@Research Paper
<#LINE#>Effect of temperature on the structural, morphological and magnetic properties of magnesium ferrite nanoparticles<#LINE#>Lavanya @Khanna,S.K. @Tripathi <#LINE#>1-9<#LINE#>1.ISCA-RJRS-2017-002.pdf<#LINE#>Department of Physics, Panjab University, Chandigarh-160014, India@Department of Physics, Panjab University, Chandigarh-160014, India<#LINE#>1/9/2016<#LINE#>28/1/2017<#LINE#>In the present paper, magnesium ferrite nanoparticles were synthesized by conventional sol–gel method. The as-synthesized material was calcined at different temperatures and their structural, magnetic, FTIR, morphological and compositional analyses were studied. XRD patterns revealed formation of cubic structured magnesium ferrite nanoparticles. With the increase in calcination temperature, the crystallite size increased and crystallinity improved.   No peaks corresponding to any impurity or additional phases were detected; this was also confirmed by the FTIR spectra. With increase in the temperature, a gradual disappearance of C-H, hydroxylate and carboxylate groups occurred, while Fe-O bond became prominent. The magnetic analysis done by VSM revealed superparamagnetic behavior of the calcined nanoparticles. With increase in temperature, magnetic saturation, coercivity, remanent magnetization and magnetic squareness value increased, owing to improved crystallization and bigger particle size. Considering biomedical application, this is an undesired feature as more the squareness value, lesser is the superparamagnetic character. The sample calcined at 500°C was found to be the most suitable for carrying out further investigations. Its morphological and compositional analysis revealed its spherical agglomerated formation with the desired elemental composition. In vitro cytotoxicity test on HaCaT cells using MTT (3-(4, 5-Dimethylthiazol-2-yl)-2, 5- diphenyltetrazolium bromide, a tetrazole) assay revealed the concentration-dependent cell-viability of the synthesized magnesium ferrite nanoparticles. The spherical formation, superparamagnetism and cell-viability (at lower concentrations) allows for its successful application in biomedicine.<#LINE#>Gupta A.K. and Gupta M. (2005).@Synthesis and surface engineering of iron oxide nanoparticles for biomedical applications.@Biomater, 26(18), 3995–4021.@Yes$Pankhurst Q.A., Connolly J., Jones S.K. and Dobson J. (2003).@Applications of magnetic nanoparticles in biomedicine.@J. Phys. D: Appl. Phys. 36(13), R167–R181.@Yes$Khot V.M., Salunkhe A.B., Phadatare M.R. and Pawar S.H. (2012).@Formation, microstructure and magnetic properties of nanocrystalline MgFe2O4.@Mater. Chem. Phy. 132(2), 782– 787.@Yes$Tomitaka  A.,  Hirukawa  A.,  Yamada  T.,  Morishita S. and Takemura Y.  (2009).@Biocompatibility  of various ferrite nanoparticles evaluated by in vitro cytotoxicity assays using HeLa cells.@J. Magn. Magn. Mater., 321(10) 1482–1484.@Yes$Zhang J., Rana S., Srivastava R.S. and Misra R.D.K. (2008).@On the chemical synthesis and drug delivery response of folate receptor-activated, polyethylene glycol-functionalized magnetite nanoparticles.@Acta Biomater, 4(1), 40–48.@Yes$Yallapu M.M., Othman S.F., Curtis E.T., Gupta B.K., Jaggi M. and Chauhan S.C. (2011).@Multi- functional magnetic nanoparticles for magnetic resonance imaging and cancer therapy.@Biomaterials, 32(7), 1890–1905.@Yes$Yin H., Too H.P. and Chow G.M. (2005).@The effects of particle size and surface coating on the cytotoxicity of nickel ferrite.@Biomaterials. 26(29), 5818–5826.@Yes$Rana S., Gallo A., Srivastava R.S. and Misra R.D.K. (2007).@On the suitability of nanocrystalline ferrites as a magnetic carrier for drug delivery: functionalization, conjugation and drug release kinetics.@Acta Biomaterialia, 3(2), 233–242.@Yes$Khanna L. and Verma N.K. (2013).@Size-dependent magnetic properties of calcium ferrite nanoparticles.@J.   Magn.Magn. Mater., 336, 1-7.@Yes$Khanna L. and Verma N.K. (2013).@PEG/CaFe2O4 nanocomposite: Structural, morphological, magnetic and thermal analyses.@Physica B, 427, 68–75.@Yes$Khanna L. and Verma N.K. (2014).@Biocompatibility and superparamagnetism in novel silica/CaFe2O4 nanocomposite.@Mater. Lett., 128, 376-379.@Yes$Khanna L. and Verma N.K. (2013).@Synthesis, characterization and invitro cytotoxicity study of calcium ferrite nanoparticles.@Mater. Sci. Semicond. Process., 16(6), 1842–1848.@Yes$Khanna L. and Verma N.K. (2015).@Study on novel, superparamagnetic and biocompatible PEG/KFeO2 nanocomposite.@J. Appl. Biomed., 13(1), 23-32.@Yes$Khanna L. and Verma N.K. (2013).@Silica/potassium ferrite nanocomposite: Structural, morphological, magnetic, thermal and in vitro cytotoxicity analysis.@Mater. Sci. Eng. B, 178(18), 1230-1239.@Yes$Khanna L. and Verma N.K. (2014).@Synthesis, characterization and biocompatibility of potassium ferrite nanoparticles.@J. Mater. Sci. Tech., 30(1), 30-36.@Yes$Mohapatra S., Rout S.R., Maiti S., Maiti T.K. and Panda A.B. (2011).@Monodisperse mesoporous cobalt ferrite nanoparticles: synthesis and application in targeted delivery of antitumor drugs.@J. Mater. Chem., 21(25), 9185-9193.@Yes$Baldi G., Bonacchi D., Franchini M.C., Gentili D., Lorenzi G., Ricci A. and Ravagli C. (2007).@Synthesis and coating of cobalt ferrite nanoparticles: a first step toward the obtainment of new magnetic nanocarriers.@Langmuir 23(7), 4026–4028.@Yes$Rana S., Philip J. and Raj B. (2010).@Micelle based synthesis of cobalt ferrite nanoparticles and its characterization using Fourier transform infrared transmission spectrometry and thermogravimetry.@Mater. Chem. Phys., 124(1), 264–269.@Yes$Yang H., Zhang C., Shi X., Hu H., Du X., Fang Y., Ma Y., Wu H. and Yang S. (2010).@Water-soluble superparamagnetic manganese ferrite nanoparticles for magnetic resonance imaging.@Biomater., 31(13), 3667–3673.@Yes$Leung K.C.F. and Wang Y.X.J. (2010).@Nanowires Science and Technology in N. Lupu (Ed.).@InTech, Croatia, 331–344.@No$Ferreira da Silva M.G. and Valente M.A. (2012).@Magnesium ferrite nanoparticles inserted in a glass matrix— Microstructure and magnetic properties.@Mater. Chem. Phy., 132(2), 264-272.@Yes$Foroughi F., Hassanzadeh-Tabrizi S.A. and Bigham A. (2016).@In situ microemulsion synthesis of hydroxyapatite-MgFe2O4 nanocomposite as a magnetic drug delivery system.@Mater. Sci. Eng. C, 68, 774-779.@Yes$Nedim Ay A., Konuk D. and Karan B.Z. (2011).@Magnetic nanocomposites with drug-intercalated layered double hydroxide shell supported on commercial magnetite and laboratory-made magnesium ferrite core materials.@Mater. Sci.Eng. C 31(5), 851–857.@Yes$Nonkumwong J., Pakawanit P., Wipatanawin A., Jantaratana P., Ananta S. and Srisombat L. (2016).@Synthesis and cytotoxicity study of magnesium ferrite-gold core-shell nanoparticles.@Mater. Sci. Eng. C, 61,123–132.@Yes$Hyun S.W., Kim H.J., Park C.S., Kang K.S. and Kim C.S. (2009).@Synthesis and Size Dependent Properties of Magnesium Ferrites.@IEEE Transactions on Magnetics, 45(6), 2551-2553.@Yes$Huang Y., Tang Y., Wang J. and Chen Q. (2006).@Synthesis of MgFe2O4 nanocrystallites under mild conditions.@Mater. Chem. Phy., 97(2), 394-397.@Yes$Hussein S.I., Elkady A.S., Rashad M.M., Mostafa A.G. and Megahid R.M. (2015).@Structural and magnetic properties of magnesium ferrite nanoparticles prepared via EDTA-based sol–gel reaction.@J. Magn. Magn. Mater., 379, 9-15.@Yes$Chandradass J. and Kim K.H. (2011).@Solvent effects in the synthesis of MgFe2O4 nanopowders by reverse micelle processing.@J. Alloys Compds., 509(5), L59-L62.@Yes$Pradeep A., Priyadharsini P. and Chandrasekaran G. (2008).@Sol– gel route of synthesis of nanoparticles of MgFe2O4  and XRD, FTIR and VSM study.@J. Magn. Magn. Mater., 320(21), 2774–-2779.@Yes$Das H., Sakamoto N., Aono H., Shinozaki K., Suzuki H. and Wakiya N. (2015).@Investigations of superparamagnetism in magnesium ferrite nano-sphere synthesized by ultrasonic spray pyrolysistechnique for hyperthermia application.@J. Magn. Magn. Mater., 392, 91–100.@Yes$Chandradass J., Jadhav A.H., Kim K.H. and Kim H. (2012).@Influence of processing methodology on the structural and magnetic behavior of MgFe2O4  nanopowders.@J. Alloys Compds., 517, 164-169.@Yes$Sivakumar N., Narayanasamy A., Greneche J.M.,  Murugaraj R. and Lee Y.S.  (2010).@Electrical  and magnetic behaviour of nanostructured MgFe2O4 spinel ferrite.@J. Alloys Compd., 504(2), 395-402.@Yes$Candeia R.A., Bernardi M.I.B., Longo E., Santos I.M.G. and Souza A.G. (2004).@Synthesis and characterization of spinel pigment CaFe2O4 obtained by the polymeric precursor method.@Mater. Lett., 58(5), 569-572.@Yes$Thant A.A., Srimala S., Kaung P., Itoh M., Radzali O. and Fauzi M.N.A. (2010).@Low temperature synthesis of MgFe2O4 soft ferrite nanocrystallites.@J. Aust. Ceramic Society, 46, 11-14.@Yes$Wyrzykowski D., Hebanowska E., Wiczk G.N., Makowski M. and Chmurzynski L. (2011).@Thermal behaviour of    citric    acid    and    isomeric    aconitic    acids.@J.   Thermal	Analysis    Calorimetry, 104(2), 731-735.@Yes$Preet S. Pandey S.K., Saini N., Koul A. and Rishi P. 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<#LINE#>Effect of extraction temperature and technique on phenolic compounds and antioxidant activity of Tamarindus indica seeds<#LINE#>Atreyi @Sarkar ,Uma @Ghosh <#LINE#>10-15<#LINE#>2.ISCA-RJRS-2017-007.pdf<#LINE#>Department of Food Technology and Biochemical Engineering, Jadavpur University, Kolkata – 700032, India@Department of Food Technology and Biochemical Engineering, Jadavpur University, Kolkata – 700032, India<#LINE#>16/11/2016<#LINE#>27/1/2017<#LINE#>Natural antioxidants from tamarind seed pose preservative effect in food and disease protective benefits in biological system. Extraction being the initial and crucial most step of antioxidant recovery is influenced by many conditions. In this study the effects of technique and temperature during solvent extraction of phenolic antioxidants from tamarind seed have been studied. The extraction techniques compared have been shaking and magnetic stirring. A binary solvent system of 50 % ethanol has been used and extraction has been carried out at varied temperatures (ranging 25 - 60° C). Total Polyphenol Content (TPC) and Total Antioxidant Activity (TAA) determined at these conditions have indicated magnetic stirring as the most convenient and exhaustive technique. While the maximum TPC has been extractable at 60° C, the highest TAA has been recorded at the extraction temperature of 40 ° C. Results have indicated that extracting temperature and technique significantly (P<0.05) influenced the antioxidant property and total phenolic compound recovery from tamarind seed.<#LINE#>Riley P.A. (1994).@Free radicals in biology: oxidative stress and the effects of ionizing radiation.@International journal of radiation biology, 65(1), 27-33.@Yes$Sies H. (1991).@Oxidative stress: from basic research to clinical application.@The American journal of medicine, 91(3), S31-S38.@Yes$Perumalla A.V.S. and Hettiarachchy N.S. 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(2001).@Natural antioxidants from residual sources.@Food chemistry, 72(2), 145-171.@Yes$Hayouni E.A., Abedrabba M., Bouix M. and Hamdi M. (2007).@The effects of solvents and extraction method on the phenolic contents and biological activities in vitro of Tunisian Quercus coccifera L. and Juniperus phoenicea L. fruit extracts.@Food Chemistry, 105(3), 1126-1134.@Yes$Lapornik B., Prošek M. and Wondra A.G. (2005).@Comparison of extracts prepared from plant by-products using different solvents and extraction time.@Journal of food engineering, 71(2), 214-222.@Yes$Spigno G., Tramelli L. and De Faveri D.M. (2007).@Effects of extraction time, temperature and solvent on concentration and antioxidant activity of grape marc phenolics.@Journal of food engineering, 81(1), 200-208.@Yes$Pinelo M., Rubilar M., Jerez M., Sineiro J. and Núñez M.J. (2005).@Effect of solvent, temperature, and solvent-to-solid ratio on the total phenolic content and antiradical activity of extracts from different components of grape pomace.@Journal of Agricultural and Food Chemistry, 53(6), 2111-2117.@Yes$Musa K.H., Abdullah A., Jusoh K. and Subramaniam V. (2011).@Antioxidant activity of pink-flesh guava (Psidium guajava L.): effect of extraction techniques and solvents.@Food Analytical Methods, 4(1), 100-107.@Yes$Ismail A. and Tan S.H. (2002).@Antioxidant activity of selected commercial seaweeds.@Malaysian Journal of Nutrition, 8(2), 167-177.@Yes$Khiari Z., Makris D.P. and Kefalas P. (2009).@An investigation on the recovery of antioxidant phenolics from onion solid wastes employing water/ethanol-based solvent systems.@Food and Bioprocess Technology, 2(4), 337-343.@Yes$Akowuah G.A., Ismail Z., Norhayati I. and Sadikun A. 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<#LINE#>Effect of yoga hand mudra on cardiac and neurological parameters in preventing heart attack<#LINE#>Tripathi @D.,Kalantri @Y.,Kumar @H.,Chitnis @V.,Chitnis @S.,Kalantri @R.C.,Bhatt @J.K. <#LINE#>16-20<#LINE#>3.ISCA-RJRS-2017-008.pdf<#LINE#>Shivoma Ashram, 83 Dwarkapuri, 20x40 Block Line, Indore, M.P., India@Shah Pathology, 410, Nandlalpura Chouraha, Jawahar Marg, Indore, M.P., India@Department of Biochemistry and Biophysics, University of California San Francisco, CA, USA@CHL Hospital, Department of Microbiology, AB Road, Near LIG Square, Indore, M.P., India@CHL Hospital, Department of Microbiology, AB Road, Near LIG Square, Indore, M.P., India@Kalantri Nursing Home, 219, Jawahar Marg, Indore, M.P., India@Shivoma Ashram, 83 Dwarkapuri, 20x40 Block Line, Indore, M.P., India<#LINE#>2/12/2016<#LINE#>25/1/2016<#LINE#>Heart attack is the leading cause of death worldwide and incidence of cases are increasing every day. Yoga hand mudra is effective in improving medical conditions like heart attack, blood pressure, diabetes and many more. In our study, male and female subjects (n=41)(normal 27 and heart patients 14) aged between 30-65 years were included. On all subjects, yoga hand mudra was tried as per study protocol and both cardiac and neurological parameters were recorded before and after performing mudra. In heart patient subjects, there was a substantial reduction in systolic, diastolic blood pressure, heart rate and blood viscosity. Moreover, increase in myocardial blood perfusion volume, coronary perfusion pressure, brain tissue blood supply and memory index was observed. We propose, this yoga mudra makes its effect through the nerve endings in fingers. The interplay of fingers sensitizes nerves in palm and wrist area which in turn makes a systemic effect on cardiovascular system and improves it. This yoga mudra is an emergency tool for primary supportive medical care on the spot for heart attack till hospitalization. Thus, this mudra is coined as V Mudra - a possible victory over death.<#LINE#>Nohria A., Lewis E. and Stevenson L.W. (2002).@Medical management of advanced heart failure.@J Am Med Assoc., 287(5), 628-40.@Yes$WHO (2016).@The Impact of Chronic Disease in India.@http://www.who.int/chp/chronic_disease_report/media/india.pdf.@No$Dorairaj P. and Salim Y. (2010).@Cardiovascular disease in India: Lessons learnt & challenges ahead.@Indian J Med Res., 132(5), 529-530.@Yes$Huffman M.D. and Prabhakaran D. (2010).@Heart failure: epidemiology and prevention in India.@Natl Med J India., 23(5), 283-288.@Yes$Paula Pullen R., Sameer Nagamia H., Puja Mehta K., Walter Thompson R., Dan Benardot, Ramadan Hammoud, Janice Parrott M., Srikanth Sola, Bobby Khan V. (2008).@Effects of yoga on inflammation and exercise capacity in patients with chronic heart failure@, J Card Fail., 14(5), 407-13.@Yes$Yogendra J., Yogendra H.J., Ambardekar S., Lele R.D., Dave M., Naaznin Husein and Shetty S. (2004).@Beneficial effects of yoga lifestyle on reversibility of ischaemic heart disease: Caring heart project of international board of yoga.@J Assoc Physicians India., 52, 283-289.@Yes$Bharshankar J.R., Bharshankar R.N., Deshpande V.N., Kaore S.B. and Gosavi G.B. (2003).@Effect of yoga on cardiovascular system in subjects above 40 years.@Indian J Physiol Pharmacol., 47(2), 202-206.@Yes$Damodaran A., Malathi A., Patil N., Shah N. and Marathe S. (2002).@Therapeutic potential of yoga practices in modifying cardiovascular risk profile in middle aged men and women.@J Assoc Physicians Indi., 50(5), 633-640.@Yes$Bhavanani A.B., Sanjay Z. and Basavaraddi I.V. (2012).@Immediate cardiovascular effects of pranava pranayama in hypertensive patients.@Indian J Physiol Pharmacol., 56(3), 273-278.@Yes$Shantakumari N. and Sequeira S. (2013).@Effects of a yoga intervention on lipid profiles of diabetes patients with dyslipidemia.@Indian heart J., 65(2), 127-131.@No$Nripendrntha Sengupta and Balai Chandra Sengupta (1937).@Susruta, Susrutasamitha, Calcutta: C.K. Sen & Company.@@Yes$Prasad L.V. (2002).@Indian System of Medicine and Homoeopathy Traditional Medicine in Asia.@Chaudhury Ranjit Roy, Rafei Uton Muchatar, editors, New Delhi: WHO- Regional Office for South East Asia, 283-286.@Yes$Muralikrishnan K., Balakrishnan B., Balasubramanian K. and Visnegarawla F. (2012).@Measurement of the effect of isha yoga on cardiac autonomic nervous system using short-term heart rate variability.@J Ayurveda Integr Med., 3, 91-96.@Yes$Hirschi Gertrud (2003).@Mudras.@Yoga in your Hands Samuel Weiser, Inc., United states of America, 224.@No$Tripathi D., Bhatt J.K., Kalantri Y., Chitnis V., Chitnis S. and Kalantri R.C. (2016).@Effect of Yoga Hand Mudra for controlling High Blood pressure.@Res. J. Recent. Sc., 5, 33-35.@Yes$Fedrick W. Bunce (2005).@Mudras in buddhist and hindu practices.@DK print world pvt. Ltd.@Yes$Pallav Sengupta (2012).@Health Impacts of Yoga and Pranayama: A State-of-the-Art Review.@Int J Prev Med., 3(7), 444-458.@Yes$Bandi Hari Krishna, Pal Pravati, Pal G.K., Balachander J., Jayasettiaseelon E., Sridhar M.G., Gaur G.S. and Sreekanth Y. (2014).@Effect of yoga therapy on heart rate, blood pressure and cardiac autonomic function in heart failure.@Journal of Clinical and Diagnostic Research., 8(1), 14-16.@Yes$Santha J., Sridharar K., Patil S.K., Kumaria M.L., Selvamurthy W., Nayar H.S. and Joseph N.T. (1981).@Study of some physiological and biochemical parameters in subjects undergoing yoga training.@Indian J medicineres., 74, 120-124.@Yes$Anand B.K. (1991).@Yoga and medical sciences.@Indian J Physio Pharmocol., 35(2), 84-87.@Yes$Bhavanani B. and Ramanathan M. (2013).@Immediate Cardiovascular effects of a single yoga session in different conditions.@Alternative and Integrative Medicine, 2(9), 1-4.@Yes$Chapman Sandra B., Aslan Sina., Spence Jeffrey S., DeFina Laura F.., Keebler Molly W., Hanzhang Lu and Nyaz Didehbani (2013).@Shorter term aerobic exercise improves brain, cognition, and cardiovascular fitness in aging,@Frountiers in ageing neuroscience, 5,75.@Yes
<#LINE#>Synthesis of 14-imino-11-methyl-9, 13-dioxo-8H-pyrimido [1, 2-a] pyrimido [4, 5-d] pyrimido [2, 1-b] [1, 3] benzothiazole derivatives and evaluation of their biological activity<#LINE#>Sandeep G. @Sontakke <#LINE#>21-24<#LINE#>4.ISCA-RJRS-2017-009.pdf<#LINE#>P.G. Research centre, Department of Chemistry, Yeshwant Mahavidyalaya, Nanded -431602, MS, India<#LINE#>30/11/2016<#LINE#>14/1/2017<#LINE#>The  broad  spectrum  biological  importance  of sulphur and  nitrogen  containing  heterocycles  were  constantly  encouraged chemists to synthesize their large number of derivatives during last  few  decades.  one  of the most  significant compound  among  these  are  benzothiazole  derivatives  which  was  found  to  be biologically and medicinally potent. in this study we condensed a mixture of 3-cyano-2-methylthio-6-methyl-4, 8-dioxo-9H-pyrimido [1, 2-a] pyrimidine   and differently substituted benzothiazoles in the incidence of K2CO3 and DMSO as a  reaction solvent, to get corresponding 14-imino-11-methyl-9, 13-dioxo-8H-pyrimido [1, 2-a] pyrimido - pyrimido [2, 1-b] [1, 3] benzothiazole derivatives. All the products were confirmed on the basis of IR, 1H NMR and mass spectroscopic techniques and evaluate their biological activity.<#LINE#>Venkatesh P. and Pandeya S.N. (2009).@Synthesis, characterization and anti-inflammatory activity of some 2-amino benzothiazole derivatives.@Int. J. Chem Tech Res., 1(4); 1354-1358.@Yes$Russo F., Romeo G., Santagati N.A., Caruso A., Cutuli V. and Amore D. (1994).@Synthesis of new thienopyrimidobenzothiazoles and thienopyrimidobenzoxazoles with analgesic and antiinflammatory properties.@European Journal of Medicinal Chemistry. 29(7-8), 569-578.@Yes$Shivani Choudhary, Suvarna G. Kini and Muhammad Mubeen. (2013).@Antioxidant activity of novel coumarin substituted benzothiazole derivatives.@Der Pharma Chemica, 5(4), 213-222.@Yes$Mariappan G., Prabhat P., Sutharson L., Banerjee J., Patangia U., Nath S. (2012).@Synthesis and Antidiabetic Evaluation of Benzothiazole Derivatives.@Journal of the Korean Chemical Society; 56(2),  251-256.@Yes$Singh M.K., Tilak R., Nath G., Awasthi S.K. and Agarwal A. (2013).@Design, synthesis and antimicrobial activity of novel benzothiazole analogs.@Eur J Med Chem., 63, 635-644.@Yes$Netalkar Priya P. , Netalkar Sandeep P. , Srinivasa Budagumpi and Revankar Vidyanand K.  (2014).@Synthesis, crystal structures and characterization of late &#64257;rst row transition metal complexes derived from benzothiazole core: Anti-tuberculosis activity and special emphasis on DNA binding and cleavage property.@European Journal of Medicinal Chemistry, 79, 47-56.@Yes$Kochichiro Y., Katsumi G., Kazuya Y., Tominori M. and Goro T. (1990).@Organic phosphorus compounds. 5.(4-Benzothiazol-2-ylbenzyl) amidophosphonate as potent calcium antagonistic vasodilators.@Journal of Medicinal Chemistry, 33(8), 2192-2196.@Yes$Tashfeen Akhtar, Shahid Hameed, Najim Al-Masoudi, Roberta Loddo and Paolo Colla (2008).@In vitro antitumor and antiviral activities of new benzothiazole and 1,3,4-oxadiazole-2-thione derivatives.@Acta Pharmaceutica; 58(2), 135-149.@Yes$Yaseen A. Al-Soud, Haitham H. Al-Sa’doni, Bahjat Saeed, Ihsan H. Jaber, Mohammad O. Beni-Khalid, Najim A. Al-Masoudi, Tahsin Abdul-Kadir, Paolo La Colla, Bernardetta Busonera, Tiziana Sanna, and Roberta Loddo (2008).@Synthesis and in vitro antiproliferative activity of new benzothiazole derivatives.@ARKIVOC,  (15), 225-238.@Yes$Suvarna Kini, S.P. Swain and A.M. Gandhi (2007).@Synthesis and evaluation of novel benzothiazole derivatives against human cervical cancer cell lines.@Indian Journal of Pharmaceutical Sciences, 69(1), 46-50.@Yes$Vartale Sambhaji P., Kalyankar, Nagesh D., Halikar and Nilesh K. (2013).@Synthesis and Preliminary Antimicrobial Activity of New Pyrimido [4, 5-b]-quinoline and Pyrido [2, 3-d] pyrimidine.@Phosphorus, Sulfur, and Silicon. 183(9), 2119-2138.@Yes$Selinay Eriskin, Nesrin Sener, Serkan Yavuz and I&#729;zzet Sener (2014).@Synthesis, characterization and biological activities of 4-imino-3-arylazo-4H-pyrimido[2,1-b][1,3]benzothiazole-2-oles.@Med Chem Res, 23(8), 3733-3743.@Yes
<#LINE#>Biosorption efficiency of tea residue for analysis of cadmium and lead ions using open circuit potential for real time measurement<#LINE#>Ansari @S.,Devnani @H. ,Satsangee @S.P. <#LINE#>25-29<#LINE#>5.ISCA-RJRS-2017-010.pdf<#LINE#>Department of Chemistry, Dayalbagh Educational Institute, Agra - 282005, India@Department of Chemistry, Dayalbagh Educational Institute, Agra - 282005, India@Department of Chemistry, Dayalbagh Educational Institute, Agra - 282005, India<#LINE#>13/11/2016<#LINE#>1/1/2017<#LINE#>The present paper reports the biosorption efficiency of tea residue (TR) for extermination of Pd+2 and Cd+2 ions from aqueous system using potentiometry as analytical tool. A three electrode cell setup with metal-coated gold (Au) electrode and platinum (Pt) electrode were utilized in form of working electrode for Pb+2 and Cd+2  deposition, respectively. Open circuit potential (OCP)values of metal ion concentration were observed which decreased for both heavy metals with addition of TR. Fourier transform infra-red (FTIR) spectroscopy showed the involvement of OH, C=O and C-O functional groups in the biosorbent. Scanning Electron Microscopy (SEM) analysis was carried out to study morphological features and showed the porous surface associated with biosorbent. The biosorption efficiency was analyzed to be 126 mg.g-1 for Pb+2 and 60.52 mg.g-1 for Cd+2. TR was found to be a potential biosorbent for removal of Pd+2 and Cd+2ions from aqueous solution. OCP built method offers a green approach which is uncomplicated for real time analysis of biosorption efficiency.<#LINE#>Vazquez O.F.G., Virgen M.D.R.M., Montoya V.H., Gomez R.T., Flores J.L.A., Cruz M.A.P. and Moran M.A.M. (2016).@Adsorption of heavy metals in the presence of a magnetic field on adsorbents with different magnetic properties.@Industrial and engineering chemistry research, 55(34), 9323-9331.@Yes$Matlok M., Petrus R. and Warchol J.K. (2015).@Equilibrium study of heavy metals adsorption on kaolin.@Ind. eng. Chem. Res., 54(27), 6975-6984.@Yes$Qin L., Yan L., Chen J., Liu T., Yu H. and Du B. (2016).@Enhanced removal of Pb2+, Cu2+, and Cd2+ by amino-functionalized magnetite/kaolin clay.@Ind. eng. Chem. Res., 55(27), 7344-7354.@Yes$Zeng G., Liu Y., Tang L., Yang G., Pang Y., Zhang Y., Zhou Y., Li Z., Li M., Lai M., He X. and He Y. (2015).@Enhancement of Cadmium adsorption by polyacrylic acid modified magnetic mesoporous carbon.@Chem. Eng. J., 259, 153-160.@Yes$Masoumi A., Ghaemy M. and Bakht A.N. (2014).@Removal of metal ions from water using poly (MMA-co-MA)/Modified-Fe3O4 magnetic nanocomposite: isotherm and kinetic study.@Ind. eng. Chem. Res., 53(19), 8188-8197.@Yes$Garrison N., Cunningham M., Varys D. and Schauer D.J. (2013).@Discovering new biosorbents with atomic absorption spectroscopy: an undergraduate lab experiment.@J. Chem. Educ.,91(4), 583-585.@Yes$Thakur L.S. and Mukesh P. (2013).@Adsorption of Heavy metal (Cu+2, Ni+2 and Zn+2) from synthetic waste water by tea waste adsorbent.@International journal of chemical and physical. Sciences, 2(6), 6-19.@Yes$Aikpokpodian P.E., Ipinmoroti R.R. and Omotoso S.M. (2010).@Evaluation of tea biomass for nickel contaminated waste water treatment.@J. soil Nature, 4(1), 7-16.@Yes$Zuorro A. and Lavecchia R. (2010).@Adsorption of Pb (II) on spent leaves of green and black tea.@Am. J. App. Sci., 7(2), 153-159.@Yes$Nandal M., Hooda R. and Dhania G. (2014).@Tea wastes as a sorbent for removal of heavy metals from wastewater.@IJCET, 4(1), 243-247.@Yes$Mahvi A.H., Naghipour D., Vaezi F. and Nazmara S. (2005).@Teawastes as an adsorbent for heavy metal removal from industrial wastewaters.@Am. J. app. Sci., 2(1), 372-375.@Yes$Satsangee S., Rajawat D.S., Singh P., Sharma S. and Kardam A. (2015).@Real time measurement of biosorption efficiency of chemically modified coconut powder for Pb (II) and Cd (II) using open circuit potential.@TACL, 5(3), 140-148.@Yes$Ahadi M.M. and Attar M.M. (2007).@OCP measurement: A method to determine CPVC@Scientia Iranica, 14(4), 369-372.@Yes$Zhou H., Park Z.H., Fan F.F. and Bard A.J. (2012).@Observation of single metal nanoparticles collisions by open circuit (Mixed) potential changes at an ultramicroelectrode.@J. Am. chem. Soc., 134(32), 13212-13215.@Yes$Martinez-Sanchez C., Torres-Rodriguez L.M. and Cruz R.F.G. (2013).@Kinetic modeling of biosorption of Cd+2 ions from aqueous solutions onto Eichhornia Crassipes roots using potentiometry: low –cost alternative to conventional methods.@Quimica Nova, 36, 1227-1231.@Yes$Radi S., Tighadouini S., Massaoudi M.E., Bacquet M., Degoutin S., Revel B. and Mabkhot Y.N. (2015).@Thermodynamics and kinetics of heavy metals adsorption on silica particles chemically modified by conjugated ß-ketoenol furan.@J. Chem. Eng. Data, 60(10), 2915-2925.@Yes
<#LINE#>The study of flow rate, resistive impedance of blood flowing through stenosed artery<#LINE#>Neeta D. @Kankane,N.S. @Bodke <#LINE#>30-34<#LINE#>6.ISCA-RJRS-2017-013.pdf<#LINE#>Department of Mathematics, Maharashtra Institute of Technology, Pune, India@Department of Mathematics, Dr. B. N. Purandare Arts, Commerce and Science College, Lonavla, Pune, India<#LINE#>29/11/2016<#LINE#>27/1/2017<#LINE#>The present paper aims to compute flow rate, resistive impedance of blood flowing through stenosed artery. The flow of blood in constricted artery is studied. The blood is treated as Newtonian fluid. The equations involved in the mathematical model are solved using finite difference approximations. The flow rate is calculated at the beginning and end of arterial segment. It is also calculated in the region of stenosis. Flow rate and resistive impedance are plotted axially for different values of time.<#LINE#>Young D.F. (1968).@Effect of a time-dependent stenosis on flow through a tube.@Journal of engineering for industry, 90(2), 248-254.@Yes$Liepsch D. (2002).@An introduction to biofluid mechanics-basic models and applications.@Journal of Biomechanics, 35(4), 415–435.@Yes$Haldar K. (1985).@Effect of the shape of stenosis on the resistance to blood flow through an artery.@Bulletin of mathematical biology, 47(4), 545-550.@Yes$Srivastava V.P., Rati Rastogi and Rochana Vishnoi (2010).@A two-layered suspension blood flow through an overlapping stenosis.@Computers and Mathematics with Applications, 60(3), 432-441.@Yes$Yakhot A., Leopold Grinberg and Nikolai Nikitin (2005).@Modelling rough stenoses by an immersed-boundary method.@Journal of Biomechanics, 38(5), 1115–1127.@Yes$Agarwal R., Katiyar V.K. and Pradhan Prabhakar (2008).@A mathematical modeling of pulsatile flow in carotid artery bifurcation.@International Journal of Engineering Science, 46(11), 1147–1156.@Yes$Mazumdar J.N. (2015).@Biofluid mechanics.@Biofluid Dynamics and Biofluidics.@Yes$Burton A.C. (1972).@Physiology and Biophysics of the circulation.@Year Nook Medical Publisher, Chicago.@Yes$Chakravarty S. and Sannigrahi A. (1999).@A nonlinear Mathematical model of blood flow in a constricted artery experiencing body acceleration.@Mathematical and Computer modelling, 29(8), 9-25.@Yes$Yang W.Y., Cao W., Chung T.S. and Morris J. (2005).@Numerical methods using MATLAB.@John Wiley and Sons.@Yes$Brice Carnahan, Herbert Luther A. and James Wilkes O. (1969).@Applied numerical methods.@John Wiley & Sons, Inc.@Yes$Fung Y.C. (1981).@Biomechanics: Mechanical properties of living tissues.@Springer-Verlag New York.@Yes
<#LINE#>Synthesis of dye-sensitized solar cells using polyaniline and natural dye extracted from beetroot<#LINE#>Patni @N.,Sharma @P.,Kumari @K. ,Pillai @S.G. <#LINE#>35-39<#LINE#>7.ISCA-RJRS-2017-014.pdf<#LINE#>Department of Chemical Engineering, Institute of Technology, Nirma University, S. G. Highway, Ahmedabad-382481, Gujarat, India@Department of Chemical Engineering, Institute of Technology, Nirma University, S. G. Highway, Ahmedabad-382481, Gujarat, India@Department of Chemical Engineering, Institute of Technology, Nirma University, S. G. Highway, Ahmedabad-382481, Gujarat, India@Department of Chemical Engineering, Institute of Technology, Nirma University, S. G. Highway, Ahmedabad-382481, Gujarat, India<#LINE#>28/11/2016<#LINE#>24/1/2017<#LINE#>In today’s world where fossil fuels are on the verge of depletion, solar energy offers a much valuable path to harness its abundance, which has  led to the discovery of third gen organic solar cells. The paper reports a detailed methodology for the preparation of polymer based dye sensitized solar cell (DSSC) using polyaniline (PANI). The cells were made using natural dye extracted from beetroot and indium tin oxide (ITO) coated glass. Three solar cells having different electrolytes were prepared and their efficiencies were determined. A mixture of conventional electrolyte (iodide and triiodide mixture) and HCl doped PANI have also been used and the results obtained from all the three cells were observed, compared and discussed. Ultraviolet spectroscopic results confirm the presence of dye extracted from beetroot and by the I-V curves, efficiencies of the cells calculated was 0.04694% (conventional electrolyte), 0.03170% (HCl doped PANI as electrolyte) and 0.02699% (conventional and PANI mixture as electrolyte).<#LINE#>Al-Amir J. and Abu-Hijleh B. (2013).@Strategies and policies from promoting the use of renewable energy resource in the UAE.@Renewable Sustainable Energy Rev., 26, 660–667.@Yes$Rodopoulou S., Samoli E., Chalbot M.C.G. and Kavouras I.G. (2015).@Air pollution and cardiovascular and respiratory emergency visits in Central Arkansas: a time-series analysis.@Sci. Total Environ., 536, 872–879.@Yes$Pandey A.K., Tyagi V.V., Jeyraj A., Selvaraj L., Rahim N.A. and Tyagi S.K. (2016).@Recent advances in solar photovoltaic systems for emerging trends and advanced applications@. Renewable Sustainable Energy Rev., 53, 859-884.@Yes$Federico B. and Claudio G. (2016).@Natural Polymers for Dye-Sensitised Solar Cells: Electrolytes and Electrodes Redox electrolyte Cathode.@Encyclopaedia of Polymer science and Technology.@Yes$Brian O’regan and Grfitzeli M. (1991).@A Low-Cost, High-Efficiency Solar Cell Based on Dyesensitized Colloidal TiO2 Films.@Nature, 353(6346), 737-740.@Yes$Senthil T.S., Muthukumarasamy N., Velauthapillai D., Agilan S., Thambidurai M. and Balasundaraprabhu R. (2011).@Natural dye (cyanidin 3-O-glucoside) sensitized nanocrystalline TiO2 solar cell fabricated using liquid electrolyte/quasi-solid-state polymer electrolyte.@Renew. Energy, 36(9), 2484-2488.@Yes$Mohammed A.A., Ahmad A.S.S. and Azeez W.A. (2015).@Fabrication of Dye Sensitised Solar Cell Based on Titanium Dioxide (TiO2).@Advances in Materials Physics and Chemistry, 5(9), 361-367.@Yes$Hemmatzadeh R. and Jamali A. (2015).@Enhancing the optical absorption of anthocyanins for dye sensitised solar cells.@Journal of Renewable and Sustainable Energy, 7(1), 013120.@Yes$MacDiarmid A.G. and Epstein A.J. (1992).@Polyanilines: Synthesis, Chemistry and Processing.@New Aspects of Organic Chemistry 1 Proceedings of the Fifth International Kyoto Conference on New Aspects of Organic Chemistry.@Yes$Osorio-Fuente J.E., Gómez-Yáñez C., Hernández-Pérez M.D.L.A. and Fidel-Pérez M. (2014).@Camphor Sulfonic Acid-hydrochloric Acid Codoped Polyaniline/polyvinyl Alcohol Composite: Synthesis and Characterization.@Journal of the Mexican Chemical Society, 58(1), 52-58.@Yes$Babu V.J., Vempati S. and Ramakrishna S. (2013).@Conducting polyaniline-electrical charge transportation@. Materials Sciences and Applications, 4(1), 1-10.@Yes$Manzoli A., Steffens C., Paschoalin R.T., Correa A.A., Alves W.F., Leite F.L. and Herrmann P.S. (2011).@Low-cost gas sensors produced by the graphite line-patterning technique applied to monitoring banana ripeness.@Sensors, 11(6), 6425-6434.@Yes
<#LINE#>Determination of elemental and morphological properties of Aegle marmelos (L.) by FTIR and FESEM technique<#LINE#>Jadhav @M.G.,Pawar @S.S. ,Deokar @T.G. <#LINE#>40-45<#LINE#>8.ISCA-RJRS-2017-015.pdf<#LINE#>Department of Zoology, Yashwantrao Mohite College of Arts, Science and Commerce, Bharati Vidyapeeth Deemed University Erandwane,  Pune-411038, India@Department of Zoology, Yashwantrao Mohite College of Arts, Science and Commerce, Bharati Vidyapeeth Deemed University Erandwane,  Pune-411038, India@Department of Zoology, Yashwantrao Mohite College of Arts, Science and Commerce, Bharati Vidyapeeth Deemed University Erandwane,  Pune-411038, India<#LINE#>30/11/2016<#LINE#>27/1/2017<#LINE#>Aegle marmelos (L.) is a supreme indigenous medicinal plant. It’s all parts have been used in ethnomedicine to make use of its medicinal properties including antidiarrhoel, antidysentric, antioxidant, anti-inflammatory etc. Different parts of Aegle marmelos (L.) contains alkaloids, flavonoids, tannins, steroids, polyphenols etc. The objective of this study was to identify the functional groups present in Aegle marmelos (L.) leaves by Fourier Transform Infrared Spectroscopy and to determine its elemental and morphological properties by Field Emission Scanning Electron Microscopy. Result of the FTIR spectra of Aegle marmelos (L.) leaves revealed the presence of different functional groups indicating the presence of aldehydes, amines, alcohols, phenols, ethers, esters, carbohydrates etc. These results confirm the presence of secondary metabolites like alkaloids, saponins, tannins, flavonoids, steroids, polyphenols etc. The FESEM technique with EDAX showed the presence of various elements like C, O,  N, K, Ca, Mg, Al, Cl, Se, Pt, Na, S, P, Be, Ba, Cu, Ag, Cr, Ni, Co, Mn, Zn and Fe. The present study on Aegle marmelos (L.) leaves will provide useful information about qualitative, quantitative and pattern of composition of these biocomponents responsible for its medicinal properties.<#LINE#>Hiral K.M. and Patel V. (2013).@A Review: Tremendous Pharmacological Worth of Aegle marmelos.@Indo Ame. J. Pharm.  Res., 3(8), 6044-6054.@Yes$Gangadhara A., Ramya R. and Subashini R. (2014).@In- vitro Anti-inflammatory and Mosquito Larvicidal Efficacy of Nickel Nanoparticles Phytofabricated from Aqueous Leaf Extracts of Aegle marmelos Correa.@Acta Tropica., 135,19-26.@Yes$Kumari K.D.K.P., Weerakoon T.C.S., Handunnetti S.M., Samarasinghe K. and Suresh T.S. (2014).@Anti-Inflammatory Activity of Dried Flower Extracts of Aegle marmelos in Wistar Rats.@J. Ethnopharm., 151(3), 1202-1208.@Yes$Arora D., Sharma N., Singamaneni V., Sharma V., Kushwaha M., Abrol V., Guru S., Sharma S., Gupta A.P., Bhushan S., Jaglan S. and Gupta P. (2016).@Isolation and Characterization of  Bioactive Metabolites from Xylaria psidii, an Endophytic Fungus of the Medicinal Plant Aegle marmelos and Their Role in Mitochondrial Dependent Apoptosis Against Pancreatic Cancer Cells.@Phytomedicine, 23(12), 1312-1320.@Yes$Pawar S.S., Jadhav M.G. and Deokar T.G. (2016).@Study of Phytochemical Screening, Physiochemical Analysis and Antimicrobial Activity of Bacopa monnieri (L) Extracts.@Int. J. Pharm. Clin. Res., 8(8), 1222-1229.@Yes$Siddique N.A., Mujeeb M., Ansari S.H., Ahmad S., Ali B. and Junaid A. (2010).@Development of Quality Standards of Aegle marmelos L. Leaves.@J. Phyto., 2(2), 36-43.@Yes$Varughese B. and Tripathi J. (2013).@Phytochemical Evaluation of Different Solvent Extracts of Aegle marmelos Fruit at Different Stages of its Ripening.@Adv. Lif. Sci. Tech., 8,8-12.@Yes$Mujeeb F., Bajpai P. and Pathak N. (2014).@Phytochemical Evaluation, Antimicrobial Activity and Determination of Components from Leaves of Aegle marmelos.@Biomed. Res. Int., 1-11.@Yes$Gupta A.K., Verma S. and Doshi N. (2015).@Phytochemical Analysis and Antioxidant Property of Aegle marmelos Extracts.@Int. J. Curr. Microbiol. App. Sci., 4(9), 826-830.@Yes$Amirtham S., Jeyanthi P. and Settu A. (2016).@Phytochemical and Anti-cholesterol Activity of Aegle marmelos (L.) Corr. Leaf Extract Using in Albino Mice.@Int. J. Curr. Microbial. App. Sci., 3, 82-87.@Yes$Dhuley J.N. (2002).@Investigation on the Gastroprotective and Antidiarrhoeal Properties of Aegle marmelos Unripe Fruit Extracts.@Hindustan Antibiotics Bulletin., 41(1-4),41-46.@Yes$Faizi S., Farooqi F., Rehman S.Z., Naz A., Noor F., Ansari F., Ahmad A. and Khan S.A. (2009).@Shahidine, A Novel and Highly Labile Oxazoline from Aegle marmelos: The Parent Compound of Aegeline and Related Amides.@Tetrahedron, 65(5), 998-1004.@Yes$Rana B.K., Singh U.P. and Taneja V. (1997).@Antifungal Activity and Kinetics of Inhibition by Essential Oil Isolated from Leaves of Aegle marmelos.@J. Ethnopharm., 57(1), 29-34.@Yes$Singh S., Singh P., Singh S.K., Trivedi M., Dixit R.K. and Shankar P. (2013).@Biological Activities and Therapeutic Potential of Aegle marmelos (Bael): A Review.@Int. J. Pharm. App. Sci., 3(1), 1-11.@No$Anand S.P., Jeyachandran R. and Nandagopalan V. (2011).@NMR Spectral Analysis on Root Extract of Zehneria scabra- A Vital Medicinal Climber.@J. Pharm. Sci. Res., 3(1), 1015-1018.@Yes$Thomas E., Aneesh T.P., Thomas D.G. and Anandan R. (2013).@GC-MS Analysis of Phytochemical Compounds Present in the Rhizomes of Nervilia aragoana Gaud.@Asian J. Pharm. Clin. Res., 6(3), 68-74.@Yes$Gomathi D., Kalaiselvi M., Ravikumar G., Devaki K. and Uma C. (2015).@GC-MS Analysis of Bioactive Compounds from the Whole Plant Ethanolic Extract of Evolvulus alsinoides (L.).@J. Food Sci. Tech., 52(2), 1212-1217.@Yes$Pawar S.S. and Jadhav M.G. (2015).@Determination and Quantification of Bacoside A from Bacopa monnieri (L) By High Performance Thin Layer Chromatography.@Int. J. Pharm. Phyto. Res., 7(5), 1060-1065.@Yes$Kutyshenko V.P., Beskaravayny P. and Uversky N. (2015).@In-Plant NMR: Analysis of the Intact Plant Vesicularia dubyana by High Resolution NMR Spectroscopy.@Molecules, 20(3), 4359-4368.@Yes$Malhotra V.K. (2011).@Biochemistry for Students. Tenth Edition.@J.B. Medicinal Publishers (P) Ltd, New Delhi, India.@Yes$Eruvbetine D. (2003).@Canine Nutrition and Health.@A Paper Presented at the Seminar Organized by Kensington Pharmaceuticals Nig. Ltd., Lagos, 21.@Yes$Hays V.W. and Swenson M.J. (1985).@Minerals and Bones. In: Dukes Physiology of Domestic Animals.@Tenth Edition. 449-466.@Yes$Ozcan M. (2004).@Mineral Contents of Some Plants Used as Condiments in Turkey.@Food Chemistry, 84(3), 437-440.@Yes$Soetan K.O., Olaiya C.O. and Oyewole E. (2010).@The Importance of Mineral Elements for Humans, Domestic Animals and Plants: A Review.@African J. Food Sci., 4(5), 200-222.@Yes$Ramamurthy N. and Kannan S. (2007).@Fourier Transform Infrared Spectroscopic Analysis of A Plant (Calotropis gigantean Linn) From An Industrial Village, Cuddalore, District, Tamilnadu, India.@Romanian J. Biophysics, 17 (4), 269 276.@Yes$Manoj K. and Ragothaman G. (1997).@Effect of Mercury, Copper and Cadmium on The Red Blood Cells of Boleophthamus duosumieri (Cuv.).@journal of postgraduate medicine, 43(4), 149-152.@Yes$Dukor R.K. 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<#LINE#>Rheological properties of water based slurry under turbulent flow condition<#LINE#>Yogita @Weikey,Shobha Lata @Sinha,Satish Kumar @Dewangan <#LINE#>46-53<#LINE#>9.ISCA-RJRS-2017-016.pdf<#LINE#>Mechanical Engineering Department, National Institute of Technology, Raipur, 492010, C.G, India@Mechanical Engineering Department, National Institute of Technology, Raipur, 492010, C.G, India@Mechanical Engineering Department, National Institute of Technology, Raipur, 492010, C.G, India<#LINE#>13/11/2016<#LINE#>27/1/2017<#LINE#>In previous researches the testing of additives had been performed under laminar flow conditions where as in this paper, results are taken under turbulence flow condition. So the results that are getting from this research may be varying from other that had been performed under laminar flow condition. This paper presents the effect of different additives on rheological properties of water- bentonite slurry by studying the rheological behaviour of additives. This work present the results to relate the turbulent flow condition of any fluid flow. In the present investigation, 19 different samples have been prepared by varying concentration of additives. The variation of shear stress and shear rate has been plotted and on the basis of this behaviour of fluids has been explained. The value of k and n are calculated by using Power law.<#LINE#>Abdou M.I., Al Sabagh A.M. and Dardir M.M. (2013).@Evaluation of Egyptian bentonite and nano-bentonite as drilling mud.@Egyptian Journal of Petroleum, 22(1), 53–59.@Yes$Vipulanandan C. and Mohammed A.S. (2014).@Hyperbolic rheological model with shear stress limit for acrylamide polymer modified bentonite drilling muds.@Petroleum Science and Engineering, 122, 38–47.@Yes$Kok M.V. (2004).@Determination of rheological models for drilling fluids (a statistical approach).@Energy Sources, 26(2), 153-165.@Yes$Vipulanandan C. and Mohammed A. (2015).@Effect of nano-clay on the electrical resistivity and rheological properties of smart and sensing bentonite drilling muds.@Journal of Petroleum Science and Engineering, 130, 86–95.@Yes$National Iranian Oil Company (2002).@Drilling formation.@Department of drilling chemistry, Ahwaz, Iran.@No$Yan J.N. (2001).@Drilling Fluid Technology.@The Press of University of Petroleum, Dongying, 358-359.@Yes$Mahto V. and Sharma V.P. (2004).@Rheological study of a water based oil well drilling fluid.@Journal of Petroleum Science and Engineering, 45(1), 123-128.@Yes$Garc&#305;a-Ochoa F., Santos V.E., Casas J.A., Gomez E. (2000).@Xanthan gum: production, recovery, and properties.@Biotechnology Advances, 18(7), 549-579.@Yes$Benchabane A. and Bekkour K. (2008).@Rheological properties of carboxy-methyl cellulose (CMC) solutions.@Colloid and Polymer Science, 286(10), 1173-1180.@Yes$Esther Vermolen, Menno Van Haasterecht J.T., Shehadeh Masalmeh K., Marinus Faber J., Diederik Michiel Boersma, Marc Gruenenfelder A. (2011).@Pushing the envelope for polymer flooding towards high-temperature and high-salinity reservoirs with polyacrylamide based terpolymers.@Society of Petroleum Engineering, 141497.@Yes$Kok M.V. and Alikaya T. (2005).@Effect of Polymers on the Rheological Properties of KCl/Polymer Type Drilling Fluids.@Energy Sources, 27(5), 405-415.@Yes$Chilingarian G.V. and Vorabutr P. (1983).@Drilling and drilling fluids.@Elsevier Science Pub. Co., Inc., New York, NY.@Yes$Darley H.C.H. and George Gray R. (1988).@Composition and properties of drilling and completion fluids.@fifth edition, Gulf Professional Publishing, Texas.@Yes
<#LINE#>Ganesh idol immersion: impact on water quality of Tapi River, Surat, Gujarat, India<#LINE#>Kinjal @Sangani,Kapila @Manoj <#LINE#>55-57<#LINE#>10.ISCA-RJRS-2017-011.pdf<#LINE#>Department of Aquatic Biology, Veer Narmad South Gujarat University, Surat, Gujarat, India@Department of Aquatic Biology, Veer Narmad South Gujarat University, Surat, Gujarat, India<#LINE#>30/11/2016<#LINE#>13/1/2017<#LINE#>India is a country of diverse cultural and religious festivals. Ganesh Chaturthi and Durga Puja are two major festivals involving idol immersion as ritual. The present study was carried out to assess the impact of idol immersion on water quality of Tapi river during Ganesh festival. Water samples were collected for pre-immersion, immersion and post -immersion periods during morning hours. Collected samples were analyzed for various Physico-chemical and analyzed microbiological parameters viz. pH, Temperature, Dissolved Oxygen, BOD, COD, total hardness, total solids, total dissolved solids and total Viable count. Significant changes in results of all selected parameters were noted after the immersion however within BIS standard limits. Observations indicate that efforts of public awareness campaigning attain good response and helped to reduce the impact of idol immersion on water quality and also reduce the resultant pressure on the ecology of the natural water bodies.<#LINE#>Panwar P. (2015).@Idol immersion - not ideal at all!.@Available at: http://zeenews.india.com/Ganesha/story.aspx?aid=654035. 24/11/2016.@No$Ujjania N.C. and Multani A.A. (2011).@Impact of Ganesh Idol Immersion Activities on the Water Quality of Tapi River, Surat (Gujarat) India.@Res. J. Biol., 1(1), 11–15.@Yes$Desai J. and Tank S.K. (2010).@Deterioration of Water Quality Due To Immersion of Ganesh Idols in the River Tapti At Surat (India ).@J. Environ. Res. Dev., 4(4), 999–1007.@Yes$Watkar A.M. and Barbate M.P. (2014).@Impact of Idol Immersion on Water Quality of Kolar River in Saoner, Dist. Nagpur, India.@Int. Res. J. Environ. Sci. Int. Res. J. Environ. Sci, 3(3), 39-42.@Yes$Mohini G., Ekhalak A. and Ranjana S. (2014).@Pollution Load Assessment of Tapi River During Ganesh Festival, India.@Octa J. Environ. Res., 2(4), 310–313.@Yes$Anonymous. (2016).@The Environmental Impact of Ganesh Chaturthi — Welcome to the eCoexist network! ecoexist.@Available at: http://e-coexist.com/products/Ganesh-chaturthi/the-environmental-impact-of-Ganesh-chaturthi.27/11/2016@No$APHA (2005).@Standard methods for the examination of water & wastewater.@(American Public Health Association).@Yes$Trivedy R.K. and Goel P.K. (1984).@Chemical and Biological Methods for Water Pollution Studies - R.K. Trivedy, P. K. Goel - Google Books.@(Environmental Publications).@Yes$Sangani K. and Manoj K. (2015).@Assessment of Water Quality Parameters in Reference to Bacterial Population in Tapi River, Surat, Gujarat.@2nd International Conference on Multidisciplinary Research & Practice, 3(1) 71–73.@Yes$Yanamadala V. (2005).@Calcium carbonate phosphate binding ion exchange filtration and accelerated denitrification improve public health standards and combat eutrophication in aquatic ecosystems.@Water Environ. Res., 77(7), 3003–12.@Yes$Mishra S., Singh A.L. and Tiwary D. (2014).@Studies of Physico-chemical Status of the Ponds at Varanasi Holy City under Anthropogenic Influences.@Int. J. Environ. Res. Dev., 4(3) 261–268.@Yes$Times of India. (2016).@Elaborate arrangements for visarjan in Surat.@Available at: http://timesofindia.indiatimes.com/city/surat/Elaborate-arrangements-for-visarjan-in-Surat/articleshow/54302018.cms.23/11/2016@No