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Functional fungal extracts from the Quorn fermentation co-product as novel partial egg white replacers

European Food Research and Technology volume 246pages 69–80 (2020)Cite this article

Abstract

The production of mycoprotein biomass by Marlow Foods for use in their meat alternative brand Quorn is a potential source of sustainable alternatives to functional ingredients of animal origin for the food industry. The conversion of this viscoelastic biomass into the Quorn meat-like texture relies on functional synergy with egg white (EW), effectively forming a fibre gel composite. In a previous study, we reported that an extract (retentate 100 or R100) obtained from the Quorn fermentation co-product (centrate) via ultrafiltration displayed good foaming, emulsifying, and rheological properties. This current study investigated if a possible similar synergy between EW and R100 could be exploited to partially replace EW as foaming and/or gelling ingredient. The large hyphal structures characteristic of R100 solutions were observed in EW–R100 mixtures, while EW–R100 gels showed dense networks of entangled hyphal aggregates and filaments. R100 foams prepared by frothing proved less stable than EW ones; however, a 75/25 w/w EW–R100 mixture displayed a similar foam stability to EW. Simlarly, R100 hydrogels proved less viscoelastic than EW ones; however, the viscoelasticity of gels prepared with 50/50 w/w and 75/25 w/w EW–R100 proved similar to those of EW gels, while 75/25 w/w EW–R100 gels displayed similar hardness to EW ones. Both results highlighted a functional synergy between the R100 material and EW proteins. In parallel tensiometry measurements highlighted the presence of surface-active material in EW–R100 mixtures contributing to their high foaming properties. These results highlighted the potential of functional extracts from the Quorn fermentation process for partial EW replacement as foaming and gelling agent, and the complex nature of the functional profile of EW–R100 mixtures, with contributions reported for both hyphal structures and surface-active material.

Graphic abstract

Introduction

Due to its excellent foaming properties, egg white is widely used in desserts, cakes, biscuits, and many aerated prepared dishes including soufflés and mousses. Egg white also displays excellent gelling properties used for various cooking or baking applications. However, due to the high environmental costs and market volatility of animal-derived functional ingredients including milk and egg proteins, the food industry is looking for sustainable alternatives [1]. One of the strategies employed consists in screening unexploited co-product streams from the food industry for extraction of potential functional alternatives. In this context, the production of mycoprotein by Marlow Foods for use in their meat alternative product Quorn is a potential source of sustainable functional ingredients. The term mycoprotein refers to the high-protein biomass produced by fermentation of the fungus Fusarium venenatum A3/5 (ATCC PTA-2684) by Marlow Foods, which forms the basis of their Quorn brand products. Mycoprotein contains all essential amino acids [2] and the net protein utilisation value of Fusarium venenatum mycoprotein is comparable to that of milk [3]. Moreover, the fermentation of starch into protein by Fusarium venenatum results in 90% lower emission of greenhouse gases and benefits in terms of land and water footprints in comparison with beef products [4].

Following fermentation, the broth undergoes an RNA-reduction step during which it is first heat-shocked above 68 °C for 30–45 min, then further heated at 90 °C, and finally centrifuged [5]. This heat shock step stops growth, disrupts ribosomes, and activates endogenous RNAases which break down cellular RNA to nucleotides [5]. The resulting solid deposit (mycoprotein biomass) is then processed into a dough ready for conversion to the meat-like texture characteristic of Quorn foods. However, the heat-shock RNA-reduction step also induces diffusion of a fraction of the cell components through the cell wall [5]. The liquid supernatant (centrate) generated by the subsequent centrifugation step thus contains residual hyphal biomass, carbohydrates, nucleotides, and proteins as well as the residues of the fermentation feedstock, and is currently an unexploited co-product stream.

Following centrifugation, the viscoelastic mycoprotein biomass is mixed with egg albumen and the material is discharged into industrial block formers. The pressure exerted allied with the flow characteristics of the mixed material result in the introduction of laminations or layers which can be considered as textural precursors for the final meat-like texture [6]. The mix is heated to 90 °C then chilled and frozen to approximately − 10 °C. This controlled freezing step results in an entangled mass of mycoprotein hyphae with gelled albumen protein within the interstitial space, a system described as fibre gel composite which confers a meat-like texture to the products [6].

Egg white is a complex system of proteins with different physicochemical properties. Lysozyme (14.3 kDa) is a very basic protein with an isoelectric point at pH 10.5, making it the only egg white protein that is positively charged in physiological conditions [7]. The high foaming properties of egg white could be due to a synergy in adsorption at the air/water interface between the positively charged lysozyme and other negatively charged proteins including ovalbumin and ovotransferrin, with intermolecular interactions occurring between the oppositely charged proteins after their unfolding, which stabilises the air bubbles [8,9,10]. Such synergy at the air/water interface has also been reported between lysozyme and whey proteins [11, 12], with intermolecular interactions reported in the bulk solution as well as at the air–water interface, resulting in higher foam stability due to the reduction of electrostatic repulsive interactions in the protein film.

In a previous study [13], we reported that an extract (retentate 100 or R100) obtained via a 100 kDa ultrafiltration of the centrate displayed good foaming stability, emulsifying, and rheological properties (viscosity, viscoelasticity, and gelation). R100 solutions displayed high viscosity, while R100 solutions and hydrogels showed high viscoelasticity. R100 foams displayed high stability, while oil-in-water R100 emulsions showed small and stable oil droplet size distributions. Large hyphal aggregates were reported in R100 solutions and gels, correlating with their high viscosity and viscoelasticity. A dense hyphal network was observed in R100 foams and contributed to their stability. In parallel tensiometry measurements at the oil/water interface highlighted the presence of interfacially active molecules in R100 which formed a rigid film stabilising the oil droplets. A number of functional metabolites and proteins were identified in the centrate, including a cerato-platanin protein, cell membrane constituents (phospholipids, sterols, glycosphingolipids, and sphingomyelins), cell wall constituents (chitin, chitosan, proteins), and guanine and guanine-based nucleosides and nucleotides. The current study investigated if a similar synergy to the one reported between EW and mycoprotein in the formation of the Quorn meat-like texture could be exploited between EW and R100 with a view to partially replacing EW as foaming and/or gelling ingredient. As part of this work, the functional profile (foaming and rheological properties) of a range of mixtures of EW and R100 was characterised.

Materials and methods

Sample preparation

Centrate samples were collected from the Marlow Foods fermenter site at Belasis, Billingham and frozen. Following thawing, the centrate underwent a 100 kDa ultrafiltration step using a Vivaflow 200 crossflow cassette (Sartorius, UK) connected to a Masterflex Easy-Load peristaltic pump (Sartorius, UK). The resulting retentate 100 or R100 (composed of molecules larger than 100 kDa) was freeze-dried in a Super Modulyo unit (Edwards, UK). A commercial agglomerated egg white (EW) powder was used as control.

Nitrogen content

We previously reported that a wide range of functional molecules present in centrate and concentrated in the R100 fraction contained nitrogen, including fungal cell membrane and cell wall constituents such as phospholipids, glycosphingolipids, sphingomyelins, chitin, chitosan, and proteins [13]. In that regard, the nitrogen-containing material (NCM) content was measured using the Kjeldahl method [14] to provide a guideline for preparation of standardised sample quantities for functional tests. Sets of 0.1 g of EW and R100 were digested in concentrated sulphuric acid (92%) using a Kjeltec Basic Digestion Unit 20 (Foss, UK) at 440 °C in the presence of a selenium catalyst. The digested samples were then distilled into boric acid using a Tecator Kjeltec 8100 Manual Distillation Unit (Foss, UK). Finally, the distilled samples were titrated using 0.1 N hydrochloric acid. The % nitrogen was calculated using the following formula:

$$ \% \, {\text{Nitrogen}} = \frac{{{\text{Titration volume }}\left( {\text{ml}} \right) \times 1 4. 0 0 7 { }}}{{{\text{Sample weight }}\left( {\text{g}} \right) \times 100}}. $$

The % nitrogen obtained was then multiplied by the general conversion factor of 6.25 recommended for mycoprotein biomass [15] to obtain a % nitrogen-containing material (NCM). Measurements were repeated three times. The functional profile of the four following samples was then assessed: EW control, R100, 75/25 EW–R100 (75% EW + 25% R100 on w/w basis for specified NCM content), and 50/50 EW–R100 (50% EW + 50% R100 on w/w basis for specified NCM content).

Gel electrophoresis

Sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) was performed using a Mini-Protean Tetra Cell System with Mini-Protean TGX 4–20% Tris–glycine precast gels (Bio-Rad Laboratories Ltd., UK) according to the methods of Laemmli [16] and Havea et al. [17] with minor modifications. One percent w/w nitrogen-containing material (NCM) solutions of the EW, R100 and 75/25 EW–R100 samples were prepared in deionised water and stirred for 1 h. One set of each solution was sonicated for 3 min at 20 kHz and 50% amplitude using a Sonics Vibra-Cell VCX-500 probe sonicator (Sonics, UK) to provide a reference for protein de-aggregation, while the other set was left untreated.

SDS-PAGE samples were prepared by mixing equal proportions of sample solution and Laemmli 2 × concentrate sample buffer (Sigma Aldrich Ltd., UK) followed by heating at 70 °C for 10 min. The See Blue Plus2 pre-stained standard (Life Technologies Ltd., UK) was used as molecular weight marker. The wells were loaded with 20 μl of sample or 10 μL of marker and the gels were run in Tris/Glycine/SDS buffer (Bio-Rad Laboratories Ltd., UK) at 100 V for 1 h. The gels were subsequently stained in a Coomassie brilliant blue solution (VWR Ltd., UK) for 1 h and destained overnight in the corresponding destaining solution (glacial acetic acid:methanol:deionised water 1:4:5). Gels were scanned using a ChemiDoc XRS + imaging system (Bio-Rad Laboratories Ltd., UK) and analysed using the associated Image Lab software.

Rheological properties

Viscosity and gelation measurements were performed using a Bohlin Gemini controlled stress rheometer (Malvern Instruments, UK) using cone-and-plate geometry. 10% w/w NCM solutions of EW, R100, 75/25 EW-R100, and 50/50 EW/R100 were prepared in deionised water and stirred for 2 h. To assess the potential contribution of the R100 material to the EW gelling profile, EW solutions at 7.5% and 5% w/w NCM concentrations (matching the respective EW concentrations of the 75/25 EW–R100 and 50/50 EW/R100 samples) were also tested. Measurements were repeated three times.

Viscosity measurements were performed using a 4°/40 mm cone (gap 150 μm) at 20 °C. The instantaneous viscosity (Pa.s) was measured through a shear rate increase from 0.001 to 50 s−1. Prior to gelation tests, the linear viscoelasticity region of each sample was determined via oscillatory measurements of elastic and viscous moduli (G’ and G’’) carried out at 1 Hz over a strain amplitude sweep ranging from 0.00005 to 50. Gelation profiles were then assessed via small-amplitude oscillatory measurements using a 2°/40 mm cone (gap 70 μm) with the applied strain chosen from within the linear viscoelastic region for each sample. The elastic and viscous moduli (G’ and G’’) were measured through a temperature sweep test ranging from 40 to 90 °C in up-down mode (15 min up-sweep and 15 min down-sweep) and the oscillation frequency was 1 Hz.

Texturometry on hydrogels

Ten milliliter solutions of 10% w/w NCM EW, R100, 75/25 EW-R100, and 50/50 EW/R100 were prepared in deionised water and stirred for 2 h. 10 ml solutions of 7.5% and 5% w/w NCM EW were also assessed as controls. The solutions were then heated for 1 h at 95 °C in a water bath and cooled down at 4 °C for 3 h. The resulting gels were tested for hardness using a BDO-FBO5.TS texture analyser (Zwick-Roell, UK) equipped with a 40 mm height/20 mm bottom diameter cylindrical probe. A single compression test was performed at a 1 mm/sec crosshead speed and 10 mm gel penetration depth. Measurements were replicated twice. The results were analysed using the associated testXpert 11.02 software (Zwick-Roell, UK).

Foaming properties

Two types of foaming methods (frothing and gas sparging) were carried out at room temperature (20 °C). Both foaming ability and stability were investigated using a frothing test. Fifteen gram solutions of 1% w/w NCM solutions of EW, R100, 75/25 EW-R100, and 50/50 EW/R100 were prepared in 50 ml glass beakers, which corresponds to an initial volume of 18 cm3 (1.4 cm sample height and 4 cm beaker diameter), and stirred for 1 h. To assess the potential contribution of the R100 material to the EW foaming profile, EW solutions at 0.75% and 0.5% w/w NCM concentrations (matching the respective EW concentrations of the 75/25 EW–R100 and 50/50 EW/R100 samples) were also tested. The solutions were frothed for 1 min using a handheld whisk-type frother (Aerolatte, UK). The height of the resulting foam was measured immediately after whisking and every 10 min until collapse of the foam. The foaming ability was expressed as the initial height of the foam, while the foam stability was determined as the time needed for the foam to fully collapse. Measurements were repeated twice.

A gas-sparging test was also used according to Rudin [18] with minor modifications to assess the stability of foams prepared with EW, R100, and EW–R100 mixture solutions. 40 g solutions of 1% w/w NCM solutions of EW, R100, and 50/50 EW/R100 were stirred for 1 h and transferred to a column, which corresponds to an initial volume of 48 cm3 (3.8 cm sample height and 4 cm column diameter). A 0.5% w/w NCM EW was also tested as control. Gas sparging was carried out at constant flow rate of CO2 (100 cm3/min) until the foam reached the top indicator of the column (at 32.5 cm height from the bottom), which corresponds to a foam volume of 409 cm3. The foam stability was quantified as the time needed for the foam to collapse to the bottom indicator of the column. Measurements were repeated three times.

Surface tension

One percent w/w NCM solutions of EW, R100, and 75/25 EW–R100 were serially diluted to obtain 0.5%, 0.25%, and 0.1% w/w NCM solutions. The surface tension of the solutions was measured using the Du Nouy method with an EZ-Pi Plus tensiometer (Kibron, UK). Deionised water was used as control with a surface tension reading of 72 mN/m. 1.5 ml of solution was placed into a sterile cup holder. Triplicate measurements were carried out at 20 °C.

Confocal microscopy

EW, R100, 75/25 EW-R100, and 50/50 EW/R100 solutions, foams, and hydrogels were imaged using a Leica TCS2 confocal laser scanning microscope (Leica Microsystems, Germany). 1% and 10% w/w NCM solutions were prepared in deionised water supplemented with the fluorescent dye rhodamine B, respectively, stirred for 1 h and 2 h, and imaged. Foams and hydrogels were prepared following the procedures described in the foaming and texturometry sections and imaged. The dye was excited at 514 nm, the collection range was 600–700 nm, and a 10x/0.25 dry lens was used. Micrographs were recorded at a resolution of 512 × 512 pixels and analysed using the manufacturer’s software (Leica Software Development Kit DM SDK version 4.2.1).

Human/animal rights

This article does not contain any studies with human or animal subjects.

Results and discussion

Characterisation of EW–R100 mixtures

The NCM content of the R100 and agglomerated EW samples were, respectively, 55.2% and 91.8% based on Kjeldahl measurements. The NCM content of the R100 fraction obtained was similar to the one measured in our previous study (56.7%) [13].

As previously observed [13], large hyphal structures were present in R100 (Fig. 1c), resulting from the aggregation of centrate hyphal debris during their retention on the 100 kDa ultrafiltration membrane. Hyphal structures were also observed in the 75/25 EW–R100 mixture (Fig. 1b). Fungal aggregate formation has been attributed to a combination of electrostatic interactions, hydrophobic interactions, and specific interactions between cell wall components including proteins and polysaccharides [19], and the influence of temperature on hyphal aggregation was previously reported for the filamentous fungus Rhizopus sp. [20]. The aggregation process observed could thus have resulted from the pressure exerted on the ultrafiltration membrane-retained material and/or from the temperature increase occurring during ultrafiltration.

Fig. 1
figure 1

Confocal microscopy of EW, R100, and 75/25 EW–R100 solutions (1% w/w NCM concentration, rhodamine, magnification × 10). a EW, b 75/25 EW-R100, and c R100

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To visualise both the concentrated EW protein bands and the fainter R100 ones, a high-contrast scan of the SDS–PAGE gel was produced (Fig. 2). The main egg white proteins were observed on the SDS-PAGE profile of the untreated agglomerated EW sample (Fig. 2), including ovalbumin (45 kDa), ovotransferrin (76–80 kDa), and lysozyme (14 kDa). An additional band (A) was observed in untreated agglomerated EW, but disappeared following sonication or combination with untreated or sonicated R100. The molecular weight of band A matched with that of a lysozyme dimer (28 kDa), which was in accordance with previous reports in which lysozyme was shown to dimerise when heated [21]. In addition, densitometry of the gel showed that the monomer lysozyme band (14 kDa) was much more concentrated in untreated agglomerated egg white in comparison with its sonicated counterpart (not shown). Self association of egg white lysozyme has previously been reported following heat-based processes including the dry heating process applied during agglomeration of the EW control sample [22], indicating that the concentrated monomeric and dimeric lysozyme bands observed in agglomerated EW could result from the breakdown of larger aggregates (formed during agglomeration) by β-mercaptoethanol during the SDS-PAGE treatment. The incomplete reduction of lysozyme dimers into monomers under the action of β-mercaptoethanol as indicated by the presence of the weak band A in the untreated EW sample has previously been documented, with a number of disulphide bonds within dimers remaining uncleaved in the presence of β-mercaptoethanol [23].

Fig. 2
figure 2

SDS-PAGE of native and sonicated EW, R100, and EW–R100 solutions (1% w/w NCM, original pH, and high-contrast gel scan). (1) See blue marker, (2) untreated R100, (3) sonicated R100, (4, 5) untreated 75/25 EW-R100, (6, 7) sonicated 75/25 EW-R100, (8) untreated EW, (9) sonicated EW, and (10) see blue marker

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The disappearance of the protein A band and the weaker monomeric lysozyme band observed in the EW–R100 mixture suggested the possible aggregation of monomeric and dimeric lysozyme forms with R100 proteins. Aggregation between the positively charge lysozyme and negatively charged whey proteins through electrostatic interactions has previously been reported [11, 12].

Another explanation for the EW–R100 gel profile was the potential binding of monomeric and dimeric lysozyme forms to fungal cell walls. Lysozymes, also known as muramidases or N-acetylmuramide glycanhydrolases, are a family of enzymes binding and catalysing the hydrolysis of β-1-4 glycosidic bonds within peptidoglycans contained in bacterial cell walls, resulting in antimicrobial effects [24]. Due to their chemical similitude with peptidoglycan (both type of polysaccharides contain β-1-4 linked N-acetylglucosamine units), chitin and chitosan contained in fungal cell walls have also been reported as viable binding and hydrolysis substrates for a number of lysozymes including egg white lysozyme [25, 26].

Rheological properties of EW–R100 mixtures

R100 and 50/50 EW–R100 solutions proved more viscous than EW ones at 10% w/w NCM (Fig. 3) due to the presence of the large hyphal structures observed in Fig. 1, which resisted flow. Similarly, a high concentration of hyphal aggregates was previously correlated with a decrease of the flow index for fermentation broths of the filamentous fungus Aspergillus terreus [27]. In parallel, our previous study [13] also showed the presence of compounds with known viscosifying properties in the centrate, including cell wall and membrane constituents which concentrated in the R100 fraction as part of the hyphal aggregates and contributed to the viscosity of EW–R100. The viscosifiers reported included chitin and chitosan [28, 29], inulin [30], galactan [31], nucleosides and nucleotides (including guanine-based compounds) and their derivatives [32], and sugar alcohols [33].

Fig. 3
figure 3

Viscosity profiles of EW, R100, and EW–R100 mixtures during shear rate increase (10% w/w NCM concentration, original pH, n = 3)

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R100 and both 75/25 and 50/50 EW–R100 solutions showed higher viscous and elastic moduli than EW at 10% w/w NCM at 40 °C prior to gelation (Fig. 4, viscous moduli results not shown). 75/25 and 50/50 EW–R100 hydrogels displayed similar viscous and elastic moduli to EW ones and higher values than 7.5% and 5% EW ones. The viscous and elastic moduli of R100 gels proved higher than 5% EW ones, but lower than 7.5% EW ones. The viscoelasticity of R100 gels was due to the very dense networks of entangled hyphal aggregates and filaments formed during gelation as observed in Fig. 5c. The entanglement of hyphal aggregates and filaments reported for EW–R100 gels was reminiscent of the microstructure of Quorn products, which is responsible for their meat-like texture and described as a fibre gel composite composed of an entangled mass of mycoprotein hyphae with gelled albumen protein within the interstitial space [6]. EW gels presented a dense homogenous network (Fig. 5a), which correlated with their high viscoelasticity.

Fig. 4
figure 4

Gelation profiles (elastic modulus G’) of EW–R100 mixtures (10%, 7.5%, or 5% w/w NCM concentration, original pH, n = 3)

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Fig. 5
figure 5

Confocal microscopy of EW, R100, and 75/25 EW–R100 gels (10% w/w NCM concentration, original pH, rhodamine, and magnification × 10). a EW, b 75/25 EW-R100, and c R100

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R100 gels proved less viscoelastic than 7.5% EW ones; however, 75/25 EW–R100 gels displayed a higher viscoelasticity than 7.5% EW ones (Fig. 4), highlighting a synergistic interaction between the R100 material and egg albumen. As reported by Finnigan [6], the mixing of mycoprotein biomass and egg albumen during the production of Quorn mince and pieces introduces laminations which can be considered as textural precursors for the final meat-like texture. In the current study, such interaction could be due to the binding of lysozyme to chitin and chitosan contained in fungal cell walls [25, 26], which was supported by the SDS-PAGE results with the respective disappearance and weakening of the dimeric and monomeric lysozyme bands when EW was mixed with R100 (Fig. 2).

In parallel, our previous study [13] showed the presence of compounds with known gelling properties in the centrate, including cell wall and membrane constituents which concentrated in the R100 fraction as part of the hyphal aggregates and contributed to the EW–R100 gelling profile. The gelifiers reported included chitin and chitosan [28, 29], phytosterols and phytosterol esters [34], ceramides and sphingomyelins [35], glycosphingolipids [36], inulin [30], galactan [31], and nucleobases, nucleosides, and nucleotides (including guanine-based compounds) and their derivatives [32].

R100 hydrogels displayed low hardness (Fig. 6). However, 75/25 EW–R100 hydrogels proved harder than 7.5% EW ones and replicated the hardness of 10% EW ones, which, in addition to their similar viscoelasticity, highlighted the potential of R100 as partial EW replacer for gelling applications. The 50/50 EW–R100 and 5% EW hydrogels showed lower and similar hardness values (9.1 N for 75/25 EW–R100 and 8.3 N for 5% EW, results not shown).

Fig. 6
figure 6

Hardness profile of EW, R100, and EW–R100 hydrogels (10% or 7.5% w/w NCM concentration, original pH, n = 3)

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The combined rheological and textural results also highlighted the possibility of re-introducing centrate extracts back into the process at the manufacturing stage as partial egg albumen replacers while maintaining the characteristic fibre gel composite structure of Quorn products.

Foaming properties of EW–R100 mixtures

Foams produced by gas sparging with R100 and 50/50 EW–R100 proved as stable as 1% EW foams (foams prepared with 1% w/w NCM EW solutions) and more stable than 0.5% EW foams (Fig. 7). Frothing results showed higher foaming abilities for 1% and 0.75% EW in comparison with R100, while 75/25 EW–R100 ranged as intermediate (Fig. 8). R100 foams produced by frothing showed the lowest stability; however, 75/25 EW–R100 foams proved more stable than 0.75% EW ones and displayed a similar foam height to 1% EW ones after 540 min, indicating a functional synergy between the R100 material and EW proteins.

Fig. 7
figure 7

Foam stability of EW, R100, and 50/50 EW–R100 as determined by the Rudin method (1% or 0.5% w/w NCM concentration, original pH, n = 3)

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Fig. 8
figure 8

Foaming ability and stability profiles of EW, R100, and EW–R100 mixtures (1% or 0.75% w/w NCM concentration, original pH, n = 3)

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A high density of air bubbles was observed in EW and 75/25 EW–R100 foams following frothing (Fig. 9a, b) while only few air bubbles were observed in R100 foams (Fig. 9c). Micrographs showed that air bubbles in R100 foams were trapped in a dense network of hyphae and cell debris (Fig. 9c). These observations were in agreement with previous studies in which highly viscous fermentation media displayed issues with gas–liquid mass transfer for the filamentous fungus Aspergillus terreus [27]. Hence, the high viscosity related to the dense hyphal network observed in R100 solutions (Fig. 1) only allowed a limited number of air bubbles to be formed and transported within the liquid, leading to a poor foaming ability (Fig. 8), but, on the other hand, prevented the destabilisation of the air bubbles formed by limiting their movement in the liquid, leading to a high foam stability (Figs. 7, 8). Foams prepared with 75/25 EW–R100 showed a less dense hyphal network around the air bubbles (Fig. 9b), which, in addition to the action of egg white proteins, allowed a higher number of air bubbles to be formed, leading to a higher foaming ability than R100, while nonetheless contributing to their stabilisation due to viscosity.

Fig. 9
figure 9

Confocal microscopy of EW, R100, and 75/25 EW–R100 foams prepared by frothing (1% w/w NCM concentration, original pH, rhodamine, and magnification × 10). a EW, b 75/25 EW-R100, and c R100

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In addition, depending on their hydrophobicity, the possible concentration of Fusarium venenatum cells and/or spores in the R100 fraction as a result of the ultrafiltration process could also have contributed to the stabilisation of R100 and EW–R100 foams as the shapes and sizes of bacterial cells, viruses, and spores fall within the range for stabilisation of biphasic dispersions including foams and emulsions [37]. Moreover, a correlation between foam stability and cell surface hydrophobicity was reported for different strains of Acinetobacter calcoaceticus [38].

In parallel, surface tension measurements were undertaken to assess the potential contribution of surface-active material from R100 to the foaming properties of EW–R100 samples. Solutions prepared with 1% w/w NCM EW, R100, and 75/25 EW–R100 showed significantly lower surface tension values than deionised water (72 mN/m) (Fig. 10), which was in agreement with their foaming properties. Measurements were carried out 1 min after adding the solution to the cell to allow for the large hyphal structures observed in Fig. 1b and c to settle at the base of the cell, as observed in our previous study using a Krüss Easydrop tensiometer (Krüss GmbH, Germany) equipped with a video camera [13]. The surface tension of R100 and EW–R100 proved lower than that of EW, which highlighted the presence of surface-active molecules from R100 at the air–water interface and their contribution to the foaming properties of EW–R100 samples. We previously reported a number of proteins in the centrate and R100 fraction with known foaming properties [13]. A cerato-platanin was concentrated in the R100 fraction in comparison with the centrate and the serpin SERPB1 was detected in both samples. The cerato-platanin EPL1 from the fungus Trichoderma atroviride was previously reported to form ordered self-assembled layers at the air/water interface [39] and hydrophobic/hydrophilic interfaces [40], while serpins Z4 and Z7 from barley have been characterised as foam-positive proteins in beer [41, 42]. In addition, a range of metabolites with known foaming properties were also identified in the centrate, including cell wall and membrane constituents which concentrated in the R100 fraction as part of the hyphal aggregates and contributed to the EW–R100 foaming profile. The foam-positive compounds reported included chitin and chitosan [28, 29], monoglycerides and diglycerides [43], glycosyl diglycerides [44], triterpenoid and steroidal saponins [45], cerato-platanin [46], and fatty amides [47]. Moreover, the possible release of surface-active molecules and cell debris from the R100 hyphal aggregates during gas sparging or frothing could also have contributed to the stabilisation of R100 and EW–R100 foams.

Fig. 10
figure 10

Surface tension of EW, R100, and 75/25 EW–R100 solutions (1% w/w NCM concentration, original pH, n = 3)

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The higher foam stability exhibited by 75/25 EW–R100 in comparison with 0.75% EW following frothing (Fig. 8) could also be due to the presence of surface-active aggregates formed between lysozyme and R100 proteins, as suggested by the respective weakening and disappearance of monomeric and dimeric lysozyme bands on the 75/25 EW–R100 SDS-PAGE profile (Fig. 2). Due to its high isoelectric point (10.7), lysozyme was charged positively in the 75/25 EW–R100 mixture and possibly combined with negatively charged proteins present in R100 through electrostatic interactions. Such aggregation process was previously reported between lysozyme and negatively charged whey proteins [11, 12].

Similarly, a synergy in adsorption at the air/water interface between lysozyme and negatively charged R100 proteins when foamed together could also have contributed to the higher foam stability exhibited by 75/25 EW–R100 in comparison with 0.75% EW following frothing (Fig. 8) and by 50/50 EW–R100 in comparison with 0.5% EW following gas sparging (Fig. 7). In this case, intermolecular interactions between the oppositely charged proteins occur at the interface after the unfolding of the proteins, which stabilises the air bubbles due to the reduction of electrostatic repulsive interactions in the protein film. Such synergy at the air/water interface was previously reported between the two egg white proteins lysozyme and ovalbumin [8]. Synergistic effects between lysozyme and whey proteins were shown to result from intermolecular interactions in the bulk solution as well as at the air–water interface, resulting in higher foam stability [11, 12].

The combined foaming, microscopy, and tensiometry results highlighted that surface-active material present in R100 and/or synergistically combining with EW proteins contributed to the high stability of EW–R100 foams, while the dense hyphal network observed in these foams contributed via physical stabilisation of the air bubbles. Foam-positive material present in R100 included hyphal aggregates, fungal cells, foaming molecules, and hyphal fragments or molecules released from hyphal aggregates during the foaming process. These results highlighted the potential of R100 for use as partial replacer of EW as foaming agent.

Conclusions

The study investigated if a similar synergy to the one reported between EW and mycoprotein in the formation of the Quorn meat-like texture could be exploited between EW and a functional extract from the Quorn fermentation co-product (R100). The viscoelasticity and hardness of 75/25 EW–R100 hydrogels proved similar to 10% EW ones and higher than 7.5% EW ones. Frothed 75/25 EW–R100 foams showed similar stability to 1% EW ones and higher stability than 0.75% EW ones, while gas-sparged 50/50 EW–R100 foams proved as stable as 1% EW ones and more stable than 0.5% EW ones. These results highlighted the potential of centrate extracts for partial EW replacement as foaming and gelling agent.

R100 foams prepared by frothing proved less stable than 7.5% EW ones; however, a 75/25 w/w EW–R100 mixture displayed a higher foam stability than 7.5% EW ones. Similarly, R100 gels proved less viscoelastic than 7.5% EW ones; however, 75/25 EW–R100 gels displayed a higher viscoelasticity than 7.5% EW ones. Both results highlighted a functional synergy between the R100 material and EW proteins.

In parallel tensiometry measurements highlighted the presence of surface-active material in EW–R100 mixtures contributing to their high foaming properties. In particular, the SDS-PAGE profile of EW–R100 mixtures indicated a possible aggregation of monomeric and dimeric forms of lysozyme with R100 proteins and/or fungal cells, contributing to their foaming and rheological properties. The results highlighted the complex nature of the functional profile of EW–R100 mixtures, with contributions reported for both hyphal structures and surface-active material.

Future work will assess the partial functional replacement of EW ingredients by centrate extracts in food formulations. Additional studies are needed to further understand the potential synergy between EW and R100 and the contribution of both hyphal structures and surface-active molecules to EW–R100 functionality. Finally, this study highlights the possibility of re-introducing Quorn fermentation co-product extracts back into the process at the manufacturing stage as partial egg albumen replacers.

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Acknowledgements

The authors wish to thank Dr. Tim Finnigan and Dr. Sue Gordon from Marlow Foods for their support during this project.

Funding

This work was supported by the Engineering and Physical Sciences Research Council [Grant Number EP/J501682/1 Foaming and Fat Replacer Ingredients].

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Authors and Affiliations

  1. School of Health Sciences, Queen Margaret University Drive, Queen Margaret University, Edinburgh, EH21 6UU, UK

    J. Lonchamp

  2. Quorn Foods, Station Road, Stokesley, TS9 7BR, UK

    M. Akintoye

  3. School of Physics & Astronomy, The University of Edinburgh, Peter Guthrie Tait Road, Edinburgh, EH9 3FD, UK

    P. S. Clegg

  4. Institute of Mechanical, Process & Energy Engineering, School of Engineering and Physical Sciences, Heriot-Watt University, Edinburgh, EH14 4AS, UK

    S. R. Euston

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Lonchamp, J., Akintoye, M., Clegg, P.S. et al. Functional fungal extracts from the Quorn fermentation co-product as novel partial egg white replacers. Eur Food Res Technol 246, 69–80 (2020). https://doi.org/10.1007/s00217-019-03390-1

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Keywords

  • Quorn
  • Co-product
  • Centrate
  • Egg
  • White
  • Replacement