scholarly journals Iodine prophylaxis around the Semipalatinsk Nuclear Testing Site, Republic of Kazakstan

2003 ◽  
Vol 6 (8) ◽  
pp. 785-789 ◽  
Author(s):  
Aiko Hamada ◽  
Mairash Zakupbekova ◽  
Sagadat Sagandikova ◽  
Maira Espenbetova ◽  
Toshinori Ohashi ◽  
...  
Keyword(s):  
Iodine Deficiency ◽  
Urinary Iodine ◽  
Iodine Concentration ◽  
Radioactive Fallout ◽  
Urinary Iodine Concentration ◽  
Nuclear Testing ◽  
Spot Urine ◽  
Adults And Children ◽  
Testing Site ◽  
Urine Specimens

AbstractObjective:This study aimed to clarify the iodine deficiency status in the Semipalatinsk region that has been contaminated by radioactive fallout from nuclear testing during the period of the former USSR.Design:Based on the Japan–Kazakstan joint project of adult cancer screening around the Semipalatinsk Nuclear Testing Site (SNTS), from May to October 2002 spot urine specimens were collected at random in each village. Separately, children aged 5–15 years from around the SNTS were chosen at random and spot urine specimens were collected from them.Setting:Area contaminated by radioactive fallout around the SNTS, Republic of Kazakstan.Subjects:A total of 2609 adults aged >40 years from 16 settlements in three regions and one city, and 298 children aged 5–15 years from two regions and one city.Results:Median urinary iodine concentrations of adults and children in all regions were in the range of 116.0–381.7 and 127.7–183.0 μg l−1, respectively. The highest prevalence of values <50 μg l−1(14.1%) did not exceed 20%. Distributions within each group, adults and children, showed almost the same pattern, except for one region where more than 50% of adults had urinary iodine concentration >100 μg l−1.Conclusions:In agreement with our previous studies, the urinary iodine concentration data showed no clear evidence of iodine deficiency around the SNTS. Kazakstan is geographically and nutritionally at moderate risk of iodine deficiency disorders without fortification or iodine replacement by iodised salt. The socio-medical prophylaxis against iodine deficiency has been successfully maintained in East Kazakstan.

scholarly journals Iodine status of consumers of milk-alternative drinks v. cows’ milk: data from the UK National Diet and Nutrition Survey

2020 ◽  
pp. 1-9
Author(s):  
M. Dineva ◽  
M. P. Rayman ◽  
S. C. Bath
Keyword(s):  
At Risk ◽  
Iodine Deficiency ◽  
Urinary Iodine ◽  
Iodine Concentration ◽  
Iodine Intake ◽  
Urinary Iodine Concentration ◽  
Nutrition Survey ◽  
Iodine Status ◽  
Adults And Children ◽  
The Uk

Abstract Milk is the main source of iodine in the UK; however, the consumption and popularity of plant-based milk-alternative drinks are increasing. Consumers may be at risk of iodine deficiency as, unless fortified, milk alternatives have a low iodine concentration. We therefore aimed to compare the iodine intake and status of milk-alternative consumers with that of cows’ milk consumers. We used data from the UK National Diet and Nutrition Survey from years 7 to 9 (2014–2017; before a few manufacturers fortified their milk-alternative drinks with iodine). Data from 4-d food diaries were used to identify consumers of milk-alternative drinks and cows’ milk, along with the estimation of their iodine intake (µg/d) (available for n 3976 adults and children ≥1·5 years). Iodine status was based on urinary iodine concentration (UIC, µg/l) from spot-urine samples (available for n 2845 adults and children ≥4 years). Milk-alternative drinks were consumed by 4·6 % (n 185; n 88 consumed these drinks exclusively). Iodine intake was significantly lower in exclusive consumers of milk alternatives than cows’ milk consumers (94 v. 129 µg/d; P < 0·001). Exclusive consumers of milk alternatives also had a lower median UIC than cows’ milk consumers (79 v. 132 µg/l; P < 0·001) and were classified as iodine deficient by the WHO criterion (median UIC < 100 µg/l), whereas cows’ milk consumers were iodine sufficient. These data show that consumers of unfortified milk-alternative drinks are at risk of iodine deficiency. As a greater number of people consume milk-alternative drinks, it is important that these products are fortified appropriately to provide a similar iodine content to that of cows’ milk.

scholarly journals Vegans, Vegetarians and Pescatarians Are at Risk of Iodine Deficiency in Norway

Nutrients ◽  
2020 ◽  
Vol 12 (11) ◽  
pp. 3555
Author(s):  
Synne Groufh-Jacobsen ◽  
Sonja Y. Hess ◽  
Inger Aakre ◽  
Elin Lovise Folven Gjengedal ◽  
Kristina Blandhoel Pettersen ◽  
...  
Keyword(s):  
Iodine Deficiency ◽  
Dietary Assessment ◽  
Linear Regression Analysis ◽  
Urinary Iodine ◽  
Knowledge Score ◽  
Iodine Concentration ◽  
Multiple Linear Regression Analysis ◽  
Iodine Intake ◽  
Urinary Iodine Concentration ◽  
Spot Urine

Low iodine intakes have been documented in different population groups in Norway. We aimed to assess iodine status, dietary intake, supplement and macroalgae use, and iodine knowledge in vegans, vegetarians and pescatarians. In this study, 115 vegans, 55 vegetarians and 35 pescatarians from the Oslo region of Norway, aged 18–60 years, participated. A spot urine sample was collected along with a dietary assessment of iodine intake, supplement and macroalgae use. The median urinary iodine concentration (MUIC) in vegans was 43 µg/L (moderate iodine deficiency), in vegetarians 67 µg/L and in pescatarians 96 µg/L (mild iodine deficiency). In multiple linear regression analysis, use of iodine supplements was one of the strongest predictors of UIC. About half of the participants had median 24-h iodine intakes below estimated average requirement (EAR) of 100 µg/day. Fifty percent had low knowledge score, while 27% had very low knowledge score. Vegans, vegetarians and possibly pescatarians in Norway, are unable to reach the recommended iodine intake merely from food and are dependent on iodine supplements. There is an urgent need for dietary guidance targeting vegans, vegetarians and pescatarians to avoid inadequate iodine intake in non-supplement users, as well as avoiding excess iodine intake in macroalgae users.

scholarly journals Suboptimal Iodine Status and Low Iodine Knowledge in Young Norwegian Women

Nutrients ◽  
2018 ◽  
Vol 10 (7) ◽  
pp. 941 ◽  
Author(s):  
Sigrun Henjum ◽  
Anne Brantsæter ◽  
Astrid Kurniasari ◽  
Lisbeth Dahl ◽  
Eli Aadland ◽  
...  
Keyword(s):  
Iodine Deficiency ◽  
Young Women ◽  
Inductively Coupled Plasma ◽  
Urinary Iodine ◽  
Knowledge Score ◽  
Iodine Concentration ◽  
Iodine Intake ◽  
Urinary Iodine Concentration ◽  
Iodine Status ◽  
Spot Urine

Previous studies have documented mild to moderate iodine deficiency in pregnant and lactating women in Norway. This study focused on non-pregnant young women because their future children may be susceptible to the adverse effects of iodine deficiency. We assessed urinary iodine concentration (UIC), iodine intake from food and supplements, and iodine knowledge in 403 non-pregnant women, mainly students, aged 18–30 years. Iodine concentration was measured in spot urine samples analyzed by inductively coupled plasma mass spectrometry and iodine intake was calculated from a self-reported food frequency questionnaire. Knowledge about iodine was collected through the self-administered, paper-based questionnaire. Median (p25–p75) UIC was 75 (42–130) µg/L and 31% had UIC < 50 µg/L. Habitual iodine intake was 100 (69–136) µg/day. In multiple regression models, supplemental iodine, use of thyroid medication, and iodine intake from food were positively associated with UIC, while vegetarian practice was negatively associated, explaining 16% of the variance. Approximately 40% of the young women had low iodine knowledge score and no differences were found between women in different study programs. Young women in Norway are mild to moderately iodine-deficient, and public health strategies are needed to improve and secure adequate iodine status.

scholarly journals Clinical practice guidelines “Management of iodine deficiency disorders”

2021 ◽  
Vol 67 (3) ◽  
pp. 10-25
Author(s):  
F. M. Abdulkhabirova ◽  
O. B. Bezlepkina ◽  
D. N. Brovin ◽  
T. A. Vadina ◽  
G. A. Melnichenko ◽  
...  
Keyword(s):  
Clinical Practice ◽  
Iodine Deficiency ◽  
Clinical Guidelines ◽  
Multinodular Goiter ◽  
Urinary Iodine ◽  
Iodine Concentration ◽  
Epidemiological Studies ◽  
Urinary Iodine Concentration ◽  
Iodine Deficiency Disorders ◽  
Adults And Children

Iodine deficiency disorders is a sweeping term that includes structural and functional impairment of the thyroid gland.These clinical guidelines include algorithms for the diagnosis and treatment of euthyroid goiter and nodular/ multinodular goiter in adults and children. In addition, these clinical guidelines contain information on methods for an adequate epidemiological assessment of iodine deficiency disorders using such markers as the percentage of goiter in schoolchildren, the median urinary iodine concentration, the level of neonatal TSH, the median thyroglobulin in children and adults. As well from these clinical guidelines, you can get to know the main methods and groups of epidemiological studies of iodine deficiency disorders.

scholarly journals High Iodine Deficiency among Pregnant Women in Periurban Ghana: A Hospital-Based Longitudinal Study

2018 ◽  
Vol 2018 ◽  
pp. 1-5
Author(s):  
David Larbi Simpong ◽  
Yaw Asante Awuku ◽  
Kenneth Kwame Kye-Amoah ◽  
Martin Tangnaa Morna ◽  
Prince Adoba ◽  
...  
Keyword(s):  
Longitudinal Study ◽  
Pregnant Women ◽  
Iodine Deficiency ◽  
Urinary Iodine ◽  
Clinical Information ◽  
Iodine Concentration ◽  
Iodized Salt ◽  
Urinary Iodine Concentration ◽  
Study Cohort ◽  
Iodine Sufficiency

Background. Iodine deficiency causes maternal hypothyroidism which can lead to growth, cognitive, and psychomotor deficit in neonates, infants, and children. This study examined the iodine status of pregnant women in a periurban setting in Ghana. Methods. This longitudinal study recruited 125 pregnant women by purposeful convenience sampling from the antenatal clinic of the Sefwi Wiawso municipal hospital in Ghana. Urinary iodine concentration (UIC) was estimated by the ammonium persulfate method at an estimated gestational age (EGA) of 11, 20, and 32 weeks. Demographic information, iodized salt usage, and other clinical information were collected using a questionnaire. Results. The prevalence of iodine deficiency among the pregnant women was 47.2% at EGA 11 and 60.8% at both EGA of 20 and 32, whereas only 0.8% of participants not using iodized salt had iodine sufficiency at EGA 32. 18.4%, 20%, and 24% of participants using iodized salt had iodine sufficiency at EGA 11, 20, and 32, respectively. Conclusion. A high prevalence of iodine deficiency was observed among our study cohort.

scholarly journals Urinary iodine concentration: a biochemical parameter for assessing the iodine status

Mediscope ◽  
2018 ◽  
Vol 5 (2) ◽  
pp. 30-35
Author(s):  
GM Molla
Keyword(s):  
Iodine Deficiency ◽  
Urinary Iodine ◽  
Iodine Concentration ◽  
Iodine Intake ◽  
Urinary Iodine Concentration ◽  
Lactating Women ◽  
Iodine Status ◽  
Excessive Iodine ◽  
Pregnancy And Lactation ◽  
Neonates And Infants

Iodine is a micronutrient, which is essential for the synthesis of thyroid hormones. Thyroid hormones play a major role in the development of different functional components in different stages of life. The relationship between iodine intake level of a population and occurrences of thyroid disorders U-shaped with an increase from both low and high iodine intake. Iodine deficiency disorders (IDDs) are a major health problem worldwide in all age groups, but infants, school children, and pregnant and lactating women are vulnerable. During pregnancy and lactation, the fetus and infants are sensitive to maternal iodine intake. Even mild iodine deficiency may lead to irreversible brain damage during this period. A main cause of IDDs of neonates and infants is maternal iodine deficiency. Universal salt iodization strategy has been initiated by the World Health Organization and United Nation International Children Emergency Fund by the year 1993 for correction and prevention of iodine deficiency. Excessive iodine causes hypothyroidism, iodine-induced hyperthyroidism and autoimmune thyroid diseases. Iodine deficiency and excessive iodine, both cause goiter. There are many indicators for assessing the IDDs, such as measurement of thyroid size by palpation or ultrasonography, serum thyroid stimulating hormone, and thyroglobulin but these are less sensitive, costly and sometimes interpretation is difficult. Urinary iodine concentration (UIC) is a well-accepted, cost-efficient, and easily obtainable indicator of iodine status. Since the majority of iodine absorbed by the body is excreted in the urine, it is considered a sensitive marker of current iodine intake and can reflect recent changes in iodine status. Iodine requirements are greatly increased during pregnancy and lactation, owing to metabolic changes. During intrauterine life, maternal iodine is the only source of iodine for a fetus. UIC determines the iodine status of pregnant and lactating women. Breast milk is the only source of iodine for exclusively breastfed neonates and infants. Breast milk iodine concentration can be determined by UIC. UIC predicts the adverse health consequences of excessive iodine intake such as goiter, hypothyroidism, and hyperthyroidism. This review presents that iodine status in different groups of a population can be determined by UIC which will be helpful in assessing the iodine status in a community, finding out the cause of thyroid disorders, to predict the risk of adverse health effects of iodine deficiency and excessive iodine, and in making plan for iodine supplementation.Mediscope Vol. 5, No. 2: Jul 2018, Page 30-35

scholarly journals The assessment of iodine status – populations, individuals and limitations

2018 ◽  
Vol 56 (1) ◽  
pp. 7-14 ◽  
Author(s):  
Patrick Wainwright ◽  
Paul Cook
Keyword(s):  
Iodine Deficiency ◽  
Urinary Iodine ◽  
Population Level ◽  
Iodine Concentration ◽  
Epidemiological Studies ◽  
Health Concern ◽  
Urinary Iodine Concentration ◽  
Iodine Status ◽  
The Uk

Iodine deficiency is a significant global health concern, and the single greatest cause of preventable cognitive impairment. It is also a growing public health concern in the UK particularly among pregnant women. Biomarkers such as urinary iodine concentration have clear utility in epidemiological studies to investigate population-level iodine status, but determination of iodine status in individuals is much more problematic with current assays. This article reviews the available biomarkers of iodine status and their relative utility at the level of both populations and individuals for the investigation of iodine deficiency and iodine excess.

scholarly journals Indicators of Iodine Status in Pregnancy and Postpartum in a Group of Pregnant Women from Perimarine Area of Romania

2020 ◽  
Vol 26 (2) ◽  
pp. 63-69
Author(s):  
Scrinic Olesea ◽  
Delia Corina Elena ◽  
Toma Geanina Mirela ◽  
Circo Eduard
Keyword(s):  
Pregnant Women ◽  
Iodine Deficiency ◽  
Urinary Iodine ◽  
Iodine Concentration ◽  
Iodine Intake ◽  
Iodized Salt ◽  
Urinary Iodine Concentration ◽  
Urinary Creatinine ◽  
Iodine Status ◽  
In Pregnancy

Abstract Objective: Assessment of iodine nutritional status in pregnant women in the perimarine area of Romania, a region without iodine deficiency. Adequate iodine intake is the main source for normal thyroid function, ensuring the need for maternal thyroid hormones during pregnancy, but also for the development and growth of children in the fetal and postpartum period. Material and method: Prospective study performed on 74 pregnant women in the first 2 trimesters of pregnancy, originating from the perimarin area. The following indicators of iodine status were analyzed: urinary iodine concentration (UIC), the ratio between urinary iodine concentration and urinary creatinine (UIC/UCr), the prevalence of maternal goiter and the value of neonatal TSH (thyroid stimulating hormone). Results: The mean gestational age was 11 weeks. The ways of iodine intake are: iodized salt - 59.4%, iodized salt and iodine supplements- 23%, only iodine supplements -10.8% and 6.8% consume only non-iodized salt. The median of UIC was 133.03 mcg/l considered insufficient iodine intake (normal in pregnancy UIC >150 mcg/l), but the adjustment of UIC to urinary creatinine reveals a median of 152.83 mcg/g, a value that reflects an adequate iodine intake. The prevalence of goiter was 25.6% characteristic for a moderate iodine deficiency. The prevalence of neonatal TSH >5 mIU/L was registered in 18.8% characteristic of mild iodine deficiency. Conclusions: Monitoring of the iodine nutritional status is recommended for the prevention of disorders due to iodine deficiency under the conditions of universal salt iodization. Perimarine areas considered sufficient in iodine may show variations in iodine status in subpopulations under certain physiological conditions, such as pregnancy. An indicator of iodine status of the population is UIC, but the UIC/UCr ratio may be a more optimal indicator for pregnant women, to avoid possible overestimated results of iodine deficiency in pregnancy.

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