Quality Improvement in Apple Ciders during Simultaneous Co-Fermentation through Triple Mixed-Cultures of Saccharomyces cerevisiae, Pichia kudriavzevii, and Lactiplantibacillus plantarum

This study explored the effect of the combination of Saccharomyces yeast, non-Saccharomyces yeast (Pichia kudriavzevii), and Lactiplantibacillus plantarum during cider fermentation on physicochemical properties, antioxidant activities, flavor and aroma compounds, as well as sensory qualities. Ciders fermented with the triple mixed-cultures of these three species showed lower acid and alcohol content than those fermented with the single-culture of S. cerevisiae. The antioxidant activities were enhanced by the triple mixed-culture fermentation, giving a higher 1,1-diphenyl-2-picrylhydrazyl (DPPH) radical scavenging rate and total antioxidant capacity; specifically, the SPL5 cider showed the highest DPPH radical scavenging rate (77.28%), while the SPL2 gave the highest total antioxidant capacity (39.57 mmol/L). Additionally, the triple mixed-culture fermentation resulted in improved flavor and aroma with a lower acidity (L-malic acid) and higher aroma compounds (Esters), when compared with the single-culture fermented ciders (Saccharomyces cerevisiae); more specifically, the SPL4 cider resulted in the highest total flavor and aroma compounds. In addition, sensory evaluation demonstrated that ciders produced using the triple mixed-cultures gained higher scores than those fermented using the single-culture of S. cerevisiae, giving better floral aroma, fruity flavor, and overall acceptability. Therefore, our results indicated that the triple mixed-cultures (S. cerevisiae, P. kudriavzevii, and L. plantarum) were found to make up some enological shortages of the single S. cerevisiae fermented cider. This study is believed to provide a potential strategy to enhance cider quality and further give a reference for new industrial development protocols for cider fermentation that have better sensory qualities with higher antioxidant properties.


Introduction
Apples are rich in nutrients such as sugar, vitamins, dietary fiber, and trace minerals as well as polyphenolic bioactive compounds, giving them the ability to lower blood lipids and prevent many types of cancers [1,2]. Apple cider is one of the directions of apple processing, which preserves its original nutrients and provides a unique aroma, ultimately meeting the demand of functional-food consumers. In China, Yanyuan Fuji apple from Yanyuan County of Sichuan Province has been proved to be an excellent raw material for the production of functional foods with improved nutritional values [3]. Yanyuan Fuji apples have unique characteristics such as being pollution free with varieties of flavor substances and higher concentrations of sugar and polyphenols. However, little research has been conducted on the cider fermentation with Yanyuan Fuji apples. Based on the above literature, the apple cider quality was studied with simultaneous co-cultures of different strains of S. cerevisiae, P. kudriavzevii, and L. plantarum for the fermentation of apple cider. Some crucial parameters were determined in the study, including basic cider parameters, antioxidant activities, and aroma compounds. The study was expected to provide valuable information about the triple mixed-culture fermentation of Saccharomyces yeasts, non-Saccharomyces yeasts, and LABs on the chemical and sensory properties of apple ciders, which would help enologists to optimize the starter cultures so as to further improve apple cider quality.

Yeast and Bacterial Strains and Culture Media
Sixteen microbial strains were employed in the study, including the commercial strain of S. cerevisiae Angel (Angel Yeast Co., Ltd., Yichang, China), Saccharomyces cerevisiae (SCFF203, SCFF205, SCFF211, SCFF215, and SCFF233), Pichia kudriavzevii (SCFF163, SCFF185, SCFF204, SCFF207, and SCFF214), and Lactiplantibacillus plantarum (SCFF19, SCFF107, SCFF169, SCFF180, and SCFF200). The yeast strains were cultured on yeast extract-peptone-dextrose (YPD) medium at 28 • C. All the strains of L. plantarum were grown on de Man-Rogosa-Sharpe (MRS) medium at 37 • C. The yeasts and bacteria employed in this study came from the Culture Collection of Food Microorganisms of Sichuan University of Science and Engineering (Yibin, China).

Apple Cider Fermentation
Apple ciders were made according to the previous studies [26,27] with some modifications. The apples were washed and then drained. Subsequently, after removing the seeds, apples were cut into small pieces and crushed with a food-grade juicer to obtain an apple juice. Ascorbic acid (0.08%) was then added to the apple juice to prevent the enzymatic browning; this apple juice was then pasteurized at 95 • C for 5 min in a conical flask and subsequently cooled down to room temperature. Before inoculation, all of the yeast strains of S. cerevisiae and P. kudriavzevii were cultured in YPD liquid medium via shaking at 150 rpm in a shaker at 28 • C for 24 h, while all L. plantarum strains were cultured in MRS liquid medium at 37 • C for 16 h. S. cerevisiae, P. kudriavzevii, and L. plantarum were incubated under anaerobic conditions for two generations to make these microbial strains grow in an anaerobic environment. Afterward, cells were separated from the liquid medium with centrifugation at 4500× g for 10 min. The pellets were washed with sterile saline (0.85%) and centrifuged at 4500× g for 10 min, and the process was repeated three times successively. The cells were then resuspended in the pasteurized apple juice for subsequent fermentation. All microbial strains were inoculated at a final count of 10 7 CFU/mL in 1000 mL apple juice. Six fermentation tests were subsequently carried out: (1) single inoculation with the commercial strain of S. cerevisiae Angel (SCA); (2) simultaneous inoculation with S. cerevisiae SCFF205, P. kudriavzevii SCFF185, and L. plantarum SCFF200 (SPL1); (3) simultaneous inoculation with S. cerevisiae SCFF233, P. kudriavzevii SCFF163, and L. plantarum SCFF107 (SPL2); (4) simultaneous inoculation with S. cerevisiae SCFF203, P. kudriavzevii SCFF214, and L. plantarum SCFF19 (SPL3); (5) simultaneous inoculation with S. cerevisiae SCFF211, P. kudriavzevii SCFF207, and L. plantarum SCFF180 (SPL4); and (6) simultaneous inoculation with S. cerevisiae SCFF215, P. kudriavzevii SCFF204, and L. plantarum SCFF 169 (SPL5). The pasteurized apple juice with no inoculation was considered the control (AJ). The simultaneous inoculation method was used in this study with the inoculum ratio of S. cerevisiae, P. kudriavzevii, and L. plantarum at 2:2:1 [8,9]. The apple juice fermentation was carried out at 20 • C in the dark for 16 days. At the end of the fermentation process, the apple cider was collected from the strains and lees by centrifugation at 7000× g Foods 2023, 12, 655 4 of 16 for 10 min (at 4 • C). The supernatant was collected and stored at −20 • C to prevent the interferences from oxygen and light, which was subjected to further analysis.

Physicochemical Analysis
Physicochemical properties of the samples were analyzed according to the method described by the previous report [13] with some modifications. The pH value was determined using a pH meter (PH-100, Lichen, Shanghai, China). The soluble solid content (SSC) was measured by a digital refractometer (RA-620, Kyoto, Japan). The total acidity content was determined with acid-base titration with 0.1 M NaOH, while the reducing sugar content was determined by 3,5-dinitrosalicylic acid based on the method in GB/T 15038-2006. The alcoholic content of apple ciders was determined on the basis of the second method in GB 5009.225-2016.

Determination of Antioxidant Activity
The antioxidant activities of the apple juice and ciders were determined with 1,1-diphenyl-2-picrylhydrazyl (DPPH) free radical superoxide anion reducing power and the total antioxidant activity, which were calculated according to the method described by the previous report [28] with some modifications.

GC-TOF-MS Analysis
GC-TOF-MS analysis was carried out with an Agilent 7890 gas chromatograph and a time-of-flight mass spectrometer (MS) on the basis of the previously described method [27] with some modifications. The Agilent DB-5MS capillary column was used in the system with helium as the carrier gas. The injection volume was one µL in splitless mode. The front inlet purge flow was 3 mL/min, and the gas flow rate through the column was 1 mL/min. The initial temperature was 50 • C (Holding for 1 min), subsequently raised to 310 • C at 10 • C/min and maintained at this temperature for 8 min. The injection, transfer line, and ion source temperatures were 280 • C, 280 • C, and 250 • C, respectively. Electron ionization (Electron impact mode at 70 eV) spectra in the m/z range from 50 to 500 were acquired in full-scan mode at 12.5 spectra per second after a solvent delay of 6.25 min. The compounds were determined using semi-quantitative analysis on the basis of the added internal standard (2-octanol).

LC-MS/MS Analysis
LC-MS/MS analyses were performed according to the method described by Zhou and coworkers with some modifications [29] using the UHPLC system (Vanquish, Thermo Fisher Scientific), equipped with a Waters ACQUITY UPLC BEH Amide column (2.1 mm × 100 mm, 1.7 µm) together with Q Exactive HFX mass spectrometer (Orbitrap MS, Thermo Fisher Scientific). Two solvents were used to elute: mobile phase A (25 mmol/L ammonium acetate and 25 mmol/L ammonia hydroxide in water) and mobile phase B (100% acetonitrile). The auto-sampler temperature was kept at 4 • C, and a 2 µL aliquot of samples was injected. The QE HFX MS was employed to collect MS/MS spectra in an information-dependent acquisition mode through the acquisition software (Xcalibur, Thermo). In this mode, the acquisition software continuously evaluates the full scan MS spectrum. The operating conditions of the electrospray ionization source were applied as follows: sheath gas flow rate was 30 Arb; aux gas flow rate was 25 Arb; the capillary temperature was 350 • C; full MS resolution was 120,000; MS/MS resolution was 7500; collision energy was 10/30/60 eV in NCE mode; and spray voltage was 3.6 kV (Positive) or −3.2 kV (Negative), respectively.

Sensory Analysis
Sensory analysis was performed on the basis of the previous method with some modifications [30]. The sensory properties of the finished ciders were evaluated by a group of 15 panelists, comprising students and teachers with relevant experiences and background knowledge. The age and gender of the volunteers were not taken into consideration. Cider quality was evaluated through six attributes: fruity taste, sweetness, bitterness, sourness, flavor, and overall acceptability; these attributes were scored according to the nine-point hedonic scale (one indicated poor, and nine represented excellent). About 50 mL of each cider sample was served in a wine glass, labeled with a random code number; then, evaluation was conducted under white light and at room temperature. The sensory quality of each finished cider was assessed by calculating and plotting the average scores of all characters.

Statistical Analysis
Each experiment was conducted in triplicate, and the result was expressed as means ± standard deviation (SD). The difference between experimental groups was analyzed with Duncan's multiple comparison test using IBM SPSS version 26 (SPSS Inc., Chicago, IL, USA), and the level of statistical significance was accepted to at least 5%. Hierarchical cluster analysis (HCA) and principal component analysis (PCA) were performed with Origin 9.0 (Hampton, MA, USA).

Changes in Physicochemical Parameters
Physicochemical characteristics of apple juice and ciders (mono-fermented with S. cerevisiae or co-fermented with S. cerevisiae, P. kudriavzevii, and L. plantarum) are displayed in Table 1. At the end of the fermentation, the pH values of the apple ciders were lower than that of the apple juice, except for SPL3 cider. The total acid contents of the apple ciders ranged from 3.62 mg/mL to 5.32 mg/mL, which were higher than that of the apple juice, confirming the previous result [8]. The cider fermented with S. cerevisiae Angel (SCA) showed the highest acidity content (5.32 ± 0.12 mg/mL), which was higher than that of other finished apple ciders of simultaneous fermentation with S. cerevisiae, P. kudriavzevii, and L. plantarum, indicating that triple mixed-culture fermentations had a biological deacidification ability. Note: Data with different letters (a, b, c, d, e, f, g) in the same row are significantly different (p < 0.05). SSC = soluble solid content (expressed as • Brix); "-" means not detected.
The sugar consumption abilities varied among all simultaneous fermentation processes with S. cerevisiae, P. kudriavzevii, and L. plantarum. The reducing sugar contents of the apple ciders fermented with simultaneous fermentation with S. cerevisiae, P. kudriavzevii, and L. plantarum changed in an opposite direction; for example, the reducing sugar contents for SPL2 (5.07 ± 0.01 mg/mL), SPL4 (4.55 ± 0.01 mg/mL), and SPL5 (6.07 ± 0.03 mg/mL) changed more quickly than that for SCA (mono-fermentation with S. cerevisiae Angel) (7.00 ± 0.01 mg/mL), while that for SPL1 (15.89 ± 0.06 mg/mL) and SPL3 (25.44 ± 0.07 mg/mL) showed a slower decrease. The alcohol percentage in all apple ciders fermented with simultaneous co-fermentation processes with S. cerevisiae, P. kudriavzevii, and L. plantarum were lower than that in the mono-fermented cider with S. cerevisiae Angel (SCA), revealing that the simultaneous co-fermentation process had a relatively lower alcohol-producing capacity.

Comparative Analysis of Antioxidant Activity
Total antioxidant activity and DPPH free radical superoxide anion reducing power in apple juice and finished apple ciders were studied. Overall, the antioxidant activities of apple ciders were higher than that of apple juice. Figure 1 showed that the total antioxidant activity and DPPH free radical scavenging rate of apple ciders after monoand co-fermentation were higher than those in apple juice before fermentation. Moreover, total antioxidant activity and DPPH free radical scavenging rate in ciders of triple mixed-cultures (for example, SPL1, SPL2, SPL3, and SPL5) were significantly higher than those in the single-culture (SCA). Specially, SPL5 cider showed the highest DPPH radical scavenging rate (77.28% ± 0.12%), while SPL2 cider showed the highest total antioxidant capacity (39.57 ± 0.06 mmol/L), suggesting that the triple mixed-cultures improved the antioxidant activities of the apple cider. Our results were consistent with the previous studies [26,31].
mented with simultaneous co-fermentation processes with S. cerevisiae, P. kudriavzev L. plantarum were lower than that in the mono-fermented cider with S. cerevisiae (SCA), revealing that the simultaneous co-fermentation process had a relatively low cohol-producing capacity.

Comparative Analysis of Antioxidant Activity
Total antioxidant activity and DPPH free radical superoxide anion reducing p in apple juice and finished apple ciders were studied. Overall, the antioxidant activi apple ciders were higher than that of apple juice. Figure 1 showed that the total an dant activity and DPPH free radical scavenging rate of apple ciders after mono-an fermentation were higher than those in apple juice before fermentation. Moreover antioxidant activity and DPPH free radical scavenging rate in ciders of triple mixe tures (for example, SPL1, SPL2, SPL3, and SPL5) were significantly higher than th the single-culture (SCA). Specially, SPL5 cider showed the highest DPPH radical sca ing rate (77.28% ± 0.12%), while SPL2 cider showed the highest total antioxidant cap (39.57 ± 0.06 mmol/L), suggesting that the triple mixed-cultures improved the antiox activities of the apple cider. Our results were consistent with the previous studies [2

Analysis of Esters, Higher Alcohols, Aldehydes, and Ketones
In this study, a total of 31 compounds, including 21 esters, 5 aldehydes, 3 high cohols, and 2 ketones, were determined by GC-MS in apple juice and the finished ( Table 2). The total response values of the triple mixed-culture fermented apple (SPL) were significantly higher (p < 0.05) than those in the single S. cerevisiae ferm cider (SCA), indicating that the triple mixed-cultures improved the production of a producing substances because a mixed-culture fermentation of yeasts and bacteria tributed these compounds to regulate the wine aroma complexity [32]. SPL4 cider the highest total compound concentrations (3105.6 ± 356.62 μg/L), which were s cantly higher than those in other fermented ciders.

Analysis of Esters, Higher Alcohols, Aldehydes, and Ketones
In this study, a total of 31 compounds, including 21 esters, 5 aldehydes, 3 higher alcohols, and 2 ketones, were determined by GC-MS in apple juice and the finished ciders ( Table 2). The total response values of the triple mixed-culture fermented apple ciders (SPL) were significantly higher (p < 0.05) than those in the single S. cerevisiae fermented cider (SCA), indicating that the triple mixed-cultures improved the production of aromaproducing substances because a mixed-culture fermentation of yeasts and bacteria contributed these compounds to regulate the wine aroma complexity [32]. SPL4 ciders had the highest total compound concentrations (3105.6 ± 356.62 µg/L), which were significantly higher than those in other fermented ciders. The most abundant compounds were esters in the finished ciders (Table 2). Esters are compounds that are considered special in having an essential impact on cider flavor, which provide pivotal qualities concerning desired fruity aromas [33,34]. A total of 21 ester compounds were determined, including 7 ethyl esters, 5 methyl esters, and 9 other esters ( Table 2). Ester concentrations in AJ and SCA samples had no significant difference (p > 0.05); however, those in SPL1, SPL2, SPL3, SPL4, and SPL5 apple ciders were significantly higher (p > 0.05), suggesting that the mixed cultures helped the production of more esters, which was consistent with previous studies [30,34,35]. In particular, SPL1 cider was characterized by the highest level of esters (2348.14 ± 355.68 µg/L). The concentrations of ethyl esters in triple mixed-culture fermented ciders were significantly higher than those in the monofermented cider. This was especially true for ethyl tetradecanoate, ethyl isovalerate, and ethyl phenylacetate.
The heatmap cluster analysis was used to analyze the differences of ester compounds among different apple ciders (Figure 2a). The results displayed the increase or decrease in ester compound formation in each triple mixed-culture fermentation compared with the apple juice and control cider (SCA). Moreover, the ester compounds in the apple juice and ciders were divided into three clusters. Ester components in AJ and SCA cider were grouped in cluster I, while components in SPL1, SPL3, SPL4, and SPL5 ciders were grouped in cluster II, while SPL2 cider was alone grouped in cluster III. These results showed that the ester compound profiles were different not only between the single-culture and mixed-culture fermentations but also among different mixed-culture fermentations with different strains. The heatmap cluster analysis was used to analyze the differences of ester compounds among different apple ciders (Figure 2a). The results displayed the increase or decrease in ester compound formation in each triple mixed-culture fermentation compared with the apple juice and control cider (SCA). Moreover, the ester compounds in the apple juice and ciders were divided into three clusters. Ester components in AJ and SCA cider were grouped in cluster I, while components in SPL1, SPL3, SPL4, and SPL5 ciders were grouped in cluster II, while SPL2 cider was alone grouped in cluster III. These results showed that the ester compound profiles were different not only between the single-culture and mixed-culture fermentations but also among different mixed-culture fermentations with different strains. A small number of aldehydes, higher alcohols, and ketones were also identified and quantified in the finished ciders. Higher alcohols (which were deemed to be one of the most significant precursors of esters) were conducive to fresh fruity notes and were believed to give a pleasant attribute to the aromatic complexity of fruit wines when their concentrations were below 300 mg/L [27,36]. In this study, the contents of higher alcohols in apple ciders fermented with mixed-cultures were higher (from 39.12 ± 0.47 μg/L to 79.53 ± 7.65 μg/L) than those in the initial apple juice (6.67 ± 0.44 μg/L) and single-culture fermented cider (34.37 ± 2.51 μg/L). Moreover, alcohols, together with organic acids, contribute to the production of esters with a pleasant taste. Aldehydes are generally believed to contribute off-flavors to the apple ciders [37]. Our observations showed that the triple mixed-culture fermentation formed significantly lower aldehyde contents than single S. cerevisiae fermentation. The production of ketones was increased considerably in all the ciders with the triple mixed-culture fermentation, compared to the cider with pure fermentation (SCA). Consequently, ciders fermented with mixed microbial strains not only increased esters but also enhanced higher alcohols, aldehydes, and ketones.
For further differentiation of the compounds in apple juice, single-culture fermented cider, and co-culture fermented ciders, PCA analysis of the GC-MS data was conducted. The first and second components accounted for 32.2% (PC1) and 24.8% (PC2) of the total variation, respectively. The scatter plot displayed that apple juice and cider samples were separated from each other (Figure 2b). Apple juice (AJ) and the control cider (SCA) were positioned in the third quadrant. Ciders produced by the mixed-culture fermentation were in the first quadrant (SPL5), second quadrant (SPL1 and SPL3), and fourth quadrant (SPL2 and SPL4). A small number of aldehydes, higher alcohols, and ketones were also identified and quantified in the finished ciders. Higher alcohols (which were deemed to be one of the most significant precursors of esters) were conducive to fresh fruity notes and were believed to give a pleasant attribute to the aromatic complexity of fruit wines when their concentrations were below 300 mg/L [27,36]. In this study, the contents of higher alcohols in apple ciders fermented with mixed-cultures were higher (from 39.12 ± 0.47 µg/L to 79.53 ± 7.65 µg/L) than those in the initial apple juice (6.67 ± 0.44 µg/L) and singleculture fermented cider (34.37 ± 2.51 µg/L). Moreover, alcohols, together with organic acids, contribute to the production of esters with a pleasant taste. Aldehydes are generally believed to contribute off-flavors to the apple ciders [37]. Our observations showed that the triple mixed-culture fermentation formed significantly lower aldehyde contents than single S. cerevisiae fermentation. The production of ketones was increased considerably in all the ciders with the triple mixed-culture fermentation, compared to the cider with pure fermentation (SCA). Consequently, ciders fermented with mixed microbial strains not only increased esters but also enhanced higher alcohols, aldehydes, and ketones.
For further differentiation of the compounds in apple juice, single-culture fermented cider, and co-culture fermented ciders, PCA analysis of the GC-MS data was conducted. The first and second components accounted for 32.2% (PC1) and 24.8% (PC2) of the total variation, respectively. The scatter plot displayed that apple juice and cider samples were separated from each other (Figure 2b). Apple juice (AJ) and the control cider (SCA) were positioned in the third quadrant. Ciders produced by the mixed-culture fermentation were

Analysis of Organic Acids, Polyphenols, and Terpenoids
The starter culture has an essential effect on organic acids, polyphenols, and terpenoids produced in the apple ciders. A total of 86 compounds were determined by LC-MS/MS in all samples, including 44 organic acids, 34 polyphenols, and 8 terpenoids (Table 3).
Since organic acids in ciders can make a difference in sensory quality and exert an effect on flavor balance by regulating pH, stability, and comprehensive quality of the fruit wine, it is essential to determine organic acid contents [38,39]. The results showed that total organic acids in all the finished ciders ranged from 44.58 ± 1.33 µg/L to 77.77 ± 1.30 µg/L ( Table 3). A heatmap analysis showed that those organic acids in apple juice and ciders were mainly assigned into three clusters (Figure 3a). Components in cluster I included shikimic acid and L-malic acid; the level of L-malic acid in the triple mixed-culture fermented ciders was lower than that in apple juice (AJ) and the mono-fermented cider (SCA). Cluster II included 27 organic acids with lower levels of lactic acid in the triple-mixed-culture fermented ciders, while cluster III had 15 organic acids with higher levels of pyruvic acid in the triple mixed-culture fermented ciders. In particular, high contents of malic acid leads to a harsh taste and unpleasant flavor of apple ciders. As displayed in Table 3, lower concentrations of malic acid and higher concentrations of lactic acids were found in the triple mixed-culture fermented ciders with L. plantarum (SPL) than those in AJ and the single-culture fermented cider with S. cerevisiae (SCA), illustrating that L. plantarum might have the ability of deacidification. Consequently, the results in this study were consistent with the research that L. plantarum had the capability of biological deacidification to transform malic acid to lactic acids. Moreover, high concentrations of pyruvic acid and lactic acid had a positive effect on the color stability and the soft perception of fruit wines, respectively [9,40]. Polyphenols had a significant effect on both cider quality and health-promoting properties [41,42]. Previous studies revealed that apple ciders fermented with the cultures of non-Saccharomyces yeast and L. plantarum were rich in polyphenol contents and had higher antioxidant activities [26]. Among 86 detected compounds in this study, 34 polyphenols were identified (Table 3). Moreover, polyphenol concentrations in AJ and SCA    Polyphenols had a significant effect on both cider quality and health-promoting properties [41,42]. Previous studies revealed that apple ciders fermented with the cultures of non-Saccharomyces yeast and L. plantarum were rich in polyphenol contents and had higher antioxidant activities [26]. Among 86 detected compounds in this study, 34 polyphenols were identified (Table 3). Moreover, polyphenol concentrations in AJ and SCA samples were lower than those in the triple mixed-culture fermented ciders; among them, SPL4 cider had the highest level of polyphenols (20.98 ± 5.24 µg/L). According to the heatmap cluster analysis results in Figure 3b, there were significant differences in polyphenol components of ciders fermented using different starters. Moreover, bergapten, hesperidin, 2-benzylbutanedioic acid, and chlorogenic acid clustered into one group (G1). Cluster G2 included 30 phenol compounds; among them, caffeic acid, epicatechin, gallic acid, naringenin, glabranin, phlorizin, and phloretin were found in higher levels in the triple mixedculture fermented ciders than in the AJ and SCA samples. Hence, the triple mixed-cultures enhanced the formation of many polyphenol compounds, improving the comprehensive quality of apple ciders.
The triple mixed-cultures had significant effects on terpenoids in apple ciders (Table 3, Figure 3c). The addition of P. kudriavzevii and L. plantarum significantly increased the total amount of terpenoids in apple ciders (from 514.96 ± 11.86 µg/L to 1661.52 ± 48.05 µg/L), especially in SPL3 cider (1661.52 ± 48.05 µg/L), which was about 7-fold higher than that determined in the cider from the single-culture of S. cerevisiae (SCA) (231.69 ± 15.56 µg/L). The difference was principally owing to the increase in geranylacetate, nerylacetate, and citronellyl acetate.

Sensory Evaluation
The sensory evaluation of apple ciders is displayed in Figure 4. Compared to the single commercial yeast fermentation, the sensory scores of ciders with the triple mixed-cultures were much higher. More importantly, the floral aroma, fruity and sweet flavors, and overall acceptability in the ciders of the triple mixed-cultures were significantly improved. The results in this study were consistent with the previous reports, revealing that double mixed-cultures of P. kudriavzevii with S. cerevisiae, and L. plantarum with S. cerevisiae had a positive effect on the floral aroma, fruity flavors, and overall acceptability of ciders [8,31,43]. Moreover, sensory evaluation displayed that there were also significant differences among the apple ciders fermented with triple mixed-cultures with different microbial strains, demonstrating that strains were also an essential factor influencing the sensory quality of ciders, which was consistent with the previous study [5]. The difference was principally owing to the increase in geranylacetate, nerylacetate, and citronellyl acetate.

Sensory Evaluation
The sensory evaluation of apple ciders is displayed in Figure 4. Compared to the single commercial yeast fermentation, the sensory scores of ciders with the triple mixed-cultures were much higher. More importantly, the floral aroma, fruity and sweet flavors, and overall acceptability in the ciders of the triple mixed-cultures were significantly improved. The results in this study were consistent with the previous reports, revealing that double mixed-cultures of P. kudriavzevii with S. cerevisiae, and L. plantarum with S. cerevisiae had a positive effect on the floral aroma, fruity flavors, and overall acceptability of ciders [8,31,43]. Moreover, sensory evaluation displayed that there were also significant differences among the apple ciders fermented with triple mixed-cultures with different microbial strains, demonstrating that strains were also an essential factor influencing the sensory quality of ciders, which was consistent with the previous study [5].

Conclusions
In summary, this study investigated the effects of the triple mixed-cultures of S. cerevisiae, P. kudriavzevii, and L. plantarum on the cider quality, including basic physicochemical parameters, antioxidant activities, aroma and flavor compounds, and sensory quali-

Conclusions
In summary, this study investigated the effects of the triple mixed-cultures of S. cerevisiae, P. kudriavzevii, and L. plantarum on the cider quality, including basic physicochemical parameters, antioxidant activities, aroma and flavor compounds, and sensory qualities. The results showed that simultaneous co-inoculations of S. cerevisiae together with non-Saccharomyces yeast and L. plantarum provided a practical way to enhance apple cider quality. Co-inoculating these three species improved antioxidant abilities, compared to those generated by just a single-culture of S. cerevisiae. Moreover, the ciders fermented with co-inoculation of the three cultures resulted in higher concentrations of esters, terpenes, and higher alcohols, while exhibiting prominent floral and fruity tastes with a higher overall acceptability. Hence, the results collectively indicated that the triple mixed-cultures provided a potential method to make up the enological shortage of the single-culture fermented cider and further enhanced the quality of apple ciders, facilitating the application of co-culture fermentation technology with different species in cider-making. Our results contributed to the investigation of suitable microbial combinations for cider-making. However, the interactions between different yeasts and L. plantarum during fermentation are complex, and the number of these microbial cultures at the end of fermentation therefore needs further study.