Thursday, September 5, 2019
Mineral Resource in Ecofriendly Invertebrate Powder
Mineral Resource in Ecofriendly Invertebrate Powder A SEARCH OF BIO MACRO AND MICRO MINERAL RESOURCE IN ECOFRIENDLY INVERTEBRATE POWDER: Eudrilus eugeniae J. Anitha, R. Selvakumarà and Indira A. Jayraaj Abstract Quantification of macro and micro nutrients from earthworm (Eudrilus eugeniae) was aimed and successfully elucidated in the present study. Macro minerals like calcium, magnesium, phosphorous, potassium, nitrogen and sodium and micro or trace elements like iron, selenium, zinc, copper, sulphur, Nickel, Chromium and molybdenum was assayed using colorimeter, Micro-Kjeldahl method, flame photometer, EDTA Titrimetric method and specifically atomic absorption spectrophotometer (AAS). From the study, it is evident that the earthworm powder of E. eugeniae is a rich source of macrominerals (Calcium and Magnesium) and trace elements (Iron and selenium) together with notable quantities of other important elements, indicating that this earthworm contain potentially useful quantities of many nutrients that are critical to the health of the humans and animals who consume them. Keywords: AAS, Earthworm powder, Eudrilus eugeniae, Metals, Macro minerals. Introduction Metals are nutrients in soil are absorbed by plants, transferred to animals and men by food chains, and finally return to the soil. Earthworms are found virtually worldwide and live in almost any type of soil that contains the right amounts of moisture and organic particles and of various sizes and colors [1]. It has dense nutritional content because of their soil based origin [2]. The earthworm is a widely used Chinese herbal medicine [3]. Although Wallace [4;5] reported more than 100 years ago the inclusion of earthworms in diets of Amerindian tribal) populations little is known about the nutritive value of those edible invertebrates [6]. Extracting medicinal compounds from the earthworm has traditionally been practiced by indigenous people throughout the world, more particularly in Asia [7]. Previous earthworm studies have shown its antimicrobial [3] hepatoprotective [4], anticancer [8] and scar wound healing characteristics [9]. The anti-inflammatory activity together with antiox idant properties seems to be due to the high polyphenolic content in earthworm tissue [10]. Moreover, crude earthworm extract has a thrombolytic effect that could significantly promote blood circulation to remove stasis [11]. Minerals are the nutrients that exist in the body, and are as essential as our need for oxygen to sustain life. Minerals are also found in organic and inorganic combinations in food. It plays a vital role for all mental and physical processes including for total well being. They are most important factors in maintaining all physiological processes, are constituents of the teeth, bones, tissues, blood, muscle, and nerve cells [12]. Therefore, since the drive of animal farmers worldwide is to source for cheaper means of nutritive dietary supplement which may replace fishmeal wholly or partly in animal diet and also supply micro and macro-nutrients [13]. Considering the above facts the present study was aimed to quantify macro and micro or trace mineral profile of earthworm species Eudrilus eugeniae. Materials and methods Collection of earthworm The earthworm Eudrilus eugeniae was collected from Aarthi farms, Kondegoundanpalayam village, Pollachi Taluk, Coimbatore District, Tamil Nadu, India. The collected species were cultured under optimal conditions in compost yard at Kongunadu Arts and Science College Premises, Coimbatore 641 029, Tamil Nadu, India, for further use. Processing of earthworm The earthworms were washed with running tap water to remove any dirt from body surface. The earthworms were kept in 0.5% NaCl at room temperature for 1-2h with few changes of solution until their digestive systems were clean. Cleaned earthworms are taken and dried at 65-800C in forced draught, stainless-steel lined ovens. Ground the samples completely to a particle size of less than 1mm, and mixed thoroughly before a sub sample of suitable size is stored for analysis. Store the samples in a clearly labelled, airtight, glass or polycarbonate containers to prevent samples from contamination. Storage at room temperature is sufficient, but long term storage of reference material requires freezing. Re-dry the samples at 650C for 12 hours prior to weighing for heavy metal analysis. Digestion of earthworm Weigh 0.5 1 g sample accurately into acid washed 250 ml digest tubes. Add 6 10 ml concentrated HNO3, swirl to mix sample and acid. Place tubes onto a Tecator 40 system, or similar set at 1000C for 2 hours. Reduce the total volume to 1 ml. The sample solution becomes thick slurry. Remove samples from digestion block; allow cooling and diluting to 10 or 20 ml with deionized water. Allow samples to settle (minimum 2 hours, preferably overnight), and filter through Whatman No. 40 filter paper or centrifuge at 6000 rpm for 15 minutes. Run at least two digest blanks with samples. The schematic representation of analytical procedure of minerals is given in figure1. Figure 1. Schematic diagram of the micro and macro nutrient analytical procedure Method of mineral analysis The processed earthworm powder was subjected to quantification of macro minerals (calcium, magnesium, phosphorous, potassium, nitrogen and sodium) and micro or trace elements (iron, selenium, zinc, copper, sulphur, nickel, chromium and molybdenum) using the methods of Jackson [14] for spectrophotometer (Perkin elmer Lamada EZ201), flame photometer (Cole-Parmer, 500731), EDTA Titrimetric and specifically atomic absorption spectrophotometer (Hitachi Z9000) [15;16]. Results The selected earthworm species, E. eugeniae was successfully converted into powdered and subjected to mineral analysis in that six macro minerals namely calcium, magnesium, nitrogen, phosphorus, potassium, and sodium and eight trace elements like iron selenium, zinc, copper, sulphur, nickel, chromium and molybdenum was noticed and are depicted in table 1 and 2. Table 1: Macrominerals content in EWP (E. eugeniae) Table 2: Microminerals or trace elements content in EWP (E. eugeniae) The trend observed in macrominerals of E. eugeniae contained a higher concentration of calcium (0.75%) which is followed by magnesium (0.66%), phosphorous (0.36%), potassium (0.33%), nitrogen (0.29%) and sodium (0.19%) respectively. Among the trace elements, iron (1.73%) was found to be maximum followed by selenium (0.96%). Apart from these two micro elements the traces of zinc (0.50%), copper (0.43%), sulphur (0.22%), nickel (0.14%), chromium (0.10%) and molybdenum (0.02%) was also noticed. Discussion Now a dayââ¬â¢s importance of minerals is clinical known and these minerals are inorganic chemical elements not attached to a carbon atom.There is a distinction between minerals and trace minerals. If the body requires more than 100 milligrams then that substance is labelled as a mineral. If the cellular body requires less than this, it is labelled a trace mineral. Trace minerals are generally needed in quantities of only a few milligrams (mg) or micrograms (à µg) per day. The higher content of calcium in E. eugenia suggests that this species of earthworm probably has a higher capacity of storage of calcium in its tissues as suggested by the presence of calcium gland in it [17]. The earthworms also contain nutritionally significant amounts of calcium, which would be important for pregnant or lactating women, young children at risk of calcium-deficiency rickets and postmenopausal women in whom there might be concern about osteoporosis and fractures [6]. Earthworms require these minerals for their day to day physiological activities. It may be because they have to burrow or swallow their way through hard packed soil. For in order to perform these various physiological bioactivities, the earthworm must maintain a constant firing (electrical potential) of the nerve and muscle cells and needed for this is the higher calcium and magnesium concentration. Calcium and magnesium have been shown to be involved in regulating nervous excitability and muscular contraction i.e. maintaining the electrical potential in nerve and muscle cells [18]. Nitrogen occurs in all organisms, primarily in amino acids (and thus proteins) and also in the nucleic acids (DNA and RNA). The human body contains about 3% by weight of nitrogen, the fourth most abundant element in the body after oxygen, carbon, and hydrogen [19]. Phosphorous works with calcium to develop and maintain strong bones, teeth and enhances use of other nutrients. It plays a key role in cell membrane integrity, intercellular communication and for proper energy processing in the body. Potassium is important in DNA and protein synthesis, Apart from this potassium is important in cell volume regulation [20]. Sodium in EWP of E. eugeniae was found to be 0.19 ppm. Sodium is the major cation of the extracellular fluid which in conjunction with potassium forms the Na+-K+ pump which effectively maintains Na+ as an impairment extracellular solute [21]. Paloetti et al. [6] reported that all of the earthworm (kuru and motto) preparations were excellent sources of iron, having iron contents that ranged from 1050 à µg-1 in kuruââ¬â¢s meat to 2990 à µg-1 in mottoââ¬â¢s meat. They compared the iron contents of these two earthworm preparations with those of some other meats. This means that, assuming good bioavailability of the iron in the earthworms, they could be a useful food source to mitigate the risk of iron-deficiency anaemia. Selenium is essential component of teeth, key antioxidant enzyme and necessary for normal growth and development. It has a function in detoxification of heavy metals such as mercury and plays an important role in the production of antibodies by the immune system. Zinc is an important antioxidant, which records 0.5% in the present study. It plays an essential part of more than 200 enzymes involved in digestion, metabolism, immune response and wound healing. Copper is an essential element for the formation of normal red blood cell and connective tissue formation. It acts as a catalyst to store and release iron to help form haemoglobin and also contributes to central nervous system function. Sulfur is involved in the formation of structural protein, including muscles and hair. It also severs critical role in liver detoxification. Its important function is to act as an antioxidant nutrient and oxygen handling role in growth. Nickel is found in all animal tissues and the highest concentration was noticed in nucleic acids, particularly RNA, and is involved in protein structure or function. It may activate certain enzymes related to the breakdown or utilization of glucose [22]. Chromium helps in glucose metabolism and aids to regulate blood sugar by potentiating insulin and serving as a component of glucose tolerance factor. Molybdenum contributes to normal growth and development. It is a key component in many enzyme systems involved in detoxification. In conclusion, the minerals in earthworm powder obtained from E. eugenaie are capable of satisfying a significant fraction in daily requirements of minerals which plays a significant role in human nutrition without any adverse side effects. References Ogbulie JN, Uwazuoke JC, Ogieho SI. Introductory Microbiology Practical. Springfield Publishers Nigeria. 1998; 70-120. Ansari AA, Sitaram K. An investigation into antimicrobial and antifungal properties of earthworm powder obtained from Eisenia fetida. American Journal of Food Technology 2011;6(4): 329-335. Balamurugan M, Parthasarathi K, Ranganathan LS, Cooper EL. Hypothetical mode of action of earthworm extract with hepatoprotective and antioxidant properties. Journal of Zhejiang University- Science B 2008;9(2):141ââ¬â147. Cooper EL. CAM eCAM, bioprospecting: The 21st century pyramid. Evidence-Based Complementary and Alternative Medicine 2005;2(2):125ââ¬â127. Wallace AR. On the insects used for food in the Indians of the Amazon. R. Entomol. Soc. Lond. 1853;2:241ââ¬â244. Wallace AR. A narrative of travels on the Amazon and Rio Negro. New York: Dover Publications Inc. 1889. Paoletti MG, Buscardo DJ, Vander Jagt A, Pastuszyn Pizzoferrato L, Huang YS, Chuang LTM, Millson H, Cerda Torres F, Glew RH. Proceedings: The Royal Society of Biological Sciences, London. 2011;249-257. Ranganathan LS. Vermibiotechnology ââ¬â from soil health to human health. Agrobios. 2006. Cooper EL, Ru B, Weng N. Earthworms: sources of antimicrobial and anticancer molecules. Advances in Experimental Medicine and Biology 2004;546: 359ââ¬â389. Zhang M, Li X, Liu Y, Ye F, Qiu G. Effects of extract of Dilong (Pheretima) on the scalded skin in rats. Journal of Traditional Chinese Medicine 2006;26(1): 68ââ¬â71. Cooper EL, Balamurugan M, Parthasarathi K, Ranganathan LS. Earthworm paste (Lampito mauritii, Kinberg) alters inflammatory, oxidative, haematological and serum biochemical indices of inflamed rat. European Review for Medical and Pharmacological Sciences 2007;11(2): 77ââ¬â 90. Zhang ZX, Wang FF. Effects of crude extract of earthworm on promoting blood circulation to removing stasis. Zhongguo Zhong Xi Yi Jie He Za Zhi 1992;12(12): 741ââ¬â710. Alvarez S. The Magnesium: Importance of Minerals and Trace Minerals in Human Nutrition. 2002;Pp 22. Dedeke GA, Owa SO, Olurin KB. Amino acid profile of four earthworms species from Nigeria. Agric. Biol. J. N. Am 2010;1(2): 97-102. Jackson ML. Soil chemical analysis. Prentice hall. Indian private limited. India.1973;498-516. AOAC. Association of Official Analytical Chemists. Official Methods of Analysis (20th Ed.) USA. 1995. Lindsay WL, Norvell WA. Development of a DTPA soil test for zinc, iron, manganese, and copper. Soil Sci. Soc. Amer. J 1978;42: 421-428. Owa SO. Taxonomy and Distribution of Nigerian earthworms of the family Eudrilidae and their use as possible indicators of soil properties. Ph.D thesis Obafemi Awolowo University, Ile-Ife Nigeria. 1992. Ganong WF. A review of Medical Physiology (7th Ed). Prentice Hall New Jersey USA. 1995. Murray R, Harry K. Nitrogen Purfication: Pilot Plant Removal of Oxygen. Industrial and Engineering Chemistry 1957;49(5): 869ââ¬â873. Bray JJ, Cragg PA, Maknight ADC, Mills RG. Lecture notes on human physiology, Blackwell science Ltd, UK. 1999;542. Maier RJ, Stephane L, Benoit, Seshadri S. Nickel-binding and accessory proteins facilitating Ni-enzyme maturation in Helicobacter pylori. Biometals 2007;20(3-4): 655ââ¬â664.
Subscribe to:
Post Comments (Atom)
No comments:
Post a Comment
Note: Only a member of this blog may post a comment.