Utilization Of Micronutrients Research Articles

Glacial interglacial variations in the natural iron fertilization during the low sea ice periods along the eastern continental margin of Antarctica

The Southern Ocean sequesters atmospheric CO2 through biological pumps, though its driving factors are debated. Modern productivity is regulated by natural iron fertilization from micronutrient influx through dust, regeneration, and Antarctic glaciers and sea ice melting (ice melt). The productivity along the eastern Antarctic continental margin was low during the last glacial period and gradually increased through the deglacial to Late Holocene, marked by distinct productivity peaks. The micronutrients also varied similarly, with reduced glacial influx and an increase in the Holocene, which may cause productivity peaks. Therefore, the coherence of enhanced productivity and micronutrient influx is considered as enhanced iron fertilization period. The productivity peaks declined within ∼1.5 kyr, mostly due to the Ekman transport and sea ice formation. Along with ice melt, the independent weathering pattern that responds with glacial- interglacial ice volume changes suggest the source of micronutrients is not terrigenous. Shelf interaction of oceanic currents can influence the water column nutrient stock significantly, while its utilization occurs during reduced ice periods (low sea ice and high glacier melting) for productivity. Therefore, enhanced natural iron fertilization periods are considered as ice low periods that occurred in a periodicity of 2 kyrs, at ∼7.5 kyr BP, ∼5.5 kyr BP, ∼4 kyr BP, ∼ 2.5 kyr BP, and ∼0.5 kyr BP, likely due to the combined effects of atmospheric and oceanographic factors driven by the high amplitude regional temperature variability during the mid to late Holocene.

Foliar application of Zinc and Boron improved physiological traits, productivity and shelf life of onion

Micronutrients play a crucial role in enabling crops and vegetables to achieve optimum productivity, improve storage quality, and overcome physiological disorders. The present study focuses on evaluating the effects of the foliar application of Zinc, Borax, and their combined application in enhancing onion yield and shelf life of Allium cepa L. (cultivars Red coral and Liberty). An experimental study was conducted for two years at Agriculture Research Unit, DIHAR Leh (34.1383˚N, 77.5725˚E) to assess the impact of different doses of ZnSO4, Borax, and their combination on onion yield and shelf-life improvement. Four treatments of ZnSO4 and Borax (T1: 0.5% ZnSO4; T2: 0.25% Borax; T3: 0.5% ZnSO4 + 0.25% Borax and T4: control) were applied twice, once at 30 DAT and again after 45 DAT. Among four treatments, T3 showed a significant impact on growth parameters, yield, and onion shelf-life followed by T1 and T2 compared to the control T4 treatment. Foliar sprays of ZnSO4 and Borax, rather than only ZnSO4 or Borax application, significantly improved plant height, leaves number, leaf area index, chlorophyll content, and onion yield. The storage examination revealed an important correlation between the concurrent application of ZnSO4 and Borax on onion, demonstrating a significant reduction in weight loss, an increase in Total Soluble Solids (T.S.S), and an extension of the onions’ shelf life. These findings hold the potential for significant implications in elucidating the optimal utilization of micronutrients for improving onion cultivation and preservation practices in cold desert regions of Ladakh.

A review on soil fertility and soybean yield improvement by managing micronutrients

The importance of micronutrients to plant growth is comparable to that of macronutrients such as nitrogen, phosphorus, and potassium, even though they are required at much lower concentrations. They are necessary for the process of cell division, the development of meristematic tissue, photosynthesis, respiration, the transfer of energy and nucleotides, and the overall growth of plants. Although plants only require very modest levels of micronutrients for optimal growth and productivity, the absence of these nutrients disrupts a wide variety of physiological and metabolic processes. It is necessary for plants to receive specific amounts of micronutrients in specific forms at specific times in order for them to grow and develop to their full potential. Lack of micronutrients in the soil significantly reduces soybean production. This article evaluates and summaries information on micronutrient utilization in soybeans at global level. We discussed micronutrient deficiency symptoms and their impact on soybean yields. Micronutrient application methods and dosages are also considered. This study compiled information on micronutrient use in soybean to better understand its impact on fertility, soil health, and grain yield.

Exploring the Immune-Boosting Functions of Vitamins and Minerals as Nutritional Food Bioactive Compounds: A Comprehensive Review

Food components have long been recognized to play a fundamental role in the growth and development of the human body, conferring protective functionalities against foreign matter that can be severe public health problems. Micronutrients such as vitamins and minerals are essential to the human body, and individuals must meet their daily requirements through dietary sources. Micronutrients act as immunomodulators and protect the host immune response, thus preventing immune evasion by pathogenic organisms. Several experimental investigations have been undertaken to appraise the immunomodulatory functions of vitamins and minerals. Based on these experimental findings, this review describes the immune-boosting functionalities of micronutrients and the mechanisms of action through which these functions are mediated. Deficiencies of vitamins and minerals in plasma concentrations can lead to a reduction in the performance of the immune system functioning, representing a key contributor to unfavorable immunological states. This review provides a descriptive overview of the characteristics of the immune system and the utilization of micronutrients (vitamins and minerals) in preventative strategies designed to reduce morbidity and mortality among patients suffering from immune invasions or autoimmune disorders.

Addition of biochar to acidic boreal podzolic soils enhances micronutrient availability and crop productivity

Abstract Results of a recent multiyear experiment conducted on an agricultural plot that was recently converted from boreal forest (Labrador, Canada) suggested that NPK fertilizers contributed to better crop establishment and higher yield but only when it was applied along with biochar. The failure of fertilizer only treatments to allow crop establishment and desirable growth and yield could be related to the deficiency of one or more micronutrients. Consequently, a missing element trial with a number of micronutrients (Mn, Cu, Zn, and Mo) was initiated on the same soil to investigate whether biochar can facilitate the availability of one or more of these micronutrients, contributing to crop growth and yields. Results show that the incorporation of chemical fertilizers with biochar produced significantly higher yields than in the absence of biochar. Furthermore, in the absence of biochar, the addition of micronutrients (i.e., Mn, Cu, Zn, and Mo) did not significantly increase yield. On the other hand, among the treatments that included biochar, the absence of a micronutrient (i.e., only three of the four micronutrients included) had either no effect (e.g., absence of Mn or Zn) or was associated with the increased yields (i.e., absence of Cu or Mo). Thus, it is proposed that while all tested micronutrients were present in the podzolic soil, with Cu and Mo possibly oversupplied, co-application with biochar enhanced both macronutrient and micronutrient utilization by plants. The data on the availability of micronutrients in the soil, their concentration in plants, and total uptake also support this conclusion. Thus, biochar facilitates the plant uptake of both naturally occurring and added micronutrients, and associated crop productivity, in a podzolic soil typical for lands converted from forest to agricultural use in the boreal ecoregion of Labrador. These results also challenge the view that micronutrients must always be added to Podzols to achieve maximum productivity; biochar-mediated micronutrient plant uptake deserves consideration when managing Podzols.

Influence of soil temperature and moisture on micronutrient supply, plant uptake, and biomass yield of wheat, pea, and canola

Crop yield response to micronutrient fertilization is difficult to predict, particularly under unfavorable environmental conditions as these may alter both crop nutrient demand and the soil micronutrient supply to plant roots. The research objective was to evaluate the effect of various soil temperature and moisture conditions on crop growth response to added micronutrient copper (Cu), zinc (Zn), and boron (B) along with soil micronutrient supply and distribution among fractions. Brown and Dark Brown farm soils collected from southern Saskatchewan were used to grown wheat, pea and canola within controlled environment chambers. The biomass yields of all crops decreased under cold soil temperature and moisture stress (drought and saturated) conditions. Greater plant uptake of Cu, Zn, and B was associated with optimum (i.e., field capacity) soil moisture and warm temperature (23°C) growing conditions, compared to drought (i.e., 50% field capacity), saturated, and cold (5°C) temperature conditions. Environmental stress had the greatest impact on pea growth, reducing crop yield and micronutrient utilization efficiency more than 95%. Soil supplies of Cu and Zn were most negatively impacted by drought stress due to reduced mobility of these diffusion limited nutrients. The extractable micronutrients levels and chemical speciation fractions of Cu, Zn, and B indicating that bioavailability and micronutrient transformation were not affected during our short-term (i.e., six-weeks) study. However, it is suggested that assessments of micronutrient forms also be conducted on soil samples under actual moisture and temperature conditions as they exist in the experiment, as well as on dried, processed samples.

Genetic Contribution to Variation in Blood Calcium, Phosphorus, and Alkaline Phosphatase Activity in Pigs.

Blood values of calcium (Ca), inorganic phosphorus (IP), and alkaline phosphatase activity (ALP) are valuable indicators for mineral status and bone mineralization. The mineral homeostasis is maintained by absorption, retention, and excretion processes employing a number of known and unknown sensing and regulating factors with implications on immunity. Due to the high inter-individual variation of Ca and P levels in the blood of pigs and to clarify molecular contributions to this variation, the genetics of hematological traits related to the Ca and P balance were investigated in a German Landrace population, integrating both single-locus and multi-locus genome-wide association study (GWAS) approaches. Genomic heritability estimates suggest a moderate genetic contribution to the variation of hematological Ca (N = 456), IP (N = 1049), ALP (N = 439), and the Ca/P ratio (N = 455), with values ranging from 0.27 to 0.54. The genome-wide analysis of markers adds a number of genomic regions to the list of quantitative trait loci, some of which overlap with previous results. Despite the gaps in knowledge of genes involved in Ca and P metabolism, genes like THBS2, SHH, PTPRT, PTGS1, and FRAS1 with reported connections to bone metabolism were derived from the significantly associated genomic regions. Additionally, genomic regions included TRAFD1 and genes coding for phosphate transporters (SLC17A1–SLC17A4), which are linked to Ca and P homeostasis. The study calls for improved functional annotation of the proposed candidate genes to derive features involved in maintaining Ca and P balance. This gene information can be exploited to diagnose and predict characteristics of micronutrient utilization, bone development, and a well-functioning musculoskeletal system in pig husbandry and breeding.

Efficiency of Biological Utilization of Micronutrients by Forests Species in Hypoxerophytic Caatinga

Efficiency of Biological Utilization of Micronutrients by Forests Species in Hypoxerophytic Caatinga

MICRONUTRIENTS DEFICIENCY ON THE NUTRITIONAL STATUS OF BANANA PRATA SEEDLINGS

ABSTRACT The knowledge of the requirements and micronutrients efficiency in banana is relevant to the development of fertilizer recommendations. This study aimed to evaluated requirements and nutritional efficiencies of banana seedlings submitted to omission of micronutrients in nutritive solution. Treatments were complete nutritive solution and solution with individual omission of B, Cu, Fe, Mn and Zn, and two Prata-Anã and BRS Platina hybrid genotypes. Leaf area, dry matter of leaves, rhizome, roots and total and micronutrient contents were determined. With results, the following indexes were calculated: uptake, transport and micronutrient utilization efficiency. B deficiency effected more intensely the growth of both banana genotypes. The nutrient uptake corresponded to the following sequence: Fe > Mn > Zn > B > Cu, which reflects the plant requirements. The BRS Platina hybrid showed higher B, Fe and Zn absorption efficiency in relation to Prata Anã cultivar, which had higher Cu absorption efficiency. BRS Platina hybrid showed higher efficiency in the transport of Fe and Mn, while Prata Anã only for Cu. Prata Anã cultivar showed higher micronutrient utilization efficiency in complete treatment and treatment with omission of micronutrients.

Functional proteomics of barley and barley chloroplasts – strategies, methods and perspectives

Barley (Hordeum vulgare) is an important cereal grain that is used in a range of products for animal and human consumption. Crop yield and seed quality has been optimized during decades by plant breeding programs supported by biotechnology and molecular biology techniques. The recently completed whole-genome sequencing of barley revealed approximately 26,100 open reading frames, which provides a foundation for detailed molecular studies of barley by functional genomics and proteomics approaches. Such studies will provide further insights into the mechanisms of, for example, drought and stress tolerance, micronutrient utilization, and photosynthesis in barley. In the present review we present the current state of proteomics research for investigations of barley chloroplasts, i.e., the organelle that contain the photosynthetic apparatus in the plant. We describe several different proteomics strategies and discuss their applications in characterization of the barley chloroplast as well as future perspectives for functional proteomics in barley research.

Understanding and Applying Chelated Fertilizers Effectively Based on Soil pH

Plant nutrients are one of the environmental factors essential for crop growth and development. Nutrient management is crucial for optimal productivity in commercial crop production. Those nutrients in concentrations of ≤ 100 parts per million (ppm) in plant tissues are described as micronutrients and include iron (Fe), zinc (Zn), manganese (Mn), copper (Cu), boron (B), chlorine (Cl), molybdenum (Mo), and nickel (Ni). Micronutrients such as Fe, Mn, Zn, and Cu are easily oxidized or precipitated in soil, and their utilization is, therefore, not very efficient. Chelated fertilizers have been developed to increase micronutrient utilization efficiency. This 7-page fact sheet provides an overview of chelated fertilizers and considerations for their use to county Extension faculty, growers, and students who are interested in commercial crop production. Written by Guodong Liu, Edward Hanlon, and Yuncong Li, and published by the UF Department of Horticultural Sciences, November 2012. HS1208/HS1208: Understanding and Applying Chelated Fertilizers Effectively Based on Soil pH (ufl.edu)

Editorial: Vitamin A as adjunct therapy for cerebral malaria: what is the evidence?

Severe malaria continues to cause significant morbidity and mortality in several settings in Africa despite the availability of efficacious and potent antimalarial drugs. This has led to an increased interest in adjunctive therapies that target the underlying pathophysiology of severe malaria as additional approaches to management that may further reduce morbidity and mortality. Several adjunctive therapies have been tested over the years including dexamethasone, exchange blood transfusion, N-acetylsysteine, anti-TNF, mannitol and levamisole. However despite numerous clinical trials, to date, effective adjunctive treatments have been elusive. Most trials have been underpowered and in a recent review many were found to have inadequate methodological quality. It is apparent therefore that different approaches to adjunctive therapy for severe malaria have been evaluated. One additional approach has been exploring the utilization of micronutrients in the management of malaria. Whereas micronutrients are well known to have antioxidant effects, their interaction with malaria is not well characterized. Their role for the treatment and prevention of malaria has however been a source of intrigue with studies reporting conflicting results on their impact. Zinc, vitamin A and E, carotenoids, vitamins B and C and folic acid have been reported to have modulatory effects on the pathogenesis of malaria1. Beneficial protective effects of vitamin A or zinc on malaria-related morbidity have been demonstrated in some settings2,3,4,5. In Burkina Faso, combined supplementation with vitamin A and zinc reduced the burden of clinical attacks of malaria in young children by 30%6. In contrast to these studies that have suggested potential protective effects of vitamin A or zinc supplementation, other studies have shown the reverse. A randomized, placebo-controlled trial in Burkina Faso of zinc supplementation failed to show a protective impact on malaria episodes7. In addition, a study done in 2006 found that iron and folic acid supplements instead increased malaria-related hospitalization and deaths by 12 per cent. In a more recent study in Tanzania, giving supplements containing iron, folic acid, copper and vitamins to about 600 children aged 6 months to 5 years with iron deficiency increased their likelihood of contracting malaria by 41 per cent8. These conflicting findings indicate that currently, there is no consensus on the exact impact of micronutrients on malaria treatment and prevention. In this issue of the African Health Sciences, Mwanga et al report results of a randomized controlled trial evaluating the effect of vitamin A adjunct therapy for cerebral malaria in children admitted to Mulago hospital9. As a leading cause of childhood mortality in sub-Saharan Africa, interventions to ameliorate mortality due to cerebral malaria are a public health priority. Vitamin A is an essential nutrient required for maintaining immune function, playing an important role in the regulation of cell-mediated immunity and in humoral antibody responses. Vitamin A has been shown to suppress growth of P.falciparum, scavenge free radicals, and exhibit synergistic action with quinine in parasite clearance10,10. Mwanga et al studied 142 children aged 6 months to 5 years, who were randomized to receive either Vitamin A or placebo and antimalarial treatment with intravenous quinine. The results show that whereas there were no significant differences in outcome measures between the two treatment arms, there was a trend towards earlier resolution of convulsions and lower mortality (8.1%) in children who received Vitamin A supplementation compared to 16.2% in the placebo. Whereas this difference in mortality did not reach statistical significance; it draws attention to the potential role of Vitamin A as adjunct therapy for cerebral malaria. Vitamin A is a particularly attractive option for this role as it is a relatively affordable, easy to administer and readily available intervention that could be appropriate for use in several malaria endemic countries. However, before any such recommendations are made, a sufficiently powered study with different dosing regimens are warranted to provide more conclusive evidence for the role Vitamin A could play as adjunct therapy. Furthermore reduction in severe malaria related mortality will also be achieved through embracing the use of intravenous artesunate as the preferred first line drug for the management of severe malaria. In several settings in sub-Saharan Africa, additional interventions will include improved health seeking behavior that will promote early treatment seeking, strengthening of referral systems, improved triage and emergency treatment approaches and finally better supportive care for hospitalized patients.

Effect of integrated nutrient management in a soybean-wheat crop sequence on the yield, micronutrient uptake and post-harvest availability of micronutrients on typic ustochrepts soil

A field experiment using various levels of phosphorus, farmyard manure (FYM) and biofertilizers was undertaken at Udaipur during 2001–02 and 2002–03 to observe the direct effect of the treatments on the yield and micronutrient uptake of soybean and their residual effect on the yield and micronutrient utilization of a subsequent wheat crop. The results revealed that the seed/grain yield of soybean and wheat significantly increased with the application of increasing levels of P, FYM and biofertilizers. The integrated use of P, FYM and biofertilizers was able to replace 20 kg P 2 O 5 ha −1 to soybean and 10 kg P 2 O 5 ha −1 to wheat.The application of increasing levels of P, FYM and biofertilizers significantly enhanced the uptake of Zn, Cu, Mn and Fe by soybean and wheat. Among the biofertilizers, dual inoculation with phosphate-solubilising bacteria (PSB) + vesicular arbuscular mycorrhiza (VAM) gave the best performance. The integrated use of P levels and biofertilizers significantly improved the Zn and Fe uptake of soybean. The highest Zn and Fe uptake (125.77 mg kg −1 and 562.03 mg kg −1 , respectively) was recorded with the combined use of 40 kg P 2 O 5 ha −1 + dual inoculation. The application of FYM and P levels resulted in a significant improvement in the organic carbon, CEC, available N and P, porosity and hydraulic conductivity of the soil after the wheat harvest. Among the biofertilizers, dual inoculation led to maximum soil-available P. Phosphorus application gave a significant decrease in the DTPA-extractable Zn and Fe content of the soil after the harvest of wheat. FYM application significantly enhanced the DTPA-extractable Zn, Cu, Mn and Fe contents of the soil.

Macro- and Micro-nutrient Utilization and Milk Production in Crossbred Dairy Cows Fed Finger Millet (Eleucine coracana) and Rice (Oryza sativa) Straw as Dry Roughage Source

Finger millet straw and rice straw are the major source of dry roughage in southern India. They distinctly vary in their morphological and nutritional characters. Hence an effort was made to study the nutrient utilization, milk yield and composition in crossbred dairy cows fed either finger millet (group 1) or rice straw (group 2) as a source of dry roughage. The cows in both the groups were fed as per requirement with concentrate, green fodder and straw in the ratio of 30:45:25 parts (DM). At the end of 50 days of preliminary feeding a digestibility trial was conducted for 7 days and pooled samples of feed, fodder, feces, urine and milk were analysed for macro and micro nutrient content. Finger millet straw contained more CP, Ca, P, Mg, Cu, Zn and Co than rice straw and rice straw contained higher ADF, ash and silica. The intake of DM, CP, EE, NDF, ADF and most micronutrients (Ca, P, Mg, Cu, Zn, Fe, Mn and Co) was significantly higher in cows fed finger millet straw. The digestibility of DM, CP, NDF and ADF was significantly higher in cows fed finger millet straw and the gut absorption of Ca, Cu, Mn and Co was significantly higher in cows fed finger millet straw. The dietary requirement of all micronutrients in both the group of cows could be met irrespective of the type of roughage fed except that of Ca, which was low (0.61 and 0.40%) in rice straw fed cows. The average daily milk yield (L/cow) was also higher (7.0 L) in cows fed finger millet straw as compared to cows fed rice straw (6.3 L). The average milk composition also did not differ except that of milk fat which was significantly (4.7 and 4.5%) low in cows fed rice straw. The overall results of this study have indicated that finger millet straw is a better source of dry fodder than rice straw and while feeding rice straw as the sole roughage to dairy cows there is need to supplement additional calcium as this could be one of the limiting nutrients for milk production.

Crescimento e composição mineral de mudas de eucalipto cultivadas sob condições de diferentes fontes de fertilizantes

The objective of this work was to evaluate the effects of different fertilizers on the growth and mineral composition of eucalyptus seedlings. Three species of eucalyptus (E. saligna, E. grandis and E. citriodora), nine fertilizers (differing in composition and solubility - rate of nutrient liberation: high and low liberation), and 4 replications were used in this study. The eucalyptus seedlings were cultivated into plastic tubes (50cm3) with commercial substratum, under controlled conditions of illumination and irrigation, during a period of 6 months. Results showed that the use of slow release fertilizers resulted in a larger accumulation of nutrients in the shoot part of the eucalyptus seedlings, except for phosphorus and potassium, that the high contents values were noticed for E. citriodora. For E. saligna and E. citriodora, the utilization of micro nutrients and foliar fertilization did not result in a significantly increase in dry mass production of eucalyptus seedlings

Nutritional and physiologic significance of human milk proteins

Human milk contains a wide variety of proteins that contribute to its unique qualities. Many of these proteins are digested and provide a well-balanced source of amino acids to rapidly growing infants. Some proteins, such as bile salt-stimulated lipase, amylase, beta-casein, lactoferrin, haptocorrin, and alpha1-antitrypsin, assist in the digestion and utilization of micronutrients and macronutrients from the milk. Several proteins with antimicrobial activity, such as immunoglobulins, kappa-casein, lysozyme, lactoferrin, haptocorrin, alpha-lactalbumin, and lactoperoxidase, are relatively resistant against proteolysis in the gastrointestinal tract and may, in intact or partially digested form, contribute to the defense of breastfed infants against pathogenic bacteria and viruses. Prebiotic activity, such as the promotion of the growth of beneficial bacteria such as Lactobacilli and Bifidobacteria, may also be provided by human milk proteins. This type of activity can limit the growth of several pathogens by decreasing intestinal pH. Some proteins and peptides have immunomodulatory activities (eg, cytokines and lactoferrin), whereas others (eg, insulin-like growth factor, epidermal growth factor, and lactoferrin) are likely to be involved in the development of the intestinal mucosa and other organs of newborns. In combination, breast-milk proteins assist in providing adequate nutrition to breastfed infants while simultaneously aiding in the defense against infection and facilitating optimal development of important physiologic functions in newborns.

Trace element bioavailability as exemplified by iron and zinc

Plant foods can be improved as sources of essential micronutrients either by increasing the concentrations of nutrients in the food, increasing the bioavailability of micronutrients in the food, or both of these. Quantities of minerals in edible portions of crops are influenced by numerous complex, dynamic and interacting factors, including plant genotype, soil properties, environmental conditions and nutrient interactions. Similarly, numerous dietary and host factors interact to affect the bioavailability to animals and people of mineral nutrients in plant foods. Micronutrient bioavailability apparently can be improved by either increasing the quantity of substances within plant foods that enhance the absorption and utilization of micronutrients or by decreasing the quantity of dietary antinutrients that inhibit micronutrient absorption; however, processes that control and regulate the bioavailability of trace elements in plant foods consumed in mixed diets are not fully understood. Use of either stable or radioactive isotopes incorporated intrinsically into edible portions of plant foods during plant growth will likely provide the most reliable estimates of the bioavailability of micronutrients consumed in mixed diets. Increasing the dietary supply of staple plant foods rich in trace elements combined with increased knowledge of micronutrient bioavailability from these foods will meaningfully improve the nutritional health and well being of people.

Micronutrient bioavailability techniques: Accuracy, problems and limitations

Within the scientific agricultural community it is widely known that the total micronutrient content of soils is not a useful measure of the amount of `available' micronutrients to plants. Thus, soil tests have been developed to determine the amounts of micronutrients in soils available to plants for growth. This same concept applies to plant foods eaten by humans because not all of the micronutrients in plant foods are available (i.e. bioavailable) for absorption and or utilization. Antinutrients and promoter substances within plant foods that can either inhibit or enhance the absorption and/or utilization of micronutrients when eaten. As a result, numerous techniques have been developed to determine the amounts of bioavailable micronutrients present in plant foods when consumed in mixed diets with other dietary constituents that can interact and affect the micronutrient bioavailability. Unfortunately, micronutrient bioavailability to humans fed mixed diets is still a confusing and complex issue for the human nutrition community. Our understanding of the processes that control micronutrient bioavailability from mixed diets containing plant foods is relatively limited and still evolving. It remains the subject of extensive research in many human nutrition laboratories globally. This article reviews some of the numerous methodologies that have arisen to account for the bioavailability of micronutrients in plant foods when eaten by humans.

The esterified plasma fatty acid profile is altered in early HIV‐1 infection

Previous studies have shown that alterations in micronutrient utilization occur in patients with Acquired Immune Deficiency Syndrome. In this study, total plasma fatty acid composition was measured in 36 homosexual men infected with the Human Immunodeficiency Virus 1 (HIV-1) and in 17 HIV-1 seronegative homosexual men in order to evaluate differences associated with early HIV-1 infection. Immunologic assessment included CD4 cell number count and lymphocyte blastogenesis in response to the mitogens phytohemagglutinin (PHA) and pokeweed (PWM). The mean total amount of omega 6 polyunsaturated fatty acids (18:2 and 20:4) was significantly lower in the HIV-1 seropositive subjects (38 +/- 8.1% SD) as compared to HIV-1 seronegative subjects (43 +/- 4.2%; P = 0.0027). This was also reflected in a higher level of total saturated fatty acids (16:0 and 18:0) in HIV-1 seropositive subjects (30 +/- 2.2% vs. 26 +/- 2.8%; P = 0.0001). The ratio of linoleic to arachidonic acid (18:2 to 20:4) was higher in the HIV-1 seropositive group (6.76 +/- 4.88) compared to the HIV-1 seronegative group (4.86 +/- 1.37; P = 0.0213). The response to PHA in seropositive subjects correlated inversely with total plasma omega 6 fatty acids (r = -0.36; P = 0.027), and directly with the 18:2 to 20:4 ratio (r = 0.33; P = 0.046). CD4 cell counts and the response to PWM did not correlate with plasma fatty acid levels in HIV-1 seropositive subjects.(ABSTRACT TRUNCATED AT 250 WORDS)

Sorption of Arsenic and Cadmium and Their Effects on Growth, Micronutrient Utilization, and Photosynthetic Pigment Composition of Asterionella formosa

By use of continuous-culture techniques, populations of the freshwater diatom Asterionella formosa were exposed to various concentrations of arsenic or cadmium for periods of 6–23 days. Sorption of arsenic (as arsenate) was a linear function of ambient concentrations < 130 μg As∙L−1 but reached an apparent plateau at ambient values > 130 μg As∙L−1. In contrast, cadmium sorption was a complex function of ambient concentration and time. Cellular arsenic and cadmium was desorbed in some of the experiments, and there appeared to be an active regulatory mechanism that kept the cellular arsenic content at a nontoxic level. For arsenic, no detrimental effects on growth or on micronutrient utilization were observed over the range of ambient concentrations used (< 160 μg As∙L−1). For cadmium, however, an ambient concentration of ~2 μg Cd∙L−1 reduced the population growth rate by an order of magnitude, while populations exposed to > 10 μg Cd∙L−1 ceased growth and micronutrient utilization in 20–30 h. Fractionation experiments suggest that a large proportion of the cellular arsenic was associated with the organic layer surrounding the frustule, while most of the cellular cadmium was associated with the cell contents. Key words: arsenic, cadmium, toxicity, sorption, diatom, Asterionella formosa