moderately inhibiting effect at the

moderately inhibiting effect at the concentration of
2500e4000 mg dm3, but had a strong inhibiting influence at
8000 mg dm3. The toxic threshold for calcium is 2800 mg dm3
CaCl2 [30]. In this study, the calcium content of apple pomace, spent
grain, rapeseed cake, strawberry pomace, potato peel and nut shells
were within the standard and did not inhibit fermentation. Calcium
concentrations exceeded the recommended levels in the remaining
substrates.
4.1.2.2. Magnesium. Magnesium ions also adjust pH during
methane formation. At optimal concentrations, magnesium is one
of the most effective pure metallic catalysts that enhance biogas
production from organic wastes [48]. In this study, the lowest
magnesium levels were reported in apple pomace (252 mg kg1
DM), and the highest e in walnut shells (1879 mg kg1 DM).
Magnesium concentrations in excess of 2400 mg dm3 MgCl2
inhibit methane formation [30]. According to Schattauer et al. [24],
organic wastes for biogas production should be characterized by
magnesium content of 360e4800 mg dm3.
4.1.2.3. Sodium. The sodium content of beetroot peel and strawberry
pomace from a hydraulic press was below 0.2 mg kg1 DM.
Carrot pomace was characterized by the highest sodium concentrations
(3138 mg kg1 DM) which differed significantly from the
remaining types of analyzed waste. Sodium levels in excess of
6000e30,000 mg dm3 inhibit methane formation [30].
4.1.2.4. Potassium. The potassium content of the evaluated food
wastes varied significantly from 200 to nearly 40,000 mg kg1 DM.
The highest potassium concentrations were noted in the peel of
potatoes cv. Verona (36,970 mg kg1 DM), and the lowest e in spent
grain (200 mg kg1 DM). Similarly to sodium, potassium has an
inhibiting effect on methane formation. The toxic threshold for
potassium has been estimated at 3000 mg dm3 [30]. Strawberry
pomace from the drum filter, nut shells and spent grain were the
only analyzed substrates where sodium levels were maintained
within the safe standard.
5. Conclusions
The analyses of heavy and light metal concentrations in food
processing wastes revealed that the investigated materials were
suitable for biogas production. The content of most metallic elements
in the analyzed substrateswas within permissible limits. The
only exception was potassium which was observed in excessive
quantities in many waste samples. This problem can be solved
through co-digestion by bringing potassium levels closer to the
standard.
The evaluated food wastes constitute suitable substrates for
biogas production and contain mineral ions that enhance methane
formation.
The negative influence exerted by heavy metals on anaerobic
digestion is determined not only by their concentrations in the
substrate, but also by their chemical form, oxidation state, pH of the
feedstock and interactions with other compounds, including
antagonistic metals.
The concentrations of heavy and light metals in food wastes
should be monitored to guarantee the efficiency of biogas production.
Metal levels should also be analyzed in digestate which is
to be used as an agricultural fertilizer.
Acknowledgments
We are very grateful to Z_ywiec Group Co. in Warka, Poland, for
supplying brewery wastes for the needs of this study. We would
like to thank Pepees S.A. in Łom_ za, Poland, for providing us with
potato pulp, and companies from the Region of Mazowsze that
contributed other waste materials to this project.
We would like to express our gratitude to the Reviewers for
valuable inputs that helped us improve this paper and provided us
with useful guidelines for future publications.
We also would like to thank Aleksandra Poprawska, MA for
translating this manuscript.