TY - JOUR
T1 - Resource recovery through bioremediation of fuel-synthesis wastewater in a biofilm photobioreactor using purple non-sulfur bacteria
T2 - A circular bioeconomy approach
AU - Shaikh, Sultan
AU - Rashid, Naim
AU - McKay, Gordon
AU - Mackey, Hamish Robert
N1 - Publisher Copyright:
© 2024 The Authors
PY - 2024/8/15
Y1 - 2024/8/15
N2 - In the current era of wastewater treatment, integrating reusable water production with resource recovery is a key goal. This study aims to treat fuel-synthesis wastewater (FSW), intending to recover various resources, including polyhydroxybutyrate (PHBs), single cell protein, bacteriochlorophylls, carotenoids, and coenzyme Q10 from suspended and biofilm growth to decrease the harvesting costs. The study considered the treatment process, biofilm growth, and resource recovery potential in a mixed-culture system enriched with purple non-sulfur bacteria for treating FSW. Specifically, the effects of four different FSW strengths (25–100 %) and nitrogen sufficiency (N+) or deficiency (N−) were evaluated in eight biofilm photobioreactors. This study observed a direct correlation between the concentration of FSW and PHB content; specifically, as the FSW content decreased from 100 % (undiluted) to 25 % the PHB content decreased. The undiluted condition achieved 17 % dry cell weight as PHB in the suspended growth and 22.6 % in the biofilm growth under N− condition. The protein content ranged between 33 and 44 %, and the presence of nitrogen had a slight positive effect on higher protein content. No trend was observed for carotenoids or bacteriochlorophylls in the N− condition. In contrast, for the N+ condition, the concentration of bacteriochlorophylls increased with decreasing wastewater concentration under suspended growth, while it decreased with decreasing wastewater concentration under biofilm growth. Coenzyme Q10 concentration was enhanced under the most growth-limited condition (25 %, N−). PHB and protein content of these resources seem most promising when using N− and N+ conditions, respectively.
AB - In the current era of wastewater treatment, integrating reusable water production with resource recovery is a key goal. This study aims to treat fuel-synthesis wastewater (FSW), intending to recover various resources, including polyhydroxybutyrate (PHBs), single cell protein, bacteriochlorophylls, carotenoids, and coenzyme Q10 from suspended and biofilm growth to decrease the harvesting costs. The study considered the treatment process, biofilm growth, and resource recovery potential in a mixed-culture system enriched with purple non-sulfur bacteria for treating FSW. Specifically, the effects of four different FSW strengths (25–100 %) and nitrogen sufficiency (N+) or deficiency (N−) were evaluated in eight biofilm photobioreactors. This study observed a direct correlation between the concentration of FSW and PHB content; specifically, as the FSW content decreased from 100 % (undiluted) to 25 % the PHB content decreased. The undiluted condition achieved 17 % dry cell weight as PHB in the suspended growth and 22.6 % in the biofilm growth under N− condition. The protein content ranged between 33 and 44 %, and the presence of nitrogen had a slight positive effect on higher protein content. No trend was observed for carotenoids or bacteriochlorophylls in the N− condition. In contrast, for the N+ condition, the concentration of bacteriochlorophylls increased with decreasing wastewater concentration under suspended growth, while it decreased with decreasing wastewater concentration under biofilm growth. Coenzyme Q10 concentration was enhanced under the most growth-limited condition (25 %, N−). PHB and protein content of these resources seem most promising when using N− and N+ conditions, respectively.
KW - Biofilm
KW - Fuel-synthesis wastewater
KW - PNSB
KW - Polyhydroxybutyrate
KW - Resource recovery
KW - SCP
UR - http://www.scopus.com/inward/record.url?scp=85194730798&partnerID=8YFLogxK
U2 - 10.1016/j.ceja.2024.100614
DO - 10.1016/j.ceja.2024.100614
M3 - Article
AN - SCOPUS:85194730798
SN - 2666-8211
VL - 19
JO - Chemical Engineering Journal Advances
JF - Chemical Engineering Journal Advances
M1 - 100614
ER -