FATTY ACIDS AND MINERAL CONTENTS ANALYSIS OF SELECTED FINFISHES - Sardinella longiceps AND Scomberomorus guttatus

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Published: 2022-12-31

DOI: 10.56557/upjoz/2022/v43i243365

Page: 569-575


ELANGOVAN GOVINDARAJAN

Department of Zoology, A. V. V. M. Sri Pushpam College (An Autonomous Institution Affiliated to Bharathidasan University), Poondi, Thanjavur-613503, Tamil Nadu, India.

GANESAN SIVAMANI

Department of Zoology, A. V. V. M. Sri Pushpam College (An Autonomous Institution Affiliated to Bharathidasan University), Poondi, Thanjavur-613503, Tamil Nadu, India.

ARJUN PANDIAN

Department of Research and Innovation, Institute of Biotechnology, Saveetha School of Engineering (SSE), Saveetha Institute of Medical and Technical Sciences (SIMATS), Thandalam, Chennai – 602105, Tamil Nadu, India.

RAMASAMY MARIAPPAN *

Department of Zoology, A. V. V. M. Sri Pushpam College (An Autonomous Institution Affiliated to Bharathidasan University), Poondi, Thanjavur-613503, Tamil Nadu, India.

*Author to whom correspondence should be addressed.


Abstract

The marine fishes are extremely contributes to the delivery of fatty acids, macro and micro nutrients in normal food diet, finfishes Sardinella longiceps and Scomberomorus guttatus selected for fatty acids types and minerals composition of S. longiceps, S. guttatus skin muscles were analyzed. The fatty acid composition showed quantitative differences in the percentages of individual acids between the species. Total fatty acids included 41.29% of SFA in S. longicepts, followed by 36.83% in S. guttatus, MUFA content of fatty acids were showed 33.23% in S. guttatus followed by 22.53% in S. longiceps, PUFA fatty acids was high in S. longicepts 36.35%, followed by S. guttatus 28.43%. The minerals (macro, micro and trace mineral) content was estimated, highest amount of sodium content was estimated 432 mg/100 g dry weight basis in S. guttatus followed by in S. longiceps 323 mg/100 g, elevated amount of potassium content from 1251 mg/100 g in S. guttatus followed by in S. longiceps 639 mg/100 g, calcium level uppermost in S. longiceps noticed 269 mg/100 g followed by 167 mg/100 g. Concluded fatty acids, minerals are involved for growth and developments of living beings.

Keywords: Arachidonic acid, calcium, elevated, linolenic acid, Sardinella longiceps, Scomberomorus guttatus


How to Cite

GOVINDARAJAN, E., SIVAMANI, G., PANDIAN, A., & MARIAPPAN, R. (2022). FATTY ACIDS AND MINERAL CONTENTS ANALYSIS OF SELECTED FINFISHES - Sardinella longiceps AND Scomberomorus guttatus. UTTAR PRADESH JOURNAL OF ZOOLOGY, 43(24), 569–575. https://doi.org/10.56557/upjoz/2022/v43i243365

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References

Hancock B, Zu Ermgassen P. Enhanced production of finfish and large crustaceans by bivalve reefs. In: Smaal A, Ferreira J, Grant J, Petersen J, Strand Ø, editors. Goods and services of marine bivalves. Cham: Springer. 2019;295-312.

Arjun P, Semwal D, Badoni Semwal R, Prasad Mishra S, Blessy Vijayan A, Krishnamoorthy M. Quality retention and shelf-life improvement of fresh-cut apple, papaya, carrot and cucumber by chitosan-soy based edible coating. Curr Nutr Food Sci. 2015;11(4): 282-91.

Guizani Salma O, Nizar EM. Atlantic mackerel amino acids and mineral contents from the Tunisian Middle Eastern coast. Int J Agric Pol Res. 2015;3(2):77-83.

Njinkoue JM, Gouado I, Tchoumbougnang F, Ngueguim JHY, Ndinteh DT, Fomogne-Fodjo CY et al. Proximate composition, mineral content and fatty acid profile of two marine fishes from Cameroonian coast: Pseudotolithus typus (Bleeker, 1863) and Pseudotolithus elongatus (Bowdich, 1825). NFS J. 2016;4:27-31.

Sundt-Hansen L, Huisman J, Skoglund H, Hindar K. Farmed Atlantic salmon Salmo salar L. parr may reduce early survival of wild fish. J Fish Biol. 2015;86(6):1699-712.

Arjun P, Semwal DK, Semwal RB, Malaisamy M, Sivaraj C, Vijayakumar S. Total phenolic Content, Volatile Constituents and antioxidative Effect of Coriandrum sativum, Murraya koenigii and Mentha arvensis. Nat Prod J. 2017;7(1):65-74.

Atalah J, Sanchez-Jerez P. Global assessment of ecological risks associated with farmed fish escapes. Glob Ecol Conserv. 2020;21:e00842.

Shaji SA, Hindumathy CK. Chemical composition and amino acid profile of Sardinella longiceps collected from Western coastal areas of Kerala, India. J Biol Earth Sci. 2013;3(1); (B1 29–B1 34).

Ashokkumar K, Jesus Simal G, Murugan M, Dhanya MK, Arjun P. Nutmeg (Myristica fragrans Houtt.) essential oil: a review on its composition, biological and pharmacological activities. Phytother Res. 2022:1-13.

Aidos I, van der Padt AVD, Luten JB, Boom RM. Seasonal changes in crude and lipid composition of herring fillets, byproducts and respective produced oils. J Agric Food Chem. 2002;50(16):4589-99.

Gökçe MA, Taşbozan O, Çelik M, Tabakoğlu ŞS. Seasonal variations in proximate and fatty acid compositions of female common sole (Solea solea). Food Chem. 2004;88(3): 419-23.

Dasari Venkateswarlu AP, Samiraj R. Detection of β-lactamase in Clinical samples of Prakasam District, Andhra Pradesh. Res J Pharm Technol. 2021;14(6):2995-8.

Tarley CRT, Visentainer JV, Matsushita M, de Souza NE. Proximate composition, cholesterol and fatty acid profile of canned sardines (Sardinella brasiliensis) in soybean oil and tomato sauce. Food Chem. 2004;88(1):1-6.

Suseela M, Ammu K, Nair PGV, Devadasan K. Seasonal variations in cholesterol content of different species of prawn. Fish Technol. 2005;42(2):171-6.

Hariprasath L, Jegadeesh R, Arjun P, Raaman N. In vitro propagation of Senecio candicans DC and comparative antioxidant properties of aqueous extracts of the in vivo plant and in vitro derived callus. S Afr J Bot. 2015;98: 134-41.

Bittolo-Bon G, Cazzolato G, Alessandrini P, Soldan S, Casalino G, Avogaro P. Effects of concentrated DHA and EPA supplementation on LDL peroxidation and vitamin E status in type IIb hyperlipidemic patients. In: Drevon CA, Baksaas I, Krokan HE, editors. Omega-3 fatty acids: metabolism and biological effects. Basel Switzerland, verlag Birkheuser. 1993; 51-8.

Mikayoulou M, Mayr F, Temml V, Pandian A, Vermaak I, Chen W et al. Anti-tyrosinase activity of South African Aloe species and isolated compounds plicataloside and aloesin. Fitoterapia. 2021;150(10):104828.

Alasalvar C, Taylor KDA, Zubcov E, Shahidi F, Alexis M. Differentiation of cultured and wild sea bass (Dicentrarchus labrax): total lipid content, fatty acid and trace mineral composition. Food Chem. 2002;79(2): 145-50.

Nair PGV, Mathew S. Biochemical composition of fish and shellfish. Cent Inst Fish Technol Technol Advisory S, Cochin, India. 2000:1-14.

Duran A, Tuzen M, Soylak M. Trace element concentrations of some pet foods commercially available in Turkey. Food Chem Toxicol. 2010;48(10):2833-7.

Elangovan G, Ganesan S, Ramakrishnan V, Arjun P. Peroximate composition and different types of amino acids analysis of economically important finfishes – Sardinella fimbriata, Scomberomorus guttatus in Nagapattinam Coast, Tamil Nadu, India. Int J Health Sci. 2022;6;Suppl 5.

Vasanthakumar S, Sasikala P, Padma M, Balachandar V, Venkatesh B, Ganesan S. EpCAM as a Novel Therapeutic target for Hepatocellular carcinoma. Journal of Oncological Sciences. 2017;3(2):71-76.

Kanimozhi C, Ganesan S, Gokila G, Manimegalai R. In vitro evaluation of Cytotoxicity, Anti- Inflammatory and Wound healing properties of Otolith Stones from Pomadasys maculates. Journal of Materials Science, A Springer Nature Publication. 2022;57:11899-910.

Nagarajan S, Das TM, Arjun P, Raaman N. Design, synthesis and gelatin studies of 4,6-O-butylidene- α,β-unsaturated-β-C-glycosidic ketones: application to plant tissue culture. J Mater Chem. 2009;26:4587-96.

AOAC. Official methods of analysis. 16th ed. Washington, DC: Association of Official Analytical Chemists; 1995.

Anthony JE, Hadgis PN, Milam RS, Herzfeld GA, Taper LJ, Ritchey SJ. Yields, proximate composition and mineral content of finfish and shellfish. J Food Sci. 1983;48(1):313-4.

AOAC. Official methods of analysis. Washington, DC: Association Of Official Analytical Chemists; 2000.Begum A. Begum A, Amin MN, Kaneco S, Ohta K. Selected elemental composition of the muscle tissue of three species of fish, Tilapia nilotica, Cirrhina mrigala and Clarius batrachus, from the fresh water Dhanmondi Lake in Bangladesh. Food Chem. 2005;93(3):439-43.

Ali D, Alarifi S, Pandian A. Somatic embryogenesis and in vitro plant regeneration of Bacopa monnieri (Linn.) Wettst., a potential medicinal water hyssop plant. Saudi J Biol Sci. 2021;28(1):353-9.

Shirai N, Suzuki H, Tokairin S, Ehara H, Wada S. Dietary and seasonal effects on the dorsal meat lipid composition of Japanese (Silurus asotus) and Thai catfish (Clarias macrocephalus and hybrid Clarias macrocephalus and Clarias galipinus). Comp. Biochem Physiol. 2002b;132:609-19.

Prasannan P, Jeyaram Y, Pandian A, Raju R, Sekar S. A review on taxonomy, phytochemistry, pharmacology, threats and conservation of Elaeocarpus L. (Elaeocarpaceae). Bot Rev. 2020;86(3-4):298-328.

Chandrasekhar K, Deosthale YG. Fat and fatty acid composition of edible muscle of indianfish. In: Devadasan K, Mukundan MK, Antony PD, Nair PGV, Perigreen PA, Joseph J, editors. Cochin: Paico Printing Press. 1994; 195-201.

Luzia LA, Sampio GR, Castellucci CMN, Torres EAFS. The influence of season on the lipid profiles of five commercially important species of Brazilian fish. Food Chem. 2003;83(1):93-7.

Krajnovic-Ozretic M, Najdek M, Ozretic B. Fatty acids in liver and muscle of farmed and wild sea bass (Dicentrarchus labrax L.). Comp. Biochem Physiol. 1994;109A:611-7.

Maskara S, Naomichi K. Proximate composition, fatty acid contents, mineral content and hardness of muscle from wild and cultured puffer fish Takifugu rubripes. Nippon Suisan Gakkaishi. 1998;64(1):116-20.

Tian X, Qin JG. A single phase of food deprivation provoked compensatory growth in barramundi Lates calcarifer. Aquaculture. 2003;224(1-4):169-79.

Kozlova TA, Khotimchenko SV. Lipids and fatty acids of two pelagic cottoid fishes (Comephorus spp.) endemic to Lake Baikal. Comp. Biochem Physiol. 2000;126B:477-85.

Njinkoue JM, Gouado I, Tchoumbougnang F, Ngueguim JHY, Ndinteh DT, Fomogne-Fodjo CY et al. Proximate composition, mineral content and fatty acid profile of two marine fishes from Cameroonian coast: Pseudotolithus typus (Bleeker, 1863) and Pseudotolithus elongatus (Bowdich, 1825). NFS J. 2016;4: 27-31.

Vinothini K, Sri Devi M, Shalini V, Sekar S, Semwal RB, Arjun P et al.. In vitro Micropropagation, Total Phenolic Content and Comparative Antioxidant Activity of Different Extracts of Sesbania grandiflora (L.) Pers. Curr Sci. 2017;113(6):1142-7.

Ashokkumar K, Arjun P, Murugan M, Dhanya MK, Sathyan T, Sivakumar P et al. Profiling bioactive flavonoids and carotenoids in select south Indian spices and nuts. Nat Prod Res (Formerly Nat Prod Lett). 2019:1-5.

Thavaselvi P, Vimala C, Bharathiraja C, Bharatiraja C, Priya PA, Arjun P. Signal, digital and image processing application in different fields. Int J Control Theor Appl. 2016;9(14):6653-7.

Devi MS, Vinothini K, Arjun P, Sekar S, Mavumengwana V. In vitro biomass accumulation of calli and root enhancement of Leucas aspera (Willed) Linn. under stress conditions. Afr J Sci Technol Innov Dev. 2015;7(6):395-400.

Gokulakrishnan K, Velmurugan K, Ganesan S, Mohan V. Circulating levels of insulin-like growth factor binding protein-1 in relation to insulin resistance, type 2 diabetes mellitus, and metabolic syndrome (CURES – 118). Metabolism. 2012;61(1):43-6.

Karthika M, Balu AR, Ganesan S, Suganya M. A comparative study on the photocatalytic, electrochemical impedance, third order nonlinear optical and antibacterial properties of marine brown alga Spatoglossum asperum J. Agardh mediated green synthesized CuS:Co and CuS:Ni nanoparticles. Springer [journal]. 2022’s Editorial Office Brazilian Journal of Physics.

Nithyakalyani M, Reddy H, Raghavan S, Sunder A, Sivamani G, Veerabathiran R. Isolation of Human Pancreatic Islets from the Indian Population – Unveiling the Synergistic Interplay between different blends of collagenases and Neutral proteases. Cardiometry Issue. 2022;24(v):243-51.

Andrew S, Chelladurai G, Subramaniyan V, Arjun P, Ganesan S. Anti- diabetic potential of Spatoglossum asperum (Brown seaweed); in silico model. Uttar Pradesh J Zool. 2022;43(19):48-57.

Andrew S, Arjun P, Ramakrishnan V, Ramasamy M, Chelladurai G, Ganesan S. Antidiabetic effects of marine brown algae Spatoglossum asperum J. Ag. ethanolic extract on 3T3-L1 pre-adipocytes activity an in vitro approach. Int J Health Sci. 2022;6;Suppl 4:11828-47.

Indumathi A, Faritha Begam H, Ganesan S, Arjun P. Composition of peroximate and types of amino acids analysis of cost-effectively essential finfishes – Lutjanus argentimaculatus, Epinephelus malabaricus Nagapattinam Coast of Tamil Nadu, South India. Int J Health Sci. 2022;6;Suppl 5:10655-68.

Elagovan G, Ganesan S, Arjun P, Ramakrishnan V, Ramasamy M. Peroximate composition and different types of amino acids analysis of economically important finfishes – Sardinella fimbriata, Scomberomorus guttatus in Nagapattinam Coast, Tamil Nadu, India. Int J Health Sci. 2022;6;Suppl 5: 10642-54.