ANTIMICROBIAL ACTIVITY OF SOME BIOFUEL PRODUCING PLANTS Nishu Jain , Richa Bhatnager* Research scholar, Centre for Medical Biotechnology, Mahrishi Dayanand University, Rohtak Email id: richabhatnagar2010@gmail.com ABSTRACT: In modern era, basic requirements are energy and prevention of diseases. There are some plant present in the nature which proves themselves as a better energy alternative. Besides this these plants provide protection against microbial diseases. So there is a great need to understand the various role of these plant and various extract prepared from these plant in order to achieve better protection from the microbes. These plant are so valuable because if it proves that these plant can cure a various infection then they can serve as better alternative of antibiotics and protect us from the side effect of this drugs. Present review represent a collection of a few biofuel producing plant and their antimicrobial properties. KEYWORDS: antimicrobial, biofuels, global warming, fossil fuel. INTRODUCTION Biodiesel is an alternate to naturally occurring diesel fuel that is produced by reaction of alcohols and vegetable oil or animal fat. Because it’s primary raw material is a vegetable oil or animal fat, so it generally considered to be renewable. Biodiesel is ecofriendly due to its very low contribution in global warming. Because for its synthesis, fatty acids are used and fatty acids are made up of carbon basically come from environment (air), so causing less global warming than fossils fuels. The main alternative diesel fuels is made from natural, renewable sources such as vegetable oil and fats [1-2] .The common sources of Biodiesel are listed in the Fig. 1. Algae , bacteria, Fungi Animal fats Biodiesel Sewage Vegetable oil(eg. soyabean,sunflower,etc.) Non-edible oil (eg. Jojoba oil,Almond oil,Karanja oil,etc) Fig. 1 Sources of Biodiesel Plants are one of the most important sources of medicine and many of the plants parts and plants derived compounds are used as a source of biodiesel [3].There There are several non-edible oil seed species such as T Thevetia (Thevetia peruviana), Karanja aranja (Pongomia pinnate), Jatropha (Jatropha atropha curca curca), Neem (Azadirachta indica)) etc, that could be utilized as a feedstock ock oil in biodiesel production) [4]. Jatropha curcas Jatropha curcas, commonly kknown as physic nut, purging nut or pig nut or jablota (Himachali) is a non-edible edible m multipurpose ultipurpose shrub or a small tree belonging to the family of Eubhorbiaceae. It was basically a native of Mexico and then by Portuguese traders ders spread to Asia and Africa as a hedge pla plant. The genus name Jatropha derives from the Greek word jatros having meaning doctor andd trophe means food, which by name indicates its medicinal uses, and the plant is traditionally used for medicinal practices[5-7]. It grows in a subtropical regions of the world and is an uncultivated non-food wild species[8]. It reaches up to height of 3-4m and its leaves are 3-5 lobed, cordiform, and stipules deciduous. Inflorescence is complex, monoecious with protandry and the first branching is racemose while subsequent branches are cymes. Its seeds contain 30 - 40% oil that can be easily isolated for processing (transesterification) andundergo laboratory refinement to produce biodiesel[9-11] . Many reports indicated that its seeds are toxic to humans and most animals and birds when injested, so commonly known as “Black vomit nut”, “Purge nut”, “Physic nut”, “Pinoncillo”, “American purging nut”, “Barbados purging nut”,“poison nut tree” the “graveyard tree”,etc[11-12]. On the other side, it also has been reported to have medicinal uses for human and veterinary purposes[12]. Its sap and crushed leaves has been known to have anti-parasitic activity[13]. Its branch extract have been shown to possess cytopathic effect with a vey low cytotoxicity as seen in HIV patients[14]. Latex of Jatropha curcas has also been reported to have strong antimicrobial activities[15]. Jatropha curcas can be used for numerous purposes including biodiesel production[16]. However being a source of fuel after removal of its toxin such as phorbols esters (in seeds) and curcin, it can be used as nutritional and economic protein supplements in animal feed[17,18]. Various parts of the plant are of medicinal value, like its bark, flowers, wood, leaves, etc. Its latex possesses broad spectrum antimicrobial activity against Bacillus subtilis, Escherichia coli, Pseudomonas aeruginosa, Stapylococcus aureus, Streptocococcus pyogenes, Candida albicans and Trichophyton sp., using agar and broth dilution methods[15] . White latex of plant is used to cure oral thrush. This latex basically contain 3 main alkanoids named Jatrophine, Jatropham and curcain, also shown to have anti- cancerous properties. It is also effective against skin diseases, piles and sores. Ethanolic extracts of its leaves possess antifungal activity against the three major dermatophytes – Trichophyton,Microsporum, Epidermophyton together with Malassezia furfur indicates its inhibitory effect on fungal isolates and also possess antimicrobial activity against all bacterial species except Bacillus subtilis[8]. When various extract and latex of this plant were analysed phytochemically, it is found that latex contain saponins, tannin, steroids, cardiac glycoside, anthraquinone terpenoid and alkaloids responcible for antimicrobial activity[19]. Certainly these metabolites are associated for its antimicrobial potency which may be utilised for the prevention of microbial infections [20]. Its leaves extract contain contain apigenin, vitexin and isovitexin which along with other factors make them to be used to combat malaria, rheumatic and muscular pains. Its root extract possess anti venom activity and can be effectively used as an antidote against snake venom. Besides this root extract can be used to treat gums bleeding[21]. Pongamia pinatta Pongamia pinnataalso known as Derris indica is a mangrove plant that belongs to the family Fabaceae and is known as Karanja in hindi, and Indian Beech in English[22]. Pongamia pinnata (L.) is widely distributed near the wet places in India[23]. It is a monotypic genus found to grow mostly along the coasts and riverbanks. The tree is known for its multipurpose benefits and as a potential source of biodiesel[24] . From its seeds a non edible oil has been extracted i.e.Pongame oil, reported as a major source of oil for biofuel production [25]. It is bitter in taste , reddish brown in color , highly viscous and nonedible oil. It is commonly used for tanning leather, making low grade soap. It is effectively used against scabies, herpes, and rheumatism[26]. Both the oil and oil presscake residues are toxic but toxicity can be removed with the help of genetic variations. The use of plant oils in biodisel industry is preferred more because it not only provide a renewable source but also leaving animal oils spare and get rid of any ethical issue as in case of animal fat[27]. This plant have a number of uses such as fodder for animal, serve as green manure, timber production etc. It has been identified to have insecticidal and nematicidal activity and also have agriculture and environmental management applications also [28]. Its leaves extract have selective antidiarrhoeal action with efficacy against cholera and antifilarial activity which prevent movement of filarial parasite[29-30]. In a study different concentration of its seed extract (oil) was tested against Aspergillus niger, A. fumigatus, Staphylococcus aureus and Pseudomonas aeruginosa. Chemical analysis of oil was performed by gas chromatography (GC) and gas chromatography/mass spectrometry (GC-MS) which showed the presence of fatty acid and it was suggested to use the fatty oil of this plant for developing plant derived antimicrobial drugs. Its flower extract prevent the growth of six potential pathogenic bacteria of genus Escherichia, Bacillus,and family enterobacteriaceae suggesting its bacteriostatic properties[31]. Bark isolates of P. Pinnata was found to have antioxidant potential due to presence of cycloart-23-ene-3β , 25-diol (called B2). This B2 contain antimicrobial, antifungal specially towards yeast and dose dependent antioxidant property[32]. Different secondary metabolites was found in different plant part extract by HPLC analysis. Its methanolic bark extract contain of protocatechuic, ellagic, ferulic, gallic, gentisic, 4-hydroxybenzoic and 4-hydroxycinnamic acids whereas its leaves extract contain sorbic, ferulic, gallic, salicylic and p-coumaric acids while its seed extract contains vanillic, gallic and tannic acids in seeds as the main phenolic acids[33]. A new rotenoid, Pongarotene and a known flavonol, karanjin were isolated from the seeds of P. pinnata also have antifungal, antibacterial and [34] . Azadirachta indica Azadirachta indica commonly known as Neem, is a fast growing evergreen tree found commonly in India, Africa and America . Neem is a native of India and is a tree of religious values for the people in the region. The plant is considered sacred and is used by the Hindus in several ceremonies and rituals. Its every part i.e. leaves, bark of stem, etc. has been used as traditional medicine for household remedy to treat skin infections and other diseases[35] . It belongs to the family Meliaceae and is commonly called Indian Lilic or Margosa. This tree is a topic of global context because it answers a number of major concerns facing mankind. It has been approved by the US Environmental Protection Agency for use on food crops and is considered harmless to humans, animals, birds, beneficial insects and earthworms[36] . Its seed contains about 25%-45% oil which is a non-edible oil, used in biodiesel production[4]. Its oil contains three bitter bioactive compounds named nimbin, nimbinin and nimbidin. These compounds are responsible for its medicinal value, and also be used in preparation of cosmetics. Its extract also acts as an effective mosquito repellent[37]. While it is known to have antiallergenic,antidermatic, anifeedent, anti-inflammatory, antipyorrhoeic, antifungal, antiscabic, insecticidal, and many other biological activities; it also possesses maximum useful non-wood products than any other tree species. Due to all these activities and enormous applications, neem is considered as a green treasure. Azadirachta indica (Neem) oil is another vegetable oil from inedible crop that has been converted to useable items. All parts of the tree (seeds, leaves, flower and bark) are used for different medicinal preparations. Neem oil is useful for skin care such as acne treatment and keeping skin elasticity[9]. Phytochemical analysis of leaves showed the presence of steroids, triterpinoids, reducing sugars, alkaloids, phenolic compounds, flavonoids and tannins which were responsible for its activity against P. aeroginosa, S. auereus, E. coli and S. typhii [38] . Its leaf extract is effective against against Methicillin-sensitive and Methicillin-resistant Staphylococcus aureus [39]. Its oil have broad spectrum antimicrobial activity which is depend upon both the protein and carbohydrate contents. It is well known that its oil content possess higher level of protein and carbohydrate results in better antimicrobial activities[40]. From its oil a compound named NIM-76 was isolated and tested for its antimicrobial activity. This compound contains significantly higher antimicrobial potential as whole neem oil. It can inhibit the growth of pathogens which are not in inhibited by the neem oil itself. Theses strains were Escherichia coli and Kleibsiella enterica. Besides its antibacterial potential, this NIM-76 was found to be effective against fungus and viruses such as Polio virus. Hence it was concluded that NIM-76 has a potent broad spectrum anti-microbial activity [41] . Ricinus communis It is a fast growing perennial shrub family Euphorbiaceae. It is also known as Palma Christi or a wonder tree [42]. It is found to be widely spread in the tropics and temperate regions of the world thoroughly [43]. Its seed extract is known as castor oil. Because of its high content of fatty acid i.e ricinoleic acid , it have a valuable role in lubricants, paints, coats, cosmetic industries[44]. Residues of castor oil production has a limited role as animal food and fertilizers because of the presence of highly toxic protein and a alkaloid ricinine. Ricin is a water-soluble protein which is not extracted into the castor oil, making industrial grade castor oil safe for use and can be used as a reactant in biodiseal production[45]. The castor biodiesel is widely used in area of extremely low temperature and during winter because of its very low cloud and pour points properties. Castor oil is mostly preferred for biodiesel production because of energy point of view. It does not need heat and subsequent energy needed when other vegetable oils are transformed into biodiesel. Plant contain a number of industrial and therapeutic approaches, antioxidant and immunomodulatory effects. All these effects are basically due to presence of various flavonoids, saponins, glycosides, alkaloids and steroids[46]. Castor oil is a valuable source of medicinal oil and a number of benefits for humans. Castor oil has industrial as well as therapeutic applications[47] . The main toxic found in its seed extract is ricin and an alkaloid ricinine[48]. Its extract possess different type of antimicrobial activity. Its leaves extract possess antibacterial activity against ENterobacters and skin pathogens.Acetone and hexane extract possess significantly higher antimicrobial property [49] . Extract possess comparatively better antibacterial activity as erythromycin, ampiclox and rifampin group for Gram positive organisms and, septrin and ceporex group for Gram negative organisms respectively [50]. Free radicals causes oxidative stress which inturn give rise to a number of metabolic and microbial associated diseases. From a study it become evident that its extract possess radical scavenging capacity[51]. Besides this, its extract contain secondary metabolites like alkaloids, saponins, flavonoids and tannins confirmed by phytochemical analysis. A novel oleanen type triterpenoid, has been isolated from butanolic extract of seeds of R. Communis that was reported to show both antimicrobial and antifungal activity[52]. In a study, the potential of Acacia nilotica and Ricinus communis as antimicrobial agents in relation with various important biomolecules and to check their correlation was explored. Water and methanol extract of different parts of A. Nilotica and R. Communis showed good inhibition against Gram positive (Staphylococcus aureus and Streptococcus enterica), and Gram negative bacteria (Pseudomonas aeruginosa, Escherichia coli, Klebsiella enterica) and some fungi (Aspergillus niger, Penicillium expansum and Aspergillus enteric) [52]. Balanites aegyptiaca Desert date (Balanites aegyptiaca), a member of family Zygophyllaceae, is a semi-evergreen, usually spiny, extremely variable shrub or small tree that grows up to 12 m high. Balanites aegyptiaca is perhaps one of the most wide-spread woody plants of the African continent. In India, Balanites are widely grown in Rajasthan and neighboring states. The branches are usually spread irregularly or pendulous, and sometimes form round crown and the bowl is usually straight with a 60 cm diameter, often fluted. The tree produces yellow date-like fruit. The trees bear heavy yields of fruits annually on a mature tree in good condition and the oil content of B. aegyptiaca seed kernels approaches 50% [53]. The fruit, which contains many valuable nutrients, is used in a variety of ways, it is most commonly used for preparing beverages, cooked foods, and medicines. It has a multiplicity of uses including biodiesel formation, and almost every part of the plant is useful including, leaves, thorns, back of root and fruit. The oil of the plant can be easily converted into biodiesel, but the viscosity of Balanite aegyptiaca oil seeds must be reduced for biodiesel application since the kinematics viscosity of biodiesel were very low compared to vegetable oils[5455].It has been reported that Balanites aegyptiaca grows on dry lands and is most tenble bio resource for industrial biodiesel production. The antifeedant, molluscidal, antidiabetic, antihelmintic, and contraceptive activities in various B. aegyptiaca extracts have been observed[56] . Its gall and leaves possess antibacterial and anti-inflammatory potentials. Dichloromethane fraction (DCMF) of galls and ethyl acetate fraction (EAF) of leaves possess best antimicrobial potential than anyother solvent [57]. DCMF extract of galls are effective against Ampicillin resistant Salmonella enterica. Galls and leaves fractions also possess lipoxygenase inhibitory activity as compare to quercetin. But this activity did not show any correlation to phenolic compounds isolated from the galls and leaves samples. Root extract possess potent anti-Candida activity [58]. Comparative study of organic extracts of Balanites aegyptiaca and Moringa oleifera leaves indicates potent antimicrobial activity of Balanites aegyptiaca than Moringa. And more interestingly, antimicrobial activity increased significantly when the extract of both of these plants were used in combination [59] . Conclusion In today’s world, the demand for energy have increase exceptionally due to day by day increase in consumption rate. From the various studies it is clear that soon all these natural resources are going to be exhausted, hence there is a great need to device other resource who can combat these natural non renewable resources like petroleum, coal and natural gas. Therefore there is a great urge of alternate of these fossil fuels. But the alternate resource must be ecofriendly, cheap and technically easy to produce. The best alternate is biodiesel produced by esterification reaction between vegetable oil and alcohols. It can also be used as low carbon altenation to heating oil. There are many sources of producing biodiesel other than vegetable oil and animal fat and those are algae, bacteria, fungi, sewage, etc. There are many plant species that contribute in the production of biodiesel such as J. curcas, A. Indica, R. Communis, etc. Some of the biodiesel producing plants also exhibit antimicrobial properties, thus proving benefits to the mankind. As this biofuel comes from the plant derivative so producing negligible environmental hazards. But some plants producing biofuels are tremendously hazardous because of causing friendly fire.Many of these species contains toxic compounds which are harmful to human or animals. In this case, toxicity must be removed or decresed to a level that it doesnot harm any other species, thus making it edible and more valuable. J. curcas, A. Indica, R. Communis, B. aegyptiaca and P. pinnata are all good biodiesel producing plants and they also have antimicrobial activity against many bacterial and fungal species. References: 1. Gerpen V J, Biodiesel processing and production, Fuel Processing Technology, 86 (2005) 1097. 2. Ratledge, Boulton C A, Fats and oils.Comparative Biotechnology in industry, agriculture and medicine, vol. 3. New York: Pergamon Press; (1985) 983. 3. Kalimuthu K, Vijayakumar S, and Senthilkumar R, Antimicrobial activity of the biodiesel plant, Jatropha curcas L., Int J Pharm. Bio. Sci., 1[3] (2010) 1. 4. Anya U, Chioma N N and Obinn O, Optimized reduction of free fatty acid content on neem seed oil, for biodiesel production, J. Basic. Appl. Chem, 2[(4] (2012) 21. 5. Sarin R, Sharma M, Sinharaya S and Malhotra R K, Jatropha–Palm biodiesel blends: An optimum mix for Asia, In: Fuel 86 (2007) 1365. 6. Foidl N, Foidl G, Sanchez M, Mittelbach M and Hackel S, Jatropha curcas L. as a resource for the production of biofuel in Nicaragua, Bioresour. Technol., 58 (1996) 7. Gressel J , Transgenics are imperative for biofuel crops, Plant Sci. , 174 (2008) 246 8. Saetae D and Suntornsuk W, Antifungal Activities of Ethanolic Extract from Jatropha curcas Seed Cake, J. Microbiol. Biotechnol., 20 (2010) 319. 9. Akintayo E T, Characteristics and composition of Parkia biglobbossa and Jatropha curcas oils and cakes, Bioresour. Technol, 92 (2004) 307. 10. Gubitz G M, Mittelbach M and Trabi M, Exploitation of the tropical oil seed plant Jatropha curcas L. , Bioresour. Technol., 67 (1990) 73. 11. Mahanta N, Gupta A and Khare S K, Production of protease and lipase by solvent tolerant Pseudomonas aeruginosa PseA in solid-state fermentation using Jatropha curcas seed cake as substrate, Bioresour. Technol. 99 (2008) 1729. 12. Irvine F R, Woody Plants of Ghana (with special reference to their uses), Oxford University Press, London, (1961) 233. 13. Matsuse I T, Lim Y A, Hattori M, Correa M and Gupta M P, A search for anti-viral properties in Panamanian medicinal plants. The eVects on HIV and its essential enzymes, Journal of Ethnopharmacology, 64 (1999) 15. 14. Igbinosa O O, Igbinosa E O and Aiyegoro O A, Antimicrobial activity and phytochemical screening of stem bark extracts from Jatropha curcas (Linn), African Journal of Pharmacy and Pharmacology, 3[2] (2009) 58. 15. Oyi A R, Onaolapo J A, Haruna A K and Morah C O, Antimicrobial screening and stability studies of the crude extract of Jatropha curcas linn latex (euphorbiaceae), Nig. Journ. Pharm. Sci, 6[2] (2007) 14. 16. Foidl N and Kashyap A, Exploring the Potential of Jatropha curcas in Rural Development and Environmental Protection, Rockefeller Foundation, New York (1999) 184. 17. Becker K and Makkar H P S, Toxic effects of phorbolesters in carp (Cyprinus carpio L.), Veterinary Human Toxicol, 40 (1998) 82. 18. Camaggio G and Amicarelli V, Jatropha Curcas : A non edible versatile cultivator , Forumware International , 1 (2012) 15. 19. Arekemase M O, Kayode R M O and Ajiboye AE, Antimicrobial Activity and Phytochemical Analysis of Jatropha Curcas Plant against Some Selected Microorganisms, IJB, 3[3] (2011) 52. 20. Ekundayo F O, Adeboye C A and Ekundayo E A, Antimicrobial activities and phytochemical screening of pignut (Jatrophas curcas Linn.) on some pathogenic bacteria, J. Med. Plant. Res, 5[7] (2011) 1261. 21. Thomas R, Sah N K, and Sharma P B, Therapeutic biology of Jatropha curcas: a mini review, Curr Pharm Biotechnol., 9[4] (2008) 315. 22. Simin K, Ali Z, Khaliq-Uz-Zaman S M, Structure and biological activity of a new rotenoid from Pongamia pinnata. Nat Prod Res, 16 (2002) 351. 23. Nadkarni K M, Indian Materia Medica, 1 (1976) 1065. 24. Azam M M, Waris A, Nahar N M, Prospects and potential of fatty acid methyl esters of some non-traditional seed oils for use as biodiesel in India. Biomass Bioenerg, 29 (2005) 293. 25. Sharma A, Saxena S, Rani U, Rajore S, and Batra A, Broad-spectrum antimicrobial properties of medicinally important plant Jatropha curcas l., Int J Pharm. Bio. Sci., 49[3] (2010) 11. 26. Burkill H M, The useful plants of West Tropical Africa (Families EJ), Royal Botanical Gardens Kew, 5 (1994) 90. 27. Scott T P , Lisette P and Ning C & Johanna S. Hadler & Michael A. Djordjevic & Peter M. Gresshoff Pongamia pinnata: An Untapped Resource for the Biofuels Industry of the Future. Bioenerg. Res, 1 (2008) 2. 28. Brijesh S, Daswani P G and Tetali P, Studies on Pongamia pinnata (L.) Pierre leaves: understanding the mechanism(s) of action in infectious diarrhea, J Zhejiang Univ Sci B , 7 (2006) 665. 29. Kagithoju S, Godishala V, Pabba S K, Kurra H B and Swamy N R, Anti bacterial activity of flower extract of Pongamia pinnata linn. an elite medicinal plant, International Journal of Pharmacy and Pharmaceutical Sciences, 4[3] (2011) 78. 30. Badole S L, Zanwar A A, Khopade A N and Bodhankar S L, In vitro antioxidant and antimicrobial activity cycloart-23-ene-3β, 25-diol (B2) isolated from Pongamia pinnata (L. Pierre), Asian Pacific Journal of Tropical Medicine: (2011) 910. 31. Niranjana K, Sathiyaseelanb V, and Jeyaseelana E C, Screening for AntiMicrobial and Phyto Chemical Properties of Different Solvents Extracts of leafs of Pongamia pinnata, International Journal of Scientific and Research Publications, 3[1] (2013) 1. 32. Sagwan S, Rao D V and Sharma R A, In vivo and in vitro proportional antimicrobial activity in karanj (Pongamia pinnata):an imperative leguminous tree, International Journal of Research and Reviews in Pharmacy and Applied science, 2[6] (2012) 981. 33. Sajid Z I, Anwar F, Shabir G, Rasul G, Alkharfy K M, and Gilani A H, Antioxidant, Antimicrobial Properties and Phenolics of Different Solvent Extracts from Bark, Leaves and Seeds of Pongamia pinnata (L.) Pierre., Molecules (2012) 3917. 34. Simin K, Ali Z, Khaliq-Uz-Zaman S M Structure and biological activity of a new rotenoid from Pongamia pinnata. Nat Prod Res, 16 (2002) 351. 35. Chopra R N, Nayar S L and Chopra I C, Glossary of Indian medicinal plants. Council of Scientific and Industrial Research, New Delhi. (1956) 145. 36. Bhowmik D, Chiranjib, Yadav J, Tripathi K K and Sampath K K K, Herbal Remedies of Azadirachta indica and its Medicinal Application, J. Chem. Pharm. Res , 2[1] (2010) 62. 37. Khan I, Srikakolupu S R, Darsipudi S, Gotteti S D and Amaranadh H, Phytochemical studies and screening of leaf extracts of Azadirachta indica for its anti-microbial activity against dental pathogens, Arch. Apll. Sci. Res., 2[2] (2010) 246. 38. Chaturvedi P, Bag A, Rawat V, Jyala N S, Satyavali V, and Jha P K, Antibacterial Effects of Azadirachta indica Leaf and Bark Extracts in Clinical Isolates of Diabetic Patients, NJIRM, 2[1] (2011) 5. 39. Vinoth B, Manivasagaperumal R and Rajaravindran M, Phytochemical analysis and antibacterial activity of Azadirachta indica A Juss., International Journal of Research in Plant Science, 2[3] (2012) 50. 40. Abalaka M, Oyewole O A, and Kolawole A R, Antibacterial Activities of Azadirachta Indica against Some Bacterial Pathogens, Advances in Life Sciences , 2[2] (2012) 5. 41. Gajanan M, Antibacterial activity of Azadirachta Indica leaves extracts against skin pathogens, International Journal of Recent Trends in Science And Technology, 2[3] (2012) 33. 42. Serpico M, White R, Oil, Fat and Wax, In Ancient Egyptian Materials and Technology; Nicholson, P.T., Shaw, I., Eds.; Cambridge University Press: Cambridge, UK, (2000) 390. 43. Verma S K, Yousuf S, Singh S K, Prasad G B K S and Dua V K, Antimicrobial potential of roots of Riccinus communis against pathogenic microorganisms, International Journal of Pharma and Bio Sciences, 2[1] (2011) 545. 44. Mutlu H and Meier M A R, Castor oil as a renewable resource for the chemical industry, Eur. J.Lipid Sci. Technol., 112 (2010) 10. 45. Barajas F and Carmen L, Biodiesel from castor oil: a promising fuel for cold weather .Department of Hydraulic, Fluids and Thermal Sciences , 2004 46. Jena J and Gupta A, Ricinus communis linn:A phyto pharmacological review. International Journal of Pharmacy and Pharmaceutical Sciences, 4 (2012) 25. 47. Audi J, Belson M, Patel M, Schier J and Osterloh J, Ricin poisoning-a comprehensive review, J Amer Med Assoc, 294 (2005) 2342. 48. Islam T , Bakshi H, Sam S, Sharma E, Hameed B, Rathore B, Gupta A, Ahirwar S, and Sharma M., Assessment of antibacterial potential of leaves of Ricinus communis against pathogenic and dermatophytic bacteria, International Journal of Pharma Research and Development, 4 (2010) 1. 49. Kensa V M and Yasmin S, Phytochemical screening and antibacterial activity on Ricinus communis L., Plant Sciences Feed, 1[9] (2011) 167. 50. Choudhury S, Sharma P, Choudhury M D, Sharma G D. Ethnomedicinal Chorei tribes of Southern Assam, North Eastern India. Asian Pac J Trop Dis, 2 (2012) 141. 51. Iqbal J, Zaib S, Farooq U, Khan A, Bibi I and Suleman S, Antioxidant, Antimicrobial, and Free Radical Scavenging Potential of Aerial Parts of Periploca aphylla and Ricinus communis, International Scholarly Research Network, (2012) 1. 52. Obumselu F O, Okerulu I O, Onwukeme V I, Onuegbu T U and Eze R C, phytochemical and antibacterial analysis of the leaf Extracts of ricinus communis, Journal of Basic Physical Research ,2 (2011) 68 . 53. Chapagain B P, Yehoshua Y and Wiesman Z , Desert date (Balanites aegyptiaca) as an arid lands sustainable bioresource for biodiesel. Bioresour. Technol. , 100[3] (2009) 122. 54. Mohamed A M, Wolf W and Spiess W E, Physical, morphological and chemical characteristics, oil recovery and fatty acid composition of Balanites aegyptiaca Del. kernels. Plant Foods Hum Nutr, 57[2] (2012) 179. 55. Kamel M S, Ohtani K, Kurokawa T, Assaf M H, El- Shanawany M A, Ali A A, Kasai R, Ishibashi S and Tanaka O, Studies on Balanites aegyptiaca fruits, an antidiabetic Egyptian folk medicine, Chemical and Pharmaceutical Bulletin, 39[5] (1991) 1229. 56. Hena J S, Adamu A, Iortsuun D N and Olonitola O S , Phytochemical screening and antimicrobial effect of the aqueous and methanolic extracts of roots of Balanites aegyptiaca (Del.) on some bacteria species, Science World Journal, 5 (2010) 59. 57. Meda N T R, Lamien M A, Kiendrebeogo O G M, Lamien C E, Identification and quantification of phenolic compounds from Balanites aegyptiaca (L) Del (Balanitaceae) galls and leaves by antioxidant , xanthine oxidase and HPLCMS. Natural Product Res, 25 (2011) 93. 58. Runyoro D K B, Ngassapa O D, Matee M I N, Joseph C C, and Moshi M J, Medicinal plants used by Tanzanian traditional healers in the management of Candida infections, J. Ethnopharmacol., 106 (2006) 158. 59. Doughari J H, Pukuma M S and De N, Antibacterial effects of Balanites aegyptiaca L. Drel. and Moringa oleifera Lam. on Salmonella typhi. African Journal of Biotechnology, 6 (2007) 2212. 19
© Copyright 2024