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Zinc status of northern Tasmanian adults

Published online by Cambridge University Press:  20 April 2015

Jeffrey M. Beckett  and
Madeleine J. Ball
Jeffrey M. Beckett*
Affiliation:
School of Health Sciences, University of Tasmania, Launceston, Australia
Madeleine J. Ball
Affiliation:
School of Health Sciences, University of Tasmania, Launceston, Australia
*
*Corresponding author: Dr J. M. Beckett, fax +61 363243995, email jbeckett@utas.edu.au

Abstract

Information regarding Zn status in the Australian population is very limited. Mild deficiencies in Zn have been associated with CVD, impaired immune function and poor healing. A cross-sectional study of 497 northern Tasmanian adults (24–82 years of age) was conducted to assess Zn status. Dietary intakes were assessed by FFQ and serum concentrations of Zn were evaluated using International Zinc Nutrition Consultative Group methodology. Mean Zn intakes were 12·6 (sd 4·4) mg/d for men and 10·9 (sd 3·6) mg/d for women. It was found that 52 % of men but only 9 % of women consumed less than the Australia/New Zealand estimated average requirement for Zn. Mean serum Zn was 13·0 (sd 2·4) µmol/l in men and 13·0 (sd 2·5) µmol/l in women. Overall, 15 % of men and 7 % of women had low serum Zn levels. Furthermore, low serum Zn was observed in 18 % of men 50 years or older and 30 % of men 70 years or older. The present results suggest that mild Zn deficiency may be prevalent in older Tasmanian adults, particularly men; and due to the importance of Zn in many areas of health, this could be of public health concern.

Keywords

Zinc statusPopulation studiesAustralia
Type
Research Article
Information
Journal of Nutritional Science , Volume 4 , 2015 , e15
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/3.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
Copyright © The Author(s) 2015

Conservative estimates place approximately 20 % of the world's population at risk of Zn deficiency( Reference Sanghvi, Van Ameringen and Baker 1 ). While it is a significant cause of morbidity in many developing countries, in developed countries information regarding the prevalence of Zn deficiency is more limited.

There is a paucity of data relating to the Zn status of Australians. As noted in a recent review of the literature concerning Zn status in Australia and New Zealand( Reference Gibson and Heath 2 ), even in population groups considered ‘at risk’ there are few studies that have assessed Zn status. Published studies are generally limited by size, have sampled only specific population groups (for example, infants, institutionalised elderly populations) or only report Zn intakes( Reference Gibson and Heath 2 ).

Studies that have assessed a broader range of healthy, community-dwelling adults in Australia have mostly reported Zn intakes only( Reference English, Najman and Bennett 3 Reference Horwath 7 ), with few reporting serum Zn data( Reference Ball and Ackland 8 , Reference Baghurst, Dreosti and Syrette 9 ). As even the most recent of these Australian studies was reported a decade ago, they also pre-date the introduction of current procedures recommended by the International Zinc Nutrition Consultative Group (IZiNCG) for the assessment of Zn status; which include standardised collection procedures and age/sex/time of day-specific cut-off values for serum Zn( Reference Brown, Rivera and Bhutta 10 ), making interpretation of the data difficult. Finding suitable biomarkers for Zn status in large study cohorts remains troublesome; various biomarkers have been investigated, such as leucocyte Zn( Reference Whitehouse, Prasad and Rabbani 11 ), lymphocyte ecto-5'nucleotidase( Reference Meftah, Prasad and Lee 12 ) as well as hair and urinary Zn. However, a 2009 systematic review suggests that serum Zn, when collected in controlled conditions, remains as perhaps the most convenient and reliable biomarker for assessing Zn status in population studies( Reference Lowe, Fekete and Decsi 13 ). Serum Zn is sensitive to acute-phase responses, feeding state and time of day, and varies with sex and age. Collection systems are also vulnerable to contamination with exogenous Zn and so the methods outlined by IZiNCG are designed to control these various factors.

In addition to Zn intake, other dietary factors, such as meat and in particular the phytate content of the diet, can influence the bioavailability of Zn. Phytate has been observed to be a particular problem in developing countries in which diets are low in animal-based foods and rich in phytate-containing unrefined grains, cereals and legumes( Reference Schlemmer, Frolich and Prieto 14 ). Although dietary fibre has also been thought to negatively affect Zn absorption it is likely that such a relationship was observed due to phytate generally being found in fibre-rich foods; research has shown that fibre in the absence of phytate has little influence on Zn absorption( Reference Lonnerdal 15 ). Even mild Zn deficiencies may be associated with increased morbidity, involving alterations in immune function( Reference Ibs and Rink 16 ) and delayed wound healing( Reference Lansdown, Mirastschijski and Stubbs 17 ); Zn insufficiency has been associated with neural tube defects( Reference Velie, Block and Shaw 18 ) and is considered by the WHO as a candidate for prenatal programming of chronic disease in later life( Reference Delisle 19 ).

Tasmania has a history of suboptimal or marginal status in other micronutrients such as iodine( Reference Guttikonda, Burgess and Hynes 20 ) and Se( Reference McGlashan, Cook and Melrose 21 , Reference Beckett and Ball 22 ), but there is very little information about the status of other trace elements in the Tasmanian population. The population is ageing and has high rates of chronic disease( 23 ). Due to the lack of data relating to Zn status in Tasmanian populations, this cross-sectional study was undertaken to determine the Zn status of an adult population sample from northern Tasmania and identify any population groups that may be at risk of suboptimal status.

Methods and materials

Study population

This was a cross-sectional population study. The participants for the study were apparently healthy community-dwelling adults residing in the main population centres in north, northwest and northeastern Tasmania. Recruitment was by way of a mail-out to a random sample of adults taken from an extract of the Australian electoral roll provided by the Australian Electoral Commission. The study was conducted according to the guidelines laid down in the Declaration of Helsinki, and all procedures involving human subjects were approved by the Human Research Ethics Committee, Tasmania (reference no. H0009038). Written informed consent was obtained from all participants.

Sample collection and preparation

Participants completed questionnaires to provide demographic and anthropometric information. A semi-quantitative FFQ( Reference Giles and Ireland 24 ) which uses Australian food content tables, was used to collect dietary data. The socio-economic status of participants was estimated by using the SEIFA (Socio-Economic Indexes for Areas) index for the area (ABS Collector District) in which each subject resided. The SEIFA index is derived from Australian Census variables related to advantage and disadvantage, including households with low or high income, unemployment rates and proportions of individuals with limited or higher education( 25 ). A lower SEIFA score in a Census district indicates that the district is relatively disadvantaged compared with one with a higher score.

Participants attended phlebotomy centres to provide a morning, non-fasting, venous blood sample, collected into trace element-free Vacutainer tubes without anticoagulant (Becton Dickinson). Following collection, blood samples were separated by refrigerated centrifugation for 15 min at 1335 g . Samples of serum were stored at –80°C until analysis. All laboratory glassware, consumables and storage vessels used during Zn analysis were acid washed (1 % HNO3) before use.

Analytical methods

Serum Zn concentrations were determined by flame atomic absorption spectrometry using a Spectra 880 spectrophotometer (Varian Inc.) and the method of Meret & Henkin( Reference Meret and Henkin 26 ). Analysis of Seronorm controls (Sero) with assayed Zn concentrations of 14·0 and 16·1 µmol/l gave means of 13·0 (CV 4·8 %; n 38) and 17·8 µmol/l (CV 4·0 %; n 38). Intra-assay precision was 3·5 % (n 13). Serum α-1 acid glycoprotein (AGP) was determined by an immunoturbidimetric method on a Konelab 20XT autoanalyser (Thermo Fisher Scientific) using Dako anti-AGP antibody. Analysis of Dako controls with AGP concentrations of 0·58 and 1·52 g/l gave means of 0·63 (CV 2·1 %; n 13) and 1·44 g/l (CV 1·8 %; n 13), respectively. Intra-assay precision was 2·2 % (n 20).

Statistical analysis

Differences in Zn status within age and sex groups were estimated using general linear modelling (GLM) with robust standard error estimation (STATA version SE12; StataCorp LP). Post-estimation Holm's test analysis was used to adjust P values for multiple comparisons( Reference Aickin and Gensler 27 ). Associations between serum Zn and Zn intake, monounsaturated fat intake, age, socio-economic status and BMI were estimated using GLM. Selection of variables for inclusion in a multivariate model was performed using stepwise regression from: Zn intake, fat, protein and carbohydrate intake, age, socio-economic status, BMI and sex. The validity of regression assumptions was tested by post hoc analysis to exclude significant heteroskedasticity and missing variable effects.

Sample serum Zn concentrations were compared with the accepted sex/age cut-off values of 10·7 µmol/l for men and 10·1 µmol/l for women, as recommended by IZiNCG( Reference Brown, Rivera and Bhutta 10 ). Most analyses used raw dietary intake data; however, as data were collected from a single time point, an adjusted estimate of the prevalence of low intakes was made, accounting for intra-individual variation, with an assumed CV of 25 %, as per IZiNCG's recommended methodology( 28 ).

As serum Zn is known to be reduced in subclinical infection or inflammation, serum AGP > 1·2 g/l was used as an indicator of current infection/inflammation. Due to the variation in response from different age and sex subgroups in the study sample, a population estimate was made using data from the 2006 Australian Census for this region, weighted for age, sex and socio-economic status.

Results

Subject characteristics

Subject characteristics are presented in Table 1. The study sample was comprised of 497 adults from northern Tasmania (191 men and 306 women) with a mean age of 57·4 (sd 12·3) years. Decadal age groups were 20–29 years (n 14), 30–39 years (n 36), 40–49 years (n 76), 50–59 years (n 128), 60–69 years (n 160), 70–79 years (n 81) and 80–89 years (n 2). Of the individuals who reported existing health conditions, the major conditions were hypertension (25 %) and arthritis (19 %); the most commonly reported medications used were anti-hypertensives (24 %), cholesterol-lowering drugs (16 %) and anticoagulants (12 %).

Table 1. Characteristics of the study subjects

(Mean values, standard deviations and ranges)

* Estimated average requirement: 12·0 mg/d for men; 6·5 mg/d for women( Reference Beckett and Ball 22 ).

Mean contributions to total energy among the cohort for carbohydrate was 44 %, fats 34 % (saturated 14 %; monounsaturated 12 %; polyunsaturated 5 %) and protein 19 %. Major food sources of energy were dairy product-based foods 23 %, cereal-based foods 22 %, meat fish and poultry 14 % and fruit and vegetables 18 %. Mean dietary fibre was 26·7 g/d in men, and 21·1 g/d in women, less than the Australian adequate intake of 30 g/d and 25 g/d, respectively. The FFQ used in the present study did not specifically assess phytate levels and Australian food tables do not contain information on phytate content. Tasmanians, however, consume a modern Western diet in which phytate-rich food such as unleavened breads are rare and unrefined grains and seeds are consumed in relatively low amounts.

Dietary zinc intake

Mean intakes of Zn were 12·6 (sd 4·4) mg/d for men and 10·9 (sd 3·6) mg/d for women. Overall, 26 % of the study sample consumed less than the Australian/New Zealand estimated average requirement (EAR) for Zn. Of the men, 52 % consumed less than the EAR for adult males (12 mg/d)( 29 ). The proportion of men that consumed less than the EAR increased with age. The lowest proportion was observed in the 20–29 years age range (20 %); increasing to 36 % (30–39 years), 46 % (40–49 years), 45 % (50–59 years), 54 % (60–69 years), 71 % (70–79 years) and 100 % in the 80–89 years age range.

Of the women, 9 % consumed less than the EAR for adult females of 6·5 mg/d. A trend for increasing proportions of low intakes with age was not observed in women; no women in the youngest or oldest age range consumed less than the EAR and the greatest proportion of women to do so were aged 40–49 years (12 %). Similar proportions of low intakes were observed in the remaining age ranges: 30–39 years, 8 %; 50–59 years, 10 %; 60–69 years, 8 %; 70–79 years, 8 %.

After adjusting for intra-individual variation (CV of 25 %)( 28 ), it was estimated that approximately 42·3 % of men and 5·4 % of women had Zn intakes below the EAR.

The major food groups contributing to Zn intakes were meat, fish and poultry, cereal products, legumes and nuts, vegetables and dairy products. Meat, fish and poultry made a significantly higher contribution to Zn intakes in men than in women (31·6 v. 26·3 %; 95 % CI of difference 3·1 to 7·2; P < 0·001), while vegetables (19·4 v. 16·8 %; 95 % CI of difference 1·2 to 3·9; P < 0·001), dairy products (20·1 v. 16·3 %; 95 % CI of difference 2·2 to 5·5; P < 0·001) and fruit (6·7 v. 5·2 %; 95 % CI of difference 0·8 to 2·1; P < 0·001) made greater contributions to Zn intakes for women.

Significantly higher vegetable consumption was observed in men older than 45 years compared with those younger than 45 years (359 v. 302 g; 95 % CI of difference 15 to 99; P = 0·008). This resulted in a significantly increased contribution to overall Zn intake from vegetables in men older than 45 years compared with younger men (17·9 v. 12·2 %; 95 % CI of difference 3·9 to 7·4; P < 0·001). The consumption of meat (132 v. 150 g; 95 % CI of difference –2 to 39; P = 0·07) and the proportion of Zn contributed by meat sources tended to be lower in the older men (31 v. 35 %; 95 % CI of difference –0·8 to 7·9; P = 0·11) but the differences did not reach statistical significance.

Other associations with zinc status

Selection of measured variables associated with serum Zn using stepwise regression (Table 2) revealed positive associations with dietary Zn intake (P = 0·036) and BMI (P = 0·015), while monounsaturated fat intake, age and socio-economic status were negatively associated with serum Zn (all P < 0·02). There was no significant association between dietary fibre and serum Zn (P = 0·89).

Table 2. Multivariate analysis: association between mean serum zinc and variables selected by stepwise regression*

SEIFA, Socio-Economic Indexes for Areas.

* The effect of dietary Zn intake, BMI, dietary monounsaturated fat, age and socio-economic status (SEIFA) (as standardised normal transformations) was estimated using general linear modelling. Variables were selected for this model from dietary Se intake, BMI, fat, protein and carbohydrate intake, age, sex and SEIFA, using stepwise regression.

† Constant is the overall mean serum Zn concentration.

‡ Derived from Australian Census variables related to advantage and disadvantage. A lower SEIFA score for a given population area indicates it is relatively disadvantaged compared with one with a higher score.

Serum zinc

Mean serum Zn was 13·0 (sd 2·4) and 13·0 (sd 2·5) µmol/l for men and women, respectively. Overall, serum Zn levels decreased with age in men, but not in women; this trend can be seen in Fig. 1(a) and (b). While 15 % of all men had low serum Zn, none aged <40 years had serum Zn below the IZiNCG cut-off (10·7 µmol/l)( Reference Brown, Rivera and Bhutta 10 ). The prevalence of low serum Zn in men varied in the older age ranges; in the 40–49 years range only 4 % had serum Zn below the cut-off, but this increased to 19 % (50–59 years) and 8 % (60–69 years) and peaked at 31 % in those aged 70–79 years.

Fig. 1. Serum zinc concentrations of population samples. (a) Serum zinc concentrations of male (n 191) and (b) female (n 306) subjects compared with International Zinc Nutrition Consultative Group (IZiNCG) cut-off values. (c) Frequency distribution (histogram), and cumulative proportion (lines) of sample (—) and population (····) estimate of serum zinc in northern Tasmania, adjusted for age, sex and socio-economic status.

Of the women, 7 % had serum Zn below the IZiNCG cut-off (10·1 µmol/l)( Reference Brown, Rivera and Bhutta 10 ). Of the women aged 20–29 years, 22 % had low serum Zn and while the only subject aged 80–89 years also had a low serum Zn level, the proportion in other age ranges was <10 %; 30–39 years (8 %), 40–49 years (8 %), 50–59 years (6 %), 60–69 years (4 %) and 70–79 years (8 %).

Of the participants, 3 % (n 15) had serum AGP > 1·2 g/l, indicating current inflammation/infection. Serum Zn was not significantly different in those who had AGP values below compared with above this level (12·1 v. 13·1 µmol/l; 95 % CI of difference –2·3 to 0·3; P = 0·13). Of these subjects with elevated AGP only two had serum Zn below cut-off values, one male in the 50–59 years age range and one female in the 30–39 years age range.

In the adjusted population estimates (Table 3 and Fig. 1(c)), serum Zn concentrations and the prevalence of low Zn intakes and serum Zn levels below relevant cut-off values were not significantly different compared with the study sample (P > 0·7).

Table 3. Estimates of population proportions with zinc intakes below the Australian/New Zealand estimated average requirement (EAR)* and with serum zinc below International Zinc Nutrition Consultative Group (IZiNCG) cut-offs†

* Estimated average requirement: 12·0 mg/d for men; 6·5 mg/d for women( Reference Beckett and Ball 22 ).

† IZiNCG serum Zn sex/age cut-off values: 10·7 µmol/l for men; 10·1 µmol/l for women( Reference Brown, Rivera and Bhutta 10 ).

‡ Risk ratio (95 % CI) estimated by Poisson regression adjusted for age, sex and socio-economic status.

Discussion

Micronutrient deficiency, including Zn deficiency, is a problem for a significant proportion of the world's population. Moreover, it appears that even the more commonly occurring mild deficiency can increase morbidity( Reference Ibs and Rink 16 , Reference Lansdown, Mirastschijski and Stubbs 17 , Reference MacDonald 30 ), but there is very little information on the Zn status in Australian populations. In fact, the present study appears to be only the second to date to report both dietary and biochemical data on Zn status from a representative population sample in Australia, and the only such study in Tasmanians. The major finding is the relatively high prevalence of low Zn status in older Tasmanian men. In the present study over half of the men consumed less than the EAR for Zn (12 mg), and the prevalence of low intakes increased with age, with nearly 75 % of men over 70 years consuming inadequate Zn. Even in an adjusted estimate of intakes using a CV of 25 %, approximately 42 % of men reported low intakes. The prevalence of low serum Zn levels (<10·7 µmol/l) in older men was also high; low serum Zn was not observed in men below 40 years, but occurred in 18 % of men 50 years or older and 30 % of men 70 years or older. It is suggested that the risk of Zn deficiency in a population is elevated and of public health concern if >25 % of individuals consume inadequate intakes, or if >20 % have serum Zn below the relevant age/sex cut-off( Reference Brown, Rivera and Bhutta 10 ).

Serum Zn concentrations can be decreased as an acute-phase response in inflammation and infection. Our assessment of serum AGP indicated that the prevalence of inflammation or infection in the population sample was low; this was not unexpected as participants had flexibility in when they could attend for phlebotomy and hence could delay providing blood samples if they were feeling unwell. Even if those with elevated AGP were excluded it would not change the interpretation of the study's results significantly; in fact it would slightly increase the proportion of both men and women with low serum Zn concentrations.

Our multivariate model indicated that the major influences on serum Zn status in this sample were dietary factors, BMI, age and socio-economic status. Interestingly, socio-economic status was negatively associated with serum Zn status, but while higher socio-economic status may often be considered to result in an improved diet quality and potentially higher micronutrient status, it has, in previous European studies, been associated with a slightly lower Zn status( Reference Novaković, Cavelaars and Geelen 31 ).

In the present study, there were varying response rates in different population subgroups; however, the lack of difference between the sample and population estimates adjusted for age, sex and socio-economic status (Table 3) suggests that the overall findings from the sample are representative of the northern Tasmanian population.

Previous Australian studies of dietary Zn in adults have reported low intakes( Reference Gibson and Heath 2 , Reference Horwath 7 ); however, many are studies of aged-care residents. Of those to assess free-living older adults, results are conflicting. In a study of South Australian residents (in 1989; n 2195) aged 65+ years, Horwath( Reference Horwath 7 ) reported relatively low mean intakes of 10·3 and 9·7 mg/d in men and women, respectively. Baghurst & Record( Reference Baghurst and Record 32 ) (in 1987; n 331) also surveyed older South Australians (65–75 years) and reported somewhat higher median intakes of 12·0 mg/d in men and 10·9 mg/d in women, similar to the median intakes for individuals aged 65+ years in the present study of 11·1 mg/d (men) and 11·0 mg/d (women).

Overall, mean intakes in men from the present study (12·6 mg/d) were lower compared with the only other published Tasmanian data (13·5 mg/d) from the 1995 National Nutrition Survey( Reference McLennan and Podger 5 ) and other Australian reports by English et al. (1983 National Dietary Survey of Adults; n 1974; 15·1 mg/d)( Reference English, Najman and Bennett 3 ) and the 20th Australian Total Diet Survey (in 2003; 14 mg/d)( 4 ). Intakes were similar, however, to the large national study reported by Baghurst et al. (in 1991; n 806; 12·8 mg/d)( Reference Baghurst, Dreosti and Syrette 9 ).

Women in the present study also consumed a similar Zn intake (10·9 mg/d) to that estimated by Baghurst et al. (in 1991; n 874; 11·2 mg/d)( Reference Baghurst, Dreosti and Syrette 9 ) and English et al. (in 1983; n 2421; 10·5 mg/d)( Reference English, Najman and Bennett 3 ) but approximately 20 % more than Tasmanian women in the 1995 National Nutrition Survey (9·1 mg/d)( Reference McLennan and Podger 5 ) and 30 % more than estimated in the 20th Australian Total Diet Survey (in 2003; 8·4 mg/d)( 4 ). While the present study, like those by Horwath( Reference Horwath 7 ) and Baghurst et al. ( Reference Baghurst, Dreosti and Syrette 9 ), utilised semi-quantitative FFQ for dietary estimates, methodological differences from many of the other previous studies make further comparisons inappropriate.

The study of Baghurst et al. ( Reference Baghurst, Dreosti and Syrette 9 ) also determined serum Zn in a smaller sample of South Australian adults, reporting mean values of 15·1 µmol/l (n 90) and 14·1 µmol/l (n 111) for men and women, respectively. This study preceded the use of IZiNCG cut-off values( Reference Brown, Rivera and Bhutta 10 ) for assessing the risk of Zn deficiency and hence did not calculate the proportions of individuals below the now-accepted cut-off values. The authors, however, did note a trend of decreasing serum Zn values with age, which, as in the present study, was most evident in men.

Comparable serum Zn data from healthy adult populations in other countries also appear limited. Similar serum Zn levels have been reported by one UK study( Reference Ghayour-Mobarhan, Taylor and New 33 ) in men (13·9 µmol/l; n 95) and women (13·3 µmol/l; n 94) with mean participant ages (45 and 49 years, respectively) lower than the present study. Serum Zn was also similar in a large Northern Ireland study( Reference McMaster, McCrum and Patterson 34 ) in both men (13·2 µmol/l; n 1142) and women (12·7 µmol/l; n 1034); this study also reported a decline in Zn status with age among men, but not women.

A New Zealand study( Reference De Jong, Gibson and Thomson 35 ) of elderly women (mean age 74·9 years; n 102) reported a mean serum Zn of 12·4 µmol/l. As noted by the authors, this concentration is relatively low compared with other published data, but it was still higher than women of a similar age in the present study (11·6 µmol/l).

A lower Zn status in older age groups is in accordance with a number of other studies( Reference Gibson and Heath 2 , Reference McMaster, McCrum and Patterson 34 Reference Haase and Rink 36 ), and is a trend possibly due to a decrease in gastrointestinal absorption efficiency with age( Reference Russell 37 ), but changes in diet, as seen in the present study, as well as social and economic factors are also likely contributors. Zn is important for many broad biological processes. Recent research( Reference Haase and Rink 36 ) indicates an association between low Zn status and decreased immune function in the elderly and that low Zn status may be an important contributor to the immunosenescence observed in old age. Zn has also been associated with CVD, diabetes, neurodegenerative disease and cancer( Reference Chasapis, Loutsidou and Spiliopoulou 38 ). Of the cancers, the development and progression of prostate cancer in particular appears to be associated with low Zn levels( Reference Costello and Franklin 39 ), which in the context of this present study's findings, may be important.

The present results suggest that low Zn status may occur in a significant proportion of community-dwelling Tasmanians, and that there could be a relatively high prevalence of low Zn status in older males. Previous studies have shown that low Zn status is common in residential aged-care populations elsewhere in Australia( Reference Gibson and Heath 2 ), and therefore the prevalence of low Zn status across the entire older Tasmanian population may be greater than suggested by the present study.

In the present study, the lack of agreement between the proportions of male subjects estimated to consume inadequate Zn and those with low serum Zn concentrations was probably due to a combination of factors, including limitations of the dietary data collection method (FFQ), intra-individual variability and under-reporting. The combined effect of these factors may explain why previous observational studies have generally failed to find significant associations between Zn intakes and serum Zn concentrations( Reference Lowe, Medina and Stammers 40 ). Established knowledge about the phytate content of Australian diets( 41 ), and the dietary information collected in the present study suggest that phytate intake is likely to have minimal influence on Zn status in this population.

The measurement of dietary intakes and serum Zn on multiple occasions for each participant would have strengthened the present study and should be included in future studies in this area. However, the findings of the study provide useful insight into groups that may be at risk of mild Zn deficiency in a population where no other data have been reported.

While the study sample had relatively low numbers of subjects in the extremes of the age range (youngest and oldest) there was reasonable representation of most age ranges and in particular those where the most significant findings were made (50+ years; n 363). Further study of middle-aged and elderly Tasmanians, including both community-dwelling and aged-care residents, would be beneficial to confirm the prevalence of mild Zn deficiency in this population. Further investigation of the Zn status in the older populations of other states of Australia may also be warranted.

Acknowledgements

The present study was supported by a research grant from the Clifford Craig Medical Research Trust (Launceston, TAS, Australia). The Launceston General Hospital Pathology Department (Launceston, TAS, Australia), the NorthWest Pathology (Burnie, TAS, Australia), the Scottsdale Doctors Surgery (Scottsdale, TAS, Australia) and the Campbell Town Health and Community Centre (Campbell Town, TAS, Australia) assisted with blood collection, and the Royal Hobart Hospital Pathology Department (Hobart, TAS, Australia) assisted with specimen analysis. Dr Iain Robertson, consultant biostatistician, assisted with the sample determination from the electoral roll and biostatistical analysis.

The authors thank Professor Graham Giles of the Cancer Epidemiology Centre of The Cancer Council of Victoria, for permission to use the Dietary Questionnaire for Epidemiological Studies(24).

J. M. B. and M. J. B. designed the study; J. M. B. recruited the subjects, collected and analysed data and wrote the manuscript. M. J. B. discussed the data, corrected the manuscript and provided significant advice throughout.

Neither author had a conflict of interest.

References

1. Sanghvi, T, Van Ameringen, M, Baker, J, et al. (2007) Vitamin and mineral deficiencies technical situation analysis: a report for the Ten Year Strategy for the Reduction of Vitamin and Mineral Deficiencies. Food Nutr Bull 28, S160S219.Google ScholarPubMed
2. Gibson, R & Heath, A-L (2011) Population groups at risk of zinc deficiency in Australia and New Zealand. Nutr Diet 68, 97108.Google Scholar
3. English, RM, Najman, JM & Bennett, SA (1997) Dietary intake of Australian smokers and nonsmokers. Aust N Z J Public Health 21, 141146.Google Scholar
4. Food Standards Australia New Zealand (2003) 20th Australian Total Diet Survey. Canberra: Food Standards Australia New Zealand.Google Scholar
5. McLennan, W & Podger, A (1995) National Nutrition Survey: Nutrient Intakes and Physical Measurements. Canberra: Australian Bureau of Statistics.Google Scholar
6. McCarty, CA, Nanjan, MB & Taylor, HR (2002) Dietary intake of older Victorians. Nutr Diet 59, 1217.Google Scholar
7. Horwath, CC (1989) Dietary survey of a large random sample of elderly people: energy and nutrient intakes. Nutr Res 9, 479492.Google Scholar
8. Ball, MJ & Ackland, ML (2000) Zinc intake and status in Australian vegetarians. Br J Nutr 83, 2733.Google Scholar
9. Baghurst, KI, Dreosti, IE, Syrette, JA, et al. (1991) Zinc and magnesium status of Australian adults. Nutr Res 11, 2332.Google Scholar
10. Brown, KH, Rivera, JA, Bhutta, Z, et al. (2004) International Zinc Nutrition Consultative Group (IZiNCG) technical document #1. Assessment of the risk of zinc deficiency in populations and options for its control. Food Nutr Bull 25, S99S203.Google Scholar
11. Whitehouse, RC, Prasad, AS, Rabbani, PI, et al. (1982) Zinc in plasma, neutrophils, lymphocytes, and erythrocytes as determined by flameless atomic absorption spectrophotometry. Clin Chem 28, 475480.Google Scholar
12. Meftah, S, Prasad, AS, Lee, DY, et al. (1991) Ecto 5' nucleotidase (5′NT) as a sensitive indicator of human zinc deficiency. J Lab Clin Med 118, 309316.Google Scholar
13. Lowe, NM, Fekete, K & Decsi, T (2009) Methods of assessment of zinc status in humans: a systematic review. Am J Clin Nutr 89, 2040S2051S.CrossRefGoogle ScholarPubMed
14. Schlemmer, U, Frolich, W, Prieto, RM, et al. (2009) Phytate in foods and significance for humans: food sources, intake, processing, bioavailability, protective role and analysis. Mol Nutr Food Res 53, Suppl. 2, S330S375.Google Scholar
15. Lonnerdal, B (2000) Dietary factors influencing zinc absorption. J Nutr 130, 1378S1383S.Google Scholar
16. Ibs, KH & Rink, L (2003) Zinc-altered immune function. J Nutr 133, 1452S1456S.Google Scholar
17. Lansdown, ABG, Mirastschijski, U, Stubbs, N, et al. (2007) Zinc in wound healing: theoretical, experimental and clinical aspects. Wound Repair Regen 15, 216.Google Scholar
18. Velie, EM, Block, G, Shaw, GM, et al. (1999) Maternal supplemental and dietary zinc intake and the occurrence of neural tube defects in California. Am J Epidemiol 150, 605616.Google Scholar
19. Delisle, H (2002) Programming of Chronic Disease by Impaired Fetal Nutrition. Evidence and Implications for Policy and Intervention Strategies. Geneva: WHO, Department of Nutrition for Health and Development.Google Scholar
20. Guttikonda, K, Burgess, JR, Hynes, K, et al. (2002) Recurrent iodine deficiency in Tasmania, Australia: a salutary lesson in sustainable iodine prophylaxis and its monitoring. J Clin Endocrinol Metab 87, 28092815.CrossRefGoogle Scholar
21. McGlashan, ND, Cook, SJ, Melrose, W, et al. (1996) Maternal selenium levels and sudden infant death syndrome (SIDS). Aust N Z J Med 26, 677682.Google Scholar
22. Beckett, JM & Ball, MJ (2011) Marginal selenium status in northern Tasmania. Br J Nutr 106, 718724.Google Scholar
23. Australian Bureau of Statistics (2006) National Health Survey: Summary of Results (2004–2005). Canberra: Australian Bureau of Statistics.Google Scholar
24. Giles, GG & Ireland, PD (1996) Dietary Questionnaire for Epidemiological Studies (Version 2). Melbourne: The Cancer Council Victoria.Google Scholar
25. Australian Bureau of Statistics (2006) Socio-Economic Indexes for Areas (SEIFA): Technical Paper. Canberra: Australian Bureau of Statistics.Google Scholar
26. Meret, S & Henkin, RI (1971) Simultaneous direct estimation by atomic absorption spectrophotometry of copper and zinc in serum, urine, and cerebrospinal fluid. Clin Chem 17, 369373.CrossRefGoogle ScholarPubMed
27. Aickin, M & Gensler, H (1996) Adjusting for multiple testing when reporting research results: the Bonferroni vs Holm methods. Am J Public Health 86, 726728.Google Scholar
28. International Zinc Nutrition Consultative Group (IZiNCG) (2007) Determining the Prevalence of Zinc Deficiency: Assessment of Dietary Zinc Intake. Technical Brief 3. Davis, CA: International Zinc Nutrition Consultative Group, c/o Program in International and Community Nutition, University of California.Google Scholar
29. National Health and Medical Research Council (2006) Nutrient Reference Values for Australia and New Zealand. Canberra: National Health and Medical Research Council.Google Scholar
30. MacDonald, RS (2000) The role of zinc in growth and cell proliferation. J Nutr 130, 1500S1508S.Google Scholar
31. Novaković, R, Cavelaars, A, Geelen, A, et al. (2014) Socio-economic determinants of micronutrient intake and status in Europe: a systematic review. Public Health Nutr 17, 10311045.Google Scholar
32. Baghurst, KI & Record, SJ (1987) The vitamin and mineral intake of a free-living young elderly Australian population in relation to total diet and supplementation practices. Hum Nutr Appl Nutr 41, 327337.Google Scholar
33. Ghayour-Mobarhan, M, Taylor, A, New, SA, et al. (2005) Determinants of serum copper, zinc and selenium in healthy subjects. Ann Clin Biochem 42, 364375.Google Scholar
34. McMaster, D, McCrum, E, Patterson, CC, et al. (1992) Serum copper and zinc in random samples of the population of Northern Ireland. Am J Clin Nutr 56, 440446.Google Scholar
35. De Jong, N, Gibson, RS, Thomson, CD, et al. (2001) Selenium and zinc status are suboptimal in a sample of older New Zealand women in a community-based study. J Nutr 131, 26772684.Google Scholar
36. Haase, H & Rink, L (2009) The immune system and the impact of zinc during aging. Immun Ageing 6, 9.Google Scholar
37. Russell, RM (1992) Changes in gastrointestinal function attributed to aging. Am J Clin Nutr 55, 1203S1207S.Google Scholar
38. Chasapis, CT, Loutsidou, AC, Spiliopoulou, CA, et al. (2012) Zinc and human health: an update. Arch Toxicol 86, 521534.Google Scholar
39. Costello, LC & Franklin, RB (2011) Zinc is decreased in prostate cancer: an established relationship of prostate cancer! J Biol Inorg Chem 16, 38.Google Scholar
40. Lowe, NM, Medina, MW, Stammers, AL, et al. (2012) The relationship between zinc intake and serum/plasma zinc concentration in adults: a systematic review and dose–response meta-analysis by the EURRECA Network. Br J Nutr 108, 19621971.CrossRefGoogle ScholarPubMed
41. International Zinc Nutrition Consultative Group (IZiNCG) (2004) International Zinc Nutrition Consultative Group (IZiNCG) technical document #1. Assessment of the risk of zinc deficiency in populations and options for its control. Food Nutr Bull 25, S95S203.Google Scholar
Figure 0

Table 1. Characteristics of the study subjects(Mean values, standard deviations and ranges)

Figure 1

Table 2. Multivariate analysis: association between mean serum zinc and variables selected by stepwise regression*

Figure 2

Fig. 1. Serum zinc concentrations of population samples. (a) Serum zinc concentrations of male (n 191) and (b) female (n 306) subjects compared with International Zinc Nutrition Consultative Group (IZiNCG) cut-off values. (c) Frequency distribution (histogram), and cumulative proportion (lines) of sample (—) and population (····) estimate of serum zinc in northern Tasmania, adjusted for age, sex and socio-economic status.

Figure 3

Table 3. Estimates of population proportions with zinc intakes below the Australian/New Zealand estimated average requirement (EAR)* and with serum zinc below International Zinc Nutrition Consultative Group (IZiNCG) cut-offs†