Zinc deficiency

Zinc deficiency
POOPO
Classification and external resources

TOOTO
ICD-10 E60
ICD-9 269.3
DiseasesDB 14272

Zinc deficiency is insufficient zinc to meet the needs of biological organisms. It can occur in both plants and animals. Zinc deficient soil is soil in which there is insufficient zinc to allow plants to grow normally.

Contents

Humans

Description

Hypozincemia is a condition where insufficient zinc is available for metabolic needs.

Prevalence

In fact, one-third of the world population is at risk of zinc deficiency, ranging from 4 to 73% depending on the country. Zinc deficiency is the fifth leading risk factor for disease in the developing world. Providing micronutrients, including zinc, to humans is one of the four quick-win solutions to major global problems identified in the Copenhagen Consensus from an international panel of distinguished economists.

Conservative estimates suggest that 25% of the world's population is at risk of zinc deficiency.[1]

Causes

Hypozincemia is usually a nutritional deficiency, but can also be associated with malabsorption, diarrhea, acrodermatitis enteropathica, chronic liver disease, chronic renal disease, sickle-cell disease, diabetes, malignancy, and other chronic illnesses.[2][3] It can also occur after bariatric surgery.

Zinc deficiency is typically the result of inadequate dietary intake of zinc, disease states that promote zinc losses, or physiological states that require increased zinc. Populations that consume primarily plant based diets that are low in bioavailable zinc often have zinc deficiencies.[4][5] Diseases or conditions that involve intestinal malabsorption promote zinc losses. Fecal losses of zinc caused by diarrhea are one contributing factor,[6] often common in developing countries. Changes in intestinal tract absorbability and permeability due, in part, to viral, protozoal, and bacteria pathogens may also encourage fecal losses of zinc.[7] Physiological states that require increased zinc include periods of growth in infants and children as well as in mothers during pregnancy.[8]

Signs and symptoms

Signs of zinc deficiency include hair loss, skin lesions, diarrhea, and wasting of body tissues. A lack of zinc can contribute to acne.[9] Eyesight, taste,[10][11][12][13][14] smell and memory are also connected with zinc. A deficiency in zinc can cause malfunctions of these organs and functions. Congenital abnormalities causing zinc deficiency may lead to a disease called acrodermatitis enteropathica.

One easily recognized sign which may be caused by zinc deficiency is white spots, bands, or lines on fingernails (leukonychia). An occasional white spot is usually evidence that the immune system overcame a bacterial or some other systemic infection, and is a positive, not negative sign. Some women may have multiple parallel white bands or lines on the fingernails marking menstrual cycles when marginal zinc deficiency was present.

Anorexia

Zinc deficiency may cause a decrease in appetite which can degenerate into anorexia or anorexia nervosa.[citation needed] Appetite disorders, in turn, cause malnutrition and, notably, inadequate zinc intake. Anorexia itself is a cause of zinc deficiency, thus leading to a vicious cycle: the worsening of anorexia worsens the zinc deficiency. The use of zinc in the treatment of anorexia has been advocated since 1979 by Bakan. At least 15 trials showed that zinc improved weight gain in anorexia. A 1994 randomized, double-blind, placebo-controlled trial showed that zinc (14 mg per day) doubled the rate of body mass increase in the treatment of anorexia nervosa (AN). Deficiency of other nutrients such as tyrosine and tryptophan (precursors of the monoamine neurotransmitters norepinephrine and serotonin, respectively), as well as vitamin B1 (thiamine) could contribute to this phenomenon of malnutrition-induced malnutrition.[15]

Cognitive and motor function impairment

Cognitive and motor function may also be impaired in zinc deficient children. Zinc deficiency can interfere with many organ systems especially when it occurs during a time of rapid growth and development when nutritional needs are high, such as during infancy.[16] In animal studies, rats who were deprived of zinc during early fetal development exhibited increased emotionality, poor memory, and abnormal response to stress which interfered with performance in learning situations.[17] Zinc deprivation in monkeys showed that zinc deficient animals were emotionally less mature, and also had cognitive deficits indicated by their difficulty in retaining previously learned problems and in learning new problems.[17] Human observational studies show weaker results. Low maternal zinc status has been associated with less attention during the neonatal period and worse motor functioning.[18] In some studies, supplementation has been associated with motor development in very low birth weight infants and more vigorous and functional activity in infants and toddlers.[18]

Diarrhea and pneumonia

Zinc deficiency contributes to an increased incidence and severity of diarrhea and pneumonia.[19] Studies have shown that zinc treatment results in a 25 percent reduction in duration of acute diarrhea and a 40 percent reduction in treatment failure or death in persistent diarrhea.[20] The studies determined that a ten-day therapy of zinc treatment can considerably reduce the duration and severity of diarrheal episodes, decrease stool output, and lessen the need for hospitalization. Zinc may also prevent future diarrhea episodes for up to three months. The current World Health Organization recommendation for diarrhea control includes the use of 20 mg per day of zinc supplementation for 10 to 14 days (10 mg per day for infants under the age of six months).[21] A zinc taste test may have potential for diagnosing deficiency.[22]

Dysmenorrhea

High dose of zinc, 30 mg 1-3 times a day, prevents dysmenorrhea.[23]

Pregnancy

Zinc deficiency during pregnancy can negatively affect both the mother and fetus. Animal studies indicate that maternal zinc deficiency can upset both the sequencing and efficiency of the birth process. An increased incidence of difficult and prolonged labor, hemorrhage, uterine dystocia and placental abruption has been documented in zinc deficient animals.[24] These effects may be mediated by the defective functioning of estrogen via the estrogen receptor, which contains a zinc finger protein.[24] A review of pregnancy outcomes in women with acrodermatitis enteropathica, reported that out of every seven pregnancies, there was one abortion and two malfunctions, suggesting the human fetus is also susceptible to the teratogenic effects of severe zinc deficiency. However, a review on zinc supplementation trials during pregnancy did not report a significant effect of zinc supplementation on neonatal survival.[24]

Vitamins A and D

Plasma zinc levels have been found to be dependent upon vitamins A and D. This suggests that a Vitamin A or D deficiency could cause a secondary zinc deficiency and that for treatment of zinc deficiency one should ensure adequate vitamin A and D intake.[25]

Hunger

The influence of zinc on hunger is complex and likely depends upon the status of other nutrients, the developmental stage of the animal, and percentage body fat. Some research groups have argued for a role of zinc deficiency decreasing appetite, while others have shown zinc ingestion can reduce feelings of hunger by increasing leptin levels. There is evidence that the way zinc influences hunger depends on the sodium/osmotic status of the organism, with low sodium/low zinc levels increasing hunger and high sodium/low zinc levels decreasing it. An organism with a low level of zinc has an increased susceptibility to hypoosmotic stress and cell rupture. Thus if the osmotic pressure is too low the organism may be inclined to eat to raise osmolality and prevent osmotic shock. It should be noted that zinc is known to affect osmolality by increasing sodium retention.

In rats, the "first visible sign" of zinc deficiency is a decreased appetite.[26]

Treatment

Zinc supplementation has been shown to reduce diarrhea prevalence and mortality in children younger than 5 years of age.[27]

To combat zinc deficiency, five intervention strategies can be used:

  • Supplementation using medicines
  • Food fortification through the incorporation of zinc additives in food
  • Dietary modification/diversification
  • Genetic biofortification through plant breeding
  • Agronomic biofortification through zinc fertilization.

These five intervention strategies may be used individually or in combination, depending on the setting, target group and degree of zinc deficiency.

The amount of zinc absorbed by the human body is a function of dietary intake of both zinc and phytate (a phosphate storage compound that chelates zinc), because the ratio between these two substances affects the bioavailability of zinc. Meeting the needs for absorbed zinc requires an increase in the zinc content and/or a decrease in the phytate content.

Plants, crops, and soils

Zinc is an essential micronutrient needed not only by people but also by crops. Almost half of the world’s cereal crops are deficient in zinc, leading to poor crop yields.[28] Many agricultural countries around the world are affected by zinc deficiencies. In China, zinc deficiency occurs on around half of the agricultural soils, affecting mainly rice and maize.

In India, zinc-deficient soils occupy almost 50% of the agricultural area and are a critical constraint on yield, but crops are highly responsive to zinc fertilization.

In Turkey, major yield and quality benefits in wheat have been obtained with the widespread use of zinc fertilizers, where half of the cereal growing land is zinc-deficient.

Research has shown that areas with zinc-deficient soils are often regions with widespread zinc deficiency in humans.

A basic knowledge of the dynamics of Zn in soils, understanding of the uptake and transport of Zn in plant systems and characterizing the response of plants to Zn deficiency are essential steps in achieving sustainable solutions to the problem of Zn deficiency in plants and humans (Zinc in soils and crop nutrition), International Fertilizer Industry Association (IFA)and International Zinc Association (IZA).)

Fertilization

Experiments show that soil and foliar application of zinc fertilizer can effectively reduce the phytate:zinc ratio in grain.[29] People who eat bread prepared from zinc enriched wheat show a significant increase in serum zinc, suggesting that the zinc fertilizer strategy may be a viable commercial approach to address zinc deficiencies in humans.

Where zinc deficiency is a limiting factor, zinc fertilization can increase crop yields. Balanced crop nutrition supplying all essential nutrients, including zinc, is a cost effective management strategy. Even with zinc-efficient varieties, zinc fertilizers are needed when the available zinc in the topsoil becomes depleted.

Plant breeding, including modern biotechnology, can improve:

Zinc uptake capacity of plants under soil conditions with low chemical availability of zinc; Zinc translocation, thus elevating zinc content in edible crop parts rather than the rest of the plant; Zinc bioavailability. For optimal efficiency, zinc-efficient genotypes should be associated with complementary soil crop management (including fertilization) to ensure adequate zinc uptake by roots and thus enhance zinc nutrition of crops and humans

Turkey

Central Anatolia, in Turkey, was a region with zinc-deficient soils and widespread zinc deficiency in humans. In 1993, a research project found that yields could be increased by 6 to 8-fold and children nutrition dramatically increased through zinc fertilization.[30]

Through a partnership with Cukurova University, the State and the private company TOROS Agri Industry Group, zinc was added to fertilizers. While the product was initially made available at the same cost, the results were so convincing that Turkish farmers significantly increased the use of the zinc-fortified fertilizer (1 per cent of zinc) within a few short years, despite the repricing of the products to reflect the added value of the content.

Today, nearly 10 years after the identification of the zinc deficiency problem, the total amount of zinc-containing compound fertilizers produced and applied in Turkey reached a record level of 300,000 tonnes per annum. It is estimated that the economic benefits associated with the application of Zn-fertilizers on Zn deficient soils in Turkey is around US$ 100 million per year. Zinc deficiency in children has been dramatically reduced.

Such a policy could be easily replicated around the world in the many zinc-deficient countries.

References

  1. ^ Maret W, Sandstead HH (2006). "Zinc requirements and the risks and benefits of zinc supplementation". J Trace Elem Med Biol 20 (1): 3–18. doi:10.1016/j.jtemb.2006.01.006. PMID 16632171. 
  2. ^ 886046736 at GPnotebook
  3. ^ Prasad AS (2003). "Zinc deficiency : Has been known of for 40 years but ignored by global health organisations". BMJ 326 (7386): 409–10. doi:10.1136/bmj.326.7386.409. PMC 1125304. PMID 12595353. http://www.bmj.com/cgi/content/full/326/7386/409. 
  4. ^ Solomons, N.W. (2001) Dietary Sources of zinc and factors affecting its bioavailability. Food Nutr. Bull. 22: 138-154
  5. ^ Sandstead HH (1991). "Zinc deficiency. A public health problem?". Am. J. Dis. Child. 145 (8): 853–9. PMID 1858720. 
  6. ^ Castillo-Duran C, Vial P, Uauy R (1988). "Trace mineral balance during acute diarrhea in infants". J. Pediatr. 113 (3): 452–7. doi:10.1016/S0022-3476(88)80627-9. PMID 3411389. 
  7. ^ Manary MJ, Hotz C, Krebs NF et al. (2000). "Dietary phytate reduction improves zinc absorption in Malawian children recovering from tuberculosis but not in well children". J. Nutr. 130 (12): 2959–64. PMID 11110854. http://jn.nutrition.org/cgi/pmidlookup?view=long&pmid=11110854. 
  8. ^ Gibson RS (2006). "Zinc: the missing link in combating micronutrient malnutrition in developing countries". Proc Nutr Soc 65 (1): 51–60. doi:10.1079/PNS2005474. PMID 16441944. http://journals.cambridge.org/abstract_S0029665106000073. 
  9. ^ Gerd Michaelsson (1981). "Diet and Acne". Nutrition Reviews 39 (2): 104–106. doi:10.1111/j.1753-4887.1981.tb06740.x. PMID 6451820. 
  10. ^ Ikeda M, Ikui A, Komiyama A, Kobayashi D, Tanaka M (2008). "Causative factors of taste disorders in the elderly, and therapeutic effects of zinc". J Laryngol Otol 122 (2): 155–60. doi:10.1017/S0022215107008833. PMID 17592661. 
  11. ^ Stewart-Knox BJ, Simpson EE, Parr H et al. (2008). "Taste acuity in response to zinc supplementation in older Europeans". Br. J. Nutr. 99 (1): 129–36. doi:10.1017/S0007114507781485. PMID 17651517. 
  12. ^ Stewart-Knox BJ, Simpson EE, Parr H et al. (2005). "Zinc status and taste acuity in older Europeans: the ZENITH study". Eur J Clin Nutr 59 Suppl 2: S31–6. doi:10.1038/sj.ejcn.1602295. PMID 16254578. 
  13. ^ McDaid O, Stewart-Knox B, Parr H, Simpson E (2007). "Dietary zinc intake and sex differences in taste acuity in healthy young adults". J Hum Nutr Diet 20 (2): 103–10. doi:10.1111/j.1365-277X.2007.00756.x. PMID 17374022. 
  14. ^ Nin T, Umemoto M, Miuchi S, Negoro A, Sakagami M (2006). "[Treatment outcome in patients with taste disturbance]" (in Japanese). Nippon Jibiinkoka Gakkai Kaiho 109 (5): 440–6. doi:10.3950/jibiinkoka.109.440. PMID 16768159. 
  15. ^ "Neurobiology of Zinc-Influenced Eating Behavior". http://jn.nutrition.org/cgi/content/full/130/5/1493S. Retrieved 2007-07-19. 
  16. ^ Sanstead, H. H. et al., (2000) Zinc nutriture as related to brain. J. Nutr. 130: 140S-146S
  17. ^ a b Black MM (2003). "The Evidence Linking Zinc Deficiency with Children's Cognitive and Motor Functioning,". J. Nutr. 133 (5 Suppl 1): 1473S–6S. PMC 3137935. PMID 12730446. http://jn.nutrition.org/cgi/pmidlookup?view=long&pmid=12730446. 
  18. ^ a b Black MM (1998). "Zinc deficiency and child development". Am. J. Clin. Nutr. 68 (2 Suppl): 464S–9S. PMC 3137936. PMID 9701161. http://www.ajcn.org/cgi/pmidlookup?view=long&pmid=9701161. 
  19. ^ Penny M. Zinc Protects: The Role of Zinc in Child Health. 2004.
  20. ^ Bhutta ZA, Bird SM, Black RE et al. (2000). "Therapeutic effects of oral zinc in acute and persistent diarrhea in children in developing countries: pooled analysis of randomized controlled trials". Am. J. Clin. Nutr. 72 (6): 1516–22. PMID 11101480. http://www.ajcn.org/cgi/pmidlookup?view=long&pmid=11101480. 
  21. ^ World Health Organization. Implementing the New Recommendations on the Clinical Management of Diarrhoea: Guidelines for Policy Makers and Programme Managers. 2006.
  22. ^ Garg HK, Singal KC, Arshad Z (October 1993). "Zinc taste test in pregnant women and its correlation with serum zinc level". Indian J. Physiol. Pharmacol. 37 (4): 318–22. PMID 8112809. 
  23. ^ Eby GA (2007). "Zinc treatment prevents dysmenorrhea". Med. Hypotheses 69 (2): 297–301. doi:10.1016/j.mehy.2006.12.009. PMID 17289285. 
  24. ^ a b c Shah D, Sachdev HP (2006). "Zinc deficiency in pregnancy and fetal outcome". Nutr. Rev. 64 (1): 15–30. doi:10.1111/j.1753-4887.2006.tb00169.x. PMID 16491666. http://openurl.ingenta.com/content/nlm?genre=article&issn=0029-6643&volume=64&issue=1&spage=15&aulast=Shah. 
  25. ^ Potocnik FC, van Rensburg SJ, Hon D, Emsley RA, Moodie IM, Erasmus RT (2006). "Oral zinc augmentation with vitamins A and D increases plasma zinc concentration: implications for burden of disease". Metab Brain Dis. Pages=139-147 21 (2–3): 139–47. doi:10.1007/s11011-006-9023-4. PMID 17171460. 
  26. ^ Shay NF, Mangian HF. (2000). Neurobiology of Zinc-Influenced Eating Behavior.
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  28. ^ Effect of zinc fertilization on rice plants and on the population of the rice-root nematodeHirschmanniella oryzae Journal of Pest Science
  29. ^ Effect of Foliar Application of Zinc, Selenium, and Iron Fertilizers on Nutrients Concentration and Yield of Rice Grain in China Journal of Agriculture and Food Chemistry, 2008
  30. ^ Enrichment of cereal grains with zinc: Agronomic or genetic biofortification? Cakmak Ismail, in Plant and Soil, 2007

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