Page 1
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
185
1. Abalos, A. Physicochemical and antimicrobial properties of new rhamnolipids
produced by Pseudomonas aeruginosa AT10 from soyabean oil refinery wastes.
Langmuir; 2001; 17; pp 1367–1371.
2. Akio Ueno, Mohammad Hasanuzzaman, Isao Yumoto, Hidetoshi
Okuyama.Verification of Degradation of n-Alkanes in Diesel Oil by Pseudomonas
aeruginosa Strain Wat G in Soil Microcosms; Current microbiology ; 2006 ; 52; pp
182–185.
3. Alexander M. Biodegradation and Bioremediation. Academic Press, Harcourt
Brace & Company publishers; 1994; pp1-443.
4. Alexander M. How toxic are toxic chemicals in soil. Environmental Science and
Technology; 1995, 24; pp 1156-1162.
5. Anderson .T.H, Joergensen R.G. Relationship between SIR and FE estimates of
microbial biomass C in deciduous forest soils at different pH. Soil Biol. Biochem.
1997; 29; pp 1033–1042.
6. Anderson. T.H, Domsch K.H. The metabolic quotient for CO2 (q CO2) as a specific
activity parameter to assess the effects of environmental conditions, such as pH,
on the microbial biomass of forest soils. Soil Biol. Biochem. ; 1993 ; 25(3) ;pp 393-
395 .
7. Aparna.C, Saritha.P, Himabindu.V, Anjaneyulu.Y. Techniques for the evaluation
of maturity for composts of industrially contaminated lake sediments.2007,pp
8. APHA, AWWA, WEF .Standard methods for the examination of water and
wastewater. American Public Health Association, American Water Works
Association, and Water Environment Federation, Washington, D.C.; (1998), 19th
edn . Appl. Microbiol., Vol. 89, pp. 158-168.
9. Arino. S, Marchal R and Vandecasteele J P. Identification and Production of a
Rhamnolipid Biosurfactant by a Pseudomonas species, Appl. Microbiol.
Biotechnol.; (1996) ; 45 ; pp 162-168 .
10. Asha A, Juwarkar, Anupa Nair, Kirti V. Dubey, S.K. Singh, Sukumar Devotta
Biosurfactant technology for remediation of cadmium and lead contaminated
soils. Chemosphere; August 2007; Volume 68; Issue 10; Pages 1996-2002.
11. Bai GY, Brusseau ML, Miller RM. Influence of cation type, ionic strength, and pH
on solubilization and mobilization of residual hydrocarbon by a biosurfactant. J
Cont Hydrol ; 1998; 30 ;pp 265–279.
Page 2
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
186
12. Bai, G., L. M., Brusseau and R. M. Miller, Influence of rhamnolipid biosurfactants
in: Biotechnology, 421-457.
13. Bai.G, Brusseau. M.L, Miller R.M. Biosurfactant-enhanced removal of residual
hydrocarbon from soil. J. Contam. Hydrol ; 1997 ; 24;pp 157–170.
14. Baker. MD, Mayfeild C.I and Inniss W.E. Degradation of Chlorophenols in soils,
sediment and water at low temperature. Water Res; 1980; 14; pp1765-1771.
15. Balba M.T.,Al-Awadhi N. ,Al-Daher R. Bioremediation of oil contaminated soil:
microbiological methods for feasibility assessment and field evaluation. Journal of
Microbiological Methods 32 .1998; pp155-164.
16. Banat I.M. Biosurfactant production and possible uses in microbial Enhanced oil
recovery and oil pollution remediation: a review. Bioresource Technol; 1995; 51;
pp 1–12.
17. Banat IM, Samarah N, Murad M, Horne R, Banerjee S. Biosurfactant production
and use in oil tank clean-up. World J Microbiol Biotechnol; 1991; 7; pp 80-84.
18. Barber W.P and Stuckey D.C.Nitrogen Removal in a Modified Anaerobic za
aesrass\4ertBaffled Reactor (ABR):1. Denitrification.Wat. Res; 2000; Vol. 10 ; pp.
2413-2422 .
19. Beal R and Betts W B. “Role of Rhamnolipid Biosurfactants in the Uptake and
Mineralization of Hexadecane in Pseudomonas aeruginosa”, J. Appl.Microbiol.,
(2000), Vol. 89, pp. 158-168.
20. Bednarski, W. Application of oil refinery waste in biosynthesis of glycolipids by
yeast. Bioresource Techn. 2004; 95; pp 15–18 .
21. Benincasa. M, Contiero J, Manresa M. A and Moraes I O. Rhamnolipid Production
by Pseudomonas aeruginosa LBI Growing on Soap Stock as the Sole Carbon
Source. J. Food. Eng; 2002; 54; pp 283-288.
22. Benincasa. M. Chemical structure, surface properties and biological activities of
the biosurfactant produced by Pseudomonas aeruginosa LBI from soapstock.
Anton. Leeuw. Int. J. G.; 2004; 85; pp 1–8.
23. Bento.F.M, Camargo, FAO., Okeke. B.C., Frankenberger. W.T. Comparative
bioremediation of soils contaminated with diesel oil by natural attenuation,
biostimulation and bioaugmentation. Bioresource Technology; 2005; 96; pp 1049-
1055.
Page 3
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
187
24. Bhushan.B., Chauhan, A., Samanta, S. K. and Jain, R. K. Kinetics of
biodegradation of p-nitrophenol by different bacteria. Biochem. Biophys. Res.
Commun.; 2000; 274; pp 626–630.
25. Bognolo.G. Biosurfactants as emulsifying agents for hydrocarbons. Colloids Surf;
1999; 152; pp 41–52.
26. Boonchan.S, Britz M.L, Stanley GL. Degradation and mineralization of high-
molecular-weight polycyclic aromatic hydrocarbons by defined fungal–bacterial
cocultures. Appl Environ Microbiol; 2000; 66:pp1007–1019.
27. Boonchan.S, Britz.M.L, Stanley.G.A. Surfactant-enhanced biodegradation of high
molecular weight polycyclic aromatic hydrocarbons by Stenotrophomonas
maltophilia. Biotechnol. Bioeng; 1998; 59; pp 482-494.
28. Bordas F, Lafrance P, Villemur R. Conditions for effective removal of pyrene from
an artificially contaminated soil using Pseudomonas aeruginosa 57SJ
rhamnolipids; Environ Pollut; 2005; 138; pp 69–76.
29. Bouchez-Naïtali M, Rakatozafy H, Marchal R, Leveau JY, Vandecasteele JP.
Diversity of bacterial strains degrading hexadecane in relation to the mode of
substrate uptake. J. Appl. Microbiol; 1999; 86; pp 421-428.
30. BoydS.A, Shelton,D.R, Berry,D and Tiedje, J.M. Anaerobic biodegradation of
Phenolic compounds in digested sludge. Appl.Environ.microbial ; 1983 ; (46) ; pp
52-54.
31. Bragg, J.R, Prince, R.C, Harner E.J, Atlas, R.M. Effectiveness of bioremediation for
the Exxon Valdez oil spill; Nature; 368, 1994; pp 413–418.
32. Brookes, P.C. The potential of microbiological properties as indicators in soil
pollution monitoring. In : Schulin R., Desaules A., Webster R., Von Steiger
B.(Eds.), Soil Monitoring; 1993.
33. Brookes, P.C., Mc Grath, S.P. Effects of metal toxicity on the size of the soil
microbial biomass. J. Soil Sci, 1984: 35; pp 341-346.
34. Burger M.M., L. Glaser and R.M. Burton. The enzymatic synthesis of rhamnose-
containing glycolipid by extracts of Pseudomonas aeruginosa. J. Biol. Chem;
1963; 238; pp 2595-2602.
35. Caetano M, Madureira M-J,ValeC. Metal remobilisation during resuspension of
anoxic contaminated sediment: short-term laboratory study. Water Air Soil
Pollution; 2002; 143 (14); pp 23–40.
Page 4
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
188
36. Calmano W, Hong J, Forstner U. Binding and mobilisation of heavy metals in
contaminated sediments affected by pH and redox potential. Water Sci Technol;
1993; 28 (8 – 9); pp 223– 35.
37. Cerniglia CE. Biodegradation of polycyclic aromatic hydrocarbons.
Biodegradation; 1992; 3; pp 351–368.
38. Cerniglia. CE. Microbial metabolism of polycyclic aromatic hydrocarbons. Adv
Appl Microbiol; 1984; 30; pp 31–71.
39. Chakrabarty.T, Subrahmanyam P.V.R, Sundaresan B.B. Biodegradation of
recalcitrant industrial wastes, Ed: Wise, D, Biotreatment Systems; 1988; 2; pp
172-234
40. Chandrasekaran, E. V, and Bemiller, J. N.. In L. Wrhiste, & M. L. Wolfrom (Eds.),
Methods in carbohydrate chemistry New York: Academic. 1980; Vol. III, pp. 89–97.
41. Chang J.S. Rhamnolipid Production by Indigenous Pseudomonas aeruginosa sJ4
Originating from Petrochemical Wastewater. Biochemical Engineering Journal;
2005; 27; pp. 146 – 154.
42. Chayabutra, C., Jian Wu. and J. Lu. Kwang. Rhamnolipid production by
Pseudomonas aeruginosa under denitrification: Effects of limiting nutrients and
carbon sources, Biotechnol. Bioeng., 2001,72,(1), 25-33.
43. Chen W, Kan AT, Fu G, Tomson M . Factors affecting the release of hydrophobic
organic contaminants from natural sediments. Environ Toxicol Chem; 2000;
19(10): 24; pp 1 –8.
44. Chen Y.C., Banks. M.K., and Schwab A.P. Pyrene degradation in the rhizosphere
of tall Fescue (Festuca arundinacea) and Switch grass (Panicum virgatum L)
Env.Sci & Tech; 2003; 37; pp 5778-5782.
45. Cheung. K.C, Zhang J.Y, HH Deng, YK Ou, HM Leung, SC Wu, MH
Wong.Interaction of higher plant (Jute), electrofused bacteria and mycorrhiza on
anthracene biodegradation Bioresource Technology; 2008; 99; 7; pp 2148-2155.
46. Chiou C.T, Mc Groddy SE, Kile DE. Partition characteristics of polycyclic aromatic
hydrocarbons on soils and sediments. Environ Sci Technol; 1998; 32(2); pp 264–
269.
47. Christofi. N, Ivshina IB. Microbial surfactants and their use in field studies of soil
remediation. J Appl Microbiol ; 2002; 93; pp 915–29.
Page 5
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
189
48. Clark.C.G and Wright S, J.L. Detoxication of isopropy; l-n-phenyl carbamate and
iso propyl-n-3chlorophenyl carbamate in soil and isolation of iso propyl-n-phenyl
carbamate metabolizing bacteria. Soil Biol. Bio chem.; 1970; (2); pp 19-26.
49. Cooper, D. G., and B. G. Goldenberg. Surface active agents from two Bacillus
species. Appl. Environ. Microbiol.; 1987; 53; pp 224–229.
50. Cooper, D.G; Biosurfactants. Microb. Sci; 3; pp 145–149.
51. Cunningham. C.J, Ivshina I.B, Lozinsky V.I, Kuyukina M.S, Philp. J.C;
Bioremediation of diesel-contaminated soil by microorganisms immobilised in
polyvinyl alcohol. Int Biodeter Biodegradation 2004; 54; pp 167– 174.
52. Das, K.; Mukherjee, A.K. Comparison of lipopeptide biosurfactants production by
Bacillus subtilis strains in submerged and solid state fermentation systems using
a cheap carbon source: some industrial applications of biosurfactants. Process
Biochem. 2007, 42, 1191–1199.
53. Dave .H, Ramakrishna .C, Bhatt BD, Desai JD .Biodegradation of slope oil from
petroleum Industry and bioreclamation of slop oil contaminated soil. World J
Microbiol Biotechnol; 1994; 10; pp 653-656.
54. Daziel. E, Paquette G, Vellemur R, Lepins F, Bisaillnon JG. Biosurfactant
production by a soil Pseudomonas strain growing on PAH's. Appl Environ
Microbiol; 1996; 62; pp 1908 – 1912.
55. Del ‘Arco JP, de Franca FP. Influence of oil contamination levels on hydrocarbon
biodegradation in sandy sediments. Environ Pollut; 2001; 110; pp 515-519.
56. Desai. A.J., R.M. Patel, and J.D. Desai. Advances in production of biosurfactants
and their commercial applications. J. Sci. Ind. Res.; 1994; 53; pp 619–629.
57. Desai. J.D and Banat I M; Microbial Production of Surfactants and their
Commercial Potential Microbiol. Mol. Biol. Rev.; 1997; 61; pp 47 – 64.
58. Di Toro DM, Mahony JD, Hansen DJ, Scott KJ, Hicks MB, Mayr SM. Toxicity of
cadmium in sediments; the role of acid volatile sulfide Environ Toxicol
Chem;1990; 9; 1; pp 487–502.
59. Dibble J.T, Bartha R. Effect of environmental parameters of the biodegradation of
oil sludge. Appl. Environ Microbial; 1979; 37; pp 729-739.
60. Dilly O. Microbial respiratory quotient during basal metabolism and after glucose
amendment in soils and litter. Soil biology & biochemistry; 2001; 33; pp 117-127.
Page 6
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
190
61. Dubey. K and Juwarkar.A. Determination of genetic basis for biosurfactant
production in distillery and curd whey wastes utilizing Pseudomonas aeruginosa
strain BS2. Indian J. Biotechnol.; 2004; 3; pp 74–81.
62. Dubey.K. and Juwarkar.A. Determination of genetic basis for biosurfactant
production in distillery and curd whey wastes utilizing as viable alternative
sources for biosurfactant production. World J. Microbiol. Biotechnol.; 2001; 17;
pp 61–69.
63. European soil portal>JRC>Land management and natural hazards unit>soil
themes> soil contamination.
64. Fan W, Wang W-X, Chen J, Li X, Yen Y-F. Cu, Ni and Pb speciation in surface
sediments from a contaminated bay of northern China. Mar Pollut Bull; 2002; 44;
pp 816– 32.
65. Ferraz.C. The influence of vegetable oils on biosurfactant production by Serratia
marcescens. Appl. Biochem. Biotechnol; 2002; 98–100; pp 841–847.
66. Fiebig.R, Schulze D, Chung JC, Lee ST.Biodegradation of polychlorinated
biphenyls (PCBs) in the presence of a bio-emulsifier produced on sunflower oil;
1997; 8; pp 67-75.
67. Fiecther.A. Biosurfactants: Moving Towards Industrial Application. Trends
Biotechnol.; 1992; 10; pp 208-217.
68. Francisco J. Ochoa-Loza, Wouter H. Noordman, Dick B. Jannsen, Mark L.
Brusseau, Raina.M.Maier. Effect of clays, metal oxides, and organic matteron
rhamnolipid biosurfactant sorption by soil. Chemosphere; 2007; 66; pp 1634–
1642.
69. Franco,I., Contin.M., Bragato.G., De Nobili.M., Microbiological resilience of soils
contaminated with crude oil. Geoderma., 2004 121; pp 17-30.
70. Frische. T, H.Hoper. Soil microbial parameters and luminescent bacteria assays
as indicators for in situ bioremediation of TNT-contaminated soils, Chemosphere;
2003; 50; pp 415–427.
71. Georgiou.G., Lin S.C. and Sharma M.M. Surface active compounds from
microorganisms. BioTechnology; 1992; 10; pp 60-65.
72. Ghosh.M. M., I. T. Yeom, Z. Shi, C. D. Cox, and K. G. Robinson. Surfactant-
enhanced bioremediation of PAH- and PCB-contaminated soils, In R. E. Hinchee,
C.M. Vogel, and F.J. Brockman (ed.), Third International In Situ and On-Site
Page 7
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
191
Bioreclamation Symposium. Battelle Press, Columbus, Ohio 2 references. pp 15–
23.
73. Gillie.J.K, Hochlowski J, Arbuckle-Keil GA. Infrared spectroscopy. Anal Chem;
2000; 72; pp 71-80.
74. Golyshin. PM, Fredrickson HL, Giuliano L, Rothmel R, Timmis KN, Yakimov
MM.Effect of novel biosurfactants on biodegradation of polychlorinated biphenyls
by pure and mixed bacterial cultures. New Microbiol; 1999; 22; pp 257-267.
75. Goodfellow. M., Williams and Wilkins Co., Baltimore. In: Williams, S.T., Sharpe,
M.E., Holt, J.G Genus Rhodococcus Zopf (Eds.); Bergey’s Manual of Systematic
Bacteriology; 1989; 4; pp 2362–2371.
76. Goossens.H, Zwolsman.JJG. An evaluation of the behaviour of pollutants during
dredging activities. Terra et Aqua; 1996; 62; pp 20–27.
77. Goulding.C, Gallen.C.J, Bolten.E. Biodegradation of substitutions benzenes, J.
Appl. Bacteriol; 1988; 65; pp 1-6.
78. Guerin. WF, Boyd SA; Differential bioavailability of soil sorbed Naphthalene to two
bacterial species; Appl Environ Microbiol 1992; 58; pp 1142 – 1152.
79. Guerra-Santos, L. H., O. Kappeli, and A. Flechter . Dependence of Pseudomonas
aeruginosa continuous culture biosurfactant production on nutritional and
environmental factors. Appl. Microbiol. Biotechnol; 1986; 24; pp 443–448.
80. Guerra-Santos. L.H., O. Kappeli, and A. Fiechter. Pseudomonas aeruginosa
biosurfactant production in continuous culture with glucose as carbon source.
Appl. Environ. Microbiol; 1984; 48; pp 301–305.
81. Haba. E, M.J. Espuny, M.Busquets and A. Manresa. Screening and production of
rhamnolipids by Pseudomonas aeruginosa 47T2 NCIB 40044 from waste frying
oils. J. Appl. Microbiol.; 2000; 88; pp 379-387.
82. Haberhauer, G.; Feigl, B.; Gerzabek, M.H.; Cerri, C. FT-IR spectroscopy of organic
matter in tropical soils: changes induced through deforestation. Appl. Spectrosc.
2000, 54, pp 221–224.
83. Haferburg. D., Hommel R., Claus R., Kleber H.P. Extracellular microbial lipids as
biosurfactants. Adv. Biochem. Eng. Biotechnol. 33- 53.
84. Hammond .M.W. and Alaxander .M. Effect of chemical structure on microbial
degradation of methyl substituted aliphatic acids, Environ. sci. Technol; 1972; 6;
pp 732 – 735.
Page 8
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
192
85. Helvaci S.S, Pecker S.O, zdemir. G. Effect of electrolytes on the surface behavior of
rhamnolipids R1 and R2. Colloids Surf. B: Biointerfaces; 2004; 35; pp 225–233.
86. Herman, D.C.; Artiola, J.F.; Miller, R.M. Removal of cadmium, lead, and zinc from
soil by a rhamnolipid biosurfactant. Environ. Sci. Technol. 1995, 29, 2280–2285.
87. Herman. D.C., Zhang, Y., Miller, R.M .Rhamnolipid (biosurfactant) effects on cell
aggregation and biodegradation of residual hexadecane under saturated flow
conditions. Appl. Environ. Microbiol; 1997; 63, pp 3622-3627.
88. Hewald, S. Genetic analysis of biosurfactant production in Ustilago maydis. Appl.
Environ. Microbiol. 2005; 71; pp 3033–3040.
89. Hirai, M.F, Chanyasart, V, Kubota,H. A standard measurement for composting
maturity, Biocycle; 1983; 24; pp 54-56.
90. Hollender J, Althoff K., Mundt M., Dott W. Assessing the microbial activity of soil
samples, its nutrient limitation and toxic effects of contaminants using a sample
respiration test. Chemosphere; 2003; 53; pp 269-275.
91. Hwang.S., Cutright.T.J. Biodegradability of aged pyrene and phenanthrene in a
natural soil. Chemosphere; 2002; 47(9); pp 891-899.
92. Insam H., Hutchinson, T.C., Reber, H.H. Effects of heavy metal stress on the
metabolic quotient if the soil microflora. Soil Biol. Biochem., 1996; 28; pp 691-
694.
93. Itoh. S, Suzuki T. Effect of rhamnolipids on growth of Pseudomonas aeruginosa
mutant deficient in n-paraffin-utilizing ability. Agric Biol Chem; 1972; 36; pp 22-
33.
94. Jackson A. W., Pardue J. H. & Araujo R. A. Monitoring of crude oil mineralization
in salt marshes: use of stable carbon isotope ratios. Environ Sci Technol; 1996;
30; pp 1139-1144.
95. Jackson. WA, Pardue JH. Assessment of metal inhibition of reductive
dechlorination of hexachlorobenzene at a Superfund site. Environ Toxicol Chem;
1998; 17; pp 1441–1446.
96. Jain, D.K. Collins-Thompson, D.L., Lee, H.and Trevors, J.T. A drop-collapsing test
for screening surfactant-producing microorganisms, Journal of Microbiological
Methods; 1991; 13; pp 271-279.
Page 9
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
193
97. Jane-Yii Wu, Kuei-Ling Yeh, Wei-Bin Lu, Chung-Liang Lin, Jo-Shu Chang.
Rhamnolipid production with indigenous Pseudomonas aeruginosa EM1 isolated
from oil-contaminated site. Bioresource Technology; 2008; 99; 5; pp 1157-1164.
98. Javaheri.M., Jenneman.G.E., McInnerney M.J., and R. M. Knapp. Anaerobic
production of a biosurfactant by Bacillus licheniformis JF 2.Appl. Environ.
Microbiol; 1985; 50; pp 698–700.
99. Jenkinson. V.S, Brookes P.D, Powslon D.S. Measuring soil microbial biomass. Soil
biology and Biochemistry; 2004; 36(1); pp 5-7.
100. Johnson DL, Anderson DR, McGrath SP; Soil microbial response during the
Phytoremediation of a PAH contaminated soil Soil Biology. Biochemistry; 2005; 37:
pp 2334–2336.
101. Kaiser. E.A., Mueller, T., Joergensen R.G., Insam .H, Heinemeyer.O. Evaluation
of methods to estimate the soil microbial biomass and the relationship with soil
texture and organic matter. Soil. Biol. Biochem; 1992; 24 (7); pp 675–683 .
102. Khanitta Somtrakoon ,Sudarat Suanjit , Prayad Pokethitiyook, Maleeya
Kruatrachue ,Hung Lee ,Suchart Upatham. Enhanced Biodegradation of
Anthracene in Acidic Soil by Inoculated Burkholderia sp. VUN10013, Curr
Microbiol; 2008; 57: pp102–106.
103. Kim IS, Park J, Kim K. Enhanced biodegradation of polycyclic aromatic
hydrocarbons using nonionicsurfactants in soil slurry. Appl Geochem; 2001a; 16:
pp1419–1428
104. Kim. H. S, Jeon J W, Kim B H, Ahn C Y, Oh H M and Yoon B D. Extra Cellular
Production of a Glycolipid Biosurfactant, Mannosylerythritol Lipid, by Candida sp.
SY16 Using Fed-Batch Fermentation. Appl. Microbiol. Biotechnol.; 2006; 70; pp.
391-396 .
105. Knackmuss, H.J. Basic knowledge and perspectives of bioelimination of
xenobiotic compounds. J Biotechnol; 1996; 51; pp 287-295.
106. Koch A.K, Kaeppeli .O, Fiecther. A and Reiser J.Hydrocarbon Assimilation and
Biosurfactant Production in Pseudomonas aeruginosa Mutants, J. Bacteriol.;
1991; 173; pp 4212-4219.
107. Kördel. W., Hennecke D. and Herrmann M.; Application of the HPLC-screening
method for the determination of the adsorption coefficient on sewage sludges
Chemosphere; 1997; 35, 1-2; pp 121-128
Page 10
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
194
108. Kosaric N. Biosurfactants and their application for soil bioremediation. Food
Technol Biotechnology; 2001; 39; pp 295–304.
109. Kosaric. N, N.C.C. Gray, and W. L. Cairns. Microbial emulsifiers and de-
emulsifiers, In H.J. Rehm and G.Reed (ed.), Biotechnology; 1983; 3; pp 575–592.
110. Kuyukina.M.S. Recovery of Rhodococcus biosurfactants using methyl tertiary-
butyl ether extraction.J. Microbiol. Meth; 2001; 46; pp 149–156.
111. Kwok C.K., Loh K.C. Effects of Singapore soil type on bioavailability of nutrients
in soil bioremediation. Advances in Environmental Research; 2003; 7(4); pp 889-
900.
112. Kyung-Hee Shin, Kyoung-Woong Kim and Ju-Yong Kim, Kyung-Eun Lee and
Sung-Sik Han. Rhamnolipid Morphology and Phenanthrene Solubility at Different
pH Values, J. Environ. Qual; 2008; 37; pp 509–514.
113. Kyung-Taek Oh, Young-Ju Kim, Van Nam Nguyen, Woo-Jin Jung, Ro-Dong Park
; Demineralization of crab shell waste by Pseudomonas aeruginosa F722. Process
Biochemistry; 2007; 42; 7; pp 1069-1074.
114. Lajoie. C.A., Layton, A.C., Easter, J.P., Menn, F.M. and Sayler, G.S. Degradation
of nonionic surfactants and polychlorinated biphenyls by recombinant field
application vectors. Journal of Industrial Microbiology & Biotechnology; 1997; 19;
pp 252-262.
115. Lamoureux EM, Brownawell BJ. Chemical and biological availability of
sediment-sorbed hydrophobic organic contaminants. Environ Toxicol Chem; 1999;
18(8):17; pp 33–41.
116. Li X, Shen Z, Wai OWH, Li Y-S. Chemical partitioning of heavy metal
contaminants in sediments of the Pearl River Estuary. Chem Speciat Bioavailab;
2000; 12(1); pp 17 – 25.
117. Liang-Ming Whang, Pao-Wen G. Liu, Chih-Chung Ma and Sheng-Shung Cheng.
Application of biosurfactants, rhamnolipid, and surfactin, for enhanced
biodegradation of diesel-contaminated water and soil. Journal of Hazardous
Materials; 2008; 151; pp155-163.
118. Lorch, H.J., Benckieser, G., Ottow, J.C.G., Basic methods for counting
microorganisms in soil and water. In: Alef, K., Nannipieri, P (Eds.), methods in
Applied Soil Microbiology, 1995.
Page 11
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
195
119. Luoma SN. Bioavailability of trace metals to aquatic organisms—a review. Sci
Total Environ; 1983; 28; pp 1– 22.
120. Lyman WJ. Transport and transformation processes. In: Rand GM, editor.
Fundamentals of aquatic toxicology: Effects, environmental fate, and risk
assessment. Second edition. USA: Taylor and Francis; 1995.
121. Ma.H, DaiS, Huang.G. Distribution of tributyltin chloride in laboratory
simulated estuarine microcosms Water Res; 2000; 34(10); pp 28-29.
122. Maier R.M and Chavez G.S. Pseudomonas aeruginosa Rhamnolipids.
Biosynthesis and Potential Applications. Appl. Microbiol. Biotechnol.; 2000; 54; pp
625-633.
123. Maier, R.M.; Soberón-Chávez, G. Pseudomonas aeruginosa rhamnolipids:
biosynthesis and potential applications. Appl. Microbiol. Biotechnol. 2000, 54,
625–633.
124. Maillard J, Schumacher W, Vazquez F, Regeard C, Hagen WR, and Holliger
C..Characterization of the Corrinoid Iron-Sulfur Protein Tetrachloroethene
Reductive Dehalogenase of Dehalobacter restrictus. Applied and Environmental
Microbiology; 2003; 69 (8): 4628-4638.
125. Mancera-López, M.E., Esparza-García, F., Chávez-Gómez, B., Rodríguez-
Vázquez, R., Saucedo-Castañeda, G. and J. Barrera-Cortés. Bioremediation of an
aged hydrocarbon-contaminated soil by a combined system of biostimulation–
bioaugmentation with filamentous fungi. International Biodeterioration &
Biodegradation. 2008; 61/2; pp 151-160.
126. Maneerat, Suppasil. Production of biosurfactants using substrates from
renewable-resources. Songklanakarin. J. Sci. Technol; 2005; 27; pp 675-683
127. Margesin R., Zimmerbauer A., Schineer F. Monitoring of bioremediation by soil
biological activities. Chemosphere; 2000; 40; pp 339-346.
128. Margesin, R. and Schinner F. Efficiency of Indigenous and Inoculated cold-
adapted soil Micro-organisms for Biodegradation of Diesel Oil in Alphine soils.
Appl. Environ. Microbial; 1997; 67(7); pp 2660 – 2664.
129. Margesin.R,SchinnerF. Bioremediation (Natural Attenuation and Biostimulation)
of Diesel-Oil-contaminated soil in an Alpine Glacier Skiing Area. Applied and
Environmental Microbiology; 2001; 67; pp 3127-3133.
Page 12
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
196
130. Marin,J.A., Hernandez.T and Garcia.C. Bioremediation of oil refinery sludge by
landfarming in semiarid conditions: Influence on soil microbial activity
Environmental Research; 2005; 98; pp 185-195.
131. Marschner, B., Kalbitz, K., Controls of bioavailability and biodegradability of
dissolved organic matter in soils. Geoderma; 2003; 113; pp 211 – 235.
132. Mata-Sandoval. J.C., Kams J. and Torrente A. Effect of nutritional and
environmental conditions on the production and composition of rhamnolipids by
pseudomonas aeruginosa UG2. Microbiol. Res.; 2000; 155; pp 1 – 8.
133. Mc Gowan.C, Fulthrope.R., Wright.A., Tiedje.J.M. Evidence for interspecies gene
transfer in the evolution of 2,4-di chlorophenoxyacetic acid degraders, Appl.
Environ. Microbial; 1998; 64; pp 4089-4092.
134. Miller R.M. Surfactant enhanced bioavailability of slightly soluble organic
compounds. In: Skipper H, Turco R (eds) Bioremediation-science and application.
Soil Science Society of America, Madison, Wis; 1995; pp 3-54.
135. Morgan P., Watkinson R.J. Biodegradation of components of petroleum,
Biochemistry of Microbial degradation; 2000; pp1-31.
136. Morikawa, M.,Y.Hirata and T.Imanaka .A study on the structure-function
relationship of Lipopeptide biosurfactants. Biochem. Bio Physi. Acta; 1988; pp
211-218.
137. Mosher J.J, Levison B.S, Johnston C.G. A simplified dehydrogenase enzyme
assay in contaminated sediment using 2-(p-iodophenyl)-3(p-nitrophenyl)-5-
phenyl Tetrazolium chloride .Journal of Microbiological Methods; 2003; 53; pp
411-415.
138. Mueller J. G., Cerniglia C. E, Pritchard P. H. Bioremediation of Environments
Contaminated by Polycyclic Aromatic Hydrocarbons. Bioremediation: Principles
and Applications, Cambridge University Press, Cambridge (1996). Pp.125–194.
139. Mukred. A.M. Enhancement of biodegradation of crude petroleum oil in
contaminated water by the addition of Nitrogen sources. School of biosciences and
biotechnology; Faculty of Science and technology, University of Kebangsaan,
Malayasia; 2002.
140. Mulligan C.N, N. Yong and B.F. Gibbs .Surfactant-enhanced remediation of
contaminated soil: A review. Eng. Geol; 2005; 60; pp 371-380.
Page 13
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
197
141. Mulligan C.N, Yong R.N., Gibbs B.F. An evaluation of technologies for the heavy
metal remediation of dredged sediments. Journal of Hazardous Materials; 2001;
85(1-2); pp 145-163.
142. Nakahara.T, Hisatsuka.K and Minoda.Y. Effect of hydrocarbon emulsification on
growth and respiration of microorganisms in hydrocarbon media. J. Ferment.
Technol; 1981; 59; pp 415-418.
143. Nanny, M. A.; Ratasuk, N. Characterization and comparison of hydrophobic
neutral and hydrophobic acid dissolved organic carbon isolated from three
municipal landfill leachates. Water Res. 2002, 36, 1572–1584.
144. Naumann, D.; Schultz, C. P.; Helm, D. What can infrared spectroscopy tell us
about the structure and composition of intact bacterial cells? In Infrared
Spectroscopy of Biomolecules; Mantsch, H. H., Chapman, D., Eds.; Wiley-Liss:
New York, 1996, pp. 279–310.
145. Navon-Venezia. S Zosim Z, Gottlieb A, Legmann R, Carnell S, Ron EZ,
Rosenberg E. Alasan a new bioemulsifier from Arthrobacter radioresistens. Appl
Environ Microbiol; 1995; 61; pp 3240- 3244.
146. Nitschke, M. and Pastore, G. Cassava flour wastewater as a substrate for
biosurfactant production. Appl. Biochem. Biotechnol; 2003; 105–108; pp 295–
301.
147. Nitschke, M. and Pastore, G. Production and properties of a surfactant obtained
from Bacillus subtilis grown on cassava wastewater. Bioresource Technol.; 2006;
97; pp 336–341.
148. Nitschke, M. and Pastore, G.M. Biosurfactant production by B.subtilis using
cassava-processing effluent. Appl. Biochem. Biotechnol. 2004; 112; pp163–172.
149. Nitschke, M. Oil wastes as unconventional substrates for rhamnolipid
biosurfactant production by Pseudomonas aeruginosa LB1. Biotechnol. Prog. ;
2005; 21; pp 1562–1566.
150. Noah, K.S. Development of continuous surfactin production from potato process
effluent by Bacillus subtilis in an airlift reactor. Appl. Biochem. Biotechnology;
2002; 98–100, pp 803–813.
151. Noah, K.S. Surfactin production from potato process effluent by Bacillus subtilis
in a chemostat. Appl. Biochem. Biotechnol. 2005; 122; pp 465–474.
Page 14
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
198
152. Noordman W H and Janssen D B “Rhamnolipid Stimulates Uptake of
Hydrophobic Compounds by Pseudomonas aeruginosa”, Appl. Environ. Microbiol.
(2002), Vol. 68, pp. 4502-4508.
153. Norman RS, Frontera-Suau R, Morris PJ. Variability in Pseudomonas
aeruginosa lipopolysaccharide expression during crude oil degradation. Appl
Environ Microbial; 2002; 68; pp 5096–5103.
154. Norris R.D., Matthews J.E. hand book of Bioremediation. CRC press; 1994; pp
1-257.
155. Ochsner, U.A. et al. (1995) Production of Pseudomonas aeruginosa rhamnolipid
biosurfactants in heterologous hosts. Appl. Environ.Microbiol. 61, 3503–3506
156. Ocio.J.A, Brookes.P.C. An evaluation of methods for measuring microbial
biomass in soil following recent additions of wheat straw and the characterization
of the biomass that develops. Soil Biol. Biochem. 1990; 22; pp 685-694. 157. Otte M.P, Gagon.J, Comeau Y., Matte.N, GreerC.W, Samson.R .Activation of
an indigenous microbial consortium for bioaugmentation of
pentachlorophenol / cresote contaminated soils. Applied microbiology and
biotechnology; 1994; 40; pp 926-932.
158. Ouatmane, A.; Provenzano, M.R.; Hafidi, M.; Senesi, N. Compost maturity
assessment using calorimetry, spectroscopy and chemical analysis. Compost Sci.
Util. 2000, 8, 124–134.
159. Palmberg, C., Nordgren. A. Soil respiration curves, a method to test the
abundance, activity and vitality of the microflora in forest soil. In: Torstensson, L.
(Ed.), Guidelines. Soil biological variables in environmental hazard assessment.
Swedish Environmental Protection Agency Report 4262, Solna; 1993; pp 149–156.
160. Paris.D.F. and Wolfe, N.L. Relationship between properties of a series of anilines
and their transformation by bacteria, Appl. Environ. Microbiol; 1987; (53); pp 911-
916.
161. Park JY, Cho HJ, Yang JW. Effects of surfactant on electrokinetic remediation of
soil contaminated by phenanthrene. Taejon/Chungnam-Kyushu Fukuoka, Japan;
2000; 13; pp 267–268.
162. Pekin, G. Production of sophorolipids from Candida bombicola ATCC 22214
using Turkish corn oil and honey. Eng. LifeSci.2005; 5; pp 357–362.
163. Philp J.C. Alkanotropic Rhodococcus ruber as a biosurfactant producer. Appl.
Microbiol. Biotechnol.; 2000; 59; pp 318–324.
Page 15
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
199
164. Płaza Grazyna A, Ulfig Krzysztof, Brigmon Robin L. Surface active properties of
bacterial strains isolated from petroleum hydrocarbon-bioremediated soil. Polish
journal of microbiology; 2005; 54; 2; pp 161-167.
165. Pooja Singh, Swaranjit Singh Cameotra. Enhancement of metal bioremediation
by use of microbial surfactants, Biochemical and Biophysical Research
Communications; 2004; 319, 2; pp 291-297.
166. Powlson.D.S. Soil microbial biomass: before, beyond and back. In: Ritz, K.,
Dighton, J., Giller, K.E. (Eds.), beyond the biomass. Willey, Chichester, UK; 1993;
pp 3-20.
167. Pritchard. P.H., Costa, C. F. & Suit, L. Aslaska. Oil Spill Bioremediation Project
(Report No.EPLA/600/9.91/0.46a, b, US Envir. Protection Ag., Gulf Breeze,
Florida; 1991.
168. Radwan.S.S., Al-Hasan. R.H., Salamah.S, Al-Dabbous.S., Bioremediation of oily
sea water by bacteria immobilised in biofilms coating macroalgae. International
Biodeterioration & Biodegradation.2002; 50, pp 55–59.
169. Rahaman K.S.M, Rahaman T.J; Banat I.M, Lord.R and Street.G. Bioremediation
of petroleum sludge using bacterial consortium with Biosurfactant. Environmental
Bioremediation Technologies; 2007; 10.1007/9783-540-34793-4-17; pp 391-408.
170. Rahman K. S. M, Banat I. M., J. Thahira, Tha. Thayumanavan,
P.Lakshmanaperumalsamy. Bioremediation of gasoline contaminated soil by a
bacterial consortium amended with poultry litter, coir pith and rhamnolipid
biosurfactant, Bioresource Technology; 2002; 81; 1; pp 25-32.
171. Rahman K. S. M, Thahira J. Rahman, Y. Kourkoutas, I. Petsas, R. Marchant, I.
M. Banat . Enhanced bioremediation of n-alkane in petroleum sludge using
bacterial consortium amended with rhamnolipid and micronutrients ; Bioresource
Technology; 2003; 90; 2, pp 159-168.
172. Rahman. K S M, Rahman T J, McClean S, Marchant R and Banat I M.
Rhamnolipid Biosurfactant Production by Strains of Pseudomonas aeruginosa
Using Low-Cost Raw Materials. Biotechnol. Prog; 2002; 18; pp 1277-1281.
173. Rahman. K.S.M., I.M. Banat, J. Thahira-Rahman, T. Thayumanavan and
P.Lakshmanaperumalsamy .Bioremediation of gasoline contaminated Soil by a
bacterial consortium amended with poultry litter, coir pith and rhamnolipid
biosurfactant. Biores. Technol; 2002a; 81; pp 25-32.
Page 16
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
200
174. Ramana, K.V., and N.G. Karanth. Production of biosurfactants by the resting
cells of Pseudomonas aeruginosa CFTR-6. Biotechnol. Lett; 1989; 11; pp 437–442.
175. Ramana. K.V., and N.G. Karanth. Factors affecting biosurfactants production
using Pseudomonas aeruginosa CFTR-6 under submerged conditions. J. Chem.
Technol. Biotechnol; 1989; 45; pp 249–257.
176. Reiling, H.E. Pilot plant production of rhamnolipid biosurfactant by
Pseudomonas aeruginosa. Appl. Environ. Microbiol; 1986; 51; pp 985–989.
177. Robert, M., Mercad´e, M.E., Bosch, P., Parra, J.L., Espuny, M.J., Manresa,M.A.,
Guinea, J.,. Effect of the carbon source on biosurfactant production by
Pseudomonas aeruginosa 44T1. 1989 Biotechnol. Lett. 11, 871–874.
178. Rodrigo J.S. Jacques, Benedict C. Okeke, Fatima M. Bento, Aline S. Teixeira,
Maria C.R. Peralba, Flavio A.O. Camargo, Microbial consortium bioaugmentation
of a polycyclic aromatic hydrocarbons contaminated soil, Bioresource Technology;
2008; 99; 7; pp 2637-2643.
179. Romantschuk. M., Sarand.I., Petanen.T.,Peltola. Means to improve the effect of
insitu bioremediation of contaminated soil: An overview of novel approaches,
Environmental pollution; 2000; 107; pp 2179-185.
180. Ronald R.Navarro, Yoruke limura, Hiroyasu Lchikawa Kenji Tatsumi.treatment
of PAHs in contaminated soil by extraction with aqueous DNA followed by
biodegradation with a pure culture of Sphingomonas Sp. Chemosphere; 2008; 73;
9; 1414-1419.
181. purchase this article.
182. Rosenberg E, Barkay T, Navon-Venezia S, Ron EZ. Role of Acinetobacter
bioemulsans in petroleum degradation. In Novel Approaches for Bioremediation of
Organic Pollution. Edited by Fass R. New York: Kluwer Academic/Plenum
Publishers; 1999; pp171-180.
183. Rosenberg E, Rubinovitz A, Gottlieb A, Rosenhak S, Ron E . Production of
biodispersan by Acientobacter calcoaceticus A2. Appl Environ Microbiol; 1988; 54;
pp 317-322.
184. Rosenberg. E; Microbial surfactants. CRC crit rev. Biotech; 1986; 3; pp 105-132.
185. Ryan.J.R., Loehr.R.C and Rucker.E. Bioremediation of organic contaminated
soils. J. Hazard. Materials; 1991; 28; pp 159-169.
Page 17
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
201
186. Saleha Husain. Identification of pyrene-degradation pathways; Bench-scale
studies using Pseudomonas fluorescens 29L, Remediation Journal; 2008; 18; 3; pp 119 – 142.
187. Sánchez M.Aggregation behaviour of a dirhamnolipid biosurfactant secreted by
Pseudomonas aeruginosa in aqueous media. Journal of Colloid and Interface
Science; 2007; 307; pp 246–253.
188. Santos EC, Jacques. RJS, FM Bento, MDR Peralba, PA Selbach, ELS Sa, FAO
Camargo. Anthracene biodegradation and surface activity by an iron-stimulated
Pseudomonas sp, Bioresource Technology; 2008; 99; 7; pp 2644-2649.
189. Saulnier .I, Mucci A. Trace metal remobilization following the resuspension of
estuarine sediments. Saguenay Fjord, Canada. Appl Geochem; 2000; 15; pp 191–
210.
190. Schreier C.G., Walker W.J., Burns J., Wilkenfield R; Total organic carbon as a
screening method for petroleum hydro carbons. Chemosphere; 1999; 39; pp 503-
510.
191. Schulz. D, Passeri A, Schmidt M, Lang S, Wagner F, Wray V, Gunkel W. Crude-
oil degrading marine microorganisms from the North-Sea. J Biosci; 1991; 46; pp
197-203.
192. Semprini .L., Roberts, PV. Hoplins G.D and Mc Carty, P.L. A field evaluation of
insitu biodegradation of chlorinated ethanes, part 2. Results of biostimulation and
biotransformation experiments. Ground Water; 1990; 28; pp 715-727.
193. Siddhartha G.V.A.O. Costa , Marcia Nitschke, Renato Haddad, Marcos N.
Eberlin , Jonas Contiero . Production of Pseudomonas aeruginosa LBI
rhamnolipids following growth on Brazilian native oils Process Biochemistry 41
(2006) pp 483–488.
194. Sifour, M.; Al-Jilawi, M.H.; Aziz, G.M. Emulsification properties of biosurfactant
produced from Pseudomonas aeruginosa RB 28. Pak. J. Biol. Sci. 2007, 10, 1331–
1335
195. Sims.J.R., Haby,V.A. Simplified colorimetric determination of soil organic
matter. Soil Sciences; 1971; 112; pp 137-141.
196. Smidt, E.; Lechner, P.; Schwanninger, M.; Haberhauer, G.; Gerzabek, M.H.
Characterization of waste organic matter by FT-IR spectroscopy—application in
waste science. Appl. Spectrosc. 2002, 56, pp 1170–1175.
Page 18
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
202
197. Smidt, E; Schwanninger, M; Characterization of Waste Materials Using FTIR
Spectroscopy: Process monitoring and Quality assessment; Spectroscopy Letters,
2005, 38; pp 247-270.
198. Smith, B. Infrared Spectral Interpretation; CRC Press: Boca Raton, FL, 1999; pp
264.
199. Socrates, G. Infrared and Raman Characteristic Group Frequencies. Tables and
Charts, 3rd edition; John Wiley & Sons Ltd.: Chichester, 2001; pp 347.
200. Song H.G., Bartha R. Effect of jet fuel on the microbial community of soil
.Appl.Environ .Microbiol; 1990; 56; pp 646-651.
201. Steinberg S.M., Poziomek E.J., Engelmann W.H., and Rogers, K.R. A review of
environmental applications of bioluminescence measurements, Chemosphere,
1995; 30; pp 21-55.
202. Sturm. T W, Amritharajh A, Tiller CL. Mobilization and fate of inorganic
contaminants due to resuspension of cohesive sediment. 2002.
203. Swaranjit Singh Cameotra, Pooja Singh. Bioremediation of oil sludge using
crude biosurfactants. International Biodeterioration & Biodegradation; October
2008; 62; 3; pp 274-280.
204. Tang. Y, Qi JL, Krieger-Brockett B.Evaluating factors that influence microbial
phenanthrene biodegradation rates by regression with categorical variables;
Chemosphere; 2005; 59; pp 729–741.
205. Thibault. SL, Anderson M, Frankenberger WT Jr. Influence of surfactants on
pyrene desorption and degradation in soils. Appl Environ Microbiol; 1996; 62; pp
283-287.
206. Thompson. D.N. Biosurfactants from potato process effluents. Appl. Biochem.
Biotechnol.; 2000; 84–86; pp 917–930.
207. Thompson. D.N. The effects of pretreatments on surfactin production from
potato process effluent by Bacillus subtilis. Appl. Biochem. Biotechnol; 2001; 91–
93; pp 487–502.
208. Timmis. K.N, Pieper DH. Bacteria designed for bioremediation. Trends
Biotechnol. 1999; 20; pp14-17.
209. Trummler. K. An integrated microbial/enzymatic process for production of
rhamnolipids andl-(+)-rhamnose from rapeseed oil with Pseudomonas sp. DSM
2874. Eur. J. Lipid. Sci. Tech.; 2003; 105; pp 563–571.
Page 19
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
203
210. Tseng, D.Y.; Vir, R.; Traina, S.J.; Chalmers, J.J. A Fourier-transform infrared
spectroscopic analysis of organic matter degradation in a bench-scale solid
substrate fermentation (composting) system. Biotechnol. Bioeng. 1996, 52, pp
661–671.
211. Tsomides. H.J, Hughes J.B, Thomas J.M, and Ward C.H. Effect of surfactant
addition on phenanthrene biodegradation in sediments, Environ. Toxicol. Chem;
1995; 14; pp 953-959.
212. Tuleva. B.K., G.R. Ivanov and N.E. Christova; Biosurfactant production by a new
Pseudomonas putida strain. Z Naturforsch.C; 2002; 57; pp 356-360.
213. Urum. K., T. Pekdemir and M. Gopur. Optimum conditions for washing of crude
oil-contaminated soil with biosurfactant solutions. Process Saf. Environ; 2003; 81;
pp 203-209.
214. Van Dyke, M. I., P. Couture, M. Brauer, H. Lee, and J. T. Trevors.
1993.Pseudomonas aeruginosa UG2 rhamnolipid biosurfactants: structural
characterization and their use in removing hydrophobic compounds from soil.Can.
J. Microbiol. 39:1071–1078.
215. Van Limbergen H, Top EM, Verstraete W .Bioaugmentation in activated sludge:
current features and future perspectives. Appl Microbiol Biotechnol; 1998; 50;
pp16–23.
216. Vance-Harrop, M.H. New bioemulsifiers produced by Candida lipolytica using D-
Glucose and Babassu oil as carbon sources. Braz. J. Microbiol.; 2003; 34; pp
120–123.
217. Vasilyeva G.K., and Strijakova E.R. Bioremediation of Soils and Sediments
Contaminated by Polychlorinated Biphenyls. Microbiology; 2007; 76; 6; pp 639–
653.
218. Vega D.M., Gallego J.L.R., Pelaez A.I., de Cordoba G.F., Moreno J., Munoz D.,
Sanchez J; Surface sediments from a contaminated bay of northern china. Res;
2007; 18; pp 299-306.
219. Verlag Chemie, Deerfield Beach, Fla. Kosaric, N., H.Y. Choi, and R. Bhaszczyk.
Biosurfactant production from Nocardia SFC-D. Tenside Surf. Det; 1990; 27; pp
294–297.
Page 20
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
204
220. Vipulanandan.C., Ren X. Enhanced solubility and biodegradation of napthalene
with biosurfactant .Journal of Environmental Engineering; 2000; 126; pp 629-
634. 221. Walworth J., Pond A., Snape I., Rayner J., Ferguson S., Harvey P.
Nitrogen requirements for maximising petroleum bioremediation in a Sub-
Antarctic soil. Cold regions Science and Technology; 2007; 48; pp 84-91.
222. Whang, L.M.; Liu, P.W.G.; Ma, C.C.; Cheng, S.S. Application of biosurfactant,
rhamnolipid, and surfactin, for enhanced biodegradation of diesel-contaminated
water and soil. J. Hazard. Mater. 2008, 151, 155–163.
223. Wikipedia; Infrared Spectroscopy correlation table.
224. Wilkinson S.G., and L. Galbraith. Studies on lipopolysaccharides from
Pseudomonas aeruginosa. Eur. J. Biochem; 1975; 52; pp 331–343.
225. Williams and Wilkins, Baltimore. Bergey’s Manual of Determinative Bacteriology;
1994; 9th ed.
226. Willson, J.T. and Willson B.H. Biotransformation of trichloroethylene in soil.
Appl. Environ. Microbiology1985; 49; pp 242-243.
227. Willson,J.T., Leach,L.E., Henson.M. and Jones, J.N. Insitu biorestoration as a
ground water remediation technique. Ground water Mon. Rev; 1986; 1; pp 56-64.
228. Wrabel, M.L., Peckol, P.,. Effects of bioremediation on toxicity and chemical
composition of no. 2 fuel oil: growth responses of the brown alga Fucus
vesiculosus. Marine Pollution. 2000; 40; pp 135-139.
229. Wu Jane-Yii, Yeh Kuei-Ling, Lu Wei-Bin, Lin Chung-Liang and Chang Jo-Shu.
Rhamnolipid Production with Indigenous Pseudomonas aeruginosa EM1 Isolated
from Oil-Contaminated Site. Bioresource Technology; 2008; 99; 5; pp 1157-1164.
230. Yoemans, J.C., Bremner, J.M. A rapid and precise method for routine
determination of organic carbon in soil. Communication in Soil Science and Plant
analysis; 1989; 19; pp 1467-1476.
231. Yu-Hong Wei, Chien-Liang Chou, Jo-Shu Chang, Wei Y H, Chou C L and Chang
J S. Rhamnolipid Production by Indigenous Pseudomonas aeruginosa sJ4
Originating from Petrochemical Wastewater. Biochemical Engineering Journal;
2005; 27, pp 146-154.
232. Zaccheo, P.; Ricca, G.; Crippa, L. Organic matter characterization of composts
from different feedstocks. Compost Sci. Util. 2002, 10 (1), 29–38.
Page 21
Ch. Rajani Kumari, Ph.D., Thesis 2010 References
205
233. Zagula. S.J, E.W. Beltinger. Developing a remediation strategy for contaminated
sediments: selecting, removal, treatment, disposal and re-use alternatives; in:
Proceedings of the 48th Purdue Industrial Waste Conference, Lewis Publishers,
Chelsea, MI, 1993; pp 199–213.
234. Zak,J., Willig, M.R., Moorhead ,D.L., Wildman, H.G .Functional diversity of
microbial communities : a quantitative approach .Soil Biol .Biochem ; 1994; 26;
pp 1101-1108.
235. Zdenek Filip, Susanne Hermann. An attempt to differentiate Pseudomonas
species and other soil bacteria by FT-IR spectroscopy Eur. J. Soil. Biol; 2001; 37;
pp 137 – 143.
236. Zhang .Y, Wu RSS, Hong H-S, Poon K-F, Lam MHW. Field study on the
desorption rates of polynuclear aromatic hydrocarbons from contaminated marine
sediment Environ Toxicol Chem; 2000; 19(10):5; pp 24-31.
237. Zhang. Y, Miller RM; Effect of rhamnolipid (biosurfactant) structure on
Solubilization and biodegradation of n-alkanes. Appl Environ Microbiol; 1995; 61;
pp 2247-2251.
238. Zhang. Y., Miller, R.M., Enhanced octadecane dispersion and biodegradation by
a Pseudomonas rhamnolipid surfactant. Appl. Environ. Microbiol; 1992; 58; pp
3276–3281.
239. Zhao .B, Zhu L, Li W, Chen B; Solubilization and biodegradation of
phenanthrene in mixed anionic–nonionic surfactant solutions; Chemosphere;
2005; 58; pp 33–40.
240. Zhu. L, Chen B. Interactions of organic contaminants with mineral-adsorbed
surfactants. Environ Sci Technol; 2003; 37; pp 4001–4006.
241. Zhuang. Y, Allen HE, Fu G. Effect of aeration of sediment on cadmium binding.
Environ Toxicol Chem; 1994; 13(5):7; pp17– 24.
242. Zoumis .T, Schmidt .A, Grigorova .L, Calmano .W. Contaminants in sediments:
remobilisation and demobilisation. Sci Total Environ; 2001; 266; pp 195– 202.
243. Zukerberg A., A. Diver, Z. Peeri, D. L. Gutnick, and E. Rosenberg. Emulsifier of
Arthrobacter RAG-1: chemical and physical properties. Appl. Environ. Microbiol;
1979; 37; pp 414–420.