Biomedical Engineering Reference
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Kaeriyama, H., Katsuki, E., Otsubo, M., Yamada, M., Ichimi, K., Tada, K., and Harrison, P.J.
(2011). Effects of temperature and irradiance on growth of strains belonging to seven
Skeletonema
species isolated from Dokai Bay, southern Japan
. European Journal of
Phycology,
46: 113-124.
Kanellos, M. (2009). Algae Biodiesel: It's $33 a Gallon. Greentech Media. [Online] Greentech
Media, 03 02 2009. [Cited: 10 12 2009.] http://www.greentechmedia.com/articles/
algae-biodiesel-its-33-a-gallon-5.
Kebede-Westhead, E., Pizarro, C., and Mulbry, W.W. (2006). Treatment of swine manure
effluent using freshwater algae; Production, nutrient recovery, and elemental compo-
sition of algal biomass at four effluent loading rates.
Journal of Applied Phycology,
18: 41-46.
Keerthi, S., Uma Devi, K., Subba Rao, D.V., Sarma, N.S. (in press). Exogenous vitamin depen-
dency in two carotenogenic
Dunaliella
strains isolated from coastal Bay of Bengal.
Khan, S.A., Hussain, M.Z., Prasad, S., and Banerjee, U.C. (2009). Prospects of biodiesel
production from microalgae in India. New Delhi. India 2009.
Renewable and Sustainable
Energy Reviews,
13: 2361-2372.
Khozin-Goldberg, I., and Cohen, Z. (2006). The effect of phosphate starvation on the lipid
and fatty acid composition of the freshwater eustigmatophyte
Monodus subterraneus
.
Phytochemistry,
67: 696-701.
Kleinegris, D.M.M., Janssen, M., Brandenburg, W.A., and Wiiffels, R.H. (2011). Two-phase
systems: Potential for in situ extraction of microalgal products.
Biotechnology Advances
,
29: 502-507.
Kong, Q.X., Li, L., Martinez, B., Chen, P., and Ruan, R. (2010). Culture of microalgae
Chlamydomonas reinhardtii
in wastewater for biomass feedstock production.
Applied
Biochemistry and Biotechnology
, 160: 9-18.
Lebeau, T., and Robert, R.M. (2006). Biotechnology of immobilized microalgae. A culture
technique for future? In
Algal Cultures, Analogues of Blooms and Applications
(Ed. Subba Rao, D.V.), Science Publishers, Enfield, NH, pp. 801-839.
Lee, Y.K., Ding, S.Y., Hoe, C.H., and Low, C.S. (1996). Mixotrophic growth of
Chlorella soro-
kiniana
in outdoor enclosed photobioreactor.
Journal of Applied Phycology,
8: 163-169.
León, R., and Fernández, E. (2007). Nuclear transformation of eukaryotic microalgae.
In
Transgenic Microalgae as Green Cell Factories
(Eds. Leon, R., Galvan, A., and
Fernandez, E.). Landes Bioscience and Springer Science+ Business Media, New York,
pp. 1-11.
Li, S., and Tsai, H. (2008). Transgenic microalgae as a non-antibiotic bactericide producer to
defend against bacterial pathogen infection in the fish digestive tract.
Fish & Shellfish
Immunology,
26: 316-325.
Li, Y., Horsman, M., Wang, B., Wu, N., and Lan, C.Q. (2008). Effects of nitrogen sources on
cell growth and lipid accumulation of green alga
Neochloris oleoabundans
.
Applied
Microbiology and Biotechnology,
81: 629-636.
Li, H., Xu, H., and Wu, Q. (2007). Large-scale biodiesel production from microalga
Chlorella
protothecoides
through heterotrophic cultivation in bioreactors.
Biotechnology and
Bioengineering,
98: 764-771.
Liu, Z.Y., Wang, G.C., and Zhou, B.C. (2008). Effect of iron on growth and lipid accumulation
in
Chlorella vulgaris
.
Bioresource Technology,
99: 4717-4722.
Major, K.M., and Henley, W. (2008). Influence of salinity and temperature on growth and
photosynthesis in the extremophilic chlorophyte,
Nannochloris
sp.
Journal of Phycology,
37: 32.
Malcata, F.X. (2010). Microalgae and biofuels: A promising partnership?
Trends in
Biotechnology,
29: 542-559.
Mandal, S., and Mallick, N. (2009). Microalga
Scenedesmus obliquus
as a potential source for
biodiesel production.
Applied Microbiology and Biotechnology,
84: 281-291.
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