PDF(551 KB)
Fate of proteins of waste activated sludge during thermal alkali pretreatment in terms of sludge protein recovery
Xiaoli Song, Zhenghua Shi, Xiufen Li, Xinhua Wang, Yueping Ren
PDF(551 KB)
PDF(551 KB)
Fate of proteins of waste activated sludge during thermal alkali pretreatment in terms of sludge protein recovery
Maillard reaction between reducing sugars and amides happened during pretreatment.
Over 90 min of TAH at the optimal condition, 67.59% sludge proteins was solubilized.
15.84% soluble proteins broke down to materials with small molecular weight.
Proteins are the major organic component s of waste activated sludge (WAS); the recovery of sludge proteins is economically valuable. To efficiently recover sludge proteins, WAS should undergo hydrolysis pretreatment to fully release proteins from sludge flocs and microbial cells into aqueous phase. One of the most widely used chemical methods for that is thermal alkali hydrolysis (TAH). Here, the soluble protein concentration achieved the highest level over 90 min of TAH pretreatment at 80°C; the sludge floc disintegration and microbial cell destruction were maximized according to the content profiles of bound extracellular polymeric substance (EPS) and ribonucleic acid (RNA) of sludge. Both less proteins broken down to materials with small molecular weight and less melanoidin generated were responsible. TAH pretreatment at 80°C for 90 min resulted in the solubilization of 67.59% of sludge proteins. 34.64% of solubilized proteins was present in soluble high molecular; 1.55% and 4.85% broke down to polypeptides and amino acids. The lost proteins via being converted to ammonium and nitrate nitrogen accounted for 9.44% of solubilized proteins. It was important to understand the fate of sludge proteins during TAH pretreatment in terms of protein recovery, which would be helpful for designing the downstream protein separation method and its potential application.
Sludge flocs / Microbial cells / Hydrolysate / Protein breakdown / Melanoidin
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