Jun 24, 2023
Iron
Scientific Reports volume 13, Article number: 13565 (2023) Cite this article 368 Accesses Metrics details A new approach for fortification of drinking water is presented for combating iron deficiency
Scientific Reports volume 13, Article number: 13565 (2023) Cite this article
368 Accesses
Metrics details
A new approach for fortification of drinking water is presented for combating iron deficiency anemia (IDA) worldwide. The idea is to leach Fe from a bed containing granular metallic iron (Fe0), primarily using ascorbic acid (AA). AA forms very stable and bioavailable complexes with ferrous iron (FeII). Calculated amounts of the FeII-AA solution can be added daily to the drinking water of households or day-care centers for children and adults (e.g. hospitals, kindergartens/schools, refugee camps) to cover the Fe needs of the populations. Granular Fe0 (e.g., sponge iron) in filters is regarded as a locally available Fe carrier in low-income settings, and, AA is also considered to be affordable in low-income countries. The primary idea of this concept is to stabilize FeII from the Fe0 filter by using an appropriate AA solution. An experiment showed that up to 12 mg Fe can be daily leached from 1.0 g of a commercial sponge iron using a 2 mM AA solution. Fe fortification of safe drinking water is a practicable, affordable and efficient method for reducing IDA in low-income communities.
Iron deficiency is reported to be the most prevalent nutritional deficiency worldwide, affecting about 5 billion people1,2,3,4. Iron deficiency is the main cause of anemia (iron deficiency anemia—IDA) in children and women4,5. The prevalence of anemia is five times higher in low-income countries than in high-income countries6,7. Another important reason for this high prevalence is that infectious diseases such as bacterial infections, hookworms, human immunodeficiency virus or acquired immunodeficiency syndrome (HIV/AIDS), intestinal parasitic infections, malaria, and tuberculosis are common conditions associated with a reduction of blood constituents, including iron1,2,4. Iron deficiency impairs cognitive development in children, reduces work capacity in adults, increases the risk of morbidity, induces poor pregnancy outcomes, and impairs immunity1,3,4,8. Iron deficiency is considered to be one of the most expensive diseases in the world, according to the World Health Organization (WHO)3,4,8,9,10,11. This is because IDA induces economic losses in the form of (1) cognitive losses among children, (2) lower productivity among adults, and (3) associated increased medical expenses for all groups9,11. Fortunately, IDA is preventable and curable, and doing so is a priority for the WHO10,11. However, despite concerted efforts for iron supplementation (e.g. beverages, food fortification, injections, syrups, drugs, pills, salt fortification, tablets), not much progress has been realized in the past three decades3,4,7,12,13,14,15,16. IDA maintains its top position as the leading cause of years lived with disability, and still contribute to up to 120,000 maternal deaths per year3,11,17.
Many strategies to prevent and treat IDA have been developed over the years2,4,7,12,18,19,20. Table 1 gives an overview of the used tools based on the oxidation-state-dependent characteristics of the used iron sources (Fe0, FeII, and FeIII). The four most commonly used strategies are: (1) dietary diversification, (2) food fortification with Fe, (3) multi-micronutrient supplementation, and (4) treatment of parasitic infections contributing to iron deficiency2,3,5. A fifth strategy that has been reported only in Brazil, is drinking water fortification with soluble ferrous iron (FeII)7,12,21,22,23,24. In this effort, a favored short-term and cost-effective strategy that is relatively easy to implement at large scale, is the use of fortification programs at kindergartens and schools5. For the prevention of IDA, the WHO recommends a daily iron supplementation for three consecutive months in a year to all pre-menopausal women, adolescent girls and young children in the majority of countries3,11.
The major challenge in combating IDA is the control of the iron bioavailability7. Iron sources are widely available on the market but not all of them are bioavailable (Table 1). Table 1 shows that the best iron source (bioavailable) is FeII sulfate with stable FeII. FeII chlorides are also highly water soluble, but not stable under physiological conditions. Fe0 and FeIII sources are less soluble and their bioavailability is correspondingly low. In other words, soluble Fe should be present as stable FeII to be absorbed by the human body2,7,17,25. This is the reason why the simultaneous consumption of Fe rich diets and vitamin C (ascorbic acid—AA) has consistently and successfully treated IDA2,7,22,24,26. Ascorbic acid is a strong reducing agent for FeIII and forms very stable complexes with FeII [FeII-AA]27,28,29. FeII-AA complexes are readily absorbed by the human body. Thus, supplying people with FeII-AA solutions has the potential to decrease IDA7,12.
This communication presents the design of a device to locally generate FeII-AA solution for drinking water fortification. Granular Fe0 is placed in a column and leached with a solution of AA. A calculated amount of the leachate is added to the drinking water tank to yield the daily needed iron concentration. Tools for the implementation of such devices in day-care centers for children and adults are discussed.
The presentation starts with a description of the Fe/AA system ("Background of the FeII-AA concept" section), followed by a discussion of current uses of Fe0 for IDA control ("Current use of Fe0 for IDA control" section). "Fe0 leaching with ascorbic acid: proof of concept" section presents some experimental data on Fe0 leaching with ascorbic acid (e.g. proof of concept), "Designing a FeII-bearing unit" section prepares the realization of the concept by discussing a FeII-AA production unit. "IDA and safe drinking water provision: killing two birds with one stone?" section formulates some recommendations for combining IDA control and safe drinking water provision. A short conclusion ("Concluding remarks" section) closes the presentation.
The ability to improve iron status in populations largely depends on the understanding of the biochemistry and absorption of Fe in the human body2,7,17,28. There are two types of iron: heme (found in red meat) and non-heme (found in plant-based foods) iron. Iron absorption in the gastrointestinal tract is lower for non-heme sources of iron. The literature contains many contradictory findings regarding parameters pertinent to the effective absorption of Fe by humans3,5,17. It seems established that ferrous salts are better than heme iron in combatting IDA, however, some newer iron formulations have claimed the opposite30,31. Fortunately, it is unequivocally reported that a combination of ascorbic acid (AA) and Fe-bearing diets improves the iron status in populations7,30. Being a weak acid, AA is a strong reducing agent for FeIII and an excellent complexing agent for FeII7,28,29. This means that, where necessary, AA reduces aqueous FeIII–FeII and builds the very stable Fe-AA complex which is available for the human body (Fact 1: AA reduces aqueous FeIII and builds stable Fe-AA complex). Therefore, Fe-AA complexes are bio-available in the human body7.
People living in a high-iron groundwater setting have demonstrated better iron status or suffer less from IDA32,33,34,35,36,37,38. The rationale for this finding is that Fe-rich groundwater contains FeII which is oxidized to FeIII upon contact with air (20% O2)39. This implies that the amount of bioavailable FeII also depends on the duration of storage. Upon oxidation FeIII precipitates as Fe hydroxides/oxides or is complexed to less/non bioavailable species. Fe-rich groundwater contains bioavailable FeII. Whenever clean Fe-rich groundwater is available as a drinking water source, it suffices to stabilize FeII, for example by addition of AA or lemon juice, to improve the Fe status of the population25,40,41.
Taken together, supplying populations with drinking water containing Fe stabilized in the ferrous form (FeII) is sufficient (Fact 1). This idea is not new, as it has been successfully applied in rural Brazil for the last three decades7,21,22,23,24,26. In its original form, each family was required to have an earthen pot with about 10 L capacity for storing drinking water. Families received a concentrated iron solution (l0 g/L) in the form of ferrous sulfate (FeSO4) and L-ascorbic acid in the molar ratio FeII:AA = 1:3, dispensed in l0 mL bottles21. The success of this approach has motivated its extension to day-care institutions7,24. The present work seeks to leach FeII from metallic iron (Fe0). Thus, commercial ferrous sulfate is replaced by a more affordable granular Fe0, which is additionally readily available, for example as iron filings, iron wire, scrap iron, sponge iron (direct reduced iron), or steel wool. Fe0 sources to be considered in this context should not contain any toxic alloying elements. Sponge iron is certainly the best material fulfilling this prerequisite. The typical mineralogical composition (in %) of sponge iron is42,43: Fe (total): 92–95; Fe0: 85–90; C: 1.0–1.5; S: 0.005–0.015; P: 0.02–0.09, SiO2: 1.0–2.0, and balanced by the gange. The gange is the residual unreduced oxides, mainly comprising of Al2O3, CaO, FeO, MgO, MnO, and SiO2. The typical mass density of sponge iron is 1600 kg m−3 and its apparent density is 3200 kg m−342.
Materials selected herein for use in the Fe fortification unit are known to be effective for producing stable soluble FeII solutions under environmental conditions. Availability and cost are also considered in the selection process because substantial quantities would be required for decentralized production. Used Fe0 particles should not contain toxic alloying elements (e.g. Cr, Ni). Fortunately, this is the case for many readily available Fe0 materials such as cast iron and low alloyed steel. For example, Lufingo et al.29 analyzed nine commercial steel wool for their elemental composition and found that the Fe0 content was constantly higher than 99%, while the (Cr + Ni) level was lower than 0.7% in all the specimens. These data suggest that a solution containing some 10 mg/L of Fe would contain non-detectable levels of (Cr + Ni). However, ideally, used Fe0 specimens should be free of Cr, Ni and Pb. Therefore, there is a need to (1) determine the chemical composition of potential Fe0 materials, and (2) test them with regard to the leaching ability of relevant toxic elements before their use for drinking water fortification. The next section presents a proof of concept, limited to illustrating the Fe leaching capability of a 0.02 M AA solution (pH = 3.5) from four selected Fe0 specimens, in five parallel experiments.
Fe0 is currently considered an adventitious source of bioavailable iron with both adverse and beneficial effects on human health (Tables 1, 2)44,45,46,47,48,49,50. On the one hand, excessive Fe intake (e.g. Fe overload or iron poisoning) is attributed to metallic poisoning derived from foods and drinks prepared in Fe0-based vessels2,18,19,20,44,45. On the other hand, Fe leached from Fe0-based cooking utensils is recommended to prevent and cure IDA18,19,20,40,49,50. Where Fe0 cooking utensils are not available, not affordable, or not socially accepted, reusable Fe0 ingots have been used51,52,53,54,55, for example in Al-based cooking utensils (Fig. 1). Figure 2 shows the photograph of a fish-shaped iron ingot as used for in-situ food fortification in Cambodia as well as a leaf-shaped iron ingot as used in India55,56.
Photograph of an aluminum cooking pot on the fire in Bamena (rural Cameroon). Photograph taken by Serge Ndokou-Nana, October 2021.
Photograph of a Lucky Iron Fish and a Lucky Iron Leaf. Photograph taken by Gerhard Hundertmark, November 2021.
Fe0 in the form of iron powders has also been widely used in food fortification14,17,56. In this context, Fe absorption is governed by the extent of the dissolution of used Fe0 powders in the gastric fluid17. The extent of Fe absorption thus depends on the intrinsic reactivity of the used Fe0 in the human gastric fluid. The lack of characterization of the Fe0 intrinsic reactivity seems to be a major shortcoming as many different Fe0 types have been tested and used without appropriate quality control58. A proper quality control would characterize the relative Fe bioavailability from used Fe0 powders. For example, H-reduced Fe0 powders for fortifying cereal flours have been largely used, while the WHO recommends only electrolytic iron powder14. The WHO recommendation is based on field evidence from Fe absorption in efficacy studies. However, it would have been better to develop an operational parameter (e.g. a dissolution index) to assess the Fe0 dissolution trend under different physiological conditions (in the gastrointestinal tract).
While it is clear that Fe0 is a relevant Fe source to cure and/or prevent IDA, it is not clear why a specific Fe0 source is preferentially used, and which specific operational conditions are optimal to meet the daily needs of a human being2,7,17,23. Relevant Fe0 sources include: (1) Fe0 cooking and storing vessels (pots and drums)44,45,59, (2) reusable Fe0 ingots51,52,53,55,60 (https://luckyironfish.com, Access 2021/10/25), and (3) Fe0 powders2,56,61,62.
Food fortification is largely considered the best strategy to increase iron intake of a population, especially for children and pregnant women2,14,15,16,55. The WHO has recognized food fortification as a potential universal tool for defeating IDA worldwide11. However, there are several concerns to be named: (1) by solving one problem (IDA) in some people, universal fortification exacerbates Fe intoxication for other people (questioned universality), and iron poisoning is as severe as IDA2, (2) because of low income, a large fraction of the population has only restricted access to commercial fortified foods (questioned affordability), and (3) it is not known which fraction of Fe0 in food is effectively solubilized during digestion and which proportion is absorbed by the body of each individual person2,7,17,23.
With the objective of solving the three named problems this communication suggests a solution that is beneficial to the segment of the population (potentially) suffering from IDA. This solution is called ‘semi-universal’ fortification2 and uses water as a vehicle7. Moreover, only drinking water is fortified and is considered affordable or at least more affordable than commercial fortified foods. Concerning the bioavailability, Fe is leached from granular Fe0 by ascorbic acid and is long-term stable and bioavailable7,21,22,23,24,26,28.
The present study presents a concept to extract FeII from Fe0 specimens, using ascorbic acid (AA) as leaching agent or lixiviant. Previously, AA has been used to leach and extract metals from natural metal oxides (e.g. marine MnO2) by reductive dissolution63,64,65,66. In this context, AA is a reduction and leaching (chelating) agent for ore processing at ambient temperature and under normal pressure. A key lesson from this hydrometallurgical process is that AA leaching has good dynamic characteristics, high reaction kinetics, and requires simple equipment. In this paper, AA is used to sustain the oxidative dissolution of Fe0 specimens. Fe0 is oxidized by water (H+) (oxidative dissolution) (Eq. 1) and the resulting Fe2+ is stabilized by chelation with AA (Eq. 2). In the absence of AA, Fe2+ would have been further oxidized to Fe3+ by oxygen present in air (Eq. 3) and precipitated as Fe(OH)3 (Eq. 4)58,67,68,69,70. From Eq. (1), a tool to increase the extent of Fe2+ leaching is to lower the pH value (H+ addition).
Once Fe(AA)2+ complexes are formed (Eq. 2), they remain stable even when the pH increases to values as high as 8.071,72. In particular, Conrad and Schade71 demonstrated that, adding NaOH to a (FeCl3 + AA) solution results in a soluble iron chelate, while adding AA to a (FeCl3 + NaOH) mixture results in an insoluble Fe(OH)3.
Organic acids (e.g. acetic acid, citric acid, oxalic acid) and other chelating agents (e.g. ethylenediaminetetraacetic acid—EDTA) can be used as effective lixiviants for fly ash and minerals73,74. Organic acid mixtures are currently tested to recover valuable metals from spent Li-batteries75. For example, the process described by Chen et al.74, used iminodiacetic acid and maleic acid to quantitatively recover Li+ and Co3+ at 60 °C. AA then converts Co3+–Co2+ and enables selective recovery of Co. The present work uses AA to sustain Fe0 dissolution (Eq. 1). Comparable approaches are efforts from our research group using two organic chelates (EDTA and 1,10-Phenanthrolin) to characterize the intrinsic reactivity of Fe0 specimens29,58,76. Moreover, our research group has been routinely using a 0.1 M AA as a washing solution to free glassware from FeIII oxides after Fe0 decontamination experiments.
This section is adapted from Ndé-Tchoupé et al.76 who characterized the reactivity of twelve Fe0 materials for H2 evolution in H2SO4. The four tested herein were included, and depicted significant different reactivity. This result was recently confirmed using a newly developed test for Fe0 screening: the ascorbic acid test58.
The working solution was prepared from a L-ascorbic acid powder (Merk, Darmstadt, Germany). The used 1,10-Phenanthroline, sodium ascorbate, and the iron standard (1000 mgL−1) were also from Merck (Darmstadt, Germany). All chemicals were of analytical grade.
Four selected Fe0 materials were used. Two of them were commercially available materials for groundwater remediation termed as: (1) “sponge iron”, and (2) “iPuTec”. Sponge iron is Eisenschwamm from ISPAT GmbH, Hamburg; while iPuTec is Graugußeisengranulat from iPutec GmbH & Co. KG, Rheinfelden; both in Germany. The other two materials were scrap iron materials from a metal recycling company (Metallaufbereitung Zwickau) termed as: “S15” and “S69”. S15 was a mixture of mild steels from various origins, while S69 was a similar mixture of cast irons. Apart from sponge iron, Fe0 materials were used in their typical state and form (i.e., “as received” state). Sponge iron was crushed into small pieces, sieved and the particles with sizes ranging between 1.0 and 1.6 mm were used, without any further pre-treatment.
Table 2 summarizes the elemental compositions of the materials based on analyses made using X-Ray fluorescence spectrometry. It can be clearly seen that the materials primarily differ in their carbon (C) and silicon (Si) contents. Thus, based on the C content, the tested materials can be divided into three classes: (1) iPuTec and S69 containing more than 3% C (cast irons), (2) S15 containing less than 2% C (mild steel), and (3) sponge iron (1.9% C), belonging to the third class, characterized by a specific manufacturing technology, which yielded porous materials42,43. All these materials were irregular in shape (filings and shavings) with rough surfaces. Sponge iron had a very rough surface and was even porous. iPutec and the two scrap irons (S15 and S69) were visibly covered with rust.
1.0 g of each Fe0 material was placed in a chromatographic column containing sand in its lower third and the 0.02 M AA solution in its upper two thirds (Fig. 3). Fe0 was leached daily for five consecutive days (Monday–Friday) every week with about 180 mL of a 0.02 M ascorbic acid solution (pH = 3.5), at constant temperature of 23 ± 2 °C. At each leaching event, the exact volume of the leachate was monitored and its iron concentration was determined. The experiment was ended after 55 leaching events. This corresponds to a leaching rate of 53% for sponge iron (the most reactive material). An accompanying experiment with 2.0 g of iPuTec was performed to enable the assessment of the impact of the Fe0 mass on the extent of Fe leaching by AA.
Column experimental set-up for Fe0 leaching by ascorbic acid (2 mM). The photograph was made at the end of the experiments. The spout of the third column was broken during the experiments but this has no incidence on the performance of the system.
Analysis for iron was performed using the Phenanthroline method. Although Fe(AA) was already Fe(II), reduction was performed to follow the analytical protocol which include calibrating the standard solutions. Iron concentrations were determined by a Cary 50 UV–Visible Spectrophotometer (Cary instruments, LabMakelaar Benelux B.V., Zevenhuizen, The Netherlands) at a wavelength of 510.0 nm using 1.0 cm glass cells. The pH values were measured by combined glass electrodes (WTW Co., Weinheim, Germany).
Table 4 and Fig. 4 summarize the results of Fe extraction from the four tested Fe0 materials. It is seen from Table 3 that sponge iron exhibited the highest extent of Fe leaching with 529.5 mg or 53% of the initial 1.0 g after 55 leaching events over 129 days. The increasing order of Fe0 reactivity with respect to the extent of Fe leaching in 0.02 M AA is: S15 < iPuTec < S69 < sponge iron. The high reactivity of sponge iron is attributed to its higher porosity and the corresponding surface area in comparison to other materials. The same order of reactivity was reported in related works58,76. Another important feature from Table 4 is the fact that using twice the amount of Fe0 (2.0 g for iPuTec) did not double the extent of Fe leaching. In fact, when doubling the initial Fe0 mass, the daily leached mass of Fe increased by only 24.4%, from 8.6 to 11.4%. This observation is consistent with the non-linear kinetics of Fe0 dissolution57.
Time-dependent extent of Fe leaching from the four tested Fe0 specimens: (a) mass per leaching event, and (b) cumulative masses. Experimental conditions: miron = 1.0 g, [AA] = 0.02 M, and T = 23 ± 2 °C.
Figure 4a shows that the daily dose of 2–12 mg of Fe could be leached from each column containing 1 g of Fe0.
For each material, the leached amount was high at the start of the experiment, then it decreased progressively with increasing leaching events (elapsed time) until about 70 days. It then increased again to values comparable to initial values for all Fe0 specimens except S15 until day 110 (Table 5). After day 110, a new decrease of the leached Fe level started. The trend was the same for all Fe0 specimens including S15, with only differences in magnitude. Interestingly, around day 70, sponge iron exhibited the lowest extent of Fe leaching. Figure 4b depicts the cumulative extent of Fe leaching and shows clearly that sponge iron is the best material over the 129 leaching events.
A combination of (1) non-constant kinetics of iron corrosion for individual materials, and (2) different laws of the variation kinetics amount materials, make any prediction of the leaching extent challenging (Table 5). Table 5 shows that for the first 10 leaching events, the increasing order of reactivity was iPuTec < sponge iron < S15 < S69. After this initial period, S15 was the least reactive material until t = 112 d, corresponding to the 52nd leaching event. Between the 10th leaching event and the 52nd there is also no uniform trend in the variation of the extent of Fe leaching from the three other materials. However, it is certain that various amounts of Fe(AA)2+ can be obtained to prepare diluted solutions to prevent or combat IDA by varying the following factors: (1) the Fe0 mass (e.g. 1.0 g, 2.0 g), (2) the Fe0 type (e.g. sponge iron, iPuTec), (3) the AA concentration (e.g. 0.02 M, 0.2 M), and eventually (4) acidifying the solution. Fe0 can first be leached by EDTA and the resulting solution (FeIIIEDTA) reduced and stabilized to Fe(AA)2+. In fact, preliminary experiments (results not shown) have demonstrated that EDTA is a far better lixiviant than AA. The ability of AA to reduce FeIIIEDTA is documented and used in analytical chemistry29,58.
This experiment has unequivocally shown that using two columns containing the same amount of a Fe0 specimen (m) will yield a larger leaching Fe level than a single column containing 2 times the same materials (2 * m). This is due to extreme complexity of the phenomena associated with aqueous iron corrosion (Table 1)29,57. Summarized, these results prove that Fe0 leaching using AA is a promising approach to generate stable FeII solutions to improve the iron status of humans.
The conceptual design of a FeII-AA production unit involves two components: (1) a reactive source of metallic iron (Fe0), and (2) an ascorbic acid (AA) solution. In principle, batch and column leaching operations are possible. However, column operations are preferred herein mainly because they can run for several months with limited labor input ("Fe00 leaching with ascorbic acid: proof of concept" section). "Fe0 leaching with ascorbic acid: proof of concept" section and available data on Fe0 leaching by ethylenediaminetetraacetic acid (EDTA)29 suggest that it is possible to leach constant amounts of Fe from Fe0 filling, sponge iron, and steel wool placed in a glass column for several weeks77 (Fig. 5). The Fe concentration in the effluent (C0) depends mainly on the intrinsic reactivity of used Fe0, the Fe0 mass used, the flow velocity of the AA solution, and the AA concentration. The C0 value (Eq. 5) is selected such that a certain volume of the effluent (V0) is added to a water reservoir (V1) to obtain the desired concentration of Fe in the fortified drinking water (C1).
Schematic representation of the process of generating the FeII-AA solution (V0) and adding it to a safe drinking water storage tank (V1). Fe0 is a reactive iron source. Sand is used as a filling material.
Assuming that available safe drinking water is iron free, the mass balance of Fe implies that C0V0 = C1V1 (Eq. 1). If 1 m3 FeII-AA fortified water (V1 = 1000 L) containing 2 mg/L FeII (C1) is to be daily produced, and 1.0 L (V0) of the effluent should be used, then the C0 value should be 2000 mg/L or 2.0 g/L (C0 = 2000 mg/L). The challenge is to find the best combination of Fe0 materials (e.g. iron filings, sponge iron), Fe0 mass, AA concentration, and flow velocity of the AA solution, yielding 1 L of a 2.0 g/L FeII effluent. In case 2.0 g/L Fe is not realistic, one should rather seek to have 10 L of the effluent with 0.2 g/L FeII (C0 = 200 mg/L).
Figure 5 shows an operational device for the production of the FeII-AA effluent for dilution. For the realization of this concept, common affordable laboratory devices for weighing (Fe0, AA) and analytically determining Fe are needed. This means that for the development of the FeII-AA method, a small chemical laboratory or FeII sensor is necessary. However, once the method is established, a laboratory is no longer necessary, and trained personnel can build columns to leach Fe0 and perform dilution in water tanks. Calculations are made herein for 1 m3. For larger populations, the 1 m3 water device can be used as a module, and as many modules as necessary can be used to cover the needs. The operational C1 value of 2 mg/L is purely arbitrarily considered. More relevant values should be selected for testing.
A survey of the literature reveals that various Fe doses have been administered to persons in individual studies. For example, Ginanjar et al.25 discussed the results of some previous studies using oral supplements of a 0 mg (placebo) to 100 mg (therapy) Fe dose in 200 mL water. Fe was added either as FeSO4 or NaFeEDTA and was administered to test persons after at least eight hours of fasting. In other words, up to 100 mg of Fe represents the daily dose to prevent and/or cure IDA. On the other hand, Rakanita et al.13 reported that women need 30–60 mg Fe/day. The World Health Organization recommends up to 30 mg Fe/day for children under five11,54. Table 6 summarizes the masses of FeSO4, FeII fumarate, FeII gluconate, and NaFeEDTA necessary to obtain 1 kg of elemental iron (Fe). It is seen that (1) 3.0 to 8.0 kg of salts are needed where just 1 kg of Fe0 suffices, (2) FeSO4 is more than 50 times the price of iron nails (Fe0). However, the (bio)availability of Fe from Fe0 is primarily uncertain. To design an appropriate FeII-AA production unit, Eq. 5 is used. The system is operated such that three liters of the drinking water (C1) bring the needed daily Fe dose for IDA prevention. For curative issues, (up to 100 mg/d), appropriate designs can be developed on the same basis.
Fe leaching as used herein is extensively employed in extractive metallurgy and in reclamation of mining media79,80,81,82. The operational parameters impacting the effectiveness of the leaching process include concentration of the AA solution, duration of the leaching operation (long-term corrosion rate), Fe0 grain size, Fe0 intrinsic reactivity, flow velocity of the AA solution (contact time), and leaching temperature. Given that the kinetics of iron corrosion are neither constant nor linear (see "Fe0 leaching with ascorbic acid: proof of concept" Section)29,82,83,84 the service life of each FeII-AA production unit (Fig. 5) cannot be predetermined. In other words, the question on when to recharge a Fe0/sand column with fresh Fe0 can only be answered by testing.
The presentation until here has revealed that many low-income settings are still seeking for reliable ways out of the iron deficiency crisis. Past Fe0-based attempts to overcome this problem include: (1) using iron cookwares, (2) adding iron ingots while cooking with aluminum cookwares, and (3) consuming food fortified with Fe0 powders. The latter is not suitable because of limited access to commercial fortified foods especially for low-income and vulnerable households. All three tools suffer from the natural time-dependent decrease of the kinetics of iron corrosion (decreased corrosion rate or “reactivity loss”)29,82,83,84,85,86,87. On the other hand, limited access to medical care and other costly iron supplements make other available tools for improving iron status less suitable for generalized use in low-income communities.
During the past three decades, a substantial body of evidence has demonstrated that iron intake from drinking water is a powerful weapon against IDA7,31,39. In this context, FeII is either naturally available, for example from groundwater30,31,34,35, or artificially added, for example as ferrous sulfate (FeSO4)21. FeSO4 is reported to be the best water-soluble and cheapest iron salt available (Table 6)7. Dutra-de-Oliveira et al.21 used 10 mg of FeSO4 and 100 mg of ascorbic acid (AA) per litre of drinking water. 10 mg of FeSO4 contains 3.7 mg of Fe, 2.1 mg of S and 4.2 mg of O. This implies that just 3.7 mg Fe is needed for 1 L or some 4.0 g for 1 m3 of water. In other words, 1 kg of Fe0 will produce more than 250 m3 of Fe fortified drinking water. The price of 1 kg of Fe0 (3.00 Euro)78 is far less than that of 1 kg of FeSO4 (Table 6), and Fe0 is readily available, for instance as iron nails or sponge iron77,88,89. The advantage of water as a vehicle for Fe is summarized by Dutra-de-Oliveira et al.7 as follows: “Water is consumed daily, everywhere by all ages”, including children, pregnant women, and adults of all ages. In other words, Dutra-de-Oliveira et al.7,90,91 have already demonstrated the success of iron-fortified drinking water to improve the iron status of low-income populations mainly consuming low iron (FeII) vegetable diet and daily drinking local water90,91,92,93,94,95,96. Consequently, provided local water is of drinking quality, a universal solution to defeat IDA is made more accessible and affordable by using the FeII-AA method presented herein ("Current use of Fe0 for IDA control" section). AA for Fe0 leaching is readily, commercially available. For example, in July 2023, 2.5 kg ascorbic acid (vitamin C), food grade can be purchased from Amazon Germany (www.amazon.de) for just 33 Euro.
The past two decades have witnessed the development of affordable solutions for safe drinking supply97,98,99,100,101,102. From these technologies, one is based on filtration on Fe0/sand beds97,100,103,104,105,106,107. In principle, it is possible to design a Fe0 filter capable of releasing about 2 mg/L FeII in the effluent. In such a case, it suffices to add a diluted solution of ascorbic acid to stabilize FeII and make it available to the human body. Research is needed to achieve the proverbial notion of “killing two birds with one stone”: (1) safe drinking water, and (2) iron-fortified water, in a decentralized manner. The problem of clean drinking water supply and IDA co-occur or are juxtaposed in low-income countries108. This points to the novelty of coupling clean drinking water supply based on Fe0 filter systems to the fortification of drinking water to overcome IDA.
There are three main approaches to control IDA: (1) supplementation with iron and folic acid tablets, (2) fortification with iron salts, metal iron and dissolved iron, and (3) natural food-based approaches. Efforts for wide implementation of the first two approaches have not really been successful in combating IDA over the past three decades14,15,109,110,111,112. The third approach is attractive as it focuses on dietary diversification and enrichment of diets with naturally iron-rich foods, but it is difficult to bring it to scale. Thus, more affordable and applicable tools are still needed.
The FeII-AA approach is an improved version of a 30-year-old method using commercially available highly soluble FeII salts7. Home iron fortification of water supplies bioavailable iron to rural and urban populations and is optimal for mass supply in schools and other institutions. Systematic research is needed to develop scalable FeII-AA producing units. Well-designed experiments are needed to determine the practicality of several potential Fe0 materials to serve as reliable Fe sources and to combat IDA.
All data generated or analyzed during this study are included in this published article and its supplementary information files.
Dewey, K. G. & Adu-Afarwuah, S. Systematic review of the efficacy and effectiveness of complementary feeding interventions in developing countries. Matern. Child Nutr. 4, 24–85 (2008).
Article PubMed PubMed Central Google Scholar
Martins, J. M. Universal iron fortification of foods: the view of a hematologist. Rev. Bras. Hematol. Hemoter. 34, 459–463 (2012).
Article PubMed PubMed Central Google Scholar
Stelle, I., Kalea, A. Z. & Pereira, D. I. A. Iron deficiency anaemia: experiences and challenges. Proc. Nutr Soc. 78, 19–26 (2019).
Article PubMed Google Scholar
Kumari, A. & Chauhan, A. K. Iron nanoparticles as a promising compound for food fortification in iron deficiency anemia: A review. J. Food Sci. Technol. 59, 3319–3335 (2022).
Article CAS PubMed Google Scholar
Field, M. S., Mithra, P., Estevez, D. & Peña-Rosas, J. P. Wheat flour fortification with iron for reducing anaemia and improving iron status in populations. Cochrane Database Syst. Rev. 7, CD011302 (2020).
PubMed Google Scholar
Miller, J. L. Iron deficiency anemia: a common and curable disease. Cold Spring Harb. Perspect. Med. 3, a011866 (2013).
Article PubMed PubMed Central Google Scholar
Dutra-de-Oliveira, J. D., Marchini, J. S., Lamounier, J. A. & de Almeida, C. A. N. A new family home approach to controlling iron deficiency anemia in all ages in less-developed and developing countries using iron-fortified water. Arch. Latin Nutr. 66, 159–164 (2016).
CAS Google Scholar
Cappellini, M. D., Musallam, K. M. & Taher, A. T. Iron deficiency anaemia revisited. J. Int. Med. 287, 153–170 (2020).
Article CAS Google Scholar
Horton, S. & Ross, J. The economics of iron deficiency. Food Pol. 32, 141–143 (2007).
Article Google Scholar
WHO. Global Nutrition Targets 2025 Anaemia Policy Brief (WHO/NMH/NHD/14·4) (World Health Organization, 2014).
Google Scholar
WHO. Guideline: Daily Iron Supplementation in Adult Women and Adolescent Girls (World Health Organization, 2016).
Google Scholar
Beinner, M. A. Fortification of drinking water with iron and ascorbic acid in eight municipal day-care centers in Brazil. Doctoral dissertation, (University of Brasilia, Distrito Federal, 2002)
Rakanita, Y. et al. The challenges in eradication of iron deficiency anemia in developing countries. Sys. Rev. Pharm. 11, 383–401 (2020).
CAS Google Scholar
Hurrell, R. F. Iron fortification practices and implications for iron addition to salt. J. Nutr. 151, 3S-14S (2021).
Article MathSciNet PubMed PubMed Central Google Scholar
Hurrell, R. F. The potential of iodine and iron double-fortified salt compared with iron-fortified staple foods to increase population iron status. J Nutr. 151, 47S-63S (2021).
Article PubMed PubMed Central Google Scholar
Shields, A. & Ansari, M. A. Review of experience of the production of salt fortified with iron and iodine. J Nutr. 151, 29S-37S (2021).
Article PubMed PubMed Central Google Scholar
Lermyte, F. et al. Metallic iron in cornflakes. Food Funct. 11, 2938 (2020).
Article CAS PubMed Google Scholar
Tripp, K. et al. Acceptability and use of iron and iron-alloy cooking pots: Implications for anaemia control programmes. Public Health Nutr. 13, 123–130 (2010).
Article PubMed Google Scholar
Arcanjo, F. P. N., Arcanjo, C. C. & Santos, P. R. Iron pots for the treatment of iron deficiency anemia: Is there sufficient favorable evidence?. Nutr Food Sci Int J. 8, 555738 (2019).
Google Scholar
Arcanjo, F. P. N. et al. Iron pots for the treatment of iron deficiency anemia: Is there enough favorable evidence?. Int. J. Health Sci. 8, 73–76 (2020).
Google Scholar
Dutra de Oliveira, J. E., Ferreira, J. F., Vasconcellos, V. P. & Marchini, J. S. Drinking water as an iron canier to control anemia in preschool children in a day-care center. J. Am. Coll. Nutr. 13, 198–202 (1994).
Article CAS PubMed Google Scholar
Dutra de Oliveira, J. E. E., Amaral-Scheid, M. M., Desai, I. D. & Marchini, S. Iron fortification of domestic drinking water to prevent anemia among low socioeconomic families in Brazil. Int. J. Food Sci. Nutr. 47, 213–219 (1996).
Article Google Scholar
Dutra-de-Oliveira, J. E. & de Almeida, C. A. N. Domestic drinking water—an effective way to prevent anemia among low socioeconomic families in Brazil. Food Nutr. Bull. 23, 213–216 (2002).
Article PubMed Google Scholar
Dutra-de-Oliveira, J. E., Marchini, J. S., Lamounier, J. & Almeida, C. A. N. Iron-fortified drinking water studies for the prevention of children’s anemia in developing countries. Anemia https://doi.org/10.1155/2011/815194 (2011).
Article PubMed PubMed Central Google Scholar
Ginanjar, E. et al. Iron absorption in iron-deficient women, who received 65 mg Fe with an Indonesian breakfast, is much better from NaFe(III)EDTA than from Fe(II)SO4, with an acceptable increase of plasma NTBI. A randomized clinical Trial. Pharmaceuticals 11, 85 (2018).
Article CAS PubMed PubMed Central Google Scholar
de Almeida, C. A. N. et al. Effect of fortification of drinking water with iron plus ascorbic acid or with ascorbic acid alone on hemoglobin values and anthropometric indicators in preschool children in day-care centers in Southeast Brazil. Food Nutr. Bull. 26, 259–265 (2005).
Article PubMed Google Scholar
Hsieh, Y. H. P. & Hsieh, Y. P. Valence state of iron in the presence of ascorbic acid and ethylenediaminetetraacetic acid. J. Agric. Food Chem. 45, 1126–1129 (1997).
Article CAS Google Scholar
Mehansho, H. Iron fortification technology development: New approaches. J. Nutr. 136, 1059–1063 (2006).
Article CAS PubMed Google Scholar
Lufingo, M., Ndé-Tchoupé, A. I., Hu, R., Njau, K. N. & Noubactep, C. A novel and facile method to characterize the suitability of metallic iron for water treatment. Water 11, 2465 (2019).
Article CAS Google Scholar
Li, N. et al. Wang X The efficacy and safety of vitamin C for iron supplementation in adult patients with iron deficiency anemia: A randomized clinical trial. JAMA Netw. Open. 3, e2023644 (2020).
Article PubMed PubMed Central Google Scholar
Pasupathy, E., Kandasamy, R., Thomas, K. & Basheer, A. Alternate day versus daily oral iron for treatment of iron deficiency anemia: A randomized controlled trial. Sci Rep 2023, 13 (1818).
Google Scholar
Briend, A., Hoque, B. & Aziz, K. Iron in tubewell water and linear growth in rural Bangladesh. Arch. Dis. Child. 65, 224–225 (1990).
Article CAS PubMed PubMed Central Google Scholar
Merrill, R. D. et al. Iron status of women is associated with the iron concentration of potable groundwater in rural Bangladesh. J Nutr. 141, 944–949 (2011).
Article CAS PubMed Google Scholar
Merrill, R. Iron in groundwater: A source for anemia prevention. Vitam. Trace Elem. 1, e1 (2012).
Article Google Scholar
Merrill, R. D. et al. High prevalence of anemia with lack of iron deficiency among women in rural Bangladesh: Arole for thalassemia and iron in groundwater. Asia Pac. J. Clin. Nutr. 21, 416–424 (2012).
CAS PubMed Google Scholar
Karakochuk, C. D. et al. Elevated levels of iron in groundwater in Prey Veng province in Cambodia: A possible factor contributing to high iron stores in women. J. Water Health. 13, 575–586 (2015).
Article PubMed Google Scholar
Wendt, A. S., Waid, J. L. & Gabrysch, S. Dietary factors moderate the relation between groundwater iron and anemia in women and children in rural Bangladesh. Curr. Dev. Nutr. 3, nzz093 (2019).
Article CAS PubMed PubMed Central Google Scholar
Rahman, S. et al. Effect of low-iron micronutrient powder (MNP) on the composition of gut microbiota of Bangladeshi children in a high-iron groundwater setting: Arandomized controlled trial. Eur. J. Nutr. 60, 3423–3436 (2021).
Article CAS PubMed PubMed Central Google Scholar
Langmuir, D. Aqueous Environmental Geochemistry (Prentice Hall, 1997).
Google Scholar
Wheeler WE. Solubility and bioavailability of metallic iron in drinking water. Master Dissertation, 60 (University of California, Davis, 1994).
Mohammadi, M., Khashayar, P., Tabari, M., Sohrabvandi, S. & Moghaddam, A. F. Water fortified with minerals (Ca, Mg, Fe, Zn). Int. J. Med. Res. Health Sci. 5, 107–115 (2016).
Google Scholar
González, J. I. V., González, D. F. & González, L. F. V. Operations and Basic Processes in Ironmaking (Springer, 2020).
Google Scholar
Matsukevich, I., Kulinich, N. & Romanovski, V. Direct reduced iron and zinc recovery from electric arc furnace dust. J. Chem. Technol. Biotechnol. 97, 3453–3458 (2022).
Article CAS Google Scholar
Charles, C. V. Happy Fish: a novel supplementation technique to prevent iron deficiency Anemia in women in rural Cambodia. PhD Dissertation, (The University of Guelph, 2012).
Gordeuk, V. R., Boyd, D. R. & Brittenham, G. M. Dietary iron overload persists in rural sub-Saharan Africa. Lancet 327, 1310–1313 (1986).
Article Google Scholar
Walker, A. R. P. & Segal, I. Iron overload in Sub-Saharan Africa: To what extent is it a public health problem?. Br. J. Nutr. 81, 427–434 (1999).
Article CAS PubMed Google Scholar
Andrews, N. C. Iron metabolism: Iron deficiency and iron overload. Ann. Rev. Genom. Hum. Genet. 1, 75–98 (2000).
Article CAS Google Scholar
Charles, C. V., Dewey, C. E., Daniell, W. E. & Summerlee, A. J. Iron-deficiency anaemia in rural Cambodia: Community trial of a novel iron supplementation technique. Eur. J. Public Health. 21, 43–48 (2010).
Article PubMed Google Scholar
Charles, C. V. et al. A randomized control trial using a fish-shaped iron ingot for the amelioration of iron deficiency anemia in rural Cambodian women. Trop. Med. Surg. https://doi.org/10.4172/2329-9088.1000195 (2015).
Article Google Scholar
Charles, C. V., Summerlee, A. J. & Dewey, C. E. Iron content of Cambodian foods when prepared in cooking pots containing an iron ingot. Trop. Med. Int. Health. 16, 1518–1524 (2011).
Article PubMed Google Scholar
Borigato, E. V. & Martinez, F. E. Iron nutritional status is improved in Brazilian preterm infants fed food cooked in iron pots. J. Nutr. 128, 855–859 (1998).
Article CAS PubMed Google Scholar
Alves, C., Saleh, A. & Alaofè, H. Iron-containing cookware for the reduction of iron deficiency anemia among children and females of reproductive age in low- and middle-income countries: A systematic review. PLoS ONE 14, e0221094 (2019).
Article CAS PubMed PubMed Central Google Scholar
Rappaport, A. I. et al. Randomized controlled trial assessing the efficacy of a reusable fish-shaped iron ingot to increase haemoglobin concentration in anemic, rural Cambodian women. Am. J. Clin. Nutr. 106, 667–674 (2017).
Article CAS PubMed Google Scholar
Rodriguez-Ramiro, I., Perfecto, A. & Fairweather-Tait, S. J. Dietary factors modulate iron uptake in Caco-2 cells from an iron ingot used as a home fortificant to prevent iron deficiency. Nutrients 9, 1005 (2017).
Article PubMed PubMed Central Google Scholar
Ebert, C., Heesemann, E., & Vollmer S. Two interventions to promote health and mental development in early childhood: A randomized controlled trial in rural India. Discussion Paper 276, (Courant Research Centre 'Poverty, Equity and Growth', Georg-August-Universität Göttingen, 2021).
Krämer, M., Kumar, S. & Vollmer, S. Improving child health and cognition: Evidence from a school-based nutrition intervention in India. Rev. Econ. Stat. 103, 818–834 (2021).
Article Google Scholar
Yang, H. et al. Numerical study on long-term effectiveness of metallic iron based permeable reactive barriers: Importance of porosity heterogeneity of the barrier. J. Hydrol. 12, 128148 (2022).
Article Google Scholar
Cui, X. et al. Developing the ascorbic acid test: A candidate standard tool for characterizing the intrinsic reactivity of metallic iron for water remediation. Water 2023, 15 (1930).
Google Scholar
Hurrell, R. et al. The usefulness of elemental iron for cereal flour fortification: A Sustain task force report. Nutr. Rev. 60, 391–406 (2002).
Article PubMed Google Scholar
Kew, M. C. & Asare, G. A. Dietary iron overload in the African and hepatocellular carcinoma. Liver Inter. 27, 735–741 (2007).
Article CAS Google Scholar
Armstrong, G. R., Dewey, C. E. & Summerlee, A. J. S. Iron release from the Lucky Iron Fish®: Safety considerations. Asia Pac. J. Clin. Nutr. 26, 148–155 (2017).
CAS PubMed Google Scholar
Hurrell, R. F. & Cook, J. D. Strategies for iron fortification of foods. Trends Food Sci. Technol. 1, 56–61 (1990).
Article CAS Google Scholar
Larsen, O., Postma, D. & Jakobsen, R. The reactivity of iron oxides towards reductive dissolution with ascorbic acid in a shallow sandy aquifer (Rømø, Denmark). Geochim. Cosmochim. Acta 70, 4827–4835 (2006).
Article ADS CAS Google Scholar
Lahiri, A. Influence of ascorbate and oxalic acid for the removal of iron and alkali from alkali roasted ilmenite to produce synthetic rutile. Ind. Eng. Chem. Res. 49, 8847–8851 (2010).
Article CAS Google Scholar
Sinha, M. K. & Purcell, W. Reducing agents in the leaching of manganese ores: A comprehensive review. Hydrometallurgy 187, 168–186 (2019).
Article CAS Google Scholar
Sinha, M. K., Purcell, W. & van Der Westhuizen, W. A. Recovery of manganese from ferruginous manganese ore using ascorbic acid as reducing agent. Miner. Eng. 154, 106406 (2020).
Article CAS Google Scholar
Xu, P. et al. Ascorbic acid enhanced the zero-valent iron/peroxymonosulfate oxidation: Simultaneous chelating and reducing. Sep. Purif. Technol. 298, 121599 (2022).
Article CAS Google Scholar
Gasim, M. F. et al. Peracetic acid activation using heterogeneous catalysts for environmental decontamination: A review. Catal. Comm. 180, 106702 (2023).
Article CAS Google Scholar
Xu, P., Wang, L., Liu, X., Xie, S. & Hou, B. Vitamin C promoted refractory organic contaminant elimination in the zero-valent iron/peracetic acid system: Efficiency, mechanism and effects of various parameters. Chemosphere 326, 138481 (2023).
Article ADS CAS PubMed Google Scholar
Zhu, S. et al. Ascorbic acid-mediated zero-valent iron enhanced hydrogen production potential of bean dregs and corn stover by photo fermentation. Bioresour. Technol. 374, 128761 (2023).
Article CAS PubMed Google Scholar
Conrad, M. E. & Schade, S. G. Ascorbic acid chelates in iron absorption: A role for hydrochloric acid and bile. Gastroenterology 55, 35–45 (1968).
Article CAS PubMed Google Scholar
Teucher, B., Olivares, M. & Cori, H. Enhancers of iron absorption: ascorbic acid and other organic acids. Int. J. Vitam. Nutr. Res. 74, 403–419 (2004).
Article CAS PubMed Google Scholar
Elomaa, H., Seisko, S., Lehtola, J. & Lundström, M. A study on selective leaching of heavy metals vs. iron from fly ash. J. Mater. Cycles Waste Manag. 21, 1004–1013 (2019).
Article CAS Google Scholar
Chen, D. et al. Synergistic leaching of valuable metals from spent Li-ion batteries using sulfuric acid- l-ascorbic acid system. Chem. Eng. J. 388, 124321 (2020).
Article CAS Google Scholar
Du, K., Ang, E. H., Wu, X. & Liu, Y. Progresses in sustainable recycling technology of spent lithium ion batteries. Energy Environ. Mater. https://doi.org/10.1002/eem2.12271 (2022).
Article Google Scholar
Ndé-Tchoupé, A. I., Hu, R., Gwenzi, W., Nassi, A. & Noubactep, C. Characterizing the reactivity of metallic iron for water treatment: H2 evolution in H2SO4 and uranium removal efficiency. Water 12, 1523 (2020).
Article Google Scholar
Dorey, C. et al. Iron speciation at physiological pH in media containing ascorbate and oxygen. Br. J. Nutr. 70, 157–169 (1993).
Article CAS PubMed Google Scholar
Hildebrant, B., Ndé-Tchoupé, A. I., Lufingo, M., Licha, T. & Noubactep, C. Steel wool for water treatment: Intrinsic reactivity and defluoridation efficiency. Processes 8, 265 (2020).
Article CAS Google Scholar
dos Santos, N. O., Teixeira, L. A., Zhou, Q., Burke, G. & Campos, L. C. Fenton pre-oxidation of natural organic matter in drinking water treatment through the application of iron nails. Environ. Technol. 43, 2590–2603 (2022).
Article PubMed Google Scholar
Pierce, E. M., Wellman, D. M., Lodge, A. M. & Rodriguez, E. A. Experimental determination of the dissolution kinetics of zero-valent iron in the presence of organic complexants. Environ. Chem. 4, 260–270 (2007).
Article CAS Google Scholar
Han, L., Chen, B., Liu, T. & Choi, Y. Leaching characteristics of iron and manganese from steel slag with repetitive replenishment of leachate. KSCE J. Civ. Eng. 23, 3297–3304 (2019).
Article Google Scholar
Jie, Y. J. et al. Reclamation of steel shots by acid leaching for powder metallurgy applications. Adv. Mechan. Eng. 11, 1–9 (2019).
Google Scholar
Alcántara, J. et al. Marine atmospheric corrosion of carbon steel: A review. Materials. 10, 406 (2017).
Article ADS PubMed PubMed Central Google Scholar
Stefanoni, M., Angst, U. & Elsener, B. Electrochemistry and capillary condensation theory reveal the mechanism of corrosion in dense porous media. Sci. Rep. 8, 7407 (2018).
Article ADS PubMed PubMed Central Google Scholar
Ali, N. & Fulazzaky, M. A. The empirical prediction of weight change and corrosion rate of low-carbon steel. Heliyon. 6, e05050 (2020).
Article CAS PubMed PubMed Central Google Scholar
Chen, Q. et al. Past, present, and future of groundwater remediation research: A scientometric analysis. Int. J. Environ. Res. Public Health 16, 3975 (2019).
Article PubMed PubMed Central Google Scholar
Li, X. et al. Bibliometric analysis of zerovalent iron particles research for environmental remediation from 2000 to 2019. Environ. Sci. Pollut. Res. 28, 4200–34210 (2021).
Google Scholar
Yang, H., Hu, R., Ruppert, H. & Noubactep, C. Modeling porosity loss in Fe0-based permeable reactive barriers with Faraday’s law. Sci. Rep. 11, 16998 (2021).
Article ADS CAS PubMed PubMed Central Google Scholar
Noubactep, C., Schöner, A. & Woafo, P. Metallic iron filters for universal access to safe drinking water. Clean Soil Air Water 37, 930–937 (2009).
Article CAS Google Scholar
Dutra-de-Oliveira, J. E., Marchini, J. S. & Desai, I. Fortification of drinking water with iron: A new strategy for combating iron deficiency in Brazil. Amer. J. Clin. Nutr. 63, 612–613 (1996).
Article CAS PubMed Google Scholar
Viteri, F. E. Reply to J.E Dutra-de-Oliveira Amer et al. J. Clin. Nutr. 63, 613–614 (1996).
Google Scholar
Dutra-de-Oliveira, J. E. & Marchini, J. S. Drinking water as an iron carrier to control iron deficiency. Nutrition 22, 853 (2006).
Article PubMed Google Scholar
Lamounier, J. A. et al. Iron fortification strategies for the control of childhood anemia in Brazil. J. Trop. Ped. 56, 448–451 (2010).
Article Google Scholar
Dutra-de-Oliveira, J. E., Marchini, J. S., Lamounier, J. & Nogueira-de-Almeida, C. A. A community public health programme to control iron-deficiency anemia through iron-fortification of drinking water. Int. J. Nutrol. 5, 140–143 (2012).
Article Google Scholar
Lamounier, J. A., Capanema, F. D. & Rocha, D. S. Iron food fortification for the control of childhood anemia in Brazil. In Public Health-Social and Behavioral Health (ed. Maddock, J.) (IntechOpen, 2012).
Google Scholar
Nogueira-de-Almeida, C. A. et al. Prevalence of childhood anaemia in Brazil: Still a serious health problem: A systematic review and meta-analysis. Public Health Nutr. 24, 6450–6465 (2021).
Article PubMed Google Scholar
Tepong-Tsindé, R., Crane, R., Noubactep, C., Nassi, A. & Ruppert, H. Testing metallic iron filtration systems for decentralized water treatment at pilot scale. Water 7, 868–897 (2015).
Article Google Scholar
Goncharuk, V. V. A new concept of supplying the population with a quality drinking water. J. Water Chem. Technol. 30, 129–136 (2008).
Article Google Scholar
Domènech, L. Rethinking water management: From centralised to decentralised water supply and sanitation models. Doc. An. Geogr. 57, 293–310 (2011).
Google Scholar
Siwila, S. & Brink, I. C. A small-scale low-cost water treatment system for removal of selected heavy metals, bacteria and particles. Water Pract. Technol. 13, 446–459 (2018).
Article Google Scholar
Huang, Z. et al. Universal access to safe drinking water: Escaping the traps of non-frugal technologies. Sustainability 13, 9645 (2021).
Article CAS Google Scholar
Kearns, J. et al. Biochar water treatment for control of organic micropollutants with UVA surrogate monitoring. Environ. Eng. Sci. 38, 298–309 (2021).
Article CAS PubMed PubMed Central Google Scholar
Naseri, E. et al. Making Fe0-based filters a universal solution for safe drinking water provision. Sustainability. 9, 1224 (2017).
Article Google Scholar
Nya, E. L., Feumba, R., Fotsing-Kwetché, P. R., Gwenzi, W. & Noubactep, C. A hybrid model for achieving universal safe drinking water in the medium-sized city of Bangangté (Cameroon). Water 13, 3177 (2021).
Article Google Scholar
Yang, H. et al. Designing the next generation of Fe0-based filters for decentralized safe drinking water treatment. Processes. 8, 745 (2020).
Article CAS Google Scholar
Tepong-Tsindé, R. Designing and piloting a household filter for the peri-urban population of Douala (Cameroon). Freiberg. Online Geosci. 61, 1–80 (2021).
Google Scholar
Lan, L. E., Reina, F. D., De Seta, G. E., Meichtry, J. M. & Litter, M. I. Comparison between different technologies (zerovalent iron, coagulation-flocculation, adsorption) for arsenic treatment at high concentrations. Water 15, 1481 (2023).
Article CAS Google Scholar
Choudhury, N. et al. Iron content of drinking water is associated with anaemia status among children in high groundwater iron areas in Bangladesh. Trop. Med. Int. Health 27, 121–216 (2022).
Article Google Scholar
Wuehler, S. E., Hess, S. Y. & Brown, K. H. Accelerating improvements in nutritional and health status of young children in the Sahel region of Sub-Saharan Africa: Review of international guidelines on infant and young child feeding and nutrition. Mater. Child Nutr. 7, 6–34 (2011).
Article Google Scholar
Wieringa, F. T. et al. The high prevalence of anemia in Cambodian children and women cannot be satisfactorily explained by nutritional deficiencies or hemoglobin disorders. Nutrients 8, 348 (2016).
Article PubMed PubMed Central Google Scholar
Lemoine, A. & Tounian, P. Childhood anemia and iron deficiency in sub-Saharan Africa–risk factors and prevention: A review. Arch. Pediatr. 27, 490–496 (2020).
Article CAS PubMed Google Scholar
Anitha, S. et al. Millets can have a major impact on improving iron status, hemoglobin level, and in reducing iron deficiency anemia—A systematic review and meta-analysis. Front. Nutr. 8, 725529 (2021).
Article PubMed PubMed Central Google Scholar
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The authors gratefully acknowledge the pre-review of the draft manuscript by Willis Gwenzi (University of Kassel, Germany). Serge Ndokou-Nana (Yaoundé/Cameroon), Gerhard Hundertmark (University of Göttingen) and Huichen Yang (University of Göttingen) are thanked for technical support. Data in section 3 were obtained by Xuesong Cui, Ran Tao and Minhui Xiao (University of Göttingen, Germany).
Open Access funding enabled and organized by Projekt DEAL.
Centre for Modern Indian Studies (CeMIS), Universität Göttingen, Waldweg 26, 37073, Göttingen, Germany
Chicgoua Noubactep & Sebastian Vollmer
Department of Chemistry, Faculty of Sciences, University of Yaoundé I, P.O. Box 812, Yaoundé, Cameroon
Joseline Flore Kenmogne-Tchidjo
Department of Water and Environmental Science and Engineering, Nelson Mandela African Institution of Science and Technology, P.O. Box 447, Arusha, Tanzania
Chicgoua Noubactep
Faculty of Science and Technology, Campus of Banekane, Université des Montagnes, P.O. Box 208, Bangangté, Cameroon
Chicgoua Noubactep
School of Earth Science and Engineering, Hohai University, Fo Cheng Xi Road 8, Nanjing, 211100, China
Chicgoua Noubactep
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Conceptualization: J.F.K.-T., S.V. and C.N.; methodology: C.N; writing—original draft: J.F.K,-T. and C.N.; writing—review and editing: S.V. and C.N.; supervision: S.V. and C.N. All authors have read and agreed to the published version of the manuscript.
Correspondence to Chicgoua Noubactep.
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Noubactep, C., Kenmogne-Tchidjo, J.F. & Vollmer, S. Iron-fortified water: a new approach for reducing iron deficiency anemia in resource-constrained settings. Sci Rep 13, 13565 (2023). https://doi.org/10.1038/s41598-023-40600-z
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Received: 29 November 2022
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Published: 21 August 2023
DOI: https://doi.org/10.1038/s41598-023-40600-z
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