Abstract
Coconut endosperm waste (CEW) was treated by Rhizopus oligosporus via in situ and ex situ fermentations together with bioconversion into valuable black soldier fly larval biomass. The ex situ fermentation could overall enrich the nutritional compositions of CEW by hydrolyzing its complex organic polymers and exuding assimilable nutrients to enhance the black soldier fly larvae (BSFL) growth. Nevertheless, the larval gut bacteria were competing with Rhizopus oligosporus in in situ fermentation, derailing the hydrolysis processes and larval growth. Accordingly, the highest growth rates achieved were around 0.095 g/day, as opposed to only 0.065 g/day whilst using 0.5 wt% of Rhizopus oligosporus to perform ex situ and in situ fermentations, respectively. These were also underpinned by the greater amount of total CEW consumed when employing ex situ fermentation, with comparable metabolic costs to feeding on in situ-fermented CEW. The mature BSFL were subsequently harvested and the amounts of protein and lipid produced were assessed in terms of their feasibility for biodiesel production. While the statistical analyses showed that the larval protein yields derived from both fermentation modes were insignificant, the BSFL could attain higher lipid and protein productivities upon feeding with ex situ- rather than in situ-fermented CEW mediums. Better yet, the larval biodiesel quality measured in terms of the fatty acid methyl ester composition were not varied significantly by Rhizopus oligosporus through the fermentation process. Thereby, the presence of 1.0 wt% Rhizopus oligosporus was considered optimum to perform ex situ fermentation, giving rise to the acceptable growth of BSFL loaded with the highest lipid yield and productivity for producing biodiesel and protein simultaneously.
Highlights
The black soldier fly larval biomass has gained tremendous attention worldwide, especially in the aquaculture and livestock farming industries, due to its potential use as a protein alimentation in animal feed [1,2]
Even with the inoculation of R. oligosporus into Coconut endosperm waste (CEW), the in situ fermentation demonstrated a negligible impact on the growth of black soldier fly larvae (BSFL) across all inoculum sizes from 0.02 to 2.5 wt%, with the biomass gained values fluctuating within the 0.7–0.8 g range
(8–10%), and C16:1 (3–5%), followed by tiny amounts of C10:0, C14:1, C18:0, and C18:2. These results showed that the fatty acid methyl esters (FAMEs) compositions derived from the BSFL biomasses were marginally impacted by the in situ or ex situ fermentation treatments on CEW executed by R. oligosporus at various inoculum sizes
Summary
The black soldier fly larval biomass has gained tremendous attention worldwide, especially in the aquaculture and livestock farming industries, due to its potential use as a protein alimentation in animal feed [1,2]. According to Schiavone et al (2018) [3], it was found that the inclusion of black soldier fly larvae (BSFL) fat as a soybean oil replacement at 50% to 100% in broiler diets had no negative impact on broilers’ growth and blood analyses. BSFL meal serving as a protein replacement in low fish meal diets could be included for juvenile Atlantic salmon without impacting their growth performance. In comparison with the third-generation biodiesel feedstocks such as yeast, the BSFL are preferable, as they can consume various types of organic waste, are low cost, and the leftover biomass can serve as a protein source for animal feeding purposes, whereas yeast oil produces a low lipid yield, has a high cost for its technology, and requires large water volumes for industry-scale application [11,12,13]
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