldehyde concentration (morning, noon and evening). Levels of significance were set at p<0.05.

Differences in parameters among the three tongue coating groups (score 0/1, 2 and 3) and the three drinking frequency groups (never, light and moderate) were analyzed by Mann-Whitney U test with Bonferroni correction. Because the number of participants with a tongue coating score of 0 was only 8, scores of 0 and 1 were combined. The level of significance was set at p<0.017.

RESULTS

Table 1 shows the characteristics of study participants. There were no decayed teeth, severe periodontitis or mucosal lesions. Acetaldehyde concentration in mouth air was 170.7 (73.5, 306.3) [median (25%, 75%)] ppb.

Table 1
Characteristics of participants (n=65)

Acetaldehyde concentration in participants with a tongue coating status score of 3 was significantly higher than in those with a score of 0/1 [248.3 (172.0, 469.4) vs. 87.9 (66.9, 121.5)] (p<0.001) (Table 2). Even in participants (n=31) who never smoked and had no Candida species, acetaldehyde concentration in participants with a tongue coating status score of 3 was significantly higher than in those with a score of 0/1 [97.7 (66.0, 141.1) vs. 315.8 (209.3, 579.4)] (p<0.001). There were no significant differences in acetaldehyde concentration between other parameters, including alcohol sensitivity and drinking habits (Table 2). No parameters were associated with acetaldehyde concentration (Table 3).

Table 2
Differences in acetaldehyde concentration in mouth air

Table 3
Correlation between acetaldehyde concentration and other parameters

Acetaldehyde concentration decreased significantly after tongue coating removal [222.0 (176.2, 575.5) vs. 141.9 (80.5, 170.1)] (Figure 2) (p<0.05). Acetaldehyde concentration did not exhibit significant diurnal variations [177.5 (53.8, 406.6) in the morning, 86.5 (42.8, 136.0) at noon and 61.7 (37.9, 536.0) in the evening] (Figure 3) (p>0.05).

Figure 2
Acetaldehyde concentration in mouth air before and after tongue coating removal. Acetaldehyde concentration decreased significantly after tongue coating removal (Wilcoxon signed rank test, p<0.05, n=6)

Figure 3
Diurnal variation in acetaldehyde concentration (morning, noon and evening). Acetaldehyde concentration did not present significant diurnal variations (Wilcoxon signed rank test, p>0.05, n=6)

DISCUSSION

Although one study has reported data on physiological concentrations of acetaldehyde in human breath (0.4-1.6 ppb)5, the relationship between its concentration and oral condition, which may affect local production of acetaldehyde, is uncertain. In this study, acetaldehyde concentration in mouth air was significantly related to tongue coating status. Furthermore, removing tongue coating significantly decreased acetaldehyde concentration. These results suggest that one of the sources of acetaldehyde in mouth air is tongue coating.

Acetaldehyde concentration in participants with a tongue coating status score of 3 was significantly higher than in those a score of 0/1. Acetaldehyde is produced in the epithelium by mucosal ALDH2, and higher levels of acetaldehyde are derived from microbial oxidation of ethanol by oral microflora9,10,12,17,23. In this study, acetaldehyde concentration was associated with tongue coating scores, but not plaque scores. Tongue coating serves as a reservoir for oral microflora24, thus, oral microflora on the tongue may be the main source of local production of acetaldehyde, rather than endogenous metabolic activity. However, we did not investigate the bacterial species on the tongue, which is a limitation of this study.

It may be important for oral health to reduce acetaldehyde concentrations in mouth air. The causes of halitosis are largely located in the mouth and can be attributed to tongue coating and periodontal disease29. Removing tongue coating improves oral malodor, which reduces acetaldehyde concentration and prevents mutations in DNA. However, further studies are required to clarify the details.

Candida species possess ALDH and are a source of acetaldehyde generation15. The production of carcinogenic acetaldehyde by Candida species has been suggested to contribute to oral carcinogenesis7,13. However, in this study, acetaldehyde concentration was not associated with the presence of Candida species. The discrepancy between the results of these studies and the present study may be due to differences in the procedure for detection of acetaldehyde concentration and in experimental conditions; we directly detected the physiological concentration in mouth air, while other studies incubated Candida species with ethanol, and acetaldehyde production was then measured7,13. As Neisseria20 and Streptococci13 strains can also be a regional source of acetaldehyde, further studies are required to investigate the main acetaldehyde-producing bacteria.

Alcohol sensitivity16, amount of alcohol consumption3 and smoking status14 can affect acetaldehyde production. On the other hand, ALDH2 genotype had no effect on salivary acetaldehyde before and after ethanol exposure8. Smoking status did not result in differences in the production of acetaldehyde in saliva6. In this study, acetaldehyde concentration was not associated with alcohol sensitivity, drinking habits or smoking status. The discrepancies between our study and previous studies are unclear. However, alcohol sensitivity, amount of alcohol consumption and smoking status may not affect acetaldehyde production in mouth air, as participants refrained from smoking and from drinking alcohol for 12 h prior to measurements, and the main source of acetaldehyde is oral microflora.

Acetaldehyde concentration [Median (25%, 75%)] in mouth air was 170.7 (73.5, 306.3) ppb in this study. The values were higher than in a previous study, which reported that the physiological concentration of acetaldehyde in human breath was 0.4-1.6 ppb using gas chromatography5. The difference may be due to experimental conditions. We measured the concentration in the morning under limited conditions for easier detection. Further investigations are necessary to monitor slight physiological changes or diurnal variations for low acetaldehyde levels (ppb order) in mouth air using a more sensitive portable monitor.

This study has other limitations. First, all subjects were recruited at Okayama University Hospital, and the number of subjects was small, which may limit the ability to extrapolate these findings to the general population. Second, although acetaldehyde concentration significantly decreased after tongue coating removal, the number of participants was small. Additional large-scale studies will thus provide information beyond the findings presented here.

CONCLUSION

This study revealed that acetaldehyde concentration in mouth air is associated with tongue coating, which may be a source of local production by oral microflora.

ACKNOWLEDGMENTS

This work was supported by Grants-in-Aid for Scientific Research (24593154) from the Ministry of Education, Culture, Sports, Science and Technology, Tokyo, Japan. We are also grateful to Mr. Gohei Oyama and Mr. Shuhei Uno (Okayama University, Okayama, Japan) for helping with data entry.

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Publication Dates

  • Publication in this collection
    Jan-Feb 2015

History

  • Received
    3 June 2014
  • Reviewed
    28 Oct 2014
  • Accepted
    30 Oct 2014
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