Agriculture Reference
In-Depth Information
R
EFERENCES
[1] Harland, J. I., Jones, C.K., & Huffors, C. (2006). Co-products. In A.P. Draycott (Ed.),
Sugar Beet
(1
st
edition, pp. 443-465). Oxford, UK: Blackwell Publishing Ltd.
[2] Čobić, T., Kasapović, S., Antov, G., & Krajinović, M. (1994).
Sugar Beet By-Products
in Feeding of Ruminants
(in Serbian, 1
st
edition). Novi Sad, Serbia: University of Novi
Sad, Faculty og Agriculture.
[3] Kelly, P. (1983). Sugar beet pulp - a review.
Animal Feed Science and Technology
, 8,
1-18.
[4] Dinand, E., Chanzy, H., & Wrignon, M.R. (1996). Parenchymal cell cellulose from
sugar beet pulp: preparation and properties.
Cellulose,
3, 183-188.
[5] Mary, M., McCann, M.C. Kolpak, F., White, A.R., Stacey, N.J, & Roberts, K. (2000).
Extraction of pectic polysaccharides from sugar beet cell walls.
Journal of the Science of
Food and Agriculture,
80, 17-28.
[6] Thibault, J.F., Renard, C.M.G.C., & Guillon, F. (2001). Production, composition,
physicochemical properties, physiological effects, safety and food application. In S.S.
Cho, & M.L. Dreher (Eds.)
Handbook of Dietary Fiber
(1
st
edition, pp. 553-582). New
York and Basel: Marcel Dekker.
[7] Zheng, Y., Yu, C., Cheng, Y.S., Zhang, R., Jenkins, B., & VanderGheynst, J.S. (2011).
Effects of ensilage on storage and enzymatic digestibility of sugar beet pulp.
Bioresource Technology,
102, 1489-1495.
[8] Xue, M., Liu, D., Zhang, H, Qi, H., & Lei, Z. (1992) A pilot process of solid state
fermentation from sugar beet pult for the production of microbial proteins.
Journal of
Fermentation and Bioengineering,
73, 203-205.
[9] Spagnuolo, M., Pizzigallo, M.D.R., & Ruggiero, P. (1997). Synergistic effects of
cellulolytic and pectinolytic enzymes in degrading sugar beet pulp.
Bioresource
Technology,
60, 215-222.
[10] Zheng, Y., Yu, C., Cheng, Y.S., Zhang, R., Jenkins, B., & VanderGheynst, J.S. (2013).
Improving the efficiency of enzyme utilization for sugar beet pulp hydrolysis.
Bioprocess and Biosystem Engineering,
35, 1531-1539.
[11] Kuhnel, S., Schols, H.A., & Gruppen, H. (2011). Aiming for the complete utilization of
of sugar beet pulp: Examination of the effects of mild acid and hydrothermal
pretreatment followed by enzymatic digestion.
Biotechnology for Biofuels,
4, 14.
[12] Edwards, M.C., & Doran-Petersen, j. (2012). Pectin-rich biomass as feedstock for fuel
ethanol production.
Applied Microbiology and Biotechnology,
95, 565-575.
[13] Vandamme, E,J. (2009). Agro-industrial residue utilization for industrial biotechnology
products. In : P.S. Nigam, & A. Pandey (Eds.),
Biotechnology for Agro-Industrial
Residue Utilization (
1
st
edition, pp. 3-12). Springer Science+Business Media B.V.
[14] Ugwuanyi, J.O., McNeil, B., & Harvey, L.M. (2009). Production of protein enriched
food using agro-industrial residue as substrates. In: P.S. Nigam, & A. Pandey (Eds.),
Biotechnology for Agro-Industrial Residue Utilization
(1
st
edition, pp. 77-104). Springer
Science+Business Media B.V.
[15] Peričin, D.M., Antov, M.G., & Popov, S.D. (1998-1999). Simultaneous production of
biomass and pectinases by
Polyporus squamosus
.
Acta Periodica Technologica,
29-30,
183-189.