Fluoride (updated 2017)

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Table of updates and amendments

The table provides details about amendments made to fluoride intake recommendations, which include the AI (Adequate Intake) and UL (Upper Limit) for children aged 0-8 years.
Amendment type Amendment detail Date updated Version number

Revision of fluoride NRVs as follows:

  • AI for children 0-8 years
  • UL for children 0-8 years

Amendments to the resources across the NRV suite have been made to reflect the latest scientific evidence and recommendations.

NHMRC approved the revised NRV recommendations for fluoride on
21 November 2016 under Section 14A
of the NHMRC Act 1992.
The supporting material including the
Methodological Framework, any literature
reviews and evidence summaries are authored
by the Australian Government Department of
Health and Aged Care (formerly the Department of Health
and Ageing) and the New Zealand Ministry
of Health.
www.eatforhealth.gov.au/nutrient-reference-values/resources
n35-n36-n37
March 2017 1.1

Update 1.1: revision of fluoride (2017)

The fluoride AI and UL for 0-8 year olds were approved by the Chief Executive Officer of the National Health and Medical Research Council on 21 November 2016, under Section 14A of the National Health and Medical Research Council Act 1992.

Australia and New Zealand have pursued public health policy to adjust fluoride intake at the population level with the aim of preventing dental caries. It is considered desirable to have a fluoride intake that is sufficient to prevent dental caries (an AI) without exceeding intakes that are associated with severe dental fluorosis (a UL). The AI and UL refer to habitual intake of fluoride and are used to assess fluoride intakes at a population level.

Fluoride was identified as a priority for review, given recent estimates of fluoride intakes in Australia and New Zealand have suggested that the fluoride intake of a substantial proportion of infants and young children may exceed the UL set in 2006, without widespread occurrence of moderate or severe dental fluorosis, suggesting the UL needed revising. The scope of the review was narrowed to an AI and UL for fluoride for infants and young children up to eight years of age, as this is the period of time in which permanent teeth are formed and therefore the critical age group to consider for dental caries and fluorosis.

The supporting material including the 2017 technical report containing the literature review and evidence summaries can be found on the resources page.

The recommendations for the revised AI and UL for fluoride for 0-8 year olds have no implications for the current Drinking Water Guidelines in Australia, the current Drinking Water Standards for New Zealand or for recommendations on fluoride ingestion from toothpaste.

The AIs and ULs for children and adolescents over 8 years of age, adults, pregnant and lactating women were not reviewed and remain as per the 2006 NRVs for Australia and New Zealand. This publication has been revised to incorporate the revised AIs and ULs for infants and children up to 8 years of age.

Background

Fluoride is naturally present in the food and drink we consume and is considered a normal constituent of the human body. The fluoride concentration in bones and teeth is about 10,000 times that in body fluids and soft tissues (Bergmann and Bergmann 1991; 1995). Nearly 99% of the body’s fluoride is bound strongly to calcified tissues. Fluoride in bone appears to exist in both rapidly and slowly exchangeable pools.

Fluoride is ingested from several sources including foods, fluoridated and unfluoridated water, fluoridated toothpastes and some dietary supplements. Fluoride intake from most foods is low. Both inadequate and excessive fluoride intakes can affect dental health.Inadequate intakes are associated with increased tooth decay (dental caries) and excessive intakes with damage to tooth enamel (dental fluorosis).

Fluoride available systemically during tooth development is incorporated into teeth as fluorapatite in tooth enamel. Fluorapatite in tooth enamel alters its crystalline structure, reducing the solubility of enamel to acid dissolution, or demineralisation. At higher fluoride intakes the crystalline structure may be disrupted during tooth development periods, forming porosities which are the basis of dental fluorosis, a change in the cosmetic appearance of teeth (Aoba 1997, Fejerskov et al. 1994, Aoba and Fejerskov 2002). Moderate dental fluorosis is uncommon and severe dental fluorosis is rare in Australia and New Zealand. Prolonged exposure to very high fluoride intakes can result in outcomes such as skeletal fluorosis and bone fractures, however there have been no reported cases in Australia (Jack et al. 2016).

Fluoride at the surface of enamel can also form calcium fluoride, a more rapidly exchangeable pool of fluoride to alter the demineralisation-remineralisation balance, which is the dynamic process underlying dental decay (Aoba 1997, Fejerskov et al. 1994, Aoba and Fejerskov 2002). Tooth decay (dental caries) is a largely preventable but highly prevalent chronic disease in Australian and New Zealand children and adults. It remains the most common form of childhood infection and creates a significant health burden (Do and Spencer 2016). The fluoridation of drinking water aims to bring fluoride levels up to a range that can help to prevent or minimise tooth decay by 26-44% in children, teenagers and adults (Jack et al.2016).

2017 reference body weight data 0-8 years

The fluoride AI and UL for 0-8 year olds were updated in 2017. The following updated reference bodyweights were used when the NRVs were expressed in mg fluoride/day; 0-6 months 6 kg, 7-12 months 9 kg, 1-3 years 12 kg, 4-8 years 22 kg.

The most recent United States reference bodyweight data (IOM 2005) was used for infants and young children aged 1-3 years (mean bodyweight of 12 kg), as no suitable Australian and New Zealand data were available.

New reference bodyweight data was derived from the 2011-2012 Australian Health Survey (AHS) and the 2011-12 New Zealand Health Survey for Australian and New Zealand children aged 4-8 years (ABS 2014) and rounded up to the nearest whole number, resulting in a mean bodyweight of 22 kg for children aged 4-8 years.

Recommendations by life stage and gender

Infants and young children

The table outlines fluoride intake recommendations for different age groups, specifically infants and children.
Age AI
0-6 months* -
7-12 months* 0.5 mg/day#
1-3 yr* 0.6 mg/day
4-8 yr* 1.1mg/day

* The fluoride AI and UL for 0-8 year olds were updated in 2017. The following reference body weights were used when the 2017 NRVs for infants and young children aged 0-8 years were expressed in mg fluoride/day; 0-6 months 6 kg, 7-12 months 9 kg, 1-3 years 12 kg, 4-8 years 22 kg.
# Rounded to the first decimal place

Rationale: The purpose of the AI for infants and young children is to provide information on the level of intake that provides protection from inadequate intake, which in the case of fluoride results in
increased risk of dental caries.

An AI has not been established for infants less than six months of age: The review of evidence did not
find a preventive effect (reduction in dental caries) with fluoride intake in the first six months of life.
This is in line with the view expressed by the Institute of Medicine (IOM) in 1997 and supported by
the American Dental Association’s Council on Scientific Affairs statement in 2011 that the preventive
effect of fluoride in the first six months of life has not been established.

This does not impact on infant formula composition.

AI for 6 months to 8 years of age: A reduction in the prevalence and severity of dental caries associated
with communities having fluoridated water (approx. 1 mg F/L) has been confirmed by numerous
epidemiological studies conducted in several countries throughout the world (Murray et al. 1991,
McDonagh et al. 2000, Rugg-Gunn and Do 2012). The average daily dietary intake of fluoride under
conditions that results in near maximal caries prevention is approximately 0.05 mg /kg/ day and as
such the AI of 0.05 mg F/kg bw/day was reaffirmed to be an intake likely to be associated with
appreciably reduced rates of dental caries in a population for infants aged 6 months and over and
young children up to 8 years.

Children & adolescents

This table presents fluoride intake recommendations for children and adolescents.
Age AI
Boys
9-13 yr 2.0 mg/day
14-18 yr 3.0 mg/day
Girls
9-13 yr 2.0 mg/day
14-18 yr 3.0 mg/day

Rationale: The AI for 9-18 year olds were not reviewed in the 2017 update.The AI for children is based on the requirement of 0.05 mg/kg body weight/day and adjusted for the standard body weights of 40 kg for 9-13 year olds, 64 kg for boys aged 14-18 years and 57 kg for 14-18 year-old girls. Supplements may be necessary for children in non-fluoridated areas, (Burt 1992).

Adults

This table outlines fluoride intake recommendations for adults based on different age groups and genders.
Age AI
Men
19-30 yr 4 mg/day
31-50 yr 4 mg/day
51-70 yr 4 mg/day
>70 yr 4 mg/day
Women
19-30 yr 3 mg/day
31-50 yr 3 mg/day
51-70 yr 3 mg/day
>70 yr 3 mg/day

Rationale: The AI for adults was not reviewed in the 2017 update. The AI for adults is based on the requirement of 0.05 mg/kg body weight/day outlined above and adjusted for the standard body weights of 76 kg for men and 61 kg for women.

Pregnancy

This table provides fluoride intake recommendations for pregnant individuals across different age groups.
Age AI
14-18 yr 3 mg/day
19-30 yr 3 mg/day
31-50 yr 3 mg/day

Rationale: The AI for pregnancy was not reviewed in the 2017 update. There is no evidence that requirements in pregnancy are greater than those of the non-pregnant woman.

Lactation

This table outlines copper intake recommendations for individuals during the lactation stage across different age groups.
Age AI
14-18 yr 3 mg/day
19-30 yr 3 mg/day
31-50 yr 3 mg/day

Rationale: The AI for lactation was not reviewed in the 2017 update. There are no studies of the metabolism of fluoride in pregnancy. Fluoride concentrations in milk are very low and fairly insensitive to differences in the fluoride concentration of maternal drinking water. The AI is not greater than that of women in the non-pregnant, non-lactating state.

Upper level of intake

This table provides upper level recommendations for fluoride intake across different age groups.
Age UL
Infants and young children
0-6 months* 1.2 mg/day
7-12 months* 1.8 mg/day
1-3 yr* 2.4 mg/day
4-8 yr* 4.4 mg/day
* The fluoride AI and UL for 0-8 year olds were updated in 2017. The following reference body weights were used when the 2017NRVs for infants and young children aged 0-8 years were expressed in mg fluoride/day; 0-6 months 6 kg, 7-12 months 9 kg, 1-3 years 12 kg, 4-8 years 22 kg.  

Rationale: 

The purpose of the UL is to provide information on the upper level of intake above which the risk of an adverse effect increases, in the case of fluoride, severe dental fluorosis. The estimated UL for fluoride, based on the endpoint of enamel pitting or loss and visible as severe dental fluorisis is 0.20 mg/kg bw/day for children aged 0 to 8 years. The UL is based on the 95th percentile of fluoride intake (representative of high consumers) and a theoretical water fluoridation level of drinking water of 1.9 mg fluoride/litre (beyond which several enamel fluorosis is likely to appear). Beyond 8 years of age, when the enamel forms on permanent teeth, the ingestion of fluoride does not cause further developmental changes to teeth.

 

Upper Level 0-6 month olds: The UL for the 0-6 month age range is primarily focused on fluoride intake among infant formula fed and complementary fed infants, as the review of evidence found that breast milk is low in fluoride and fluoride intakes for breastfed infants of this age are unlikely to exceed the UL. The mean bodyweight of 6 kg was applied for 0-6 month olds when expressed in mg fluoride/day.

 

Infant formula sold in Australia and New Zealand contains very low amounts of fluoride (reported
0.07 mg fluoride/kg) (Clifford et al. 2009). Guidance is given in the Australia New Zealand Food Standards

Code for labelling infant formula products in relation to fluoride content. A labelling statement on the package is required if the fluoride concentration is more than 17 μg/100 kJ in powdered or concentrated product prior to reconstitution, or more than 0.15 mg/100 mL (1.5 mg fluoride/L) in ready to drink formula products. This statement should indicate that consumption of the formula has the potential to cause dental fluorosis plus a statement recommending that the risk of dental fluorosis should be discussed with a medical practitioner or other health professional (FSANZ 2016).

 
Children and Adolescents
9-13 yr 10.0 mg/day
14-18 yr 10.0 mg/day
Adults 19+ yr
Men 10.0 mg/day
Women 10.0 mg/day
Pregnancy
All ages 10.0 mg/day
Lactation
All ages 10.0 mg/day

Rationale: The UL for 9 year olds and over were not reviewed in the 2017 update.The UL was set on the basis of moderate enamel fluorosis. A LOAEL of 0.10 mg/kg body weight for infants and children up to 8 years was set on the basis of community studies (Dean 1942, FNB:IOM 1997). A UF of 1 was applied, as the adverse effect is cosmetic rather than functional. For older children and adults, a NOAEL of 10 mg/day was derived based on data on the relationship between fluoride intake and skeletal fluorosis (FNB:IOM 1997, Leone et al 1954, 1955, McCauley & McClure 1954, Schlesinger et al 1956, Sowers et al 1986, Stevenson & Watson 1957). A UF of 1 was selected, as there are no signs of symptomatic skeletal fluorosis at this level of intake. No data exist to show increased susceptibility in pregnancy or lactation, so the same UL was adopted.

References

Australian Bureau of Statistics 2014. Ideal bodyweights (calculated), customised report, Commonwealth of Australia
Bergmann KE, Bergmann RL. Salt fluoridation and general health. Adv Dent Res 1995; 9:138-43.

Bergmann RL, Bergmann KE. Fluoride nutrition in infancy - is there a biological role of fluoride for growth? In: Chandra RK, ed. Trace elements in nutrition of children II. Nestle Nutrition Workshop Series, Vol 23. New York: Raven Press, 1991. Pp 105-17.

Burt BA. The changing patterns of systemic fluoride intake. J Dent Res 1992;71:l228-37.

Chowdhury NG, Brown RH, Shepherd MG. Fluoride intake of infants in New Zealand. J Dent Res 1990;69:1828-33.

Clifford H, Olszoury H, Young M, Hegart J, Cross M 2008. Flouride content of powdered infant formula
meets Australian Food Safety Standards, Aust NZ J Public Health, 33(6):573-576.

Dabeka RW, Karpinski KF, McKenzie AD, Bajdik CD. Survey of lead, cadmium and fluoride in human milk and correlation of levels with environmental and food factors. Food Chem Toxicol 1986;24:913-21.

Dean HT. The investigation of physiological effects by the epidemiological method. In: Moulton FR, ed. Fluorine and dental health. Washington, DC: American Association for the Advancement of Science, 1942. Pp 23-31.

Food and Nutrition Board: Institute of Medicine. Dietary Reference Intakes for calcium, phosphorus, magnesium, vitamin D and fluoride. Washington DC: National Academy Press, 1997.

Leone NC, Shimkin MB, Arnold FA, Stevenson CA, Zimmerman ER, Geiser PB, Lieberman JE. Medical aspects of excess fluoride in a water supply. Publ Hlth Rep 1954;69:
925-36.

Leone NC, Stevenson CA, Hilbish TF, Sosman MC. A roentgenologic study of a human population exposed to high-fluoride domestic water: a ten-year study. Am J Roentg 1955;74:874-85.

McCauley HB, McClure FJ. Effect of fluoride in drinking water on the osseous development of the hand and wrist in children. Pub Hlth Rep 1954;69:671-83.

Ministry of Health. No date. Frequently Asked Questions about Fluoridation http://www.moh.govt.nz/moh.nsf/wpg_Index/About-Fluoridation and
http://www.moh.govt.nz/moh.nsf/0/de19679af662e1d0cc256e3e0071744a? 
Open Document. https://www.health.govt.nz/our-work/preventative-health-wellness/fluoride-and-oral-health

Schlesinger ES, Overton DE, Riverhead LI, Chase HC, Cantwell KT. Newburgh-Kingston caries-fluorine study XIII. Pediatric findings after ten years. J Am Dent Assoc 1956;52:296-306.

Silva M, Reynolds EC. Fluoride content of infant formulae in Australia. Aust Dent J 1996;41:37-42.

Sowers M, Clark MK, Jannausch ML, Wallace RB. A prospective study of bone mineral content and fractures in communities with differential fluoride exposure. Am J Epidemiol 1991;133:649-60.

Stevenson CA, Watson AR. Fluoride osteosclerosis. Am J Roentg Rad Ther Nucl Med 1957;78:13-8.