Comprehensive industry-relevant black soldier fly bioconversion characterisation by a novel chamber system.

Autor: Fuhrmann A; ETH Zurich, Laboratory of Sustainable Food Processing, Schmelzbergstrasse 9 8092, Zurich, Switzerland; Singapore-ETH Centre,1 Create Way 138602, Singapore., Gold M; ETH Zurich, Laboratory of Sustainable Food Processing, Schmelzbergstrasse 9 8092, Zurich, Switzerland; Singapore-ETH Centre,1 Create Way 138602, Singapore. Electronic address: moritz.gold@hest.ethz.ch., Lau Heckmann LH; Better Insect Solutions A/S, Agro Food Park 15 8200, Aarhus, Denmark., Pedersen P; SKOV A/S, Hedenlund 4 7870, Roslev, Glyngøre, Denmark., Shakhnovich K; ETH Zurich, Laboratory of Sustainable Food Processing, Schmelzbergstrasse 9 8092, Zurich, Switzerland; Singapore-ETH Centre,1 Create Way 138602, Singapore., Chu CX; National University of Singapore, Department of Biological Science, 14 Science Drive 4 117543, Singapore., Haberkorn I; Singapore-ETH Centre,1 Create Way 138602, Singapore., Puniamoorthy N; National University of Singapore, Department of Biological Science, 14 Science Drive 4 117543, Singapore. Electronic address: nalini@nus.edu.sg., Mathys A; ETH Zurich, Laboratory of Sustainable Food Processing, Schmelzbergstrasse 9 8092, Zurich, Switzerland; Singapore-ETH Centre,1 Create Way 138602, Singapore.
Jazyk: angličtina
Zdroj: Waste management (New York, N.Y.) [Waste Manag] 2024 Dec 24; Vol. 193, pp. 409-418. Date of Electronic Publication: 2024 Dec 24.
DOI: 10.1016/j.wasman.2024.12.016
Abstrakt: Black soldier fly larvae (BSFL) efficiently convert biowaste into valuable animal feed. Sustainable and reliable bioconversion is desirable to achieve optimal economic and environmental outcomes. Thus, science and industry require an accessible research platform to study complex bioconversion processes under conditions mirroring industrial-scale settings. In this study, industry-relevant respiration chambers were designed, tested, and replicated for BSF feeding trials. Each open-circuit chamber housed three industrial rearing crates. The substrate/frass and air temperature, mass change, NH 3 and CO 2 emissions, and relative humidity were measured. The design was validated for CO 2 recovery, airtightness, airflow homogeneity, and BSFL performance using firstly, a uniform control substrate and secondly, uniform food waste across four parallel chambers. In a third trial, the composition of food waste was varied across parallel chambers to detect differences in metabolic processes. For trials using uniform substrates, low variability across chambers in performance parameters confirmed the reproducibility and comparability of the design (e.g. bioconversion rate: <1%, final larval mass: ≤2 mg, standard deviations, dry matter based). In contrast, the trial with varying food waste compositions showed a strong effect on average substrate/frass temperature (e.g. 31.5 °C vs 41.8 °C) and final dry larval mass (e.g. 67 mg vs 40 mg). This is the first study to systematically assess heat generation directly from heterogeneous food waste, a crucial parameter for efficient BSFL bioconversion. These chambers provide an opportunity for science and industry to thoroughly assess and understand the metabolic bioconversion characteristics. The findings are key for the optimisation of sustainable bioconversion processes.
Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.
(Copyright © 2024 The Author(s). Published by Elsevier Ltd.. All rights reserved.)
Databáze: MEDLINE