Quality Determination of a High-Pressure Processed Avocado Puree-Based Smoothie Beverage

: The aim was to study the quality stability of a high-pressure (HP) processed avocado puree-based smoothie beverage and to determine its shelf life. To achieve this mathematical description of HP process parameters (pressure, temperature, and pH conditions) on polyphenoloxidase (PPO) inactivation of avocado-puree (base of the smoothie beverage), use of the appropriate kinetic models was undertaken. Inactivation rate constants were obtained for combinations of constant pressure (600, 700, 750 MPa) and temperature (25, 35, 45 ◦ C) for pH values 4 and 5. According to the Eyring and Arrhenius equations, activation volumes and activation energies, respectively, representing pressure and temperature dependence of the inactivation rate constant, were calculated for all temperatures and pressures studied. The combined use of HP led to PPO inactivation (<10% remaining PPO activity). An increase in the temperature at pressure 600 or 750 MPa caused an increase in PPO inactivation (4.5 and 9.0%, respectively). The ultimate goal was to produce a HP processed avocado puree-based smoothie beverage (containing acid whey and other ingredients) with superior quality and increased shelf life (under refrigeration). The blended ingredients were HP processed in PET packages (600 MPa-25 ◦ C-10 min, 600 MPa-35 ◦ C-10 min, 750 MPa-25 ◦ C-5 min, 750 MPa-35 ◦ C-5 min) based on PPO inactivation as well as industrial practices. Non-processed as well as thermally (TM) processed (90 ◦ C-5 min) samples were used as control samples. No signiﬁcant differences were found in sensorial attributes between non-processed and HP samples, although the aroma and acceptability scores decreased signiﬁcantly for thermally pasteurized smoothies. Based on the data obtained, 600 MPa-25/35 ◦ C-10 min are sufﬁcient to obtain safe smoothies (of pH 5 approximately) (up to 6 months) whose organoleptic properties are equally as acceptable to consumers as freshly made smoothies.


Introduction
Avocado (Persea americana Mill.) is a tropical/subtropical fruit of excellent sensory properties with high nutritional value [1]. Eight million metric tons are harvested annually, with 72.5% produced from America, 12.8% from Africa, 11.4% Asia, 1.7% Europe, and 1.6% Oceania [2]. The harvesting and consumption of avocado ("Hass" being the most produced and consumed variety) has increased more than two-fold in the last ten years. Avocado fruit (oil fraction 15-30%, depending on the variety) is recognized for its high content of lipids, mainly monounsaturated fatty acids (75%) and polyunsaturated fatty acids (10-15%); the consumption of avocado is also related to beneficial health effects [3]. It is consumed fresh (whole fruit of chunks or halves) or processed (e.g., avocado puree, avocado-based paste such as guacamole). Avocado puree is also considered as a good source of dietary fibers, carbohydrates, minerals, proteins, and vitamins (e.g., C, E).

High-Pressure Processing
The avocado puree extracts were vacuum packed in multi-layered polymer film (EVOH and LDPE) and HP processed as following: HP (600, 700, 750 MPa), temperature (25,35,45 • C), time (0, 5,10,15,20,30,40,45, 60 min), and pH (4,5,6). HP processing conditions were selected to ensure adequate endogenous enzyme inactivation. The HP unit (Food Pressure Unit FPU 1.01, Resato International BV, Holland) comprised a pressure intensifier and one vessel (1.5 L), with a maximum operating pressure and temperature of 1000 MPa and 90 • C. Pressure and temperature in the chamber were constantly monitored and recorded (in 1 s intervals) during the process. The polyphenoloxidase (PPO) in avocado puree extract was measured according to the Fang et al. methodology, with slight modifications as following [24]. The crude enzyme was prepared by mixing 3 g of avocado puree or avocado puree-based smoothie beverage with 6 mL of 0.2-M sodium phosphate (Na 2 HPO 4 /NaH 2 PO 4 ) buffer (pH 6.5) containing 4% (w/v) PVPP and 1% (v/v) Triton X100. The mixture was then stirred (ambient temperature, 10 min) and centrifuged (6000 rpm, 15 min). The obtained supernatant, which contained crude PPO, was filtered (Chromafil PVDF-45/25, Macherey-Nagel, Dueren, Germany) and kept at 0 • C before analysis (high-pressure processing at selected pressure and temperature conditions). PPO activity was determined using a 100 µL aliquot of the PPO extracts. The enzyme was diluted in 3 mL of 0.05 M sodium phosphate buffer (pH 6.5) with catechol at a concentration of 0.07 M. The increase in absorbance at 420 nm for 2 min was recorded. The absorbance graph (A 420 nm) with the reaction time was plotted to simulate the enzyme inactivation kinetics.

Modeling Avocado Polyphenoloxidase (PPO) Inactivation
PPO inactivation followed a first order kinetic model [4]. PPO activity decrease was described by Equation (1) or Equation (2) as a function of time at constant pressure (600-750 MPa) processing conditions.
Here, A and A 0 are the enzymatic activity at time t and time zero, respectively, t is the time, and k is the inactivation rate constant.
The temperature dependence of the inactivation rate constant (k PPO ) was expressed by the activation energy (E a ) using the Arrhenius equation (Equation (3)) [4].
Here, k Tref is the inactivation rate constant at the reference temperature, T ref (K), and R is the universal gas constant (8.314 J/(mol·K)).
The pressure effect on the reaction rate constant, k p , was described by the activation volume, V aT (mL/mol), using the Eyring equation as following [4]: where k Pref the inactivation rate (min −1 ) at the reference pressure, P ref , and R is the universal gas constant (8.314 J/mol·K). The combined effects of temperature and pressure were described by a mathematical model Equation (5) taking into account the effect of temperature on the activation volume and the effect of pressure on the activation energy.
The produced avocado puree-based smoothie beverages were tested for enzymatic browning (color) and for PPO activity. The color change was measured in CIELab scale by a chromatometer after up to 24 h of storage at 25 • C. The total color difference was expressed by ∆E value and it was mathematically modelled using a three-parameter sigmoid equation (t 0 , k ∆E , ∆E max ; supplementary files). PPO activity was determined spectrophotometrically and expressed as % remaining activity (A/A 0 ) (based on methodology in Section 2.2.1).

Quality and Shelf-Life Determination
The avocado puree-based beverage samples were stored at stable temperature conditions (5, 10, 15 • C) (Sanyo MIR 153, Sanyo Electric, Ora-Gun, Gunma, Japan). Kinetic analysis of the selected quality parameters of the beverages was conducted in order to estimate the quality loss during refrigerated storage and estimate shelf life. Color, nutritional (vitamin C), microbiological (Total Viable Count, Yeasts & Molds), and sensorial analyses were conducted.

Color
Instrumentally (CR-200 Chromameter ® , Minolta Co., Tokyo, Japan) measured avocadobased beverage color was expressed by three color coordinates: the L (lightness), the a value (from +: red to −: green) and the b value (from +: yellow to −: blue), and the total color difference, ∆E, calculated by Equation 6.
Here, ∆E is the total color difference, ∆E max is the maximum color change for each studied sample, t 0 is the required maximum storage time for reaching ∆E max , and k is the rate of total color change (supplementary files). All measurements were conducted in triplicate.
Vitamin C Vitamin C (L-ascorbic acid) was determined using a high-performance liquid chromatography method as described by Giannakourou and Taoukis [27]. The results were expressed in mg L-ascorbic acid/100 g fresh material (f.m.). Three replicates were performed for each studied sample. Vitamin C content loss during storage was mathematically described by a first-order reaction as follows (Equation (8)).
Beverages 2023, 9, 38 5 of 16 Here, C vitC is the vitamin C concentration (mg/g initial dry mass) at time t, C vitC0 is the concentration of vitamin C at zero time, and k vitC is the rate constant of vitamin C loss. The temperature dependence of vitamin C loss was described by the Arrhenius equation (Equation (3)).

Sensory Analysis
Twelve trained panellists evaluated some organoleptic characteristics of the produced avocado puree-based beverage according to ISO standards (1993) [28]. The panellists scored from 1 to 9 (9: high quality; 1: low quality) several sensory attributes such as odor, color (the intensity of green color), consistent texture, creamy texture, natural/fresh-like flavor, off flavor, and the overall sensory quality in terms of their preference [18,29]. A score of 5 was set as the limit score for minimum acceptability. Obtained scores for the overall sensory impression were mathematically modeled by using apparent zero-order kinetics (Equation (9)): where S and S 0 are the scores for the overall impression examined at time t and time 0, respectively, and k sens (d −1 ) is the rate constant of overall impression degradation at each storage temperature. The temperature dependence of sensory quality degradation was described by the Arrhenius equation (Equation (3)).

Microbiological Analysis
All samples were analysed in terms of microbial growth during their storage. Total aerobic viable count (TVC) was enumerated on plate count agar (PCA, Merck, Darmstadt, Germany) after incubation at 25 • C for 72 h. The kinetic parameters, such as microbial growth rate (k micr , days −1 ), lag phase λ (d), and initial and final microbial loads, N 0 (log CFU/g ) and N max (log CFU/g ), respectively, were estimated at all tested temperature conditions, using the Baranyi Growth Model [30]. All measurements were conducted in duplicate.

Inactivation Models of Avocado Puree PPO by Thermal and High-Pressure Treatment
Residual PPO activity of the avocado puree with high-pressure processing time, at pressures 600, 700, and 750 MPa and temperatures 25, 35, and 45 • C, is shown in Figure 1 (pH: 4) and Figure 2 (pH: 5). PPO inactivation rates in the avocado puree are calculated according to Equations (1) and (2) for all samples ( Table 1). The activation energy (E a ) and the activation volume (V aT ) are calculated according to Equations (3) and (4) for all samples (Table 1). Avocado puree PPO was high-pressure resistant at ambient temperature. Increasing pressure above 600 MPa led to PPO inactivation as also reported in literature [19,31]. Based on results, the combined effect of pressure and temperature resulted in high inactivation rates of the avocado puree PPO (at pH values 4 and 5) (p < 0.05). An increase in pH from 4 to 5 led to a decrease in the PPO inactivation rate. At pH value 6, avocado PPO was not inactivated (under experimental conditions). In literature, PPO activity was shown to significantly reduced by high-pressure processing [7,9,32]. Palou et al. reported that the residual PPO activities of guacamole reduced to 51% after a 5-min treatment and 37% after a 10-min treatment at 689 MPa [19]. Similarly, Jacobo-Velázquez and Hernández-Brenes reported an average residual PPO activity of 51% and lipoxygenase (LOX) activity of 55% in avocado paste following 600 MPa for 3 min [7].
In this study, the combined effects of pressure and temperature are described by a three-parameter mathematical model (Equation (5); Table 2). The mathematical description of enzyme inactivation is a useful tool to (a) evaluate the effectiveness of HP process applied to beverages, (b) to determine their quality (browning), and (c) estimate their shelf life.     Table 1. Estimated kinetic parameters, inactivation rate k PPO (min −1 ), activation energy E a (kJ/mol), and activation volume V a (mL/mol) for 600, 700, and 750 MPa of avocado puree PPO from 25 to 45 • C (Samples pH: 4 and 5).  Values are mean ± standard error. Values assigned with the same number in the same column (1, 2, 3) and with the same letter (a, b, c) in the same row, for sample pH value 4 and 5, are not statistically significant, regarding the HP processing conditions and the storage temperature effect on the presented kinetic parameters, respectively (p < 0.05).

Selection of the HP Processing Conditions for Avocado Puree-Based Smoothie Beverage Production
The experimental conditions 600 MPa-25 • C-10 min, 600 MPa-35 • C-10 min, 750 MPa-25 • C-5 min, and 750 MPa-35 • C-5 min were selected as the processing conditions for the further step of the avocado puree-based smoothie beverage production. The 750 MPa-5 min conditions were the optimum processing HP conditions based on the results of the previous experiment of the study of HP effect on avocado puree PPO activity (Section 3.1). The 600 MPa-25 • C-10 min conditions were selected to simulate the industrial processing conditions (commonly used in food industry for HP processed products such as juices, sauces). The 600 MPa-35 • C-10 min conditions were applied to study the temperature effect on the shelf life of the developed beverage, under constant pressure.
In Figure 3a, the remaining PPO activity values are presented for HP processed avocado puree-based smoothie beverage samples, respectively. HP processing at 600-750 MPa and temperatures of 25-35 • C led to PPO inactivation (<10% remaining PPO activity). An increase in temperature at pressure 600 or 750 MPa caused an increase in PPO inactivation (4.5 and 9.0%, respectively). Higher values of PPO activity reduction were reported in literature. Palou et al. show that after HP treatment at 689 MPa for 10 min, the remaining PPO activity of guacamole was determined to be equal to 37% [19]. Jacobo-Velázquez and Hernández-Brenes reported that HP treated (600 MPa, 3 min) avocado paste had decreased  [19]. Woolf et al. proved that HP treatment at pressures above 400 MPa resulted in POD activity decreasing and PPO activity increasing (~30% increase compared to control) in avocado (no pH adjustment; ∼ = pH 6.2-6.5) [9]. The avocado PPO has different sensitivity towards HP in terms of pressure and temperature, as well as pH.
sensitivity towards HP in terms of pressure and temperature, as well as pH.
In Figure 3b, the color change (ΔE) values are presented for HP processed avocado puree-based smoothie beverage samples, respectively. The maximum color difference is reported for the experimental conditions 600 MPa-10 min at 25 and 35 °C (15) (no statistically significant differences between different HP processing temperatures 25 and 35 °C; p > 0.05). The respective ΔE values for experimental conditions 750 MPa-25 °C-5 min and 750 MPa-35 °C-5 min are 5 and 6 (no statistically significant differences between different HP processing temperatures 25 and 35 °C; p >0.05). Minor color alteration was observed at the higher pressure of 750 MPa. The color change, ΔE, was significantly decreased with the increase in pressure from 600 to 750 MPa (p < 0.05), whereas it was not significantly affected by the increase in temperature from 25 to 35 °C (p > 0.05). HP processed at 750 MPa smoothie showed a well-visible difference when compared to HP processed at 600 MPa, which showed great differences, according to classification proposed by Cserhalmi et al. (2006) [33]. The avocado puree samples without HP processing had higher PPO activity, resulting in more intense and faster pulp browning. Same results with this study were obtained by Soliva-Fortuny et al. and Bustos et al. [6,10].

Color
In Figure 4, luminosity (L), yellowness (b), and redness (a) at initial time (storage time 0 days) of non-processed, thermally processed, and HP processed avocado beverage samples stored at temperatures 5, 10, and 15 °C are presented, respectively. Color coordinates of non-and HP treated avocado beverages (600 MPa-25 °C-10 min) had no statistically significant differences (p > 0.05), as PPO activity in the early stage did not affect color. The thermal processing (atmospheric-90 °C-5 min) increased the L value and decreased the a value, but did not affect the value of b, resulting in slightly less translucent, less green, and browner smoothies. In Figure 3b, the color change (∆E) values are presented for HP processed avocado puree-based smoothie beverage samples, respectively. The maximum color difference is reported for the experimental conditions 600 MPa-10 min at 25 and 35 • C (15) (no statistically significant differences between different HP processing temperatures 25 and 35 • C; p > 0.05). The respective ∆E values for experimental conditions 750 MPa-25 • C-5 min and 750 MPa-35 • C-5 min are 5 and 6 (no statistically significant differences between different HP processing temperatures 25 and 35 • C; p >0.05). Minor color alteration was observed at the higher pressure of 750 MPa. The color change, ∆E, was significantly decreased with the increase in pressure from 600 to 750 MPa (p < 0.05), whereas it was not significantly affected by the increase in temperature from 25 to 35 • C (p > 0.05). HP processed at 750 MPa smoothie showed a well-visible difference when compared to HP processed at 600 MPa, which showed great differences, according to classification proposed by Cserhalmi et al. (2006) [33]. The avocado puree samples without HP processing had higher PPO activity, resulting in more intense and faster pulp browning. Same results with this study were obtained by Soliva-Fortuny et al. and Bustos et al. [6,10] In Figure 4, luminosity (L), yellowness (b), and redness (a) at initial time (storage time 0 days) of non-processed, thermally processed, and HP processed avocado beverage samples stored at temperatures 5, 10, and 15 • C are presented, respectively. Color coordinates of non-and HP treated avocado beverages (600 MPa-25 • C-10 min) had no statistically significant differences (p > 0.05), as PPO activity in the early stage did not affect color. The thermal processing (atmospheric-90 • C-5 min) increased the L value and decreased the a value, but did not affect the value of b, resulting in slightly less translucent, less green, and browner smoothies. More intense HP conditions (samples: 600 MPa-35 • C-10 min, 750 MPa-25 • C-5 min, 750 MPa-35 • C-5 min) led to similar color alteration with thermal processing (increase in L and b and decrease in a). It was reported that a value (green color) showed sensitivity towards heat and pressure processing [34][35][36]. Al-Ghamdi et al.
observed that L value (luminosity) and a value (red to green) were equally important for the processed avocado paste [34]. At the same time b (yellowness to blue) increased due to the exposure to heat in avocado.
Beverages 2023, 9, x FOR PEER REVIEW 9 of 17 showed sensitivity towards heat and pressure processing [34][35][36]. Al-Ghamdi et al. observed that L value (luminosity) and a value (red to green) were equally important for the processed avocado paste [34]. At the same time b (yellowness to blue) increased due to the exposure to heat in avocado. In Figure 5, color change (calculated as ΔΕ) versus storage time for non-processed, thermally processed, and HP processed avocado beverage samples stored at temperatures 5, 10, and 15 °C are presented, respectively. The kinetic parameters (kcolor, Ea,color), calculated according to Equation 6, are provided in the supplementary files. At the beginning of storage time, the total color difference, ΔE, of each studied sample was increasing significantly, achieving stable values: ΔΕ value of 5, approximately, for storage times >4-10 days at 5-15 °C for thermally processed beverage samples, ΔΕ value of 1.5-2.5, approximately, for storage times >6-10 days Palou et al. reported that HP (689 MPa-5-20 min) did not affect the color of guacamole. However, during storage, several color changes occurred, more specifically [19], the green (a value) color gradually decreased. Changes in hue and chroma were correlated with a values, indicating that severe browning of guacamole was observed when the a value was positive. Lopez-Malo et al. reported that the loss of the green color of avocado puree was negatively affected by residual PPO activity, initial pH, and storage temperature [5]. An acceptable color of the avocado puree was maintained during refrigerated storage for a longer time when the high pressure was applied (517/689 MPa) and the pH was 4.1 or 3.9. Color changes during storage could be attributed to residual PPO activity after high-pressure processing and also to possible PPO regeneration during storage [37]. Inhibition of undesirable enzymatic reactions, such as browning of avocado products, requires the combination of pressure treatments with one or more additional factors to inhibit enzyme activity, such as refrigeration temperatures [19]). Studies of the effects of HP In Figure 5, color change (calculated as ∆E) versus storage time for non-processed, thermally processed, and HP processed avocado beverage samples stored at temperatures 5, 10, and 15 • C are presented, respectively. The kinetic parameters (kcolor, E a,color ), calculated according to Equation 6, are provided in the supplementary files. At the beginning of storage time, the total color difference, ∆E, of each studied sample was increasing significantly, achieving stable values: ∆E value of 5, approximately, for storage times >4-10 days at 5-15 • C for thermally processed beverage samples, ∆E value of 1.5-2.5, approximately, for storage times >6-10 days at 5-5 • C for HP samples processed at 600 MPa (−25 • C-10 min, −35 • C-10 min), and ∆E value of 2-6, approximately, for storage times >6-10 days at 5-15 • C for HP samples processed at 750 MPa (−25 • C-5 min, −35 • C-5 min). HP samples at 750 MPa showed significantly higher ∆E values at higher storage temperatures (p < 0.05).
Palou et al. reported that HP (689 MPa-5-20 min) did not affect the color of guacamole. However, during storage, several color changes occurred, more specifically [19], the green (a value) color gradually decreased. Changes in hue and chroma were correlated with a values, indicating that severe browning of guacamole was observed when the a value was positive. Lopez-Malo et al. reported that the loss of the green color of avocado puree was negatively affected by residual PPO activity, initial pH, and storage temperature [5]. An acceptable color of the avocado puree was maintained during refrigerated storage for a longer time when the high pressure was applied (517/689 MPa) and the pH was 4.1 or 3.9. Color changes during storage could be attributed to residual PPO activity after high-pressure processing and also to possible PPO regeneration during storage [37]. Inhibition of undesirable enzymatic reactions, such as browning of avocado products, requires the combination of pressure treatments with one or more additional factors to inhibit enzyme activity, such as refrigeration temperatures [19]). Studies of the effects of HP on the oxidative enzymes in fruit derivatives revealed differing levels of enzyme inactivation [38]. on the oxidative enzymes in fruit derivatives revealed differing levels of enzyme inactivation [38].

Vitamin C
In Table 3, the kinetic parameters (kvitC, Ea,vitC), calculated according to Equations (3) and (7), are provided. In the supplementary files (Supplementary Figure S1), the remaining vitamin C content versus storage time for HP processed avocado beverage samples stored at temperatures 5, 10, and 15 °C is presented. The vitamin C loss rate is significantly

Vitamin C
In Table 3, the kinetic parameters (k vitC , E a,vitC ), calculated according to Equations (3) and (7), are provided. In the supplementary files (Supplementary Figure S1), the remaining vitamin C content versus storage time for HP processed avocado beverage samples stored at temperatures 5, 10, and 15 • C is presented. The vitamin C loss rate is significantly affected by the storage temperature for either thermal processing or HP processing, both pressures of 600 and 750 MPa (p < 0.05) and temperatures of 25 and 35 • C (p < 0.05); however, it is not significantly affected by the processing pressure at processing temperature 25 • C (p > 0.05). From the above, it could be concluded that the heat treatment leads to the vitamin C reduction in the smoothie beverage and, consequently, its nutritional value, probably due to the presence of residual oxygen. Specifically, in the 39 days of storage at a temperature of 15 • C, the thermally pasteurized beverage has a 90% reduced concentration of vitamin C. On the same day, the HP processed samples showed a decrease in concentration of less than 60%. This is also shown by the vitamin C loss reaction rates, k vitC , which are 10-fold in the thermally processed samples, both those treated with HP as well as the non-processed ones. HP helps to maintain the vitamin C concentration. The highest values of concentrations are observed for processing conditions of 750 MPa at 25 and 35 • C for 5 min, the values of which are about 90% of the initial vitamin C content at 5 • C, 85% at 10 • C, and 77% at 15 • C. Andres et al. reported that after HP (600 MPa/3 min/20 • C), ascorbic acid content of a smoothie was almost unaffected (92% of the initial content) [38]. Table 3. Estimated kinetic parameters, k vitC (days −1 ), and activation energy, E a,vitC (kJ/mol), values for vitamin C loss in avocado puree-based smoothie beverages stored at temperatures 5, 10, and 15 • C. Samples: 600 MPa-25 • C-10 min, 600 MPa-35 • C-10 min, 750 MPa-25 • C-5 min, and atmospheric-90 • C-5 min (thermally processed).

HP Processed Smoothie Beverage
Storage Temperature E a,vitC (kJ/mol) Values are mean ± standard error. Values assigned with the same small and capital letter in the same column (a, b, c, and A, B) are not statistically significant, regarding the HP processing conditions and the storage temperature effect on the presented kinetic parameters, respectively (p < 0.05).
Higher percentages of ascorbic acid retention in HP processed than in thermally processed smoothie beverages were reported [39,40]. The ascorbic acid retention was noticeably higher in HP (450 and 600 MPa) smoothie beverages (95% and 92%, respectively) than in thermally processed ones (88%). Similar percentages of losses were reported for orange juice-milk beverage at 400 MPa [41] and tomato-based smoothie beverage at 600 MPa [42]. It was also observed that the degradation rate of ascorbic acid was enhanced by increasing pressure [14,41,42]. Sakhale et al. suggested the ascorbic acid deterioration of HP processed samples could be explained by the possible existence of other anti-or prooxidants, pressure-induced enzyme activation, and aerobic and non-enzymatic anaerobic reactions [43]. Cao et al. observed that ascorbic acid decreased 39.61% in cloudy strawberry juices treated with HP (600 MPa, 4 min) after 6 months of storage at 4 • C [44].

Sensory Quality
In Figure 6, the sensory scores for the selected properties (odor, the intensity of green color, consistent texture, creamy texture, natural/fresh-like flavor, off flavor, and the overall sensory quality) of non-processed, thermally processed, and HP processed avocado puree-based beverage samples, at initial time (storage time 0 days), are presented. The maximum preference scores were given for the avocado puree-based beverage samples processed at 600 MPa-35 • C-10 min and 600 MPa-25 • C-10 min (7.3 and 7.0 average scores for the sensory quality, respectively). The samples processed at 750 MPa-25 • C-5 min and 750 MPa-35 • C-5 min and thermally processed sample received lower scores (6.5, 6.0, and 6.3 average scores for the sensory quality, respectively). All HP processed samples were characterized by "fresh-like" avocado fruit characteristics (vivid green color, creamy and consistent texture, natural avocado flavor) and were evaluated positively by trained sensory panellists. However, HP processed samples at 750 MPa were characterized by a slight metallic taste and TH-processed samples by a cooked-like taste as well as a bitter taste (also reported for thermally processed avocado pulps by Bates and Degenhardt & Hofmann [11,45]. This was depicted in the sensory scores for the off-flavor development. The HP processed samples at 750 MPa and thermally processed samples received the lowest scores, 5.3 and 5.8, respectively. The HP processed samples at 750 MPa-35 • C-10 min were characterized by the lowest scores for the texture characteristics (consistent and creamy texture, 6.1 the average score) compared to other HP samples (the respective scores ranged from 7.1-8.0). Overall. the highest sensory quality scores (taking into account texture, flavor, as well as off-flavor development) were given for the samples processed at 600 MPa 6.3 average scores for the sensory quality, respectively). All HP processed samples w characterized by "fresh-like" avocado fruit characteristics (vivid green color, creamy a consistent texture, natural avocado flavor) and were evaluated positively by trained s sory panellists. However, HP processed samples at 750 MPa were characterized by a sli metallic taste and TH-processed samples by a cooked-like taste as well as a bitter ta (also reported for thermally processed avocado pulps by Bates and Degenhardt & H mann [11,45]. This was depicted in the sensory scores for the off-flavor development. T HP processed samples at 750 MPa and thermally processed samples received the low scores, 5.3 and 5.8, respectively. The HP processed samples at 750 MPa-35 °C-10 min w characterized by the lowest scores for the texture characteristics (consistent and crea texture, 6.1 the average score) compared to other HP samples (the respective scores rang from 7.1-8.0). Overall. the highest sensory quality scores (taking into account texture, vor, as well as off-flavor development) were given for the samples processed at 600 M (25 and 35 °C, 10 min; 7.3 and 7.0 average scores, respectively). The Palou et al. and Lop Malo et al. reported that HP treatments (689 MPa-5-20 min) preserve sensory attribute the avocado paste product (guacamole) [5,19]. In the supplementary files (Supplementary Figure S2), the sensory quality cont versus storage time for HP processed avocado beverage samples stored at temperatu 5, 10, and 15 °C are presented. In Table 4, the respective kinetic parameters (ksens, Ea,s calculated according to Equations (4) and (8), are provided. The sensory quality loss r In the supplementary files (Supplementary Figure S2), the sensory quality content versus storage time for HP processed avocado beverage samples stored at temperatures 5, 10, and 15 • C are presented. In Table 4, the respective kinetic parameters (k sens , E a,sens ), calculated according to Equations (4) and (8), are provided. The sensory quality loss rate is significantly affected by the storage temperature for either thermal processing or both processing pressures of 600 and 750 MPa (p < 0.05) and processing temperatures of 25 and 35 • C (p < 0.05) at storage temperatures (T > 10 • C). Similarly, it is significantly affected by the processing (either thermally or both HP) at higher storage temperatures (e.g., T = 15 • C) (p > 0.05).

Microbial Stability
Microbial data confirmed that the HP as well as thermally processed samples (TVC, yeasts, and moulds not detected) had increased stability. HP and thermal treated avocado puree-based smoothie beverages did not present microbial growth (<2 log CFU/mL). No significant differences were observed between HP and TH processed samples (p < 0.05). Unni, Chauhan, and Raju reported that HP (200-600 MPa/5 min/30 • C) and thermal (90 • C/5 min) treatments were effective to decrease equally the microbial counts in ginger paste [35]. HP guacamole was microbiologically stable <10 cfu for 30 days at 5, 15, and 25 • C, whereas guacamole controls, at 5 • C, spoiled within the first 5 days [19]. Table 4. Estimated kinetic parameters, k sens (days −1 ) and activation energy (E a,sens , kJ/mol) values for sensory quality of avocado puree-based smoothie beverages stored at temperatures 5, 10, and 15 • C. Samples: 600 MPa-25 • C-10 min, 600 MPa-35 • C-10 min, 750 MPa-25 • C-5 min, and atmospheric-90 • C-5 min (thermally processed). Values are mean ± standard error. Values assigned with the same small and capital letter in the same column (a, b, c, and A, B) are not statistically significant, regarding the HP processing conditions and the storage temperature effect on the presented kinetic parameters, respectively (p < 0.05).

Shelf-Life Determination
The shelf life of HP processed samples was calculated based on the total sensory quality criteria (final score = 5/9) [e.g., 600 MPa 35 • C 10 min 160 days] ( Table 5). The shelf life of TH processed samples was 25 days, based on 50 vitamin C loss. The shelf life of the non-processed smoothie beverage was 7 days, calculated based on microbial growth. The application of HP (and mild temperatures, up to 35 • C) can lead to the production of a smoothie beverage of superior quality and stability with "fresh-like" characteristics. HP processed avocado guacamole has an approximate shelf life of 3 months at refrigeration temperature [34]. Table 5. Shelf life (days) calculated based on microbial growth (logCFU value at the end of shelf life, 8), vitamin C loss (maximum acceptable vitamin C loss at the end of shelf life, 50% of the initial), and sensory quality (final score at the end of shelf life, 5.0/9.0). Samples: non-processed, thermally processed, HP processed 600 MPa-25 • C-10 min, 600 MPa-35 • C-10 min, 750 MPa-25 • C-5 min, and 750 MPa-35 • C-5 min.
It is widely known that HP processing is an efficient pasteurization method, obtaining microbiologically safe food products with minimum effect on nutritional and sensorial properties. Hurtado et al. studied the effects of HP treatments (350, 450 MPa-5 min, 600 MPa-3 min, both at 10 • C, and thermal pasteurization 85 • C-7 min) on sensory, enzymatic, quality, nutritional properties, and microbial quality after 30 days of refrigerated storage of fruit smoothies [5]. HP (>450 MPa) resulted in microbiological safety, retention of quality, vitamin C content, and sensory characteristics of smoothies. The thermal treatment led to inactivation of oxidase and pectin enzymes, although there was loss of vitamin C and "cooked" flavour in smoothies.

Conclusions
High-pressure processing is an alternative non-thermal food processing technique applied to smoothie beverages with minimal negative effects on nutritional and sensory parameters compared to conventional thermal processing. In the present study, highpressure processing conditions studied (600-750 MPa, 25-45 • C, 5-10 min, pH [4][5] show that high pressure leads to a satisfactory result for a smoothie beverage with minimum quality/sensory changes (in terms of color, texture, overall sensory quality, high retention of vitamin C) and increased shelf life compared to the respective freshly made smoothie beverage (as well as thermally processed). HP processing at 600 MPa (at mild temperatures up to 35 • C for time 10 min) are recommended as the optimum HP processing conditions for the design and production of an innovative avocado puree-based smoothie beverage (along with other ingredients). At the same time, the PPO inactivation in avocado puree as well as in avocado puree-based smoothie beverage has been studied. A three-parameter mathematical model that describes the temperature and pressure dependence of the PPO inactivation rate in avocado puree has been developed. This model can serve as a prediction tool for PPO inactivation (in the range of temperature, HP, and pH of the experiment).

Data Availability Statement:
The data presented in this study are available on request from the corresponding author.