Impact of Copper Fungicide Use in Hop Production on the Total Metal Content and Stability of Wort and Dry-Hopped Beer

Impact of Copper Fungicide Use in Hop Production on the Total Metal Content and Stability of Wort and Dry-Hopped Beer

Transition metals, including copper, iron, and manganese, are known to catalyze the generation of reactive oxygen species (ROS) in beer leading to reduced product stability. Metals in beer are generally derived from raw ingredients. The present study aims to evaluate the impact of brewing and dry-ho...

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Bibliographic Details
Main Authors: Benjamin J. Chrisfield, Helene Hopfer, Ryan J. Elias
Format: Article
Language:English
Published: MDPI AG 2020-08-01
Series:Beverages
Subjects:
hops
beer
brewing
dry hopping
copper-based fungicides
transition metals
Online Access:https://www.mdpi.com/2306-5710/6/3/48
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spelling doaj-392b366f589b43c48855da38d8f32dea2020-11-25T03:38:40ZengMDPI AGBeverages2306-57102020-08-016484810.3390/beverages6030048Impact of Copper Fungicide Use in Hop Production on the Total Metal Content and Stability of Wort and Dry-Hopped BeerBenjamin J. Chrisfield0Helene Hopfer1Ryan J. Elias2Department of Food Science, College of Agricultural Sciences, The Pennsylvania State University, University Park, PA 16802, USADepartment of Food Science, College of Agricultural Sciences, The Pennsylvania State University, University Park, PA 16802, USADepartment of Food Science, College of Agricultural Sciences, The Pennsylvania State University, University Park, PA 16802, USATransition metals, including copper, iron, and manganese, are known to catalyze the generation of reactive oxygen species (ROS) in beer leading to reduced product stability. Metals in beer are generally derived from raw ingredients. The present study aims to evaluate the impact of brewing and dry-hopping using hops treated with copper-based fungicides (CBFs) on the final transition metal content of model buffer solutions and pilot-scale systems of wort and beer. Copper levels in model wort and beer solutions were elevated (105.6% and 230.4% increase, respectively) when CBF-treated hops were used. In laboratory-prepared wort, elevated copper concentrations were not observed when CBF-treated hops were used for boiling. Dry hopping of beer using CBF-treated hops led to significant increases in total copper content (ca. 75 µg/kg vs. ca. 40–50 µg/kg in the control-hopped beer) when yeast was absent from the treated beer, but not when yeast was present. It was observed that manganese levels were significantly elevated in all hopped beers (ca. 495–550 µg/kg vs. 90–125 µg/kg in the unhopped control), regardless of hop treatment. A hop varietal thiol, 4-Mercapto-4-methylpentan-2-one, was spiked into treated beers, and the rate of oxidative loss was monitored during aging. Rates of thiol loss in treated beer samples did not differ across CBF treatments but were significantly lower in unhopped controls in the absence of yeast (<i>p</i> < 0.0001) and correlated significantly with total manganese content of the beers (R<sup>2</sup> = 0.4228, <i>p</i> = 0.0006). The rate of staling in hopped beers as measured by the rate of 1-hydroxyethyl radical generation did not differ among hop treatments, suggesting that excess copper content contributed from the hops does not negatively impact the oxidative stability of the beers. These findings suggest that brewers can use CBF-treated hops without any negative implications for the shelf stability of their beers and do not contraindicate the use of CBF in hops production when necessary.https://www.mdpi.com/2306-5710/6/3/48hopsbeerbrewingdry hoppingcopper-based fungicidestransition metals
collection DOAJ
language English
format Article
sources DOAJ
author Benjamin J. Chrisfield
Helene Hopfer
Ryan J. Elias
spellingShingle Benjamin J. Chrisfield
Helene Hopfer
Ryan J. Elias
Impact of Copper Fungicide Use in Hop Production on the Total Metal Content and Stability of Wort and Dry-Hopped Beer
Beverages
hops
beer
brewing
dry hopping
copper-based fungicides
transition metals
author_facet Benjamin J. Chrisfield
Helene Hopfer
Ryan J. Elias
author_sort Benjamin J. Chrisfield
title Impact of Copper Fungicide Use in Hop Production on the Total Metal Content and Stability of Wort and Dry-Hopped Beer
title_short Impact of Copper Fungicide Use in Hop Production on the Total Metal Content and Stability of Wort and Dry-Hopped Beer
title_full Impact of Copper Fungicide Use in Hop Production on the Total Metal Content and Stability of Wort and Dry-Hopped Beer
title_fullStr Impact of Copper Fungicide Use in Hop Production on the Total Metal Content and Stability of Wort and Dry-Hopped Beer
title_full_unstemmed Impact of Copper Fungicide Use in Hop Production on the Total Metal Content and Stability of Wort and Dry-Hopped Beer
title_sort impact of copper fungicide use in hop production on the total metal content and stability of wort and dry-hopped beer
publisher MDPI AG
series Beverages
issn 2306-5710
publishDate 2020-08-01
description Transition metals, including copper, iron, and manganese, are known to catalyze the generation of reactive oxygen species (ROS) in beer leading to reduced product stability. Metals in beer are generally derived from raw ingredients. The present study aims to evaluate the impact of brewing and dry-hopping using hops treated with copper-based fungicides (CBFs) on the final transition metal content of model buffer solutions and pilot-scale systems of wort and beer. Copper levels in model wort and beer solutions were elevated (105.6% and 230.4% increase, respectively) when CBF-treated hops were used. In laboratory-prepared wort, elevated copper concentrations were not observed when CBF-treated hops were used for boiling. Dry hopping of beer using CBF-treated hops led to significant increases in total copper content (ca. 75 µg/kg vs. ca. 40–50 µg/kg in the control-hopped beer) when yeast was absent from the treated beer, but not when yeast was present. It was observed that manganese levels were significantly elevated in all hopped beers (ca. 495–550 µg/kg vs. 90–125 µg/kg in the unhopped control), regardless of hop treatment. A hop varietal thiol, 4-Mercapto-4-methylpentan-2-one, was spiked into treated beers, and the rate of oxidative loss was monitored during aging. Rates of thiol loss in treated beer samples did not differ across CBF treatments but were significantly lower in unhopped controls in the absence of yeast (<i>p</i> < 0.0001) and correlated significantly with total manganese content of the beers (R<sup>2</sup> = 0.4228, <i>p</i> = 0.0006). The rate of staling in hopped beers as measured by the rate of 1-hydroxyethyl radical generation did not differ among hop treatments, suggesting that excess copper content contributed from the hops does not negatively impact the oxidative stability of the beers. These findings suggest that brewers can use CBF-treated hops without any negative implications for the shelf stability of their beers and do not contraindicate the use of CBF in hops production when necessary.
topic hops
beer
brewing
dry hopping
copper-based fungicides
transition metals
url https://www.mdpi.com/2306-5710/6/3/48
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AT helenehopfer impactofcopperfungicideuseinhopproductiononthetotalmetalcontentandstabilityofwortanddryhoppedbeer
AT ryanjelias impactofcopperfungicideuseinhopproductiononthetotalmetalcontentandstabilityofwortanddryhoppedbeer
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