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Re-exploration of dietary iodine intake in Chinese adult males using a modified iodine balance study

Published online by Cambridge University Press:  06 March 2023

Xiaobing Liu
Affiliation:
Chinese Center for Disease Control and Prevention, National Institute for Nutrition and Health, Beijing 100050, People’s Republic of China Shenzhen Center for Chronic Disease Control, Shenzhen, Guangdong 518020, People’s Republic of China
Jun Wang
Affiliation:
Shenzhen Polytechnic, School of Food and Drug, Shenzhen, Guangdong 518055, People’s Republic of China
Yajie Li
Affiliation:
Changzhi Medical College, Changzhi, Shanxi 046000, People’s Republic of China
Hongxing Tan
Affiliation:
Shenzhen Center for Chronic Disease Control, Shenzhen, Guangdong 518020, People’s Republic of China
Xiuwei Li
Affiliation:
Chinese Center for Disease Control and Prevention, National Reference Laboratory for Iodine Deficiency Disorders, Beijing 100050, People’s Republic of China
Deqian Mao
Affiliation:
Chinese Center for Disease Control and Prevention, National Institute for Nutrition and Health, Beijing 100050, People’s Republic of China
Yanyan Liu
Affiliation:
Shenzhen Center for Chronic Disease Control, Shenzhen, Guangdong 518020, People’s Republic of China
Weidong Li
Affiliation:
Chinese Center for Disease Control and Prevention, National Institute for Nutrition and Health, Beijing 100050, People’s Republic of China
Wei Yu
Affiliation:
Shenzhen Center for Chronic Disease Control, Shenzhen, Guangdong 518020, People’s Republic of China
Jiaxi Lu
Affiliation:
Chinese Center for Disease Control and Prevention, National Institute for Nutrition and Health, Beijing 100050, People’s Republic of China
Junan Yan
Affiliation:
Shenzhen Center for Chronic Disease Control, Shenzhen, Guangdong 518020, People’s Republic of China
Jianhua Piao
Affiliation:
Chinese Center for Disease Control and Prevention, National Institute for Nutrition and Health, Beijing 100050, People’s Republic of China
Lichen Yang
Affiliation:
Chinese Center for Disease Control and Prevention, National Institute for Nutrition and Health, Beijing 100050, People’s Republic of China
Chongzheng Guo*
Affiliation:
Changzhi Medical College, Changzhi, Shanxi 046000, People’s Republic of China
Xiaoli Liu*
Affiliation:
Shenzhen Center for Chronic Disease Control, Shenzhen, Guangdong 518020, People’s Republic of China
Xiaoguang Yang*
Affiliation:
Chinese Center for Disease Control and Prevention, National Institute for Nutrition and Health, Beijing 100050, People’s Republic of China Shenzhen Center for Chronic Disease Control, Shenzhen, Guangdong 518020, People’s Republic of China
*
*Corresponding authors: Xiaoguang Yang, email [email protected]; Xiaoli Liu, email [email protected]; Chongzheng Guo, email [email protected]
*Corresponding authors: Xiaoguang Yang, email [email protected]; Xiaoli Liu, email [email protected]; Chongzheng Guo, email [email protected]
*Corresponding authors: Xiaoguang Yang, email [email protected]; Xiaoli Liu, email [email protected]; Chongzheng Guo, email [email protected]
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Abstract

There is still controversy about optimal dietary iodine intake as the Universal Salt Iodization policy enforcement in China. A modified iodine balance study was thus conducted to explore the suitable iodine intake in Chinese adult males using the iodine overflow hypothesis. In this study, thirty-eight apparently healthy males (19·1 (sd 0·6) years) were recruited and provided with designed diets. After the 14-d iodine depletion, daily iodine intake gradually increased in the 30-d iodine supplementation, consisting of six stages and each of 5 d. All foods and excreta (urine, faeces) were collected to examine daily iodine intake, iodine excretion and the changes of iodine increment in relation to those values at stage 1. The dose–response associations of iodine intake increment with excretion increment were fitted by the mixed effects models, as well as with retention increment. Daily iodine intake and excretion were 16·3 and 54·3 μg/d at stage 1, and iodine intake increment increased from 11·2 μg/d at stage 2 to 118·0 μg/d at stage 6, while excretion increment elevated from 21·5 to 95·0 μg/d. A zero iodine balance was dynamically achieved as 48·0 μg/d of iodine intake. The estimated average requirement and recommended nutrient intake were severally 48·0 and 67·2 μg/d, which could be corresponded to a daily iodine intake of 0·74 and 1·04 μg/kg per d. The results of our study indicate that roughly half of current iodine intakes recommendation could be enough in Chinese adult males, which would be beneficial for the revision of dietary reference intakes.

Type
Research Article
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of The Nutrition Society

Iodine is one of the essential elements required for normal body functioning, and it is an intrinsic constituent of thyroid hormones, including thyroxine (T4) and triiodothyronine (T3), that are important regulators of multiple biological process and metabolism(Reference Zimmermann1,Reference Lazarus2) . So far, accumulating adverse consequences in populations with iodine deficiency has been documented, such as goitre, lower intelligence quotient, growth retardation and reproductive health problems(Reference Zimmermann3,Reference Patriota, Lima and Nilson4) . However, as is the case for virtually all essential nutrients, long-term inadequate or excessive iodine intake will potentially cause thyroid dysfunctions(Reference Pearce, Lazarus and Moreno-Reyes5).

Iodine deficiency is a serious public health problem, and its prevalence is considerably high in China compared with that in other countries. Approximately 425 million Chinese people living in iodine-deficient areas are affected, and nearly 35 million cases of goitre have been reported before 1995(Reference Liu, Liu and Lin6). Fortunately, the status quo of iodine deficiency had been greatly improved as the implementation of Universal Salt Iodization policy(Reference Li, Teng and Ba7). Yet, numerous potential threats probably due to excessive iodine intake have gradually attracted more attention, although its health association has not well understood(Reference Du, Gao and Meng8,Reference Farebrother, Zimmermann and Andersson9) . Excessive iodine intake can increase the risk of clinical hypothyroidism, which has been reported in the Chinese populations(Reference Teng, Shan and Teng10). The U-shaped curve relationship has also been observed between urinary iodine concentration and the prevalence of thyroid nodules(Reference Song, Zou and Guo11). Thus, a rigorous problem is repeatedly mentioned, that is, whether the current dietary iodine intake is much higher than that required for a certain population.

To date, the WHO, the United Nations International Children’s Emergency Fund (UNICEF) and the International Council for Control of Iodine Deficiency Disorders (ICCIDD) had jointly recommended iodine intakes of 120 μg/d for schoolchildren, 150 μg/d for adolescents and adults and 250 μg/d for pregnant and lactating women(Reference Karwowska and Breda12). The Chinese Nutrition Society also suggested that the dietary iodine intake was calculated by the adjustment of adult body weight in the data from other countries’ studies. In theory, the dietary reference intakes should be set according to the physiological requirement of certain population in the traditional balance study(Reference Costa, Bacci and Campagnoli13,Reference Dold, Zimmermann and Baumgartner14) . Regrettably, only a few relevant studies have been conducted(Reference Costa, Bacci and Campagnoli13,Reference Vought and London15,Reference Hays16) . The issue on whether superfluous iodine is stored in the thyroid is mentioned in current China, and the traditional balance study may no longer be suitable for the individuals with iodine over-nutrition. The iodine overflow hypothesis was thus proposed in order to avoid the interferences, and that had been validated by recent studies in the south and north China(Reference Wang, Zhang and Mao17,Reference Yang, Wang and Yang18) . However, some points should be noted that the smaller iodine intake range and sex difference, especially female menstrual cycle, can affect the collection of urine specimens.

Therefore, to avoid the known interferences, this study aimed to examine the iodine dynamic changes and to explore the iodine requirement in Chinese adult males based on a modified iodine balance study using the iodine overflow hypothesis; furthermore, it aimed to provide the data reference to the new Chinese iodine dietary reference intakes, such as the estimated average requirement (EAR) and recommended nutrient intake (RNI).

Methods

Participants

Participants were recruited in Changzhi Medical College, located in northern China; participants were required of 18–21 years; with a BMI of 18·5–27; with no thyroid, liver and kidney dysfunction; with no infection and inflammatory condition; with no overt constipation and who were not exposed to iodine-containing drugs and iodinated contrast media within the previous 6 months. The sample size of participant was estimated using the software of G × Power (version 3.1.9). As this study was a self-control study, it was estimated that thirty-four participants would be required for a paired t test to detect a medium effect size (F = 0·5) with a statistical power (1–β error probability) of 80 % and an α of 0·05. Thus, the sample size of 38 was adequate.

Iodine overflow hypothesis

The hypothesis demonstrated that the ingested iodine could be effectively absorbed and utilised only before or only when thyroid hormone biosynthesis and necessary for storage in vivo are adequate; meanwhile, the remaining iodine will be totally excreted from the body. The increment (Δ) iodine excretion will increase as the Δ iodine intake increases until a certain threshold (i.e. Δ iodine excretion = Δ iodine intake) after a short-term iodine depletion following a long-term superfluous status. A zero iodine balance will dynamically arrive to a similar iodine imminent ‘overflow’ in the human body. In this case, the iodine intake was exactly regarded as the basic iodine requirement of the individuals.

Study design

As shown in Fig. 1, this study was carried out for 44 d. The former 14 d was set as the depletion period to reduce the supersaturated iodine level in the thyroid. The later 30 d was set as the supplementation period to increase the iodine intake by stages, which involved the provision of milk or eggs based on the participants’ daily diet; the 30 d was divided into six stages, and each stage lasted for 5 d. Physical examination was arranged at baseline day (Day0) before iodine depletion, at start day (Daystart) and at end day (Dayend) for iodine supplementation. The weight and height of participants were measured by calibrated instruments, and blood samples were together collected through venous puncture after fasting for 8 h. Serum thyroid-stimulating hormone, free thyroxine, free triiodothyronine, alanine transaminase and aspartate aminotransferase levels were measured. The study protocol was conducted according to the guidelines of the Declaration of Helsinki of the World Medical Association(19) and approved by the Ethics Committee of National Institute of Nutrition and Health of Chinese Center for Disease Control and Prevention. Signed informed consent was obtained from all participants after explaining the nature of the study. This study was registered in medresman.org (ChiCTR1800016184).

Fig. 1. Flow chart of iodine balance study in Chinese adult males.

Diet preparation, sample collection and determination

The iodine contents of raw materials such as rice, flour and other food items and the compound condiments were measured in advance. Diet plans were then carefully designed by a professional dietician based on balanced meals to avoid the use of condiments and foods with high iodine content, including kelp, seaweed and marine products and uniformly prepared with non-iodised salt. Details of the recipe used in preparing a typical daily meal are provided in Table 1. In this study, serving foods and drinking water were restrictively monitored and provided to all participants at the college canteen. The amounts of daily consumed foods were weighed and recorded. All foods were collected by duplicate portion method and stored in a cryogenic refrigerator at –20°C. The 24-h urine specimens were collected and weighed upon delivery at baseline and the whole study, and the estimated amount of missed urine was accordingly recorded. To ensure the integrity of the faecal sample collection, all participants were asked to take a carmine capsule to visually label the faeces at the onset of each stage and at the end of the 6th stage. The faecal samples were subsequently collected and homogenised at each stage according to the labelled red pigmentation; a portion was proportionally taken, lyophilised and stored at –20°C. After this study, all specimens were sent to the National Institute of Nutrition and Health in Chinese Center for Disease Control and Prevention for analysis. The iodine contents in urine specimens, faecal samples from all six stages and foods were determined using inductively coupled plasma MS and the Sandell–Kolthoff method after acid wet washing(Reference Machado, Lima and Mesquita20). The urinary creatinine level was measured by kinetic calorimetric assay(Reference Chromy, Rozkosna and Sedlak21). The quality control samples were analysed in each assay. The recovery of measurement was between 92·3 and 106·7 %. The intra-day and inter-day precision for urinary indicators ranged from 2·1 % to 5·7 %.

Table 1. Typical daily meal plan

Quality control

All exogenous sources of iodine were determined to eliminate unknown food sources of iodine or iodine-containing drugs. In addition, the excreta sample was deemed incomplete or invalid if any one of the following occurred: (1) the urinary creatinine concentration was < 0·1 mmol/kg per d, (2) the 24-h urine volume was < 500 ml and (3) no red pigmentation was observed in staged faeces.

Statistical analysis

All analyses were performed in the SAS 9.3 (SAS Institute) and R statistical software (version 3.5.1) using the nlme and ggplot 2 packages for data processing and statistical analyses. The Shapiro−Wilk test was used to evaluate the distribution of data, while the Mauchly’s test was used to assess whether the assumption of sphericity was met or not. The differences in height, weight, urinary electrolytes excretion, alanine transaminase, aspartate aminotransferase, and serum thyroid-stimulating hormone, free triiodothyronine and free thyroxine were compared using ANOVA with Bonferroni correction or Kruskal−Wallis test for multiple comparisons. P value < 0·05 was considered significant.

The data on iodine intake and urinary and faecal iodine excretion per stage in each participant were provided. Iodine intake, iodine excretion and iodine retention were expressed in micrograms per day (μg/d) and in micrograms per kilogram of body weight per day (μg/kg per d) in order to obtain a clearer illustration. According to the iodine overflow hypothesis, the Δ iodine intake was calculated by subtracting the corresponding iodine intake at stage 1 of each participant from the daily iodine intake from stage 2 to stage 6; meanwhile, the Δ iodine excretion was calculated by subtracting the corresponding excretion at stage 1 from the iodine excretion from stage 2 to stage 6. Lastly, the Δ iodine retention was calculated by subtracting the Δ iodine excretion from the Δ iodine intake.

In this study, 1140 data points for iodine intake and iodine excretion were collected, while 1031 data points were originally retained through the data screening for the incomplete collection. Data on the Δ iodine intake and the Δ iodine excretion were further removed as outliers for triple standard difference method, leaving 985 data for statistical analysis. The association of the Δ iodine intake and the Δ iodine excretion was assessed using the mixed effects models (MEM) for micrograms per day and micrograms per kilogram of body weight per day, with the Δ iodine intake of the individuals as fixed factor and the participants as random factor compared with those used in previous literature(Reference Dold, Zimmermann and Baumgartner14). The selection of predicted function was determined based on the Akaike information criterion and evaluated using goodness-of-fit plots. In addition, a linear regression function was built to determine the association between the Δ iodine intake and the Δ iodine excretion, as well as between the Δ iodine intake and the Δ iodine retention. The predicted Δ iodine excretion and predicted Δ iodine retention increment based on the actual Δ iodine intake of each participant were obtained. The association between measured and predicted values of the Δ iodine excretion and the Δ iodine retention was further evaluated using Pearson’s correlation coefficient (r). The dynamic zero iodine balance (Δ iodine intake = Δ iodine excretion, Δ iodine retention = 0 μg/d) was obtained from the MEM of the Δ iodine intake compared with the Δ iodine retention per day or per kilogram of body weight per day, with the former used to estimate the proposed EAR. In addition, a 20 % variable coefficient (CV) of the EAR is more inclined to suggest the estimation of iodine RNI, rather than the 10 % CV if considering a relative variation in populations according to previous studies(22). In this case, the current iodine RNI was calculated as equal to the EAR plus twice the CV (i.e. 1·4 times the EAR) to satisfy the requirement among the majority of individuals.

Results

Participants’ characteristic

The baseline characteristics of all participants are shown in Table 2. In total, thirty-eight healthy male adults aged 19·1 (sd 0·6) years were enrolled and finished the modified iodine balance study. The mean 24-h urinary iodine concentration was 237·7 μg/l at baseline (Day0), initially decreased to 30·9 μg/l at the Daystart, and then eventually increased to 88·8 μg/l at the Dayend. Significant differences were found in the 24-h urinary iodine concentration, 24-h urinary iodine excretion, alanine transaminase, aspartate aminotransferase, urea, creatinine, uric acid and thyroid-stimulating hormone (P < 0·05), but no significant differences were observed in other indicators, including weight, 24-h urine volume, Hb, free triiodothyronine and free thyroxine (P > 0·05).

Table 2. Baseline characteristics of thirty-eight Chinese adult males

(Mean values and standard deviations)

Day0, means the day at baseline; Day start and Day end, mean the start and the end day for iodine supplementation; 24-h UIC, 24-h urinary iodine concentration; 24-h UIE, 24-h urinary iodine excretion; ALT, alanine transaminase; AST, aspartate aminotransferase; TSH, thyroid-stimulating hormone; FT4, free thyroxine; FT3, free triiodothyronine and other values are expressed as mean values and standard deviations. Differences are examined by repeated-measures ANOVA by use of Bonferroni correction for multiple comparisons. Values with different superscript letters (a, b, c) are significantly different (P < 0·05).

Iodine intake and excretion

Iodine status of participants was assessed using WHO/UNICEF/ICCIDD references ranges(23), as shown in Table 3; the majority of participants had more than adequate iodine levels at baseline, while the urinary iodine levels were distinctly changed to induce iodine depletion. The median 24-h urinary iodine concentration immediately decreased from 256·1−205·5 μg/l to 28·7−28·8 μg/l, whilst the median 24-h urinary iodine excretion decreased from 197·0−198·6 μg/d to 47·7−50·0 μg/d at the end of iodine depletion.

Table 3. Comparison of 24-h UIC and 24-h UIE at baseline and last 2 d of iodine depletion for thirty-eight Chinese adult males

(Median values and inter-quartile ranges)

* Values are expressed as median (M0) and interquartile (P25, P75); 24-h UIC, 24-h urinary iodine concentration; 24-h UIE, 24-h urinary iodine excretion.

The dynamic changes in iodine balance are shown in Table 4. The iodine excretion and iodine retention increased with the iodine intake increased; the Δ iodine excretion and the Δ iodine retention also increased with iodine supplementation. Significant differences were found in the iodine intake, iodine excretion, iodine retention, and the Δ iodine intake, the Δ iodine excretion and the Δ iodine retention among all stages (P < 0·001 for all comparisons). In this study, the dose–response relationship between the Δ iodine intake and the Δ iodine excretion was investigated based on the MEM estimate each day, as well as that between the Δ iodine intake and the Δ iodine retention according to the data distribution. We fitted the linear function for the Δ iodine excretion or the Δ iodine retention along with the Δ iodine intake per kilogram of body weight to intuitively understand the correlation; these predicted formulas were expressed as follows:

  • Δ iodine excretion (μg/d) = 0·736 × Δ iodine intake (μg/d) + 8·359

  • Δ iodine retention (μg/d) = 0·262 × Δ iodine intake (μg/d) – 8·216

  • Δ iodine excretion (μg/kg per d) = 0·738 × Δ iodine intake (μg/kg per d) + 0·134

  • Δ iodine retention (μg/kg per d) = 0·259 × Δ iodine intake (μg/kg per d) – 0·129

Table 4. Iodine intake, excretion, retention and Δ iodine intake, Δ excretion and Δ retention for thirty-eight Chinese adult males among the six stages of iodine supplementation*

(Mean values and standard deviations)

* Values are expressed as mean values and standard deviations. Difference of iodine intake and excretion is evaluated using repeated-measures ANOVA with Bonferroni correlation. Values with different superscript letters (a, b, c, d, e) are significantly different (P < 0·05); n. a., not applicable.

Predicted excretions are calculated from observed intake by use of MEM: Δ iodine excretion (μg/d) = 0·736 × Δ iodine intake (μg/d) + 8·359; predicted Δ iodine retention is calculated from observed Δ iodine intake by use of MEM: Δ iodine retention (μg/d) = 0·262 × Δ iodine intake (μg/d) – 8·216.

Predicted Δ iodine excretions is calculated from observed Δ iodine intake by use of MEM: Δ iodine excretion (μg/kg per d) = 0·738 × Δ iodine intake (μg/kg per d) + 0·134; predicted Δ iodine retention is calculated from observed Δ iodine intake by use of MEM: Δ iodine retention (μg/kg per d) = 0·259 × Δ iodine intake (μg/kg per d) – 0·129.

The graphical demonstration showed that the dose–response association of the Δ iodine excretion and the Δ iodine intake obtained from the MEM agreed well with the measured data, as well as the Δ iodine retention and the Δ iodine intake. As shown in Figs. 2 and 3, the locally weighted scatter plot smoothing lines were comparable with the predicted function obtained from the MEM analysis. Furthermore, a distinct correlation was observed between the measured and predicted data for iodine excretion (r = 0·749, P = 0·0001, for μg/d) and iodine retention (r = 0·392, P = 0·0001, for μg/d) and that between iodine excretion (r = 0·766, P = 0·0001, for μg/kg per d) and iodine retention (r = 0·387, P = 0·0001, for μg/kg per d). In this study, the dynamic zero iodine balance (Δ iodine intake = Δ iodine excretion, Δ iodine retention = 0 μg/d) was obtained using the MEM based on the incremental change and achieved at a transient Δ iodine intake of 31·7 μg/d. Therefore, an iodine intake of 48·0 μg/d was precisely suitable when the dynamic zero iodine balance was reached in the body. As shown in Figs. 2 and 3, the use of a linear regression function also yielded a similar estimation of the Δ iodine intake at null balance as the MEM but did not change the data interpretation for the association.

Fig. 2. Dose–response relationship of the increment (Δ) of iodine intake and the Δ iodine excretion (a), together with the Δ iodine retention (b) by the mixed effects model (dashed) and linear regression function (solid) for iodine supplementation.

Fig. 3. Dose–response relationship of the increment (Δ) of iodine intake per kilogram of body weight and the Δ iodine excretion per kilogram of body weight (a), together with the Δ iodine retention per kilogram of body weight (b) by the mixed effects model (dashed) and linear regression function (solid) for iodine supplementation.

Discussion

This was a modified iodine balance study, which was performed on a group of Chinese adult males according to our suggested iodine overflow hypothesis. In this study, the dose–response functions were consecutively established between the Δ iodine intake and the Δ iodine excretion using the MEM and linear regression analysis, as well as between the Δ iodine intake and the Δ iodine retention. Through these formulas derived from the available data, the estimates of dietary iodine intake were considered as appropriate for 48·0 μg/d of EAR and 67·2 μg/d of RNI. These values further corresponded to daily iodine intakes of 0·74 μg/kg per d and 1·04 μg/kg per d.

Given that the enforcement of Universal Salt Iodization policy in China over 20 years, it had probably induced the iodine oversaturation in the most individuals(Reference Liu, Li and Teng24,Reference Shan, Chen and Lian25) , particularly those living in areas whose drinking water contains high iodine levels(Reference Yao, Zhang and Wang26). Furthermore, daily consumption of salt and iodine is usually higher in male than that in female. In our study, the majority of participants were more than adequate iodine levels at baseline; this finding is slightly higher as compared with the results of a national survey, which reported that nearly 42 % of the population had more than adequate and excess iodine intake(Reference Li, Teng and Ba7). In this case, the traditional balance study could no longer be used, as previously mentioned(Reference Wang, Zhang and Mao17,Reference Yang, Wang and Yang18) . With regard to the dilemma, our iodine overflow hypothesis could accurately simulate the iodine dynamic change in vivo; moreover, iodine depletion was only required within a short period of time in those individuals with excess iodine exposure. Noteworthy, after iodine supplementation, the Δ iodine excretion gradually increased with the Δ iodine intake increased until the iodine ‘overflow’ threshold was reached, following the excretion of excess iodine.

In line with previous studies(Reference Vought and London15,Reference Malvaux, Beckers and De Visscher27) , negative iodine balance without exception occurred in the participants following a low iodine supplementation (from 16·3 to 134·2 μg/d). In our opinion, it is only a short-term adaptation to the changes of iodine intake levels rather than a long-term change in the body, considering that the thyroid hormone levels remained normal if the absence of iodine recycling and depletion of iodine storage in the thyroid for over 3 months. This might be attributed to the excessive amounts of iodine administered previously or the delayed response in iodine insufficiency. By contrast, a recent iodine balance study reported that there was no negative iodine balance in Chinese women(Reference Tan, Tian and Wang28). It was believed to be due to the high iodine intake (194·8–487·1 μg/d), that is, the administrative iodine intake far exceeds its metabolic absorption and redundant iodine be then excreted.

In our study, the proposed EAR was 48·0 μg/d, and the RNI was 67·2 μg/d based on an EAR of 1·4 times in view of the characteristics and complexity of the balance study design in the population(22). These estimates of iodine requirement are relatively consistent with those of previous studies reported(Reference Yang, Wang and Yang18,Reference Malvaux, Beckers and De Visscher27,Reference Harrison29,Reference Ingenbleek and Malvaux30) , but significantly lower than the recommended iodine intake of adults, based on the new EAR (85 μg/d) and RNI (120 μg/d)(31). In addition, the USA and Canada used an iodine intake of 90 μg/d as a safe EAR limit for adults(Reference Harrison29), while Australia and New Zealand suggested an EAR of 100 μg/d and RNI of 150 μg/d(Reference Thomson32,Reference Mackerras and Eastman33) . The European Scientific Committee for Food recommended 100 and 130 μg/d(Reference Zimmermann and Delange34), while Chinese women suggested 110 and 155 μg/d as the EAR and RNI of iodine, respectively(Reference Tan, Tian and Wang28). The values reported in the current study are almost one-half of the current recommended iodine intakes.

When interpreting our findings, some advantages and limitations should be noted. First, the iodine contents in foods and excreta (urine and faeces) were extremely low to measure the dynamic change in iodine intake and the amounts of urine and faeces excreted were smaller during the depletion and supplementation stages, resulting in the uncertainty of the actual iodine contents. The application of inductively coupled plasma MS has resolved the difficulty in analysing low iodine levels, and the obtained results were relatively reliable. Second, the daily iodine intake and excretion are well controlled throughout the study, although it is fairly low and easily disrupted by exogenous factors. However, the amount of iodine excreted might be underestimated as the iodine loss from sweat or other sources was not measured. Third, the current study was only conducted on a group of Chinese adult males, so the generalisability of the results might have some practical difficulties in the general population. Thus, many factors should be taken into account in the following studies, such as sex or age or geographical location.

In summary, this modified iodine balance study was conducted in Chinese adult males using our suggested iodine overflow hypothesis and provided a reliable experimental data on the iodine metabolic balance of individuals with superfluous iodine status. The findings of our study indicated that rough half of the current dietary iodine intake recommendation is enough as an iodine requirement for Chinese male adults, which would be beneficial for the revision of iodine dietary reference intakes in China.

Acknowledgements

The authors would like to sincerely thank all subjects and the work team workers who participated in this iodine balance study, including all subjects, canteen staffs and nurses for assistance.

This study was supported by the National Natural Science Foundation of China (grant no. 81872624) and the Sanming Project of Medicine in Shenzhen (SZSM201611017).

X. G. Y., X. L. L. and C. Z. G. conceived and organised the conduction of iodine balance study and reviewed and critically revised the manuscript. X. B. L., J. W. and Y. J. L. contributed equally to draft the manuscript. All authors contributed to collecting the data on field work, and all authors read, provided feedback and approved the final submitted version of the manuscript.

All authors declare that they have no competing financial interests.

Footnotes

These authors equally contributed to this work

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Figure 0

Fig. 1. Flow chart of iodine balance study in Chinese adult males.

Figure 1

Table 1. Typical daily meal plan

Figure 2

Table 2. Baseline characteristics of thirty-eight Chinese adult males(Mean values and standard deviations)

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Table 3. Comparison of 24-h UIC and 24-h UIE at baseline and last 2 d of iodine depletion for thirty-eight Chinese adult males(Median values and inter-quartile ranges)

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Table 4. Iodine intake, excretion, retention and Δ iodine intake, Δ excretion and Δ retention for thirty-eight Chinese adult males among the six stages of iodine supplementation*(Mean values and standard deviations)

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Fig. 2. Dose–response relationship of the increment (Δ) of iodine intake and the Δ iodine excretion (a), together with the Δ iodine retention (b) by the mixed effects model (dashed) and linear regression function (solid) for iodine supplementation.

Figure 6

Fig. 3. Dose–response relationship of the increment (Δ) of iodine intake per kilogram of body weight and the Δ iodine excretion per kilogram of body weight (a), together with the Δ iodine retention per kilogram of body weight (b) by the mixed effects model (dashed) and linear regression function (solid) for iodine supplementation.