Synergistic strategy for the enhancement of biohydrogen production from molasses through coculture of Lactobacillus brevis and Clostridium saccharobutylicum

This study aimed to evaluate the capacity of different inoculum sources and their bacterial diversity to generate hydrogen (H2). The highest Simpson (0.7901) and Shannon (1.581) diversity indexes for H2-producing bacterial isolates were estimated for sewage inocula. The maximum cumulative H2 production (Hmax) was 639.6 & PLUSMN; 5.49 mL/L recorded for the sewage inoculum (SS30) after 72 h. The highest H2-producing isolates were recovered from SS30 and identified as Clostridium saccharobutylicum MH206 and Lactobacillus brevis MH223. The Hmax of C. saccharobutylicum, L. brevis, and synergistic coculture was 415.00 & PLUSMN; 24.68, 491.67 & PLUSMN; 15.90, and 617.67 & PLUSMN; 3.93 mL/L, respectively. The optimization process showed that the Hmax (1571.66 & PLUSMN; 33.71 mL/L) with a production rate of 58.02 mL/L/h and lag phase of 19.33 h was achieved by the synergistic coculture grown on 3% molasses at 40 & DEG;C, pH 7, and an inoculum size of 25% (v/v). This study revealed the economic feasibility of the syner-gistic effects of coculture on waste management and biohydrogen production technology.& COPY; 2023 Hydrogen Energy Publications LLC. Published by Elsevier Ltd. All rights reserved.

Automated summary

This study aimed to evaluate the capacity of different inoculum sources and their bacterial diversity to generate hydrogen (H2). Sewage inocula showed the highest diversity indexes for H2-producing bacterial isolates. The highest H2 production was recorded for the sewage inoculum, and the highest H2-producing isolates were identified as Clostridium saccharobutylicum MH206 and Lactobacillus brevis MH223. The optimization process achieved the highest H2 production rate by a synergistic coculture grown on 3% molasses at 40°C, pH 7, and an inoculum size of 25% (v/v).