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Fractional urinary fluoride excretion of 6–7-year-old children attending schools in low-fluoride and naturally fluoridated areas in the UK

Published online by Cambridge University Press:  14 September 2012

F. V. Zohoori*
Affiliation:
School of Health and Social Care, Teesside University, Middlesbrough TS1 3BA, UK
R. Walls
Affiliation:
Centre for Oral Health Research, School of Dental Sciences, Newcastle University, Newcastle upon Tyne, UK
L. Teasdale
Affiliation:
County Durham Primary Care Trust, County Durham, UK
D. Landes
Affiliation:
County Durham Primary Care Trust, County Durham, UK
I. N. Steen
Affiliation:
Institute of Health and Society, Newcastle University, Newcastle upon Tyne, UK
P. Moynihan
Affiliation:
Centre for Oral Health Research, School of Dental Sciences, Newcastle University, Newcastle upon Tyne, UK Institute for Ageing and Health, Newcastle University, Newcastle upon Tyne, UK Human Nutrition and Research Centre, Newcastle University, Newcastle upon Tyne, UK
N. Omid
Affiliation:
School of Health and Social Care, Teesside University, Middlesbrough TS1 3BA, UK
A. Maguire
Affiliation:
Centre for Oral Health Research, School of Dental Sciences, Newcastle University, Newcastle upon Tyne, UK
*
*Corresponding author: F. V. Zohoori, fax +44 1642 342770, email [email protected]
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Abstract

F is an important trace element for bones and teeth. The protective effect of F against dental caries is well established. Urine is the prime vehicle for the excretion of F from the body; however, the relationship between F intake and excretion is complex: the derived fractional urinary F excretion (FUFE) aids understanding of this in different age groups. The present study aimed to investigate the relationships between (1) total daily F intake (TDFI) and daily urinary F excretion (DUFE), and (2) TDFI and FUFE in 6–7-year-olds, recruited in low-F and naturally fluoridated (natural-F) areas in north-east England. TDFI from diet and toothbrushing and DUFE were assessed through F analysis of duplicate dietary plate, toothbrushing expectorate and urine samples using a F-ion-selective electrode. FUFE was calculated as the ratio between DUFE and TDFI. Pearson's correlation and regression analysis were used to investigate the relationship between TDFI and FUFE. A group of thirty-three children completed the study; twenty-one receiving low-F water (0·30 mg F/l) and twelve receiving natural-F water (1·06 mg F/l) at school. The mean TDFI was 0·076 (sd 0·038) and 0·038 (sd 0·027) mg/kg per d for the natural-F and low-F groups, respectively. The mean DUFE was 0·017 (sd 0·007) and 0·012 (sd 0·006) mg/kg per d for the natural-F and low-F groups, respectively. FUFE was lower in the natural-F group (30 %) compared with the low-F group (40 %). Pearson's correlation coefficient for (1) TDFI and DUFE was +0·22 (P= 0·22) and for (2) TDFI and FUFE was − 0·63 (P< 0·001). In conclusion, there was no correlation between TDFI and DUFE. However, there was a statistically significant negative correlation between FUFE and TDFI.

Type
Full Papers
Copyright
Copyright © The Authors 2012 

F is a trace element which, following absorption from the gastrointestinal tract, is rapidly incorporated into calcified tissues that contain 99 % of body F. Although the influence of F on bone metabolism is less well defined, the protective effect against dental caries is well established(Reference Featherstone1, Reference McDonagh, Whiting and Wilson2). However, several recent studies in industrialised and developing countries have shown an increase in the prevalence of dental fluorosis in populations from communities with and without water fluoridation(Reference Szpunar and Burt3, Reference Pendrys and Stamm4), which may suggest that the threshold of F exposure for maximising caries prevention while minimising the potential risk of dental fluorosis has been exceeded. Obtaining the best balance between substantial caries reduction and the avoidance of unsightly dental enamel fluorosis is of critical importance to public health planners.

According to recent epidemiological surveys in the UK, 39 % of 5-year-olds(Reference Pitts, Boyles and Nugent5) and 33 % of 11-year-olds(Reference Pitts, Boyles and Nugent6) had evidence of dental caries experience involving dentine, while dental caries experience was even higher (48 %) in 14-year-old English children(Reference Pitts, Boyles and Nugent7). The relatively high prevalence of dental caries in UK children highlights the need for primary prevention programmes such as fluoridation schemes. Estimations of total daily F intake at an individual and community level are key when recommendations for F use are being considered. Ingestion of F may occur from water, foods, toothpaste and other therapeutic agents. Increasingly, residence in a non-fluoridated community does not automatically assure low F intake, nor does living in a fluoridated community mean adequate or high F intake, since food, drink or even bottled water produced in a fluoridated area may be transported to a non-fluoridated area and vice versa(Reference Heilman, Kiritsy and Levy8). In addition, some dietary factors can increase or reduce the absorption and excretion of F(Reference Buzalaf and Whitford9), making body F retention an important yet variable consideration. In the absence of high concentrations of certain cations (e.g. Ca and Al), almost 90 % of F ingested with food is absorbed from the gastrointestinal tract and passed rapidly into the blood. The remaining 10 % is excreted with the faeces. Urine is the prime vehicle for excretion of F that is absorbed but not taken up by bones. It is estimated that children under 6 years of age excrete approximately 50 % of their ingested F through the urine(10). F in the urine has been suggested as a suitable non-invasive biomarker for F exposure(Reference Marthaler11) because collection of information on dietary F and that ingested from toothbrushing, at a community level, is time consuming, costly and requires a high level of expertise. Furthermore, varying degrees of gastrointestinal F absorption from different sources of F intake, such as diet and dental care products, might limit the value of estimated F exposure with regard to its systemic effect. Given these limitations, measurement of urinary F excretion has been recommended as an adequate method for monitoring fluoridation schemes(Reference Marthaler11, Reference Marthaler, Steiner and Menghini12).

Studies of F intake and urinary excretion have shown a wide variation in urinary F excretion as a proportion of F intake, ranging from 32 to 80 % in children(Reference Brunetti and Newbrun13Reference Ekstrand, Ziegler and Nelson21) as summarised in Table 1. There is, therefore, a need for more assessment of the suitability and validity of urinary F excretion for monitoring fluoridation schemes as well as for predicting total F intake. The aims of the present study were therefore to investigate the relationships between (1) total daily F intake (TDFI) and daily urinary F excretion (DUFE), and (2) TDFI and fractional urinary F excretion (FUFE) in children.

Table 1 Summary of the literature on total daily fluoride intake (TDFI), daily urinary fluoride excretion (DUFE) and fractional urinary fluoride excretion (FUFE) by age group and country

* DUFE as a percentage of TDFI.

Materials and methods

The present study was conducted according to the guidelines laid down in the Declaration of Helsinki and all procedures involving human subjects/patients were approved by the County Durham and Tees Valley 2 Research Ethics Committee (ethics no. 09/H0908/9). Written informed consent was obtained from all participants/patients.

Study population and recruitment

The study was conducted in areas of the north-east of England where the water supply was not artificially fluoridated. Before commencing the study, associated ‘Research and Development’ approval was also obtained from the relevant Primary Care Trust's Research Management and Governance Unit. The Director of Children's Services Directorate and Local Education Authorities were also contacted and informed of the study.

Parents of children were contacted through the schools which agreed to take part in the study. The inclusion criteria were as follows: healthy children aged 6–7 years who were lifelong residents of the area; children not receiving any professionally applied topical F therapy.

Participating children were not randomly selected but were those for whom parental permission had been obtained. In total, forty-four informed written consents were obtained from parents of the children who met the study inclusion criteria. Following the recruitment, each child and his/her parents were visited twice at their home.

In visit 1, the weight of the child, without shoes and jacket, was measured to the nearest 0·1 kg using a portable digital balance (SOEHNLE Slim Design Linea; ADE (GmbH & Co.)). Their height was also measured to the nearest 0·1 cm using a stadiometer (SOEHNLE MZ10020; ADE (GmbH & Co.)). BMI was then calculated as weight (kg) divided by height squared (m2).

At visit 1, parents were provided with a bag that contained equipment required for collection of urine and food (duplicate plate) samples and instructions on how to collect these samples. Information on the toothbrushing habits of the child was also collected and a home tap water sample taken for subsequent F analysis.

Dietary assessment

Dietary F intake of the children was monitored by the ‘duplicate plate’ method as described by Guha-Chowdhury et al. (Reference Guha-Chowdhury, Drummond and Smillie22). The parents were asked to maintain the usual dietary habits of their children and duplicate portions of all food and drink items as precisely as possible by observing and replicating the actual consumed amounts by the children over 24 h. They were asked to remove parts of food items not normally eaten such as bones, fruit skin, cores, etc., before placing them in the container provided. They were also asked to collect drinks separately in the plastic bottles provided.

Each parent was also supplied with a 1 d food diary and accompanying instructions, for the recording of food and drink consumed on the day the duplicate plate was collected. This was done so that the researchers could cross-reference the information in the diary with the duplicate plate analysis for validation purposes. For those children who were at school during the sample collection period, researchers who were on-site during the school day obtained a duplicate of the child's school dinner and noted the items consumed. Any snacks and drinks including free school fruit and food consumed at breakfast clubs/breaks were also included in the duplicate plate.

Assessment of ingested toothpaste

F intake from ingested toothpaste during toothbrushing was estimated using the method described by Maguire et al. (Reference Maguire, Zohouri and Hindmarch18). In brief, expectorated toothpaste/saliva samples were obtained during a tooth brushing session, which took place either at the child's school or at their home. Children provided their own toothpaste and each child was provided with a new toothbrush (Aquafresh Big Teeth for 6–7-year-olds or Aquafresh Milk Teeth for 3–4-year-olds). Toothbrushes were weighed before and after the child or parent dispensed toothpaste. Any toothbrushing expectorate was collected in a small plastic sample collection pot together with the water used to rinse the toothbrush.

24 h urine collection

Collection of the 24 h urine sample started on the same day as the duplicate plate collection (day 1). Parents were advised to record the time of the child's first voided urine sample. All subsequent urine, up to and including the first passing of urine on the following day (day 2), was collected for the 24 h collection. During school hours, urine was collected by the child, supported by trained study researchers. Each child's voided urine sample was passed to the researchers for storage until the full 24 h sample had been collected.

At visit 2, which was conducted on day 2, the day following duplicate plate collections and after the final collection of urine, all samples were collected from the family home. At the same time, the researchers went through the food diary with the parent and child and checked it against the items in the duplicate plate collection.

Sample preparation and analysis

Collected samples were then taken to the F laboratory for processing. Urine collected at home and school (where applicable) was mixed together to produce a pooled sample and the volume recorded. Expectorated saliva/toothpaste samples were vortexed for 30 s. Collected samples of home and school drinks were also mixed together and the volume recorded. Food collected at home and school was mixed, weighed and then homogenised using an industrial blender (Thermomix TM31; Vorwek). Finally, three aliquots each of urine, expectorated saliva, homogenised foods, water and drinks were taken and stored at − 20°C for further analysis.

Urine, water and drink samples were analysed, in triplicate, for F by a direct F analysis method using a F-ion-selective electrode (Model 9609; Orion Research) coupled to a potentiometer (Model 720A), after sample buffering with total ionic strength adjustment buffer (III)(Reference Martínez-Mier, Cury and Heilman23). Food and expectorated saliva/toothpaste samples were analysed, in triplicate, for F concentration after overnight hexamethyldisiloxane-facilitated diffusion at room temperature using the F-ion-selective electrode and meter(Reference Taves24). Of these samples, 10 % were re-analysed for F concentration, giving a mean reproducibility of 99·6 %.

The creatinine concentration of each urine sample was measured by the Jaffe method(Reference Bonsnes and Taussky25) using an autoanalyser (ADIVA 1650; Siemens Medical Solutions Diagnostics).

Data preparation and analysis

F intake from toothpaste ingestion during toothbrushing was estimated by subtracting the F content of expectorated saliva/toothpaste from the amount of F initially loaded onto the brush during toothbrushing. F ingestion per brushing was then multiplied by the frequency of brushing (information at visit 1), to calculate the daily F intake from toothpaste for each child. Daily dietary F intake was estimated from the weight of each duplicate plate sample and the F concentrations of their aliquots. Since none of the children used any F supplements, total daily F intake (TDFI, in mg/d) was calculated by adding F intake from diet and F ingested from toothpaste.

Completeness of the 24 h urine samples was checked against two criteria: (1) the lower limits of 5 and 9 ml/h for urinary flow rate in < 6- and ≥ 6-year-olds(Reference Marthaler11), respectively, and (2) a lower limit of 11·3 mg/kg body weight (BW) per d for creatinine excretion(Reference Remer, Neubert and Maser-Gluth26). Any sample that did not meet either of these criteria was excluded from further analysis.

DUFE (mg/d) was estimated from the 24 h urine volume and F concentration of the urine sample. TDFI and DUFE were also calculated based on body weight (mg/kg BW per d). FUFE (%) was then calculated from the following equation:

$$\begin{eqnarray} FUFE\ (\%) = (DUFE/TDFI)\times 100. \end{eqnarray}$$

The data were analysed descriptively using SPSS version 17.0. The percentage of TDFI from diet and FUFE were calculated for each child, individually, before calculating the sample mean and standard deviation. The correlations between TDFI and DUFE and FUFE were examined by regression analysis and Pearson's correlation.

Results

Of the forty-four recruited, thirty-four children completed all aspects of the study. Data from one child were excluded because the urine sample was incomplete. Therefore, the final sample was thirty-three children.

F analysis of school water supply showed a mean F concentration of 0·30 (sd 0·12) μg/ml for twenty-one children (low-F group) and 1·06 (sd 0·11) μg/ml for twelve children (natural-F group). The mean F concentration of home water supply for the low-F group was 0·20 (sd 0·10) and 0·49 (sd 0·32) μg/ml for the natural-F group.

The mean age of the low-F and natural-F groups was 6·8 (sd 0·6) and 6·6 (sd 0·3) years, respectively (Table 2). Although the average body weight of the low-F group was heavier (25·4 kg) than that of the natural-F group (22·8 kg), the BMI values were similar: 16·1 and 15·8 kg/m2, respectively.

Table 2 Fluoride concentration of water supply, age, height, weight and BMI of children by fluoride area and sex (Mean values and standard deviations)

* 1·06 μg F/ml.

0·30 μg F/ml.

Data on F intake from diet and toothpaste ingestion are presented in Table 3. The mean dietary F intake for the natural-F group was 0·578 (sd 0·298) mg/d, while for the low-F group it was 0·341 (sd 0·254) mg/d. For the natural-F group, drinks provided 56 % of dietary F intake; in the low-F group, they provided 46 % of dietary F.

Table 3 Total daily fluoride intake (TDFI) from diet and toothpaste ingestion, daily urinary fluoride excretion (DUFE) and fractional urinary fluoride excretion (FUFE, %) for all participants (Mean values and standard deviations)

BW, body weight.

* 1·06 μg F/ml.

0·30 μg F/ml.

None of the children used F supplements or F tablets.

Approximately 71 % of children used a toothpaste labelled as children's toothpaste and 71 % also reported undertaking toothbrushing twice per d. On average, children ingested 51 % of the total amount of toothpaste dispensed onto the toothbrush; however, the range was very wide, from 2 to 97 %. The mean F intake from toothbrushing was 1·130 (sd 0·820) and 0·606 (sd 0·562) mg/d for the natural-F and low-F groups, respectively (Table 3).

None of the children in the present study took any F tablets or supplements. Diet and toothpaste ingestion were therefore the only sources of F intake for these children. The mean total daily F intake was 1·707 (sd 0·799) mg/d for the natural-F group and 0·945 (sd 0·621) mg/d for the low-F group. On a mg/kg BW basis, this represented 0·076 (sd 0·038) and 0·038 (sd 0·027) mg/kg BW per d for the natural-F and low-F groups, respectively. F intake from diet represented 41 and 44 % of total daily F intake for children in the natural-F and low-F groups, respectively.

Mean urine volumes for the natural-F and low-F groups were 547 (sd 304) and 607 (sd 314) ml, respectively (Table 3). Based on body weight, mean urinary F excretion was 0·017 (sd 0·007) mg/kg BW per d for the natural-F group and 0·012 (sd 0·006) mg/kg BW per d for the low-F group. FUFE was slightly lower in the natural-F group (30 %) compared with the low-F group (40 %). The relationship between TDFI and DUFE is presented in Fig. 1. No statistically significant correlation was found between TDFI and DUFE. There was a strong negative correlation between FUFE and TDFI (Pearson's correlation − 0·63), which was highly statistically significant (P< 0·001; Fig. 2).

Fig. 1 Relationship between total daily fluoride intake (TDFI) and daily urinary fluoride excretion (DUFE) for thirty-three children aged 6–7 years. Pearson's coefficient +0·22 (P= 0·22). DUFE = 0·047 (TDFI)+0·274. R 2 0·05.

Fig. 2 Relationship between total daily fluoride intake (TDFI) and fractional urinary fluoride excretion (FUFE) for thirty-three children aged 6–7 years. Pearson's coefficient − 0·63 (P< 0·001).

Discussion

The knowledge base regarding the usefulness of urinary F excretion as a tool in epidemiological surveillance for prediction of total F intake in children is inadequate. The present study demonstrated that urinary F might not be a reliable estimator for F intake in children aged 6–7 years as suggested previously.

In the present study, no child used F supplements or F tablets, and therefore diet and dentifrice ingestion were the main sources of total daily F intake for all children. In populations using F toothpaste, diet has been reported as contributing up to almost 80 % of ingested F(Reference Levy, Warren and Davis27). However, in the present study, toothpaste was the major component of TDFI, in both natural-F and low-F areas. Generally, toothpaste can make the largest percentage contribution to TDFI in children younger than 6 years, as they are not in full control of their swallowing reflex and therefore might swallow significant amounts of toothpaste unintentionally(28). At this age, the crowns of permanent teeth are still undergoing calcification and are therefore susceptible to the uptake of F into enamel apatite, and as a result, excess F intake can result in dental fluorosis(Reference Robinson, Connell and Kirkham29). The literature shows a wide variation in the contribution of F toothpaste to TDFI ranging from 22 % for 6-year-olds in Iowa(Reference Levy, Warren and Broffitt30) to 69 % for 4–5-year-olds in Puerto Rico(Reference Rojas-Sanchez, Kelly and Drake31). The differences in the contribution of toothpaste to TDFI in different studies could be explained by the differences in children ages, the F concentrations of the toothpastes used and the diet consumed, as well as the data collection methods and techniques used to measure F intake from these sources.

In the present study, mean daily F intake from drinks was substantially higher in the natural-F area compared with that in the low-F area, which confirms that the impact of F concentration of home water supply on total F intake may be decreasing due to the trend towards consumption of foods and drinks made outside the home(Reference Buzalaf and Whitford9).

The mean TDFI of children in the natural-F area (0·076 mg/kg BW per d) was slightly higher than the suggested optimum range of 0·05–0·07 mg/kg BW per d for optimal dental health benefit, whereas for children living in the low-F area, the TDFI (0·038 mg/kg BW per d) was below the optimum range. Therefore, in low-F communities, children might benefit from a community-based preventive programme such as milk fluoridation or supervised toothbrushing at schools.

The mean DUFE when expressed on a body-weight basis for the two groups of children was fairly similar, despite the considerable difference in TDFI between the groups (Table 3). The mean FUFE of children in the natural-F group (30 %) was lower than the corresponding value for children in the low-F area (40 %). The estimated FUFE varies widely in the literature from 32 % for 6–7-year-olds to 359 % for breast-fed infants (Table 1). There are several possible explanations for the wide range of reported FUFE. Almost 50 % of ingested F is absorbed from the stomach; however, several substances influence the degree of absorption. High dietary levels of fat may increase the absorption of ingested F since the fat reduces the rate of gastric emptying. In addition, foods containing appreciable amounts of divalent or trivalent cations (e.g. Ca, Mg, Fe) may reduce the degree of absorption due to the formation of insoluble complexes. The kidneys are the major route for the removal of F from the body and urinary pH can influence the renal clearance of F. When the tubular fluid is acidic, more ionic F is converted to hydrogen fluoride which is diffusible across the renal tubular epithelium. Differences in the composition of diet and the altitude of residence can significantly influence urinary pH, and consequently F excretion(Reference Buzalaf and Whitford9). Age, kidney maturation and body size (existing skeletal mass) are also important variables in F retention.

In a recent study, the relationship between urinary F excretion and TDFI was examined using previously published data on F intake and excretion in children and adults(Reference Villa, Anabalon and Zohouri32). This study showed a positive linear relationship between urinary F excretion and F intake with a slope of +0·35 and intercept of 0·03 in children, suggesting that urinary F excretion can be used to estimate daily F intake in children younger than 7 years. However, in the present study, daily urinary F excretion did not correlate with TDFI, and there was a lower slope of +0·05 and a higher intercept of 0·27. This result implies that for 6–7-year-old children living in an industrialised country, TDFI cannot be adequately predicted from urinary excretion of F, in contrast to the results of the former study. However, there are two main differences between these two studies; the present study was based on the data from only thirty-three children with a narrow age range (6–7-year-olds), whereas the former study included pooled data from 212 children with a wide age range from 0·19 to 7 years. The stage of bone maturation can influence the rate of uptake of F into bones and teeth. Since the rate of uptake is greater into newly formed bones, F retention would be greater during periods of rapid growth and development(Reference Buzalaf and Whitford9). The differences in urinary F excretion between different age groups of young children may be also attributed to the differences in their diet as well as dietary habits. For example, the absorption of F from ingested water is almost 100 %; however, when F is taken with milk, the degree of absorption might be reduced by up to 50 % due to the formation of CaF2 which has a low aqueous solubility(Reference Ekstrand and Ehrnebo33).

The negative correlation between FUFE and TDFI observed in the present study implies a higher F retention with increasing F intake. However, Fig. 2 suggests that FUFE remains almost constant above a TDFI of approximately 1·6 mg/d with the estimated FUFE reaching a limiting constant value independent of the magnitude of TDFI.

In conclusion, there was a statistically significant negative correlation between FUFE and TDFI, but no correlation between TDFI and DUFE, in 6–7-year-olds. Therefore, DUFE might not provide the basis for a reliable estimate of total F intake for 6–7-year-old children. However, this relationship should be investigated further in different age groups, separately, with larger sample sizes, in order to establish any conclusion on the use of DUFE as a reliable estimate of TDFI in children.

Acknowledgements

The present study was funded by The Borrow Foundation. A. M. and F. V. Z. designed the research and drafted the manuscript. R. W. and L. T. collected the information and samples. N. O. analysed the samples. I. N. S. provided the statistical support for the study. I. N. S. and F. V. Z. analysed the data. P. M. and D. L. were involved in the conceptualisation of the research and in the manuscript drafting. All authors read and approved the final manuscript. The authors have no conflict of interest to disclose.

References

1Featherstone, JDB (1999) Prevention and reversal of dental caries: role of low level fluoride. Community Dent Oral Epidemiol 27, 3140.CrossRefGoogle ScholarPubMed
2McDonagh, SM, Whiting, PF, Wilson, PM, et al. (2000) Systematic review of water fluoridation. BMJ 321, 855859.CrossRefGoogle ScholarPubMed
3Szpunar, S & Burt, B (1990) Fluoride exposure in Michigan schoolchildren. J Public Health Dent 50, 1823.Google Scholar
4Pendrys, DG & Stamm, JW (1990) Relationship of total fluoride intake to beneficial effects and enamel fluorosis. J Dent Res 69, 529538.CrossRefGoogle ScholarPubMed
5Pitts, NB, Boyles, J, Nugent, ZJ, et al. (2007) The dental caries experience of 5-year-old children in Great Britain (2005/6). Surveys co-ordinated by the British Association for the study of community dentistry. Community Dent Health 24, 5963.Google Scholar
6Pitts, NB, Boyles, J, Nugent, ZJ, et al. (2006) The dental caries experience of 11-year-old children in Great Britain. Surveys co-ordinated by the British Association for the study of community dentistry. Community Dent Health 23, 4457.Google Scholar
7Pitts, NB, Boyles, J, Nugent, ZJ, et al. (2004) The dental caries experience of 14-year-old children in England and Wales. Surveys co-ordinated by the British Association for the study of community dentistry. Community Dent Health 21, 4557.Google Scholar
8Heilman, JR, Kiritsy, MC, Levy, SM, et al. (1999) Assessing fluoride levels of carbonated soft drinks. J Am Dent Assoc 130, 15931599.Google Scholar
9Buzalaf, MAR & Whitford, GM (2011) Fluoride metabolism. In Fluoride and the Oral Environment: Monographs in Oral Science. Basel: Karger.CrossRefGoogle Scholar
10World Health Organisation (1994) Fluoride and Oral Health. WHO Expert Committee on Oral Health Status and Fluoride Use Report Series no. 846. Geneva: WHO.Google Scholar
11Marthaler, TM (1999) Monitoring of Renal Fluoride Excretion in Community Preventive Programmes on Oral Health. Geneva: World Health Organization.Google Scholar
12Marthaler, TM, Steiner, M, Menghini, G, et al. (1995) Urinary fluoride excretion in children with low fluoride intake or consuming fluoridated salt. Caries Res 29, 2634.Google Scholar
13Brunetti, A & Newbrun, E (1983) Fluoride balance of children 3 and 4 years old. Caries Res 17, 171.Google Scholar
14Zohouri, FV & Rugg-Gunn, AJ (2000) Total fluoride intake and urinary excretion in 4-year-old Iranian children residing in low-fluoride areas. Br J Nutr 83, 1525.Google Scholar
15Villa, A, Anabalon, M & Cabezas, L (2000) The fractional urinary fluoride excretion in young children under stable fluoride intake conditions. Community Dent Oral Epidemiol 28, 344355.CrossRefGoogle ScholarPubMed
16Haftenberger, M, Viergutz, G, Neumeister, V, et al. (2001) Total fluoride intake and urinary excretion in German children aged 3–6 years. Caries Res 35, 451457.Google Scholar
17Franco, AM, Saldarriaga, A, Martignon, S, et al. (2005) Fluoride intake and fractional urinary fluoride excretion of Colombian preschool children. Community Dent Health 22, 272278.Google Scholar
18Maguire, A, Zohouri, FV, Hindmarch, PN, et al. (2007) Fluoride intake and urinary excretion in 6- to 7-year-old children living in optimally, sub-optimally and non-fluoridated areas. Community Dent Oral Epidemiol 35, 479488.Google Scholar
19Zohouri, FV, Swinbank, CM, Maguire, A, et al. (2006) Is the fluoride/creatinine ratio of a spot urine sample indicative of 24-h urinary fluoride? Community Dent Oral Epidemiol 34, 130138.CrossRefGoogle ScholarPubMed
20Ekstrand, J, Hardell, LI & Spak, CJ (1984) Fluoride balance studies on infants in a 1-ppm-water-fluoride area. Caries Res. 18, 8792.Google Scholar
21Ekstrand, J, Ziegler, EE, Nelson, SE, et al. (1994) Absorption and retention of dietary and supplemental fluoride by infants. Adv Dent Res 8, 175180.Google Scholar
22Guha-Chowdhury, N, Drummond, BK & Smillie, AC (1996) Total fluoride intake in children aged 3 to 4 years: a longitudinal study. J Dent Res 75, 14511457.CrossRefGoogle ScholarPubMed
23Martínez-Mier, EA, Cury, JA, Heilman, JR, et al. (2011) Development of gold standard ion-selective electrode-based methods for fluoride analysis. Caries Res 45, 312.Google Scholar
24Taves, D (1968) Separation of fluoride by rapid diffusion using hexamethyldisiloxane. Talanata 15, 969974.Google Scholar
25Bonsnes, R & Taussky, H (1945) The colorimetric determination of creatinine by the Jaffe reaction. J Biol Chem 158, 581591.Google Scholar
26Remer, T, Neubert, A & Maser-Gluth, C (2002) Anthropometry-based reference values for 24-h urinary creatinine excretion during growth and their use in endocrine and nutritional research. Am J Clin Nutr 75, 561569.Google Scholar
27Levy, SM, Warren, JJ, Davis, CS, et al. (2001) Patterns of fluoride intake from birth to 36 months. J Public Health Dent 61, 7077.CrossRefGoogle ScholarPubMed
28Maternal and Child Health Bureau (2007) Topical Fluoride Recommendations for High-risk Children Development of Decision Support Matrix. Washington, DC: MCBH.Google Scholar
29Robinson, C, Connell, S, Kirkham, J, et al. (2004) The effect of fluoride on the developing tooth. Caries Res 38, 268276.CrossRefGoogle ScholarPubMed
30Levy, SM, Warren, JJ & Broffitt, B (2003) Patterns of fluoride intake from 36 to 72 months of age. J Public Health Dent 63, 211220.Google Scholar
31Rojas-Sanchez, F, Kelly, SA, Drake, KM, et al. (1999) Fluoride intake from foods, beverages and dentifrice by young children in communities with negligibly and optimally fluoridated water: a pilot study. Community Dent Oral Epidemiol 27, 288297.Google Scholar
32Villa, A, Anabalon, M, Zohouri, V, et al. (2010) Relationships between fluoride intake, urinary fluoride excretion and fluoride retention in children and adults: an analysis of available data. Caries Res 44, 6068.Google Scholar
33Ekstrand, J & Ehrnebo, M (1979) Influence of milk products on fluoride bioavailability in man. Eur J Clin Pharmacol 16, 211215.Google Scholar
Figure 0

Table 1 Summary of the literature on total daily fluoride intake (TDFI), daily urinary fluoride excretion (DUFE) and fractional urinary fluoride excretion (FUFE) by age group and country

Figure 1

Table 2 Fluoride concentration of water supply, age, height, weight and BMI of children by fluoride area and sex (Mean values and standard deviations)

Figure 2

Table 3 Total daily fluoride intake (TDFI) from diet and toothpaste ingestion, daily urinary fluoride excretion (DUFE) and fractional urinary fluoride excretion (FUFE, %) for all participants (Mean values and standard deviations)

Figure 3

Fig. 1 Relationship between total daily fluoride intake (TDFI) and daily urinary fluoride excretion (DUFE) for thirty-three children aged 6–7 years. Pearson's coefficient +0·22 (P= 0·22). DUFE = 0·047 (TDFI)+0·274. R2 0·05.

Figure 4

Fig. 2 Relationship between total daily fluoride intake (TDFI) and fractional urinary fluoride excretion (FUFE) for thirty-three children aged 6–7 years. Pearson's coefficient − 0·63 (P< 0·001).