《现代食品工程高新技术》课程教学资源（文献资料）食品包装、杀菌新技术 Comparing quality changes of cupped strawberry treated by high hydrostatic pressure and thermal processing during storage

OOD AND (06)221-22 Contents lists available at ScienceDirect Food and Bioproducts Processing IChemE ELSEVIER journal homepage:www.elsevier.com/locate/fbp Comparing quality changes of cupped strawberry Qcstht treated by high hydrostatic pressure and thermal processing during storage Ge Gao Pengyan RenXiamin CaoBing Yan Xiaojun Liaoa.b.d,Zhijian Suna.b.cd,Yongtao Wanga.b.cd. ARTICLE INFO ABSTRACT High hydrostatic pressure(HHP)and thermal processing of strawberry in ethylene vinyl alco nd During storage, tota those HHP-treated and stored at25C(/gatday 45,resp ha aaetd加ctioninhatdnes atic pressure ne rved durine gher y inc nols.total anthocyanins and ar ant ca ter color than s 6 re were serving th of cupped strawberry 2016 Institution of Chemical Engineers.Published by Elsev r B.V.All rights Introduction st62009Ho Strawberries are a soft juicy and palatable berry with bright- are rath usceptible to physical damage and fungal atta bi and flavor during and pr ertes,mainly 209.Ct2012The ant capacity of stra can participate in the prevention of cancer,cardiovascular an mnal add 3.com (Y.Wang .10 Engneers Published by Elsevier B.VAll rights reserved

food and bioproducts processing 1 0 0 ( 2 0 1 6 ) 221–229 Contents lists available at ScienceDirect Food and Bioproducts Processing journal h om epage: www.elsevier.com/locate/fbp Comparing quality changes of cupped strawberry treated by high hydrostatic pressure and thermal processing during storage Ge Gao a,b,c,d, Pengyan Rena,b,c,d, Xiamin Cao a,b,c,d, Bing Yana,b,c,d, Xiaojun Liao a,b,c,d, Zhijian Suna,b,c,d, Yongtao Wang a,b,c,d,∗ a Beijing Advanced Innovation Center for Food Nutrition and Human Health, Beijing 100083, China b College of Food Science and Nutritional Engineering, China Agricultural University, Beijing 100083, China c National Engineering Research Center for Fruit & Vegetable Processing, Beijing 100083, China d Key Laboratory of Fruit & Vegetable Processing, Ministry of Agriculture, Beijing 100083, China a r t i c l e i n f o Article history: Received 3 April 2015 Received in revised form 1 June 2016 Accepted 28 June 2016 Available online 22 July 2016 Keywords: High hydrostatic pressure processing Cupped strawberry Texture Anthocyanins Color a b s t r a c t High hydrostatic pressure (HHP) and thermal processing of strawberry in ethylene vinyl alco￾hol copolymer cups were evaluated by examining their impacts on microorganism survival and growth, texture, nutritional properties (total phenols, total anthocyanins and antiox￾idant capacity) and color during 45 days of storage at 4 and 25 ◦C. During storage, total aerobic bacteria and yeasts and molds were not detected in all treated samples except for those HHP-treated and stored at 25 ◦C (3.08 and 2.58 log10 CFU/g at day 45, respectively). There was a reduction in hardness, total phenols, total anthocyanins and antioxidant capacity of flesh, being more striking in samples stored at 25 ◦C and thermal processing treated sam￾ples, and an increase in viscosity, total phenols, total anthocyanins and antioxidant capacity of syrup during storage. Moreover, a significant decrease in the total level of nutritional properties in cupped strawberry (combined flesh and syrup) was observed during storage. All samples showed noticeable color changes, and E values significantly increased during storage. Samples treated by HHP and stored at 4 ◦C showed higher hardness, total phe￾nols, total anthocyanins and antioxidant capacity and better color than samples treated by thermal processing and stored at 25 ◦C, indicating that HHP processing and lower storage temperature were very useful tool in preserving the quality of cupped strawberry. © 2016 Institution of Chemical Engineers. Published by Elsevier B.V. All rights reserved. 1. Introduction Strawberries are a soft juicy and palatable berry with bright￾red color, and an important bioresource with good processing potential as functional foods. They are abundant in bioac￾tive compounds with antioxidant properties, mainly including phenolic compounds, especially anthocyanins (Terefe et al., 2009; Cao et al., 2012). The antioxidant capacity of strawberry can participate in the prevention of cancer, cardiovascular and ∗ Corresponding author at: College of Food Science & Nutritional Engineering, China Agricultural University, No. 17, Qinghua East Road, Haidian District, Beijing 100083, China. Fax: +86 10 62737434. E-mail address: wangyongtao102@163.com (Y. Wang). other chronic diseases (Oszmianski ´ and Wojdyło, 2009). How￾ever, strawberries have a very short postharvest life since they are rather susceptible to physical damage and fungal attack, and are also very sensitive to deterioration in color, texture and flavor during transport, storage and processing (Terefe et al., 2009). In recent years, strawberry with syrup in EVOH (ethylene vinyl alcohol copolymer) cups, preserved using ther￾mal processing (TP) has become popular in China. However, TP can deteriorate the quality of processed strawberries, http://dx.doi.org/10.1016/j.fbp.2016.06.017 0960-3085/© 2016 Institution of Chemical Engineers. Published by Elsevier B.V. All rights reserved.

222 10020161221-229 2.2. HHP and TP treatments of cupped strawberry on ion nt( (25).The diameter of the cylinder was 150mm.The nact )water wasusedasth Paz et release time. on the covalent bonds of low molecular-mass com nds ence Te gy Deve lopm procesmany fruit products such as blackberry puree(Pat the p -Santoset 2012).st juice (Pa 11,2012 mango pulp) ed to25 y running wate nd ve (400 MPa/5 min) after 2011 M wer (POD),induced The contro 1.20121 Storage onditions and sampling dates s enzymes may be propitious to pres ve the qua he quality eprodiuctsint absence of endogenou of storage. 2.4.Microbiological analysis otal phenls TAR and Y&M were estimated using the method deseribed b whngtl2ol2LTeatedandconralsamplesweresenial rocessing. Materials and methods 2.5. Measurement of pH 21 Preparation of cupped strawberry In this study the straw h at commercial maturity in March 2,was in ta or 1 min d by steam (cor G128.2 Hardness of fesh ory.Gu ngzhou,Guangdong heate I by an elec The hardness of flesh was determined using the method Foshan,Guangdo doge dt025 immediately,and p y using a texture T2i, then 154 mL syr ural a anaysis One single fruit was taken fror Beijing.China)and 0.acid wa s noured into eac cher.andplaced on the base plate of the te ure um se was me na 250N cell running water within 30min The crosshead pre-test.test.and post-test speed was1mm/s

222 food and bioproducts processing 1 0 0 ( 2 0 1 6 ) 221–229 including the color, texture, taste, and functional compounds, due to the heat sensitivity of the strawberry and its labile constituents. High hydrostatic pressure (HHP) is a non-thermal food preservation technique which subjects foods to up to 1000 MPa at room or mild process temperatures (<60 ◦C) (Cao et al., 2012). Pathogens and vegetative spoilage microorganisms are inactivated by HHP processing thereby enhancing safety and shelf life of perishable foods (Knorr, 1993; Mújica-Paz et al., 2011). HHP processing is a good alternative to heat treatment because it does not lead to deterioration of the color, flavor, texture, and nutritional values of foods due to its limited effect on the covalent bonds of low molecular-mass compounds (Balasubramaniam et al., 2008; Oey et al., 2008; Mújica-Paz et al., 2011; Cao et al., 2012). Up to now, HHP has been applied to process many fruit products such as blackberry puree (Patras et al., 2009), apple puree (Landl et al., 2010), pomegranate juice (Varela-Santos et al., 2012), strawberry puree and juice (Patras et al., 2009; Cao et al., 2011, 2012), mango pulp (Liu et al., 2012) and yellow peach in pouches (Zhang et al., 2012). Previ￾ous studies demonstrated that endogenous enzymes related to food quality may show pressure resistance or even be acti￾vated by HHP processing (Oey et al., 2008; Cao et al., 2011). The residual activity of endogenous enzymes, such as pectin methyl esterase (PME), polyphenol oxidase (PPO) and per￾oxidase (POD), induced the changes in texture, nutritional properties and color in HHP-treated fruit and vegetable prod￾ucts during processing and storage (Patras et al., 2009; Nguyen et al., 2010; Landl et al., 2010; Cao et al., 2011; Torres et al., 2011; Varela-Santos et al., 2012). Therefore, the total inactivation of endogenous enzymes may be propitious to preserve the qual￾ity of HHP-processed fruit and vegetable products. However, literature data on the effect of HHP processing on the quality of fruit and vegetable products in the absence of endogenous enzymes is very limited. The objective of this work was to evaluate the impact of HHP and TP of cupped strawberry on microorganisms, texture, total phenols, total anthocyanins, antioxidant capacity and color during storage. This study will provide technical support for commercial application of HHP technique in strawberry processing. 2. Materials and methods 2.1. Preparation of cupped strawberry In this study, the strawberry variety “Camarosa”, harvested at commercial maturity in March 2012, was obtained from Tianyi Bio-engineering Company in Changping county (Bei￾jing, China). Fresh strawberries were rinsed in tap water, blanched by steam (core temperature of strawberries 100 ◦C) for 1min in a steam pan (CJ128, Zhenghan Stainless Steel Fac￾tory, Guangzhou, Guangdong) heated by an electromagnetic furnace (Midea RT 2103, Guangdong Midea Electrical Co., Ltd., Foshan, Guangdong) to inactivate the endogenous enzymes, cooled to 25 ◦C by running water immediately, and placed in plastic cups (EVOH, 227mL). 80 g strawberries were packed in each cup, and then 154mL syrup (boiled for 10min and cooled to 60 ◦C) with 16 g/L sucrose (Beijing Sugar Tobacco & Wine Co., Beijing, China) and 0.16 g/L citric acid was poured into each cup. The cups were vacuum sealed (0.04 MPa) immediately with plastic film (nylon/polyethylene), and cooled to 25 ◦C by running water within 30min. 2.2. HHP and TP treatments of cupped strawberry HHP treatments were carried out using a hydrostatic pressur￾ization unit (HHP-700, Baotou Kefa Co., Ltd., Inner Mongolia, China) with a capacity of 7 L at ambient temperature (25 ± 1 ◦C). The diameter of the cylinder was 150mm. The pressurization rate was about 120 MPa/min and the depressur￾ization was immediate (<3 s). Distilled water was used as the pressure-transmitting fluid. The treatment time in this study did not include the pressure-increase time and pressure￾release time. TP treatment was carried out by heating samples also stored in EVOH cups in water in a thermostatic water bath (LY-9A, Qingyuan Science & Technology Development Co., Ltd., Beijing, China). A thermocouple was inserted into the center of the strawberry located at the package cold point. When sam￾ples achieved a core temperature of 75 ◦C, they were held at this temperature for 20min. Then, samples were immediately cooled to 25 ◦C by running water. According to our previous studies, after HHP (400 MPa/5min) and TP (75 ◦C/20min) treatments, total aerobic bacteria (TAB) and yeasts and molds (Y&M) were not detected, and good hardness and color of samples was preserved. Therefore, cupped strawberries were treated by these treatments, and the qualities of these treated samples were evaluated during storage in this study. The control sample was a vacuum sealed cup of strawberries in syrup that did not receive any further treatment. 2.3. Storage conditions and sampling dates The treated samples were stored at 4 ◦C and 25 ◦C in the dark. Sample analyses were carried out after 0, 15, 30 and 45 days of storage. 2.4. Microbiological analysis TAB and Y&M were estimated using the method described by Wang et al. (2012). Treated and control samples were serially diluted with sterile 0.85% NaCl solution, and 1.0mL of each dilution was plated into duplicate plates of appropriate agar. All measurements were made in triplicate. 2.5. Measurement of pH Strawberry flesh was pulped by juice extractor (JY-610, Joy￾oung Co., Ltd., Shandong, China) for 5min, and equilibrated at 25 ◦C. pH value was measured at 25 ◦C with a thermo Orion 868 pH meter (Thermo Fisher Scientific, Inc., MA, USA). All measurements were made in duplicate. 2.6. Hardness of flesh The hardness of flesh was determined using the method described by Trejo Araya et al. (2007) with some modifications. Texture profile analysis was used to evaluate the hardness of flesh by using a texture analyzer (TA-XT2i, Stable Micro Sys￾tem, Surrey, UK). Samples were equilibrated to 25 ◦C before textural analysis. One single fruit was taken from syrup, cut into cylinders (10mm long with a diameter of 12mm) by a hole puncher, and placed on the base plate of the texture analyzer. The sample was measured with a 250 N cell at a deforma￾tion rate of 1mm/s on the platform as an upright cylinder. The crosshead pre-test, test, and post-test speed was 1mm/s

FOOD AND BIOPRODUCTS FROCESSING I00 (2016)221-229 223 2.9 Quantification of total anthocyanins Strawberry flesh was pulpedfor 5min to be made into strw 2.7.Viscosity measurement of syrup The viscosity of syrup was determined using an AR550 00waegnonieh2nnnheettc anduredatu mostati er blan treatment Anthocyanin content of flesh (mg/100g) 2.8. Quantification of total phenols x m Anthocyanin content of syrup (mg/100mL) kept in the dark formn =AxMW x DF x 100 ② Wer V.the voum and reacted for15min,and then the 2.10.Antioxidant capacity measurements The dPPH and frap as med as de measurements were made in cribed b Table 1-Changes of color parameters in cupped strawberry during storage at 4C and 25C. Storage time (day) Syrup TP4C HHP 25C HHP4C TP4C HHP 25C TP 25*C 46±1 40±5 50 器 0 505 234 044 0466 0338 20

food and bioproducts processing 1 0 0 ( 2 0 1 6 ) 221–229 223 with a rest period of 5 s between cycles, and the deforma￾tion was 30% of the original height. Ten determinations were performed for each treatment. 2.7. Viscosity measurement of syrup The viscosity of syrup was determined using an AR550 rheometer (TA Instruments, Waters Co., Ltd., Surrey, UK) with a conical end concentric cylinder (stator radius 15mm, rotor radius 14mm, immersed height 42mm, gap 5.92mm). An aliquot of syrup (13.5mL) was applied at each measurement at 25 ± 0.1 ◦C controlled by circulating water in a thermostatic system. In the test, the shear rate was increased from 4 to 63 s−1, and three determinations were performed for each treatment. 2.8. Quantification of total phenols Strawberry flesh was pulped by juice extractor (JY-610, Joyoung Co., Ltd., Shandong, China) for 5min. 5 g of strawberry pulp was mixed with 30mL of methanol, and then the mixture was kept in the dark for 30min at 4 ◦C, centrifuged at 12,000 × g for 10min at 4 ◦C (GR21G, Hitachi Koki Co., Ltd., Tokyo, Japan). The supernatant was collected for further analysis. The total phenols were determined using the Folin–Ciocalteu method described by Cao et al. (2011) with some modifications. A 0.4mL volume of flesh extract (or syrup) was mixed with 2mL of Folin–Ciocalteu reagent (previously diluted 10-fold with distilled water) and set for 1h in the dark at room temperature. After that, 1.8mL of sodium carbonate solution (7.5%) was added to the mixture and reacted for 15min, and then the mixture absorbance was immediately measured at 765nm using a spectropho￾tometer (UV-726, Shimadzu, Shanghai, China). Results were expressed as mg of gallic acid equivalent (GAE) per 100 g of flesh (mg GAE/100 g), or 100mL of syrup (mg GAE/100mL). All measurements were made in duplicate. 2.9. Quantification of total anthocyanins Strawberry flesh was pulped for 5min to be made into straw￾berry syrup. 5 g strawberry pulp was mixed with 10mL of 0.1% HCl in methanol, and then the mixture was kept in the dark for 2h at 4 ◦C, centrifuged at 12,000 × g for 10min at 4 ◦C. The supernatant was collected for further analysis. The spectrophotometric pH differential method (Xu et al., 2010) was used to quantify anthocyanins in the extracts in this study. Two dilutions of the same sample (flesh extracts or syrup) were prepared using 0.025 M potassium chloride solution and 0.4 M sodium acetate solution adjusted to pH 1.0 and 4.5 with HCl, respectively. The absorbance of each dilu￾tion was measured at 520nm against a distilled water blank using a spectrophotometer (UV-726, Shimadzu, Shanghai, China). Anthocyanin content was calculated by the following equation. Anthocyanin content of flesh (mg/100 g) = A × MW × DF × V × 100 ε × L × m (1) Anthocyanin content of syrup (mg/100mL) = A × MW × DF × 100 ε × L (2) where A = ApH1.0–ApH4.5, MW is the molecular weight of pelargonidin-3-glucoside (433 g/mol); DF, the dilution factor; V, the volume of flesh extract (mL); ε, the molar absorptivity of pelargonidin-3-glucoside (22,400 L cm−1 mol−1); L, the path length (1 cm); m, the weight of flesh (g). Total anthocyanin content was reported as milligrams anthocyanins per 100 g of flesh (mg/100 g), or 100mL of syrup (mg/100mL). All measurements were made in duplicate. 2.10. Antioxidant capacity measurements The DPPH and FRAP assays were performed as described by Wang et al. (2012) with some modifications. A 100L aliquot Table 1 – Changes of color parameters in cupped strawberry during storage at 4 ◦C and 25 ◦C. Storage time (day) Flesh Syrup HHP 4 ◦C TP 4 ◦C HHP 25 ◦C TP 25 ◦C HHP 4 ◦C TP 4 ◦C HHP 25 ◦C TP 25 ◦C L* 0 38 ± 2 41 ± 5 38 ± 2 41 ± 5 32 ± 0 32 ± 0 32 ± 0 32 ± 0 15 39 ± 2 44 ± 3 41 ± 1 44 ± 2 17 ± 0 16 ±0 17 ± 0 18 ± 0 30 40 ± 0 43 ± 2 41 ± 0 43 ± 2 14 ± 0 17 ± 0 21 ± 0 16 ± 0 45 42 ± 2 46 ± 1 38 ± 4 40 ± 5 17 ± 0 20 ± 0 24 ± 0 28 ± 0 a* 0 25 ± 5 27 ± 2 25 ± 5 27 ± 2 10 ± 0 10 ± 0 10 ± 0 10 ± 0 15 24 ± 6 24 ± 1 22 ± 3 23 ± 2 21 ± 0 19 ± 0 18 ± 0 20 ± 0 30 24 ± 2 23 ± 1 21 ± 2 21 ± 2 17 ± 0 20 ± 0 20 ± 0 16 ± 0 45 24 ± 0 23 ± 2 18 ± 1 22 ± 2 17 ± 0 19 ± 0 18 ± 0 22 ± 0 b* 0 12 ± 3 12 ± 0 11 ± 3 12 ± 2 5 ± 0 6 ± 0 5 ± 0 6 ± 0 15 11 ± 3 12 ± 1 11 ± 2 11 ± 1 23 ± 0 16 ± 0 17 ± 0 16 ± 0 30 11 ± 1 11 ± 0 10 ± 1 10 ± 1 17 ± 0 19 ± 0 17 ± 0 19 ± 0 45 11 ± 2 12 ± 1 7 ± 1 9 ± 0 12 ± 0 16 ± 0 14 ± 0 18 ± 0 E 0 0 0 0 0 0 0 0 0 15 2 4 4 5 25 21 21 20 30 3 4 6 7 23 22 19 21 45 4 6 6 8 18 18 14 18 TP, thermal processing; HHP, high hydrostatic pressure processing. All data were the means ± SD, n = 3.

224 sG100(2016)221-29 ed in 40mM HCl)and the spectropho eter.Trolo rage time(day） 2.11.Color assessment Fig.1-The changs of flesh hardness of cup Color assessment was conducted at 25+2c using a colo ent spectrophotometer ( samples s red at smis ion r means±sD,n=10. samples without any storage 009 ture before measurement of the decrease in the absorption AE=I(L-1+(a*-ag)2+(b*-bg 3) A B 102030403060 102000000 D 3 2”00 。6200000 rate Sh ar rate ( samples sto

224 food and bioproducts processing 1 0 0 ( 2 0 1 6 ) 221–229 Fig. 1 – The change of flesh hardness of cupped strawberry during storage. HHP-treated samples stored at 4 ◦C; HHP-treated samples stored at 25 ◦C; TP-treated samples stored at 4 ◦C; TP-treated samples stored at 25 ◦C. Values with different letters within the same storage time are significantly different (P < 0.05). All data were the means ± SD, n = 10. of flesh extract (or syrup) was mixed with 4mL methanolic DPPH (Sigma–Aldrich, St. Louis, USA) solution (0.14mM). The samples were kept in the dark for 45min at room tempera￾ture before measurement of the decrease in the absorption at 517nm. Freshly prepared FRAP solution contained 25mL 0.3 M acetate buffer (pH 3.6), 2.5mL 10mM tripyridyltriazine (Sigma–Aldrich, St. Louis, USA, dissolved in 40mM HCl) and 2.5mL 20mM ferric chloride. 4mL FRAP solution was mixed with 100L trolox solution or sample (flesh extracts or syrup) at 37 ◦C. Ten minutes later, the ferric reducing abil￾ity of samples was measured by monitoring the increase of absorbance at 593nm using the spectrophotometer. Trolox (Sigma–Aldrich, St. Louis, USA) solutions within the range of 50–1000M were used for calibration. A new trolox calibration curve was made for each assay. The results were expressed as mg of trolox per 100 g flesh (mgTrolox/100 g), or 100mL syrup (mgTrolox/100mL). All measurements were made in dupli￾cate. 2.11. Color assessment Color assessment was conducted at 25 ± 2 ◦C using a color measurement spectrophotometer (HunterLab ColorQuest XE, Hunter Associates Laboratory, Inc., Virginia, USA) in the reflectance mode for flesh and the transmission mode for syrup. Color was expressed in L*, a* and b* values. All mea￾surements were made in triplicate and results were averaged. In addition, total color difference (E) were calculated using the following equation, where L∗ 0, a∗ 0 and b∗ 0 are the values for samples without any storage. E = [(L∗ − L∗ 0) 2 + (a∗ − a∗ 0) 2 + (b∗ − b∗ 0) 2 ] 1/2 (3) Fig. 2 – Changes of viscosity of syrup in cupped strawberry during storage at 4 and 25 ◦C. (A) HHP-treated samples stored at 4 ◦C; (B) HHP-treated samples stored at 25 ◦C; (C) TP-treated samples stored at 4 ◦C; (D) TP-treated samples stored at 25 ◦C; 0 day; 15 day; 30 day; 45 day.

00DADi0PR0 UCTS PR0cE55G100(2016)221-229 225 8 ge time(day】 Storage time (day Fig.3-Changes of total ph land anth 5C.(A)Total phenols in flesh;倒total pher eated data were the means+SD,n=2. 2.12.Statisticalanalysis atP≤0.05. 3 Results and discussion shown) eratures,which 31. hi Microbiological analysis of cupped strawberries As shown in Table 1,the initial counts of TAB and Y&M in 3.2. Hardness of fesh of cupped strawberries ored at 4 and 25'C re sho the nardne 2010)and Zhang treated samp sto red at 25C w ereower than the retention while thermal proc ing ld to existence of a sublethal injury of cells after HHP and TP hardness of flesh during storage at 4 and 25C (P.05)

food and bioproducts processing 1 0 0 ( 2 0 1 6 ) 221–229 225 Fig. 3 – Changes of total phenols and anthocyanins in cupped strawberry during storage at 4 ◦C and 25 ◦C. (A) Total phenols in flesh; (B) total phenols in syrup; (C) total anthocyanins in flesh; (D) total anthocyanins in syrup. HHP-treated samples stored at 4 ◦C; HHP-treated samples stored at 25 ◦C; TP-treated samples stored at 4 ◦C; TP-treated samples stored at 25 ◦C. Values with different letters within the same storage time are significantly different (P < 0.05). All data were the means ± SD, n = 2. 2.12. Statistical analysis The data were analyzed using the Statistical Program for Social Sciences (SPSS 12.0, Chicago, IL, USA) software for analysis of variance and Duncan’s test. The significance was established at P ≤ 0.05. 3. Results and discussion For all samples, the pH value (3.2) of strawberry flesh showed no significant change during storage at 4 and 25 ◦C (data not shown). 3.1. Microbiological analysis of cupped strawberries As shown in Table 1, the initial counts of TAB and Y&M in untreated sample were 4.62 and 3.71 log10 CFU/g, respectively. Both HHP and TP treatments resulted in reduction of TAB and Y&M to a level below the detection limit, and the counts of TAB and Y&M in HHP-treated samples stored at 4 ◦C and TP-treated ones stored at 4 and 25 ◦C remained lower than the detection limit during 45 days of storage. Therefore, HHP-treated sam￾ples stored at 4 ◦C and TP-treated ones at 4 and 25 ◦C exhibited a better microbiological stability during storage. Interestingly, the counts of the TAB and Y&M in HHP￾treated samples stored at 25 ◦C were lower than the detection limit before day 30, but increased to 3.08 and 2.58 log10 CFU/g respectively at day 45, respectively. This was interpreted as existence of a sublethal injury of cells after HHP and TP treatment, which prevented their growth until they later recovered during storage. Penas ˜ et al. (2010) ascribed the increase of TAB in sauerkraut during the third month of refrig￾erated storage after HHP to the recovery of microorganisms that were sublethally injured by HHP. Ritz et al. (2001, 2006) also found that no cell growth occurred after HHP treatment on plate count agar, and recovery was observed for L. mono￾cytogenes after 4 days of storage at 20 ◦C in phosphate (pH 7.0) and citrate (pH 5.6) buffer, but no recovery was observed in pressurized samples stored at 4 ◦C. These earlier studies indi￾cated that elevated incubation temperatures may be critical for repair of HPP-induced physiological damage, and recovery was completed at elevated incubation temperatures, which then allowed rapid growth. It was similar to our result in this study. The recovery of TAB and Y&M in HHP-treated samples was observed after 45 days at 25 ◦C, however, at 4 ◦C injured cells could not be recovered. 3.2. Hardness of flesh of cupped strawberries As shown in Fig. 1, at day 0, the hardness of HHP-treated sam￾ples was 6.1 ± 0.3 N, whereas the hardness was 2.4 ± 0.1 N in TP-treated ones, indicating that HHP treatment retained the hardness of the flesh. Similarly, Nguyen et al. (2010) and Zhang et al. (2011) proposed that HHP processing improved texture retention while thermal processing led to texture softening of carrot, jicama and yellow peach. All treated samples showed a significant reduction in the hardness of flesh during storage at 4 and 25 ◦C (P ≤ 0.05)

226 G1o0(206)221-229 Storage time(day） g4、 city in cuppe TP-teat nt (P0.05).All data which was mainly ascribed to the leaching and non-ena 00)The of ce all pect ated sam d to TP tre oles de ed by 70.1and 55.8%after45 days ofstorageat4C r cell structure and inhib and Ramaswamy,1998 tively.This suggests that lower storage ature could elay the de d that】 n hardness espe cially n HHP-re ,199 uggesting that H 。 ated sample a was low awb was reporte htiomofonepecnnpathiiornetepeet s pro 2009). 3.3 3.4. Total phenols and anthocyanins in cupped As shown in Fig 2,viscosity of syrup in cupped strawberry The change of content of total phenols and anthocyanins dur le were i days for the n that in HHP-女eate ter pro that of HHP-treated syrup.which could be attibuted to the temperature decompostion of these compounds (espec

226 food and bioproducts processing 1 0 0 ( 2 0 1 6 ) 221–229 Fig. 4 – Changes of antioxidant capacity in cupped strawberry during storage at 4 ◦C and 25 ◦C. (A) DPPH in flesh; (B) DPPH in syrup; (C) FRAP in flesh; (D) FRAP in syrup. HHP-treated samples stored at 4 ◦C; HHP-treated samples stored at 25 ◦C; TP-treated samples stored at 4 ◦C; TP-treated samples stored at 25 ◦C. Values with different letters within the same storage time are significantly different (P < 0.05). All data were the means ± SD, n = 2. which was mainly ascribed to the leaching and non-enzymatic depolymerization of cell wall pectin (Sila et al., 2006; De Roeck et al., 2008). The flesh hardness of HHP- and TP-treated sam￾ples decreased by 70.1 and 55.8% after 45 days of storage at 4 ◦C, whereas the decreases were 78.4 and 58.9% at 25 ◦C, respec￾tively. This suggests that lower storage temperature could delay the decrease of flesh hardness especially in HHP-treated samples, and that high storage temperature accelerated the change of pectin in the flesh of samples (García et al., 1999; Clark et al., 2002; Zhang et al., 2012). Moreover, HHP-treated samples had higher hardness of flesh than TP-treated ones during storage at 4 and 25 ◦C, suggesting that HHP treatment did not lead to cell wall depolymerization and loss of flesh hardness of cupped strawberry. A similar result was reported by Zhang et al. (2012) in yellow peach in pouches. This prob￾ably is due to lesser structural damages with HHP treatment, compared with TP treatment, leading to a lower leaching of cell wall pectin from flesh to syrup (Zhang et al., 2012). 3.3. Viscosity of syrup in cupped strawberry As shown in Fig. 2, viscosity of syrup in cupped strawberry showed no significant difference with the increase of shear rate. The viscosity at 63 s−1 vs. days gave the similar result at 16 s−1 vs. days for the four treatments. At day 0, the viscosity of TP-treated syrup was significantly higher than that of HHP-treated syrup, which could be attributed to the leaching of some water-soluble pectin into syrup during the processing. As compared to TP treatment, HHP treatment is possible to cause pectin leaching, but the effect was limited, which was probably due to tighter cell structure and inhibi￾tion of pectin depolymerization (Basak and Ramaswamy, 1998; Zhang et al., 2011). Due to less structural damages in HHP treatment, the increase of the viscosity in HHP-treated samples was less than that in TP-treated ones. This behavior was also observed after HHP or TP treatment in yellow peach in pouches (Zhang et al., 2012). Interestingly, after 45 days of storage, the syrup viscos￾ity of HHP- and TP-treated samples stored at 25 ◦C was lower than those at 4 ◦C, which was possibly attributed to the degra￾dation of some pectin in syrup at high storage temperature. It has been reported that pectin can be degraded through enzy￾matic and non-enzymatic degradation mechanisms (Sila et al., 2009). 3.4. Total phenols and anthocyanins in cupped strawberry The change of content of total phenols and anthocyanins dur￾ing storage were shown in Fig. 3. The level of total phenols and anthocyanins of flesh in TP-treated samples were signif￾icantly lower than that in HHP-treated ones after processing, which was probably due to more structural damages and the temperature decomposition of these compounds (especially

FOOR AND R w0c55G100(2016)221-229 色 ph ad C).all treated samples shov etc6oinwnTgern2aoo d by SThaY )the totaeve alikit a straw th ins in mples at 4 TP-treated ones ity in the macerated peel tissue ilitating the so. amples stored at4C 50 s and ore. day ed eased by 5%at the e )C/15 min) 1 of total phenols and an anins in cupped pro Cao et al.,2011),but not from PPO an POD being e (Od errano et a 4cd an fore.this berry. 3.5.Antioxidant capacity of cupped strawberry As shown in Fie.4.at day o.antioxidant capacity of flesh in TP-treated samples was not significantly lower than that

food and bioproducts processing 1 0 0 ( 2 0 1 6 ) 221–229 227 Table 2 – Analysis of pooled variance for the model and regression coefficients changes of color parameters in cupped strawberry. Origin of variance Sum of squares Degrees of freedom Mean square F Sig. L* a* b* L* a* b* L* a* b* L* a* b* L* a* b* Samples 8797.510 1053.375 263.344 1 1 1 8797.510 1053.375 263.344 2080.200 259.292 183.196 0.000 0.000 0.000 Treatment 120.031 35.250 31.781 3 3 3 40.010 11.750 10.594 9.461 2.892 7.370 0.000 0.042 0.000 Time 648.031 146.250 542.531 3 3 3 216.010 48.750 180.844 51.076 12.000 125.804 0.000 0.000 0.000 Error 270.667 260.000 92.000 64 64 64 4.229 4.063 1.438 Sum 107,489.000 40,766.000 16,799.000 96 96 96 Adjust Sum 11,412.240 266.000 1873.906 95 95 95 anthocyanins) in TP treatment, leading to a higher leaching of phenols and anthocyanins from flesh to syrup. As shown in Fig. 3(A and C), all treated samples showed a reduction in level of total phenols and anthocyanins of flesh during storage at 4 and 25 ◦C. After 45 days of storage, the level of total phenols and anthocyanins decreased by 14.0% and 33.4% in HHP-treated samples stored at 4 ◦C, by 30.4% and 57% in HHP-treated ones at 25 ◦C, by 28.0% and 35.7% in TP￾treated ones at 4 ◦C, and by 28.1% and 42.6% in TP-treated ones at 25 ◦C, respectively. The reduction in the content oftotal phe￾nols and anthocyanins of flesh was mainly due to the leaching of phenolic compounds and anthocyanins from flesh to syrup. This result was also confirmed in Fig. 3(B and D), the total level of phenols and anthocyanins of syrup in all samples increased significantly with increasing the storage time (P ≤ 0.05). Similar phenomenon, physical transfer of polyphenolics or antho￾cyanins from the fruits into the syrup, was observed in canned cherries (Chaovanalikit and Wrolstad, 2004a,b), Oregon straw￾berries (Ngo et al., 2007), blackberries (Hager et al., 2008) and blueberries (Brownmiller et al., 2008; Syamaladevi et al., 2012) during processing and storage. Furthermore, the degradation of phenols and anthocyanins would be another contributor to the reduction of content of total phenols and anthocyanins in flesh. In addition, there were higher total phenol and antho￾cyanin contents of flesh in samples stored at 4 ◦C and HHP-treated samples, compared to those stored at 25 ◦C and TP-treated ones, respectively. This might be due to increased extraction efficiency of TP treatment in the softened fruits, and higher temperature may increase membrane permeabil￾ity in the macerated peel tissue facilitating the solubilization of phenolic compounds and anthocyanins (Chaovanalikit and Wrolstad, 2004a,b). Thus, HHP-treated samples stored at 4 ◦C showed the highest level of total phenols and anthocyanins content of flesh in all samples stored at the end of storage. Furthermore, compared to the content value at day 0, the total level of phenols and anthocyanins in HHP- and TP￾treated samples (combined flesh and syrup) decreased by 11.6–25.9% and 18.5–43.5% at the end of storage, respectively. Similarly, Ngo et al. (2007) reported that the total level of com￾bined anthocyanin in canned strawberries (100 ◦C/15min) and in the syrup declined by 69% over 60-day room temperature storage. Chaovanalikit and Wrolstad (2004b) also found that total level of anthocyanins in canned Bing cherries decreased by 38% after a 5-month storage at 22 ◦C. The reduction of level of total phenols and anthocyanins in cupped strawberry was probably due to oxidation as well as condensation of anthocyanins with phenolic compounds (Castaneda-Ovando ˜ et al., 2009; Cao et al., 2011), but not from PPO and POD being related to the degradation of phenolic compounds during stor￾age (Odriozola-Serrano et al., 2009; Terefe et al., 2009) since they were totally inactivated by blanching and not detected in any of the samples in this study. Moreover, HHP-treated samples stored at 4 ◦C showed the highest total phenols (805.8mg GAE/100 g) and anthocyanins (19.4mg/100 g) in all samples after a 45-day storage. Therefore, this result suggests thatlow storage temperature and HHP treatmentinhibited the degradation of phenols and anthocyanins in cupped straw￾berry. 3.5. Antioxidant capacity of cupped strawberry As shown in Fig. 4, at day 0, antioxidant capacity of flesh in TP-treated samples was not significantly lower than that

228 100(206)221-229 Table3-Analysis of notability of changes of coor parameters in cupped strawbery time. 0 15 30 time (day 15 B B BR alues with different letters within one row are significantly different (P<0.05) nent,which was due to more leaching of phenol stru leaching of an 2 s in Tp anin e well the C)show eioninamtioxidantCapa nge to y the canned be ols and antho ed a and D),similar to th y de due to the redu 4. Conclusions tent of total phe nols and an ota h and TP-tr amples. was a reductior hard o ind of phenols and anthocyanins nt trea tm ature me oreover,there wa 36 Color analysis of cupped strawberry cupped t p during strage.After the 45 tored at 25"C and TP-trea d ones ase de and de eeb torage. syrup Acknowledgments ted sa ame less bright (lowe es),an ted by proi N0.201100081100380 nore yellow(hig ymup mn nd of h Fund for the ogram of Highe ase I the fe and Technoloey plan (948"proiect)of china. AE of 2 hle vi References 出图 days and in all s atter 30 days.Inte (11,32-38

228 food and bioproducts processing 1 0 0 ( 2 0 1 6 ) 221–229 Table 3 – Analysis of notability of changes of color parameters in cupped strawberry during storage time. Storage time (day) 0 15 30 45 0 15 30 40 L* A BC B C A C C B a* A A B AB A B B B b* A A B A A C C B Values with different letters within one row are significantly different (P 0.05). For the L*, a* and b* values of flesh in all samples, there was no significant change during storage (P > 0.05), but these parameters tended to increase, decrease and decrease, respec￾tively. The color indicated brighter, less red and less yellow in the flesh of samples, which was due to the degradation and transfer of anthocyanins from the flesh into the syrup. Cor￾responding to color change in flesh, the color of syrup in the treated samples firstly became less bright (lower L* values), more red (higher a* values), and more yellow (higher b* values), and then showed the opposite change at the end of storage. This color shift of syrup was also similar to the change of total anthocyanins in syrup. The E value, which was an indicator of total color difference, showed a significant increase in both HHP- and TP-treated samples in the flesh during storage at 4 and 25 ◦C. It has been considered that E of 2 would be a noticeable visual difference for a number of situations (Francis and Clydesdale, 1975). In this study, E > 2 was observed in almost all samples after 15 days and in all samples after 30 days. Interestingly, the E value of syrup in all samples firstly increased and then decreased during storage at 4 and 25 ◦C, which was also consistent with the change of total anthocyanins in syrup. Similarly, Cao et al. (2012) found that the E values showed a negative correlation with anthocyanin content in cloudy and clear strawberry juices. Ngo et al. (2007) also reported that the great loss and leaching of anthocyanin explain well the change to yellow-colored appearance of the canned berries. Therefore, the loss and leaching of anthocyanins were the main reason of color shift in cupped strawberry. Furthermore, after the 45-day storage, the E values of flesh in samples stored at 4 ◦C and HHP-treated samples were lower than that at 25 ◦C and TP-treated ones, respectively, indicating that low storage temperature and HHP treatment benefited to preserve a more attractive color to consumers. 4. Conclusions Both HHP and TP treatments after the preliminary heat treat￾ment resulted in inactivation of TAB and Y&M to a level below the detection limit, and a good microbiological stability was observed in all treated samples except that in HHP-treated ones at 25 ◦C at the last of storage. There was a reduction in the hardness and nutritional properties (total phenols, total anthocyanins and antioxidant capacity) of flesh, and an increase in the viscosity and nutritional properties of syrup during storage, which was significantly influenced by differ￾ent treatments and storage temperature. Moreover, there was a significant decrease in the total level of nutritional proper￾ties (combined flesh and syrup), and a noticeable increase of E values in cupped strawberry during storage. After the 45- day storage, samples stored at 4 ◦C and HHP-treated samples showed higher nutritional values and better color than those stored at 25 ◦C and TP-treated ones. In summary, there was a better quality and microbiologi￾cal stability in HHP-treated samples stored at 4 ◦C, indicating that lower storage temperature and HHP processing was a bet￾ter choice for the preservation of cupped strawberry during storage. Acknowledgments This work was supported by Project No. 20110008110038 of Specialized Research Fund for the Doctoral Program of Higher Education of China, Project No. 2014BAD04B11 of National Sci￾ence and Technology Support Plan, Project No. 2014XJ022 of Chinese Universities Scientific Fund and Project No. 2011-G20 of Recommend International Advanced Agricultural Science and Technology Plan (“948” project) of China. References Balasubramaniam, V.M., Farkas, D., Turek, E.J., 2008. Preserving foods through high-pressure processing. Food Technol. 62 (11), 32–38.

(016)21-229 29 Basak,S.Rama CeL,Lae.M,VnLoeAenaiaaM2asEfeeh and antio y of a g high- ctiono -362 phe yanins and Cha Sila,D.N Do 006 A.,Van Loe relationships. lic ancis,L.Clvdesdale re pr texture of acidifed ripeolives in pouchesJ.Food Sci.64 ard.LR.Prior.R.L.2008.Pr sing and sto d products.) ge uice du an es of 73- tos E Ochoa-Martir A.,Tabil ogical G.Reyes. hreteret ca.V. auehot od B es mson,T. Welt-C stenlizationoffoosFoog Wang.Y.Liu.E. .X.Chen,F.Hu,X.Liao,012. ng on o Y 2007.Color a Xu, od sci.Technol( Martn-ellos00.Ca 12.258-26

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