Environmental and Agricultural Microbiology. Группа авторов. Читать онлайн. Newlib. NEWLIB.NET

Автор: Группа авторов
Издательство: John Wiley & Sons Limited
Серия:
Жанр произведения: Здоровье
Год издания: 0
isbn: 9781119526742
Скачать книгу
publisher, Hauppauge, New York, US, 2014.

      69. Sand, W. and Gehrke, T., Extracellular polymeric substances mediate bioleaching/ biocorrosion via interfacial processes involving iron (III) ions and acidophilic bacteria. Res. Microbiol., 157, 49, 2006.

      70. Schippers, A. and Sand, W., Bacterial leaching of metal sulfides proceeds by two indirect mechanisms via thiosulfate or via polysulfides and sulfur. Appl. Environ. Microbiol., 65, 319, 1999.

      71. Ike, M., Yamashita, M., Kuroda, M., Microbial Removal and Recovery of Metals from Wastewater, in: Applied Bioengineering: Innovations and Future Directions, T. Yoshida (Ed.), pp. 573–595, Wiley Publisher, Weinheim, Germany, 2017.

      72. Liu, S., Zhang, F., Chen, J., Sun, G., Arsenic removal from contaminated soil via biovolatilization by genetically engineered bacteria under laboratory conditions. J. Environ. Sci., 23, 1544, 2011.

      73. Pepi, M., Gaggi, C., Bernardini, E., Focardi, S., Lobianco, A., Ruta, M., Nicolardi, V., Volterrani, M., Gasperini, S., Trinchera, G., Renzi, P., Gabellini, M., Focardi, S.E., Mercury-resistant bacterial strains Pseudomonas and Psychrobacter spp. isolated from sediments of Orbetello Lagoon (Italy) and their possible use in bioremediation processes. Int. Biodeter. Biodegr., 65, 85, 2011.

      74. Żur, J., Wojcieszyńska, D., Guzik, U., Metabolic Responses of Bacterial Cells to Immobilization. Molecules, 21, 958, 2016.

      75. Gadd, G.M., Bioremedial potential of microbial mechanisms of metal mobilization and immobilization. Curr. Opin. Biotechnol., 11, 271, 2000.

      76. Raspor, P., Batič, M., Jamnik, P., Josić, D., Milačič, R., Paš, M., Recek, M., Režić-Dereani, V., Skrt, M., The influence of chromium compounds on yeast physiology: (A review). Acta Microbiol. Immunol. Hung., 47, 143, 2000.

      78. Lee, J.H., Kim, M.G., Yoo, B., Myung, N.V., Maeng, J., Lee, T., Dohnalkova, A.C., Fredrickson, J.K., Sadowsky, M.J., Hur, H.G., Biogenic formation of photoactive arsenic-sulfide nanotubes by Shewanella sp. strain HN-41. PNAS, 104, 20410, 2007.

      1 * Corresponding author: [email protected]

      4

      Microbial-Derived Polymers and Their Degradability Behavior for Future Prospects

       Mohammad Asif Ali1,2*†, Aniruddha Nag1,3† and Maninder Singh1†

       1Graduate School of Advanced Science and Technology, Energy and Environment Area, Japan Advanced Institute of Science and Technology, Nomi, Ishikawa, Japan

       2Soft Matter Sciences and Engineering Laboratory, ESPCI Paris, PSL University, CNRS, Paris, France

       3School of Energy Science and Engineering, Vidyasirimedhi Institute of Science and Technology (VISTEC), Payupnai, Wangchan, Rayong, Thailand

       Abstract

      This chapter will focus on the development of bio-based polymers such as polyamides (PA), polylactide (PLA), and polyhydroxyalkanoates (PHAs) produced from renewable resources. NylonTM plastic is a kind of PA is a long chain fiber-forming recalcitrant and biodegradable and degradable polymer with diverse applications. Polylactic acid (PLA) is biodegradable aliphatic polyester derived from a naturally occurring organic acid (lactic acid). On the other hand, PHAs are the high molecular weight biodegradable polyesters synthesized by a wide array of microbes. However, they have an undesirable influence on the environment and substantially impact waste deposition and utilization. This chapter will emphasize the application and microbial degradability of these three kinds (PLA, PHA, and PA) of plastics.

      Keywords: Degradation, polyamides microbes, polylactide, polyhydroxyalkanoates

      1 1. Thermal degradation

      2 2. Photo-oxidative degradation

      3 3. Hydrolytic degradation

      4 4. Mechanochemical degradation

      5 5. Soil degradation

      6 6. Biodegradation

       - Color changes

       - Scission of the backbone

       - Modification of one or more end-groups

       - Disruption of a side chain

       - Mechanical

       - Photo/thermal

       - Chemical

       - Cracking and charring (weight loss)

       - The effect of light, heat, air, and moisture reflects the polymer structure.

      Biodegradation can be defined as the breaking down material when exposed to microbes such as bacteria, fungi, actinobacteria, or other biological means anaerobically or aerobically [2]. Moreover, polymers biodegradation is possible by different enzymatic and non-enzymatic hydrolysis without thermal oxidation, radiolysis, or photolysis [3]. Alternatives to the existing fossil fuel and other non-renewable sources are the prime focus of today now. This chapter describes the broad spectrum of bioavailability, biosynthesis and biodegradability of PA, PLA, and PHAs.