The pulp and paper mill generates b

The pulp and paper mill generates black effluent with very high biological oxygen demand (BOD), chemical oxygen demand (COD), toxic substances, recalcitrant organics, turbidity and high temperature. The colouring body present in the wastewater from pulp and paper mill is organic in nature and is comprised of wood extractives, tannin resins, synthetic dyes, lignin and its degradation products formed by the action of chlorine on lignin. The untreated effluents from pulp and paper mills discharged into water bodies, damages the water quality and brown colour imparted to water due to addition of effluents is detectable over long distances. The dark brown colour is due to the formation of lignin degradation products during the processing of lignocellulosics from paper and pulp manufacture. The undiluted effluents are toxic to aquatic organisms and exhibit a strong mutagenic effect. Furthermore some compounds in the effluents are resistant to biodegradation and can bioaccumulate in the aquatic food chain (Pokhrel & Viraraghavan, 2004). Several methods have been attempted for the removal of colour from the pulp and paper mill effluents. These can be classified into physical, chemical and biological methods. Physical and chemical processes are quite expensive and remove high molecular weight chlorinated lignins, colour, toxicants, suspended solids and chemical oxygen demand. But BOD and low molecular weight compound are not removed efficiently (Singh & Singh, 2004). The use of chlorine based chemicals in the bleaching process generates chlorophenol compounds which are completely resistant to microbial attack and remain as recalcitrant (Ghoreishi & Haghighi, 2007). The pollution load in terms of biological oxygen demand (BOD) from small paper mills is 2.5 times higher than that of large paper mills, which employ the soda recovery. Biological methods of the effluent treatment have the advantage of being cost effective and in addition to colour removal, they can also reduce both the BOD and COD of waste water (Christov & Driessel, 2003). Heavy metal removal by yeast from PPME has been achieved by (Thippeswamy et al. 2012). Multi-metal tolerant yeast with high concentration gradient of Cu, Zn, Ni, Cr, Cd and Pb was isolated. Result showed high Cd (52%) accumulation followed by Pb (45%), Ni (43%), Cr (41%), Zn (38%) and Cu (37%) in paper effluent treated with Saccharomyces sp.