Abstract
Iodine is an essential trace element for humans. Foliar application of micronutrients is successfully used in order to increase the concentration of essential elements in vegetables. The aim of this study was to evaluate the iodine absorption in the rat organism fed foliar biofortified lettuce. The presented study was consisted of the vegetative and animal experiment. In the vegetative experiment with lettuce, two combinations of foliar application were used: (1) control—without iodine application and (2) iodine application in the potassium iodide (KI) form. In the animal experiment, Wistar rats were divided to four groups, which received one of four diets: (1) C—control diet containing iodine in the KI form, (2) D—diet deficient in iodine, (3) D + BL—diet containing biofortified lettuce, and (4) D + CL—diet containing control lettuce (as the only source of iodine in diet, respectively). The diets contained 0.260, 0.060, 0.254 and 0.075 mg I/kg, respectively. In order to determine the iodine absorption in the rat organisms, the content of this trace element was measured in urine, faeces and in selected organs with the use of the ICP-OES technique. Foliar application of the KI increased the content of iodine in lettuce. The rats from the D + BL group excreted significantly less iodine in their urine and faeces and also accumulated more iodine in the organs than the rats from the C group. Iodine with biofortified lettuce was much bioavailable for rodents than iodine from control diet. Biofortified lettuce can be a source of iodine in a diet of human and can improve iodine nutrition.
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Introduction
Iodine is a very important micronutrient for the proper functioning of thyroid hormones, which regulate the metabolism and has crucial impact on brain development in humans and animals. Iodine deficiency (ID) causes health problems known as iodine deficiency disorders (IDD) such as goitre, hypothyroidism, foetus anomalies and mental retardation [1–3]. Further, even moderate ID results in loss of 10–15 IQ points at a population level that indirectly affects the development of whole nations [1].
The World Health Organization (WHO) and United Nations International Children’s Emergency Fund (UNICEF) have recommended the commonly implemented Universal Salt Iodization (USI) programme to counteract consequences of IDD. This programme has been a safe, efficient and cost-effective method of elimination of iodine deficiency in many countries [4, 5]. The progress in reducing the ID problem in the world was made in 2003–2011. In this period, the number of iodine-deficient countries decreased from 54 to 32 and the number of countries with adequate iodine intake increased from 67 to 105. Currently, 71 % of the population in the world has access to iodized salt, up from 20 % in 1990. However, despite this remarkable progress, around 1.9 billion people including 241 million school-age children are still at risk of ID [5, 6].
In less-industrialised countries, where salt iodization programmes have been introduced, progress in reduction of ID is observed [7]. However, in some industrialised countries, iodine intake has fallen and problem of ID has reappeared. The governments should conduct systematic assessment and monitoring of ID in populations, and every country should have a prophylaxis programme to address ID. Presently, half of the European population is mildly ID as a result of weak or non-existent iodine prophylaxis in Europe. Approximately 90 % of the salt consumption in industrialised countries is from processed food, in which salt is not always iodized [8]. Moreover, epidemiological research has shown that high salt intake is associated with significantly increased risk of stroke and other cardiovascular diseases [9]. The level of salt consumption exceeds the amount recommended by the WHO (5 g NaCl/day). In Europe and Asia, daily average consumption of salt is higher than 12 g [9, 10]. In the years 2008–2013, the WHO implemented the programme ‘Global Strategy on Diet, Physical Activity and Heath’, aimed at the reduction of salt consumption and identification of alternative ways of iodine introduction into food [11]. One of these methods can be biofortification of vegetables with iodine, through foliar application during cultivation [12, 13]. In human diet, over 80 % of iodine is from vegetal foodstuffs. Almost 100 % of iodine in food is bioavailable to humans [14]. Therefore, biofortification of vegetables with iodine could be an effective way to reduce and control ID in developed and developing countries. Lettuce was chosen as a good candidate for biofortification study because of the leaves—edible parts of this vegetable store a lot of iodine. Lettuce is almost always eaten raw with no risk of iodine loss during cooking. In addition, lettuce can be cultivated year-round.
The objective of this study was to evaluate the effect of the addition of the foliar biofortified lettuce with iodine in the potassium iodide (KI) form into rats’ diet and the iodine content in urine, faeces, selected organs as well as the thyroid-stimulating hormone (TSH) concentration in Wistar rats.
Materials and Methods
Plant Material
The experiment with hydroponic cultivation of lettuce cv. ‘Melodion’ was conducted in the spring season of 2012 in non-heated foil tunnel belonging to the Faculty of Biotechnology and Horticulture, University of Agriculture. The seedlings were produced in a greenhouse. Lettuce seeds were sown into rockwool plugs in the first half of March (12 March 2012). The seedlings were placed on rockwool blocks (10 × 10 × 6.5 cm) in a two-leaf phase. After rooting, plants in rockwool blocks were transferred to the foil tunnel. The plants received a nutrient solution with the following content of macro- and micronutrients (mg/dm3): 120 N, 25 P, 160 K, 40 Mg, 140 Ca, 0.8 Fe, 0.6 Mn, 0.3 Zn, 0.2 B, 0.1 Cu, 0.02 Mo, pH 6.0 and EC 1.6 mS/cm. The nutrient solution was applied by drip irrigation system in an open cycle (without recirculation of nutrient solution).
The lettuce plants were divided randomly into two combinations, the first with foliar application of distilled water (control) and the second with foliar application of iodine in the KI form which was soluted in distilled water. Both combinations were consisted of four replicates with 14 plants in each replicate. Foliar application was conducted thrice, every 7 days from the phase of six leaves till 7 days before the harvest. The concentration of iodine used for spraying was 0.001 % (10 mg/dm3). Totally, for three treatments, 107 cm3 of water or KI solution was used to each lettuce plant. Each head of lettuce received 1.07 mg iodine applied foliarly. At harvest (16 May 2012), representative samples of lettuce plants from both combinations were collected for the animal experiment.
Analysis in Plant Material
Fresh samples of lettuce were frozen and freeze-dried with lyophilizer (Christ Alpha 1–4, Gefriertrocknungsanlangen, Germany). In such prepared samples, the chemical composition was estimated. Total proteins (method no. 950.36), raw fat (method no. 935.38), total dietary fibre (method no. 991.43) and ash (method no. 930.05) were measured according to the AOAC [15] methods.
The nitrates (V) (NO3 −) content was analysed after extraction of 5 g fragmented fresh lettuce samples in 100 cm3 of 2 % acetic acid (aqueous solution of acetic acid). The NO3 − concentration was measured by the Flow Injection Analysis technique (FIA technique, FIA system, MLE GmbH Dresden, Germany) [16].
In order to analyse iodine content, air-dried lettuce samples were ground in a variable speed rotor mill Pulverisette 14 FRITSCH (Idar-Oberstein, Alemania, Germany) using a 0.5-mm sieve. Digestion of 0.5 g samples of lettuce in the mixture of 10 cm3 65 % HNO3 and 0.8 cm3 70 % HClO4 was conducted in the microwave system MARS-5 Xpress (CEM, World Headquarters, Matthews, NC, USA). The content of iodine was analysed by the cold vapour generation technique with the use of high-dispersion inductively coupled plasma optical emission spectrometry (ICP-OES, Prodigy spectrometer, Leeman Labs, USA) [17, 18]. A similar method was used for the determination of iodine content in the experimental diets of rats. To evaluate the accuracy of the analysis, the content of iodine in certified spinach leaves reference material (NCS ZC73013) was additionally determined. The obtained result was 0.39 ± 0.08 mg I/kg d.m., while the certified value was 0.36 ± 0.12 mg I/kg d.m.
Animal Study
Four-week-old male Wistar rats (n = 32), with an average body mass of 123 ± 10 g, were purchased from Animal Husbandry in Brwinów, Warsaw, Poland. Experimental procedures were approved by the First Local Ethical Committee on Animal Testing at the Jagiellonian University in Krakow (Poland, res. no 57/2012). The rats were acclimatised for 1 week on standard laboratory chow, before the experiment. After that, the rats were randomly divided into four experimental groups (n = 8).
Experimental diets have been prepared on the basis of the AIN-93G diet [19]. Detailed description of diets is reported in Table 1. In the first group, the rats were fed control diet (C) in which the mineral mixture contained the iodine (in the KI form) in an amount recommended by Reeves [19]. In the second group, diet deficient in iodine (D) was prepared with mineral mixture without iodine. In the next group, diet deficient in iodine contained biofortified lettuce (D + BL)—lettuce as the only source of iodine (mineral mixture without iodine) was used. Biofortified lettuce was added to the D + BL in order to obtain the same amount of iodine as in the C diet. Diet deficient in iodine of the fourth group of rats contained control (non-biofortified) lettuce (D + CL) (mineral mixture without iodine). The level of iodine in the mineral mixture of D diet was the same as in the diet with non-biofortified lettuce (D + CL) (Table 1).
The rats were housed separately in stainless steel metabolic cages at 21 °C and 12/12-h light/dark cycle. During the experiment, animals had free access to deionised distilled water. The intake of experimental diets was recorded every day. Body weight gain was recorded during the whole experiment on a weekly basis.
Urine and faeces were collected between the 8th–12th (5 days in the second week of experiment) and 22th–26th (5 days in the fourth week of the experiment) day of the experiment to assess iodine excretion. Collected urine and faeces were kept separately at −20 °C until the analyses. After 5 weeks of experimental period, fasted rats were sacrificed by decapitation, blood was obtained by heart puncture and collected in plain test tubes. Blood samples were collected to obtain serum by centrifugation (1500×g, 15 min.). Kidneys, livers, hearts and femoral muscles were dissected, washed in 0.9 % sodium chloride, dried with laboratory tissue paper and weighed. Serum and organ samples were kept frozen at −80 °C until the analysis.
Analysis in Serum and Blood
The level of TSH was measured in the serum with a Rat TSH ELISA kit (cat. no RTC007R BioVendor, BioVendor Laboratorini medicina, Brno, Czech Republic). The serum was analysed for the concentration of total cholesterol (TC) (cat no. Liquick Cor-CHOL60 2–204, PZ Cormay S.A. Lublin, Poland), high-density lipoprotein (HDL) cholesterol (cat no. Cormay HDL 2–053, PZ Cormay S.A. Lublin, Poland) and triacylglycerols (TAG) (cat no. Liquick Cor-TG60 2–253, PZ Cormay S.A. Lublin, Poland). The differences between TC and HDL were used for calculations of the amount of low-density lipoprotein and very low-density lipoprotein (LDL + VLDL) cholesterol level [20]. The level of glucose was measured in the whole blood with a glucometer (Accu-chek, Roche Diagnostic, Mannheim, Germany). The activity of alanine aminotransferase (ALT) and aspartate aminotransferase (AST) in the serum was measured using Alpha Diagnostic kits (cat no. TR70121 and TR71121, respectively; Alpha Diagnostic, Warsaw, Poland). The concentration of malondialdehyde (MDA) in the serum was measured using colorimetric assay with thiobarbituric acid [21]. Standard curve was used to determine the concentration of MDA.
Analysis of Crude Lipid and MDA Level in the Liver
The level of crude fat was determined by the Soxhlet method with a Soxtec Avanti’s 2050 Auto Extraction Unit (Tecator Foss, Hillerød, Sweden) according to Kopeć et al. [22]. The concentration of MDA in the liver homogenate was measured using colorimetric assay with thiobarbituric acid [21]. Standard curve was used to determine the concentration of MDA.
Iodine Content in Urine, Faeces and Selected Organs
Collected samples of urine were adjusted to the same volume before analysis. The faeces and organs (kidneys, livers, hearts and femoral muscles) were freeze-dried. After freeze-drying, the organs were weighed and crushed in mortal and pestle. Thus prepared samples (particle size about 1 mm) were used for measurements of iodine content. The content of iodine in these samples was analysed by the cold vapour generation technique with the use of ICP-OES [17, 18] after sample digestion in the mixture of 10 cm3 65 % HNO3 and 0.8 cm3 70 % HClO4 in the microwave system CEM MARS-5 Xpress.
Statistical Analysis
The data was presented as mean ± SD. ANOVA with the Tukey test was used for testing the differences between experimental treatments. For the iodine content in urine or faeces, a two-way MANOVA with the Tukey test was used to study the effects between treatment and week (second and fourth) of experiment, P ≤ 0.05 (Statistica v. 12.5 StatSoft, Inc., Tulsa, OK, USA).
Results
The foliar application of iodine in the form of KI in the hydroponic cultivation of lettuce did not affect the basic chemical composition of lettuce plants, compared to the control plants. However, the content of NO3 − was significantly lower in biofortified lettuce in comparison to non-biofortified lettuce. The level of iodine was significantly higher in the biofortified lettuce than in the control plants (Table 2).
The experimental diets did not affect body weight gain, food efficiency ratio (FER) and weight of kidneys, liver, heart and femoral muscle of rats (Table 3).
On the other hand, the experimental diets had a significant effect on selected biochemical parameters in rodents (Table 4). The level of TSH in the serum of rats fed the C and D + BL diets was significantly lower, compared to rats fed the D and D + CL diets. The concentration of TC was the highest in the serum of rats fed diet with biofortified lettuce. The level of TC was higher in the rats of group D + BL, in comparison to the D group. The content of LDL + VLDL cholesterol in the serum of rodents group D + BL was significantly higher than in the other experimental groups. The HDL level in the serum of the rats was not affected by the various dietary treatments. The TAG concentration in the serum as well as the glucose in the blood of the rats fed diets with biofortified and non-biofortified lettuce was significantly lower than in those fed C and D diets. The highest level of TAG was measured in the serum of rats fed the C diet. The content of crude fat in the liver of D group rats was significantly higher, compared to the C and D + BL groups. Various dietary treatments did not affect the activity of ALT and AST in the serum of rats. Statistically significant differences in the concentration of MDA in the liver and in the serum of the rats fed various experimental diets were also not found (Table 4).
The experimental diets had a significant effect on iodine excretion with urine and faeces in rats (Table 5). The highest iodine excretion was measured in urine and faeces of rats fed the C diet. The concentration of iodine in urine and faeces of groups fed C and D + BL diets was higher than groups fed D and D + CL diets. Significant differences in excretion of iodine with urine or faeces between the second and the fourth week were observed. The rats fed C diet excreted more iodine with urine in the second week in comparison to the fourth week, while rats of the third group excreted faeces with more iodine in the second week compared to the fourth week (Table 5).
Significant differences in the concentration of iodine in selected organs were also found between the experimental groups of rats (Table 5). The rodents fed the diet with addition of biofortified lettuce (D + BL) accumulated the highest content of iodine in the kidneys, liver, heart and femoral muscle. The concentration of iodine in the organs of rats fed D and D + CL diets was lower, compared to C and D + BL diets. The rats from the D + CL group accumulated more iodine in the liver and heart than the rats from the D group (Table 5).
Discussion
The main objective of biofortification is increasing the content of the mineral elements in edible tissues of crop plants. This action is focused on the nutrients commonly lacking in human diets, i.e.: Fe, Zn, Cu, Ca, Mg, Cu, I or Se [23, 24]. Foliar nutrition of plants described also as foliar feeding, fertilisation or application is one of the most efficient and the fastest methods of plants enrichment in these elements [25]. The agronomic methods of biofortification of leafy vegetables with iodine allow to achieve satisfying results of the iodine concentration in edible parts of these plants, making them good candidates for iodine source in the human diet. The previously published researches showed successful results of enrichment of spinach [26, 27] lettuce [28, 29] or pakchoi [30] with iodine. Weng et al. [14] reported that the leafy vegetables store more iodine in edible tissues than the fruit vegetables, which is even about 70-fold more. Because of the controllable and efficient systems for crop growing, the hydroponic cultivation makes a great possibility for biofortification with iodine [29, 31, 32]. This type of cultivation also allows for year-round production of vegetables. Lettuce is one of the most commonly grown hydroponic vegetables and is very effective in the uptake of iodine [29]. In this study, the foliar application of iodine in the form of iodide (I−) was an efficient method of lettuce biofortification grown in a hydroponic system. The level of iodine in biofortified lettuce was higher, about 420 %, compared to control plants. Simultaneously, foliar application of iodine did not affect the chemical composition of lettuce (beside the content of NO3 −). In the Kopeć et al. [33] study, soil fortification of lettuce with iodine also increased the concentration of this trace element in plants and had no effect on chemical parameters of plants. Lettuce heads accumulates a lot of NO3 −, which in the organism can interfere with iodine metabolism by inhibiting iodine uptake by the thyroid gland, which leads to the development of goitre in humans [34] and animals [35]. Interesting is the fact that in this study significant reduction of NO3 − content in lettuce leaves was affected by foliar application of the KI. Blasco et al. [36] also showed that lettuce biofortified with I− accumulated less NO3 − in comparison to control plants. It can be suggested that biofortification of lettuce with I− inhibits metabolism of NO3 − in plants.
Lettuce is eaten as a fresh salad. The average daily consumption of lettuce is around 50 g [29]. In our study, biofortified lettuce, which was produced in this experiment, contained 103 μg I in 50 g fresh mass of leaves. Therefore, it is 70 % of the recommended daily intake (RDI) of iodine, which is 150 μg for adult persons per day. Consequently, supplementation of diet in foliar biofortified lettuce may improve human nutrition in iodine. Moreover, greenhouse hydroponic production of plants enriched with iodine by foliar application makes them available for all seasons of the year. These plants may be an alternative to iodized salt and part of iodine prophylaxis.
The evaluation of bioavailability of iodine in the body of rats with biofortified lettuce can prove the effectiveness of lettuce foliar biofortification with iodine. The diets used in the experiment were properly balanced, and the rats consumed whole daily portion of the diet. The addition of biofortified and non-biofortified lettuce to the diets had no effect of FER, body gain and weights of the kidneys, liver, heart as well as femoral muscle of rats. In addition, Kopeć et al. [33] observed that the addition of biofortified lettuce (cultivated in filed condition) with iodine to diet of rats was safe for them.
The diagnosis of ID is based on the analysis of the thyroid goitre development, examination of the concentration of TSH, as well as the concentration of iodine in urine [2, 4]. Two methods of ID diagnosis were used in this study. The first was analysis of the level of thyroid-stimulating hormone which is the biochemical marker of thyroid gland function and its hormones. The TSH increases the uptake of iodine by the thyroid gland and stimulates secretion of the hormones thyroxine (T4) and triiodothyronine (T3) to the blood [37]. The increased TSH level can indicate the T4 and T3 synthesis disorder and on the insufficient supply of iodine in the diet. In the rats fed control diet (C) and diet with addition of biofortified lettuce (D + BL), the level of TSH was significantly lower than in the second and the fourth group of rats (D and D + CL). It indicates that iodine from biofortified lettuce was bioavailable for rats and was consequently used for the synthesis of thyroid hormones, whereas the increased TSH level in the serum of rats from the D and D + CL groups indicated an insufficient level of iodine in these diets, compared to the requirements of rats of this trace element.
The concentration of the TC and the LDL + VLDL cholesterol was the highest in the serum of rats fed diet containing biofortified lettuce (D + BL), while the level of accumulation of crude fat in the liver of this group was the lowest. Probably, it resulted from the fact that biologically active components in the lettuce, such as poliphenolics and short-chain fatty acids produced from lettuce fibre in the colon by bifidobacteria could inhibit the triacylglycerols and cholesterol accumulation in the liver [33]. However, the level of LDL + VLDL cholesterol in the serum of rats fed non-biofortified lettuce (D + CL) was not affected by addition of lettuce. In the rats, the high level of serum HDL and low LDL is connected with the fact that in the blood cholesterol is transported mainly in high-density lipoproteins [38]. Presented in study were results of high level of HDL and low LDL + VLDL in all experimental groups that were also observed in rats of control groups in the Aberare et al. [39], Kopeć et al. [33] and Silva et al. [40] studies. The increased concentration of glucose was observed in both groups fed diets without addition of lettuce (C and D). It is known that fibre slows up absorption of glucose in the intestine and improves blood glucose control [41]; therefore, the content of glucose was significantly lower in the blood of rats fed biofortified and non-biofortified lettuce. In addition, concentration of triacylglycerols in the serum of these rats was also reduced, compared to the first and the second groups. The activity of ALT and AST enzymes is one of the indicators of liver damage. The diets with addition of both types of experimental lettuce had no effect on liver functions. Kopeć et al. [33] also showed that the level of ALT and AST was not affected by addition of iodine biofortified or non-biofortified lettuce to diets of rats. The level of MDA in the serum and in the liver of rats was not affected by various dietary treatments. Malondialdehyde is an oxidative stress biomarker, and its concentration in an organism increases with increasing degree of lipid peroxidation [42]. Addition of lettuce both enriched with iodine and control to the rats’ diets (D + BL and D + CL) did not generate the oxidative stress in their body.
The second method diagnosis of ID used in this study was estimation of the iodine concentration in urine. The estimation of the iodine nutrition in a human is based on its excretion with urine [2, 4], whereas the concentration of iodine in faeces is not important for evaluation of iodine nutrition. However, the iodine nutrition of rats can be evaluated on the basis of the content of iodine in urine, faeces and organs [43, 44]. Kirchgessner et al. [43] observed that the concentration of iodine in urine, faeces and organs of rats increased with the higher content of iodine in the diet. Therefore, it could be suggested that accumulation of iodine in organs is probably aimed at protection of animals before potential occurrence of ID in food.
When iodine in the diet occurs in the form of I−, it is quickly and effectively absorbed in the digestive tract [45]. The iodine in tissues of biofortified vegetables occurs in organic and inorganic forms, but they have not been identified yet. However, it is commonly known that after foliar application of KI on the surface of leaves, I− is absorbed by leaves [46]. The I− uptake by leaves remains mainly in their cells [46, 47], primarily attributable to the cell wall and organelles [14]. Absorption of iodine with these organic structures of plant tissues can be inhibited in the human or animal organism. However, this research has shown that the iodine with biofortified lettuce was more bioavailable than from inorganic KI. The rats fed diet with addition of biofortified lettuce (D + BL) accumulated more iodine in selected organs and excreted less with urine and faeces as compared to the rats fed control diet (C) with addition of KI. Similar tendency was observed in the animal experiment of Kopeć et al. [33].
The excretion of iodine with urine and faeces and accumulation of this trace element in organs were decreased in the D and D + CL groups of rats compared to rats fed control diet and diet with biofortified lettuce (C and D + BL). These results, as well as the increased TSH level in these rats, indicated that the dose of iodine in D and D + CL diets was insufficient for rats. Interesting is the fact that rats fed diet with control lettuce (D + CL) accumulated more iodine in the heart and liver than rats with the D group. It can suggest that absorption of iodine from natural a source (non-biofortified lettuce), besides insufficient iodine dose, was more available than from the D diet.
Tonacchera et al. [48] first showed that iodine from biofortified vegetables is easily bioavailable to the human organism, which indicates that incorporation of biofortified plants into the daily diet can improve human nutrition of iodine. The presented experiment showed evaluation of absorption of iodine in the body of rodents from iodine biofortified lettuce as well as provided an important information about physiological processes in body of rats fed iodine biofortified lettuce.
In summary, spraying KI on lettuce heads in hydroponic cultivation is an effective way to produce lettuce enriched with iodine. Iodine transfer in the food chain from vegetables enriched with this trace element is effective and safe. Iodine with lettuce is bioavailable and easily assimilated by the organism. Biofortified lettuce can be a vehicle of iodine in the daily diet and part of iodine prophylaxis both in developed and developing countries.
References
Delange F (2001) Iodine deficiency as a cause of brain damage. J Postgrad Med 77:217–220
WHO/UNICEF (2007) Iodine deficiency in Europe: a continuing public health problem. Geneva, Switzerland ISBN 9789241593960.
Kabata-Pendias A, Mukherjee A (2007) Trace elements from soil to human. Springer-Verlag, Berlin Heidelberg
WHO (2007) Assessment of iodine deficiency disorders and monitoring their elimination. Geneva, Switzerland ISBN 9789241595827.
Zimmermann MB, Andersson M (2012) Assessment of iodine nutrition in populations: past, present, and future. Nutr Rev 70(10):553–570
Andersson M, Karumbunathan V, Zimmermann MB (2012) Global iodine status in 2011 and trends over the past decade. J Nutr 142:744–750
Jooste P, Andersson M, Assey V (2013) Iodine nutrition in Africa: an update for 2014. Sight and Life 27(3):50–55
Zimmermann MB (2010) Symposium on 'Geographical and geological influences on nutrition': iodine deficiency in industrialised countries. Proc Nutr Soc 69(1):133–143. doi:10.1017/S0029665109991819
Strazzullo P, D’Elia L, Kandala NB, Cappuccio FP (2009) Salt intake, stroke, and cardiovascular disease: meta-analysis of prospective studies. BMJ 339:45–67
Szybiński Z, Jarosz M, Hubalewska-Dydejczyk A, Stolarz-Skrzypek K, Kawecka-Jaszcz K, Traczyk I, Stoś K (2010) Iodine-deficiency prophylaxis and the restriction of salt consumption—a 21st century challenge. J Endokrynol Pol 61(1):135–140
WHO (2008) Action plan for the global strategy for the prevention and control of noncommunicable diseases (pp. 2008-2013). Geneva, Switzerland ISBN 9789241597418.
Smoleń S, Kowalska I, Sady W (2014) Assessment of biofortification with iodine and selenium of lettuce cultivated in the NFT hydroponic system. Sci Hortic 166:9–16
Lawson PG, Daum D, Czauderna R, Meuser H, Härtling JW (2015) Soil versus foliar iodine fertilization as a biofortification strategy for field-grown vegetables. Front Plant Sci 6:450. doi:10.3389/fpls.2015.00450
Weng HX, Hong ChL XIATH, Bao LT, Liu HP, Li DW (2013) Iodine biofortification of vegetable plants—an innovative method for iodine supplementation. Chin Sci Bull 58(17):2066–2072
AOAC (2006) Official methods of analysis, 18th edn. Association of Official Analytical Chemists International, Gaithersburg
Johnson KS, Petty RL (1983) Determination of nitrate and nitrite in seawater by flow injection analysis. Limnol Oceanogr 28(6):1260–1266. doi:10.4319/lo.1983.28.6.1260
Vtorushina EA, Saprykin AI, Knapp G (2008) Optimization of the conditions of oxidation vapor generation for determining chlorine, bromine and iodine in aqueous solutions by inductively coupled plasma atomic-emission spectrometry. J Anal Chem 63(7):643–648
Vtorushina EA, Saprykin AI, Knapp G (2009) Use of oxidation and reduction vapor generation for lowering the detection limits of iodine in biological samples by inductively coupled plasma atomic emission spectrometry. J Anal Chem 64(2):129–135
Reeves PG (1997) Components of the AIN-93 diets as improvements in the AIN-76A diet. J Nutr 127:838–841
Friedewald WT, Fredrick DS, Levy RI (1972) Estimation of concentration of low-density lipoprotein cholesterol in plasma, without use of preparative ultracentrifuge. Clin Chem 18:499–502
Ohkawa H, Ohishi N, Yagi K (1979) Assay for peroxides in animal tissue by thiobarbituric acid reaction. Anal Biochem 95:351–358
Kopeć A, Piątkowska E, Leszczyńska T, Koronowicz A (2013) Effect of long term administration of resveratrol on lipid concentration in selected organs and liver’s histolgy in rats fed high fructose diet. J Funct Foods 5:299–305
White PJ, Broadley MR (2005) Biofortifying crops with essential mineral elements. Trends Plant Sci 10(12):586–593
White PJ, Broadley MR (2009) Biofortification of crops with seven mineral elements often lacking in human diets—iron, zinc, copper, calcium, magnesium, selenium and iodine. New Phytol 182(1):49–84
Smoleń S (2012) Foliar nutrition: current state of knowledge and opportunities. In: Srivastava AK (ed) Advances in citrus nutrition. Springer Science & Business Media, Dordrecht, pp 41–58
Zhu YG, Huang YZ, Hu Y, Liu YX (2003) Iodine uptake by spinach (Spinacia oleracea L.) plants grown in solution culture: effects of iodine species and solution concentrations. Environ Int 29:33–37
Dai JL, Zhu YG, Huang YZ, Zhang M, Song JL (2006) Availability of iodide and iodate to spinach (Spinacia oleracea L.) in relation to total iodine in soil solution. Plant Soil 289:301–308
Blasco B, Rios JJ, Cervilla LM, Sanchez-Rodriguez E, Ruiz JM, Romero L (2008) Iodine biofortification and antioxidant capacity of lettuce: potential benefits for cultivation and human health. Ann Appl Biol 152:289–299
Voogt W, Holwerda HT, Khodabaks R (2010) Biofortification of lettuce (Lactuca sativa L.) with iodine: the effect of iodine form and concentration in the nutrient solution on growth, deveopment and iodine uptake of lettuce grown in water culture. J Sci Food Agr 90:906–913
Dai JL, Zhu YG, Zhang M, Huang YZ (2004) Selecting iodine—enriched vegetables and the residual effect of iodate application to soil. Biol Trace Elem Res 101(3):265–276
Landini M, Gonzali S, Perata P (2011) Iodine biofortification in tomato. J Plant Nutr Soil Sci 174:480–486
Caffagni A, Pecchioni N, Meriggi P, Bucci V, Sabatini E, Acciarri N, Ciriaci T, Pulcini L, Felicioni N, Beretta M, Milc J (2012) Iodine uptake and distribution in horticultural and fruit tree species. Ital J Agron 7(32):229–236
Kopeć A, Piątkowska E, Bieżanowska-Kopeć R, Pysz M, Koronowicz A, Kapusta-Duch J, Smoleń S, Rakoczy R, Skoczylas Ł, Leszczyńska T, Ledwożyw-Smoleń I (2015) Effect of lettuce biofortified with iodine by soil fertilization on iodine concentration in various tissues and selected biochemical parameters in serum of Wistar rats. J Funct Foods 14:479–486
Vladeva S, Gatseva P, Gopina G (2000) Comparative analysis of results from studies of goitre in children from Bulgarian villages with nitrate pollution of drinking water in 1995 and 1998. Cent Eur J Public Health 8:179–181
Jahreis G, Hesse VF, Rohde W, Prange H, Zwacka G (1991) Nitrate-induced hypothyroidism is associated with a reduced concentration of growth hormone-releasing factor in hypothalamic tissue of rats. Exp Clin Endocrinol 97:109–112
Blasco B, Rios JJ, Cervilla LM, Sanchez-Rodriguez E, Rubio-Wilhelmi MM, Rosales MA, Romero L, Ruiz JM (2011) Iodine application affects nitrogen-use efficiency of lettuce plants (Lactuca sativa L.). Acta Agr Scand 61(4):378–383
Cai J, Fang Y, Jing D, Xu S, Ming J, Gau B, Shen H, Zhang R, Ji Q (2016) Reference intervals of thyroid hormones in a previously iodine-deficient but presently more than adequate area of Western China: a population-based survey. Endocr J. doi:10.1507/endocrj.EJ15-0574
Day CE, Phillips WA, Schurr PE (1979) Animal models for an integrated approach to the pharmaclogic control of atherosclerosis. Artery 5(2):90–109
Aberare OL, Okuonghae P, Mukoro N, Dirisu JO, Osazuwa F, Odigie E, Omoredie R (2011) Triglycerides, total cholesterol, high density lipoprotein cholesterol and low density lipoprotein cholesterol in rats exposed to premium motor spirit fumes. N Am J Med Sci 3(6):277–280. doi:10.4297/najms.2011.3277
Silva AR, Cerdeira CD, Brito AR, Salles BC, Ravazi GF, Moraes GO, Rufino LR, Oliveira RB, Santos GB (2016) Green banana pasta diet prevents oxidative damage in liver and kidney and improves biochemical parameters in type 1 diabetic rats. Arch Endocrinol Metab. doi:10.1590/2359-3997000000152
Weickert MO, Pfeiffer AF (2008) Metabolic effects of dietary fiber consumption and prevention of diabetes. J Nutr 138(3):439–442
Ayala A, Muñoz MF, Argüelles S (2014) Lipid peroxidation: production, metabolism, and signaling mechanisms of malondialdehyde and 4-hydroxy-2-nonenal. Oxidative Med Cell Longev. doi:10.1155/2014/360438
Kirchgessner M, He J, Windisch W (1999) Homeostatic adjustments of iodine metabolism and tissue iodine to widely varying iodine supply in 125I labeled rats. J Anim Physiol Anim Nutr 82:238–250
Windisch W, Kirchgessner M, He J (1999) Isotope-dilution technique for determination of endogenous faecal excretion and true absorption of iodine in 125I labeled rats. J Anim Physiol Anim Nutr 82:205–215
Winger RJ, König J, House DA (2008) Technological issues associated with iodine fortification of foods. Trends Food Sci Tech 19:94–101
Shaw G, Scott LK, Kinnersley RP (2007) Sorption of caesium, iodine and sulphur in solution to the adaxial leaf surface of broad bean (Vicia faba L.). Environ Exp Bot 59:361–370
Henner P, Hurtevent P, Thiry Y, Levchuk S, Yoschenko V, Kashparov V (2013) Translocation of (125)I, (75)Se and (36)Cl to edible parts of radish, potato and green bean following wet foliar contamination under field conditions. J Environ Radioactiv 124:171–184
Tonacchera M, Dimida A, De Servi M, Frigeri M, Ferrarini E, De Marco G, Grasso L, Agretti P, Piaggi P, Aghini-Lombardi F, Perata P, Pinchera A, Vitti P (2013) Iodine fortification of vegetables improves human iodine nutrition: in vivo evidence for a new model of iodine prophylaxis. J Clin Endocrinol Metab 98(4):694–697
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This research was financed by the Ministry of Science and Higher Education of the Republic of Poland as well as grant for research of young scientists and PhD students no DS/4564/2013.
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Rakoczy, R., Kopeć, A., Piątkowska, E. et al. The Iodine Content in Urine, Faeces and Selected Organs of Rats Fed Lettuce Biofortified with Iodine Through Foliar Application. Biol Trace Elem Res 174, 347–355 (2016). https://doi.org/10.1007/s12011-016-0717-0
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DOI: https://doi.org/10.1007/s12011-016-0717-0