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Abstract

Housefly larvae (Musca domestica) composting has been increasingly adopted as an efficient practice to achieve value-added swine manure bioconversion, but few researches have evaluated the features of compost maturity by examining the biochemical compositions of dissolved organic matter (DOM) in compost. Here, we adopted spectrum fingerprint technologies to explore the related transformation mechanisms of DOM in compost by conducting field investigations in a full-scale housefly larvae composting farm. The 1-week composting with larvae significantly decreased DOM concentrations from 192.9 to 77.1 g kg⁻¹. The hydrolysis of proteins and lipids were enhanced during composting, as well as a build-up of aromatic substances, while contents of fulvic- and humic-like substances were augmented on Day 5 and Day 6 (ranged from 0.04 to 0.65 and 0.11 to 0.59 for F_max, respectively). Compared with traditional composting without the aid of larvae, the stronger biodegradation of DOM and the subsequent formation of humus in compost, led to a higher level of aromaticity and humification under housefly larvae bioconversion, generating a more stable bio-product for downstream utilisation.

Keywords

Composting animal waste spectrum technology bio-product

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References

Caricasole

Provenzano

Hatcher

(2010) Chemical characteristics of dissolved organic matter during composting of different organic wastes assessed by (13)C CPMAS NMR spectroscopy. Bioresource Technology 101: 8232–8236.

Diener

Zurbrugg

Tockner

(2009) Conversion of organic material by black soldier fly larvae: Establishing optimal feeding rates. Waste Management and Research 27: 603–610.

Domeizel

Khalil

Prudent

(2004) UV spectroscopy: A tool for monitoring humification and for proposing an index of the maturity of compost. Bioresource Technology 94: 177–184.

Droussi

D’Orazio

Hafidi

(2009) Elemental and spectroscopic characterization of humic-acid-like compounds during composting of olive mill by-products. Journal of Hazardous Materials 163: 1289–1297.

Glatman

Drabkin

Chizov-Ginzburg

(2011) Bioconversion of poultry and fish waste by Lucillia sericata and Sarcophage carnaria larvae. Asian Journal of Water Environment and Pollution 69–75.

Cui

(2014) Influence of chemical and structural evolution of dissolved organic matter on electron transfer capacity during composting. Journal of Hazardous Materials 268: 256–263.

Jiang

(2013) Structural transformation study of water-extractable organic matter during the industrial composting of cattle manure. Microchemical Journal 106: 160–166.

Wei

(2011) Physicochemical and spectroscopic characteristics of dissolved organic matter extracted from municipal solid waste (MSW) and their influence on the landfill biological stability. Bioresource Technology 102: 2322–2327.

Huang

Wong

JWC

(2006) Transformation of organic matter during co-composting of pig manure with sawdust. Bioresource Technology 97: 1834–1842.

10.

Jingyu

Shuping

Jiangmin

(2004) Structrual characteristics of dissolved organic matter fractions extracted from soils different in land use. Acta Pedologica Sinica 41: 721–727.

11.

Jouraiphy

Amir

Winterton

(2008) Structural study of the fulvic fraction during composting of activated sludge-plant matter: Elemental analysis, FTIR and 13C NMR. Bioresource Technology 99: 1066–1072.

12.

Korshin

Benjamin

(1997) Monitoring the properties of natural organic matter through UV spectroscopy: A consistent theory. Water Research 31: 1787–1795.

13.

Kothawala

Stedmon

Muller

(2014) Controls of dissolved organic matter quality: Evidence from a large-scale boreal lake survey. Global Change Biology 20: 1101–1114.

14.

Kumar

Shweta (2011) Enhancement of wood waste decomposition by microbial inoculation prior to vermicomposting. Bioresource Technology 102: 1475–1480.

15.

Lazcano

Gomez-Brandon

Dominguez

(2008) Comparison of the effectiveness of composting and vermicomposting for the biological stabilization of cattle manure. Chemosphere 72: 1013–1019.

16.

Xing

Yang

(2011) Compositional and functional features of humic acid-like fractions from vermicomposting of sewage sludge and cow dung. Journal of Hazardous Materials 185: 740–748.

17.

Xing

Zhao

(2014) Towards understanding the stabilization process in vermicomposting using PARAFAC analysis of fluorescence spectra. Chemosphere 117: 216–222.

18.

Murphy

Stedmon

Graeber

(2013) Fluorescence spectroscopy and multi-way techniques PARAFAC. Analytical Methods 5: 6557.

19.

Plaza

Xing

Fernandez

(2009) Binding of polycyclic aromatic hydrocarbons by humic acids formed during composting. Environmental Pollution 157: 257–263.

20.

Simpson

McNally

Simpson

(2011) NMR spectroscopy in environmental research: From molecular interactions to global processes. Progress in Nuclear Magnetic Resonance Spectroscopy 58: 97–175.

21.

Tang

Liu

(2011) Different analysis techniques for fluorescence excitation–emission matrix spectroscopy to assess compost maturity. Chemosphere 82: 1202–1208.

22.

Tuomela

Vikman

Hatakka

(2000) Biodegradation of lignin in a compost environment: A review. Bioresource Technology 72: 169–183.

23.

Wang

Dou

(2006) The estimation of the production amount of animal manure and its environmental effect in China. China Environmental Science 26: 614–617.

24.

Wang

Holden

Zhang

(2014a) Concentration dynamics and biodegradability of dissolved organic matter in wetland soils subjected to experimental warming. Science of the Total Environment 470: 907–916.

25.

Wang

(2014b) Transformation of dissolved organic matters in swine, cow and chicken manures during composting. Bioresource Technology 168: 222–228.

26.

Wang

Yan

(2013) Fluorescence characteristics of dissolved organic matter during composting at low carbon/nitrogen ratios. Waste Management and Research 31: 203–211.

27.

Wei

Zhao

Zhu

(2014) Assessment of humification degree of dissolved organic matter from different composts using fluorescence spectroscopy technology. Chemosphere 95: 261–267.

28.

Weishaar

Aiken

Bergamaschi

(2003) Evaluation of specific ultraviolet absorbance as an indicator of the chemical composition and reactivity of dissolved organic carbon. Environmental Science and Technology 37: 4702–4708.

29.

Wilson

Xenopoulos

(2008) Effects of agricultural land use on the composition of fluvial dissolved organic matter. Nature Geoscience 21: 37–41.

30.

Luo

(2010) PARAFAC modeling of fluorescence excitation-emission spectra for rapid assessment of compost maturity. Bioresource Technology 101: 8244–8251.

31.

Zhang

Shen

Wang

(2014) Attenuation of veterinary antibiotics in full-scale vermicomposting of swine manure via the housefly larvae (Musca domestica). Scientific Reports 4: 6844. DOI: 10.1038/srep06844.

32.

Zhang

Wang

Zhu

(2012) Swine manure vermicomposting via housefly larvae (Musca domestica): The dynamics of biochemical and microbial features. Bioresource Technology 118: 563–571.

33.

Zmora-Nahum

Markovitch

Tarchitzky

(2005) Dissolved organic carbon (DOC) as a parameter of compost maturity. Soil Biology and Biochemistry 37: 2109–2116.

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Decomposition and humification of dissolved organic matter in swine manure during housefly larvae composting

Abstract

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