Potential for increasing the content and bioavailability of Fe, Zn and Ca in plants for human nutrition

Frossard, Emmanuel; Bucher, Marcel; Mächler, F.; Mozafar, A.; Hurrell, Richard F.

doi:10.1002/(sici)1097-0010(20000515)80:7<861::aid-jsfa601>3.0.co;2-p

Cited by 438 publications

(130 citation statements)

References 139 publications

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“…In fact, it is one of the most abundant elements in the lithosphere (around 5%), primarily in the form of ferromagnesium silicates, and also a major element in most soils, averaging 3-4%. It is included here, because of its importance as a micronutrient and because Fe deficiency is considered the most widespread micro-element malnutrition problem in many crops, animals and human populations throughout the world [6][7][8]12,56,57]. The physiological functions of Fe relate to the ease of this transition element to change valency between þ2 (ferrous Fe) and þ3 (ferric Fe) and its capability to form complexes with many organic and inorganic ligands.…”

Section: Ironmentioning

confidence: 99%

Trace Element‐Deficient Soils

Schulin

Johnson

Frossard

2010

Trace Elements in Soils

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Section: Ironmentioning

confidence: 99%

Trace Element‐Deficient Soils

Schulin

Johnson

Frossard

2010

Trace Elements in Soils

Self Cite

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“…On the other hand, nutrient deficiencies (e.g. Fe, Zn, Ca, Mg) are reported not only in developing countries, where cereals and root crops form the main contribution to the diet, but sometimes also in industrialised states (Frossard et al 2000;Elmadfa et al 2003;Pfannhauser et al 2004). Wheat and rye are the most important sources of bread flour, durum wheat is used for the production of noodles, and spring barley may be utilised for the production of beer.…”

Section: Introductionmentioning

confidence: 99%

Nutritionally relevant elements in staple foods: influence of arable site versus choice of variety

Spiegel

Sager

Oberforster

et al. 2009

Environ Geochem Health

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Eighteen representative sites for the Austrian grain-growing and eight for the potato-growing zones (soils and crops) were investigated. On each site, total element contents (B, Ba, Ca, Cd, Co, Cu, Fe, K, Li, Mg, Mn, Mo, Na, P, Sr and Zn) were determined in 4-12 varieties of winter wheat (n = 136), 6 varieties of spring durum wheat (n = 30), 5 varieties of winter durum wheat (n = 15), 7 varieties of rye (n = 49), 5 varieties of spring barley (n = 30) and 5 varieties of potatoes (n = 40). Element accumulations in grain species and potato tubers varied significantly with site conditions, with the main exceptions for B in potatoes and wheat as well as for Zn, Cu and Co in durum wheat. On average, across all investigated sites, differences in varieties occurred concerning the elements Ca, Cd, Ba, Sr and Zn (except Zn in potatoes and winter durum). A rough estimation revealed that an average Austrian consumer of wheat, rye and potatoes meets more than 50% of the needs of daily element intake for K, P and Mg, between 36 and 72% for Fe, Zn and Cu, and more than 100% for Co, Mo and Mn. In particular, the elements Ca and Na have to be added from other sources.

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“…It is estimated that over 60 % of the world's 6 billion people are iron (Fe) deficient, 30 % are iodine (I) deficient, over 30 % are zinc (Zn) deficient and about 15 % are selenium (Se) deficient (White and Broadley 2009;White et al 2012). In addition, Ca, Cu and Mg deficiencies are common in several developing and developed countries (Frossard et al 2000;Graham 2002, 2005;Rude and Gruber 2004;Grusak and Cakmak 2005;Thacher et al 2006;White and Broadley 2009;White et al 2012). So, in general, these micronutrient deficiencies are a major public health problem affecting more than 30 % of the world's population (more than two billion people suffering from one or more micronutrient deficiencies, WHO 2012) and many public health strategies (like biofortification) exist to reduce or prevent these micronutrient deficiencies.…”

Section: Selenium and Its Biofortificationmentioning

confidence: 99%

Selenium in soils under climate change, implication for human health

et al. 2014

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Global climate changes can alter the suitable geographical range of different crops, leading to possible changes in cropping pattern and its extent in some regions. For example, temperature changes can interact very closely with changes in availability of water and soil nutrients, and crop growth cycle. The consequences of the biophysical impacts of climate changes will be influenced by the human responses to these impacts. There is a strong link between soils and human health, and these soils per se are controlled by climate changes. The human health is very close to both selenium (Se) element and climate changes. It is estimated that about 37-40 % of the total Se emissions to the atmosphere are due to the anthropogenic activities.Those anthropogenic activities, which are sources of Se, include coal and oil combustion, mining activities, the utilization of rock phosphates as a fertilizer and the application of sewage sludge to agricultural land. It was thought that selenium was a toxicant for a long time due to inadequate analytical data. In the recent past, Se has become very important in environmental biogeochemistry because of its influence on human health. Although Se is an essential nutrient for animals and humans, it is also toxic at high doses. Furthermore, the range between Se deficiency, lower than 40 lg day -1 , and toxicity, higher than 400 lg day -1 , is narrow. Selenium deficiency has been linked to several human diseases including multiple sclerosis, muscular dystrophy, heart disease, immune system, cancer and reproductive disorders. On the other hand, Se toxicity can lead to hair and nail loss and disruption of the nervous and digestive systems in animals and humans. Despite the obvious connections between Se element and human health under climate changes, there has not been a great amount of research done in this area. So, more and more studies should be carried out to enhance and protect human health. Therefore, this article reviews the biological and economic dimensions of the effects of Se element on human health under climate changes.

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Potential for increasing the content and bioavailability of Fe, Zn and Ca in plants for human nutrition

Cited by 438 publications

References 139 publications

Trace Element‐Deficient Soils

Trace Element‐Deficient Soils

Nutritionally relevant elements in staple foods: influence of arable site versus choice of variety

Selenium in soils under climate change, implication for human health

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