Biotechnology for Zero Waste – Emerging Waste Management Techniques (Chaudhery Mustansar Hussain (editor) etc.)

438

28 Bioconversion of Food Waste to Wealth – Circular Bioeconomy Approach

43 Tang, J., Wang, X., Hu, Y. et al. (2016). Lactic acid fermentation from food waste

with indigenous microbiota: effects of pH, temperature and high OLR. Waste

Management 52: 278–285.

44 Li, J., Zhang, W., Li, X. et al. (2018). Production of lactic acid from thermal pre-

treated food waste through the fermentation of waste activated sludge: effects

of substrate and thermal pretreatment temperature. Bioresource Technology 247:

890–896.

45 Cecilia, J.A., García-Sancho, C., Maireles-Torres, P.J., and Luque, R. (2019).

Industrial food waste valorization: a general overview. In: Biorefinery: Integrated

Sustainable Processes for Biomass Conversion to Biomaterials, Biofuels, and Fertil-

izers (eds. J.-R. Bastidas-Oyanedel and J.E. Schmidt), 253–277. Cham: Springer

International Publishing.

46 Andler, S.M. and Goddard, J.M. (2018). Transforming food waste: how immobi-

lized enzymes can valorize waste streams into revenue streams. NPJ Science of

Food 2 (1): 19.

47 Jinno, C., He, Y., Morash, D. et al. (2018). Enzymatic digestion turns food waste

into feed for growing pigs. Animal Feed Science and Technology 242: 48–58.

48 Wang, Y., Yang, Z., Qin, P., and Tan, T. (2014). Fermentative l-(+)-lactic acid

production from defatted rice bran. RSC Advances 4 (17): 8907–8913.

49 Jin, Y., Chen, T., Chen, X., and Yu, Z. (2015). Life-cycle assessment of energy

consumption and environmental impact of an integrated food waste-based

biogas plant. Applied Energy 151: 227–236.

50 Zou, L., Wan, Y., Zhang, S. et al. (2020). Valorization of food waste to multiple

bio-energies based on enzymatic pretreatment: a critical review and blueprint

for the future. Journal of Cleaner Production 277: 124091.

51 Yin, Y., Liu, Y.-J., Meng, S.-J. et al. (2016). Enzymatic pretreatment of activated

sludge, food waste and their mixture for enhanced bioenergy recovery and waste

volume reduction via anaerobic digestion. Applied Energy 179: 1131–1137.

52 Taheri, M.E., Salimi, E., Saragas, K. et al. (2020). Effect of pretreatment

techniques on enzymatic hydrolysis of food waste. Biomass Conversion and

Biorefinery 11: 219–226.

53 Pandey, P., Lejeune, M., Biswas, S. et al. (2016). A new method for convert-

ing foodwaste into pathogen free soil amendment for enhancing agricultural

sustainability. Journal of Cleaner Production 112: 205–213.

54 Bilal, M. and Iqbal, H.M.N. (2019). Sustainable bioconversion of food waste into

high-value products by immobilized enzymes to meet bio-economy challenges

and opportunities – a review. Food Research International 123: 226–240.

55 Cao, L. (2011). Immobilized enzymes. In: Comprehensive Biotechnology, 2e (ed.

M. Moo-Young), 461–476. Burlington: Academic Press.