超高压杀菌效果及机制研究进展

超高压作为一种新型的食品非热加工技术, 处理过程温度低、对食品营养成分破坏小,能在有效杀菌的同时显著提升加工食品品质,是未来食品加工技术发展的热点方向。近年来,超高压技术被广泛应用于食品加工,并在国内外实现了商业化应用。杀菌作为超高压加工食品过程中最重要的环节,是保证食品安全、延长产品货架期的关键点,因此一直是本领域研究的重点。本文介绍了超高压技术的设备和作用原理, 总结了超高压或超高压联合其他手段对微生物营养体、细菌芽孢、真菌孢子及病毒的杀灭效果和杀菌机制, 归纳了超高压杀菌中存在的杀菌机制不清、缺乏杀菌指示菌以及深休眠芽孢等问题, 以期为进一步完善超高压杀菌理论、推动超高压技术在食品加工中的产业化应用指明方向。     

High Hydrostatic Pressure Processing of Cheese

Abstract: High hydrostatic pressure (HHP) is a cutting‐edge processing technology attracting research and industrial interest in the food sector due to its potential to produce microbiologically safe products, modify the functional properties of proteins and polysaccharides, and alter biochemical reactions without significantly affecting the nutritional and sensory properties of food. Currently, there are only a limited number of pressure‐treated cheese products available in the market. Nevertheless, results from numerous research studies on various cheese varieties seem promising, especially since HHP technology is today more cost‐effective than in the past. Considering the progress made in the application of HHP on cheese during the past 15 years, this paper reviews the direct application of HHP treatments to cheese and the effects it has on its microbiology and ripening process, as well as on quality parameters such as physicochemical, rheological, and sensory properties. Detailed information of published studies is presented with the aim of providing a clear picture of the use of this technology on cheese processing. Areas of research in need of more attention are also identified.     

High hydrostatic pressure (HHP) inactivation of foodborne pathogens in low‐acid juices

Consumption of unpasteurised fruit/vegetable juices has increased in recent years due to their freshness, low calorie contribution and good nutritional quality. However, unpasteurised fresh juices with low acidity (pH > 4.6) and high water activity (a_w > 0.85) can support the growth of pathogens. Hence, pasteurisation is a necessary process in the production of low‐acid juices. Consumer demand has required minimally processed high‐quality foods that are free from additives, that are fresh tasting and microbiologically safe, and with an extended shelf life. High hydrostatic pressure (HHP) treatment is considered to be an alternative to thermal pasteurisation for fruit and vegetable juices. HHP treatment could preserve nutritional value and the sensory properties of fruits and vegetables due to its limited effect on the covalent bonds of low‐molecular‐mass compounds such as colour, flavour compounds and vitamins. However, inactivation of important foodborne pathogens in low‐acid foods by HHP is most urgent and critical. More research should be performed in order to satisfy consumer demands for fresh‐tasting products while retaining safety.     

Effect of high pressure processing on gastrointestinal fate of carotenoids in mango juice: Insights obtained from macroscopic to microscopic scales

High hydrostatic pressure (HHP) and high-pressure homogenization (HPH) were applied to mango juice to explore their effects on gastric retention rate (G-CRR), bioaccessibility (BAC) of total and individual carotenoids, and the corresponding mechanisms from macroscopic to microscopic scales. Compared to the control, both HHP and HPH at 50 MPa had no significant effect on BAC and G-CRR, whereas HPH at 100 MPa significantly increased BAC by 44.33% and G-CRR by 11.84%. Further HHP treatments (particularly at 400 MPa) on the 100 MPa-HPH-pretreated samples significantly increased BAC by 71.37% and G-CRR by 24.24%. Violaxanthins/esters were less stable than carotenes in the stomach, resulting in lower bioaccessibility of violaxanthins/esters. G-CRR and BAC were negatively correlated with the viscosity and particle size of juice, whereas they were positively correlated with the solubility/dispersibility of carotenoids. In addition, pectin-carotenoid interactions may also be an important factor affecting the digestive fate of carotenoids in juice.Industrial relevanceHigh pressure processing (High hydrostatic pressure, HHP, and high pressure homogenization, HPH) is a non-thermal technique and its effect on the bioaccessibility of carotenoids in fruits and vegetables have attracted attention from researchers. Our research found that HPH and HHP combined treatment could decrease the particle size of mango juice, and increase the viscosity and turbidity as well as the bioaccessibility of carotenoids therein. This technology can be used to preserve the physical stability of mango juice and improve the nutritional value.     

Quality degradation kinetics of pasteurised and high pressure processed fresh Navel orange juice: Nutritional parameters and shelf life

A kinetic study of post processing quality loss was conducted after high pressure processing (600 MPa, 40 °C, 4 min) or thermal pasteurisation (80 °C, 60 s) of fresh Navel orange juice. Selection of processing conditions was mainly based on pectin methylesterase inactivation. Ascorbic acid loss, colour, viscosity and sensory characteristics were measured during storage at different isothermal conditions (0–30 °C). Increased shelf life (based on ascorbic acid retention) was achieved for high pressurised compared to thermally pasteurised juice, ranging from 49% (storage at 15 °C) to 112% (storage at 0 °C). Activation energy values for ascorbic acid loss were 68.5 and 53.1 kJ/mol, respectively, for high pressurised and thermally treated juice. High pressure processing resulted in better retention of flavour of untreated juice and superior sensory characteristics compared to thermal pasteurisation. Colour change was linearly correlated to ascorbic acid loss for both types of processing. Slightly higher apparent viscosity values were determined for high pressurised juice.Industrial relevanceApplication of high hydrostatic pressure on orange juice industry. Fresh orange juice is a product of high commercial and nutritional value due to its rich vitamin C content and its desired sensory characteristics. High Hydrostatic Pressure (HHP) is an alternative non-thermal technology that has been proposed for application on orange juice. Such a treatment denaturates enzymes and eliminates microorganisms responsible for spoilage of orange juice without detrimental effects on the sensory and nutritional quality of juice. The effect of HHP on the stability of fresh orange juice has been studied by different research groups, while orange juices processed with the new technology have already been commercially available in Japan, U.S.A., Mexico and Europe. However, a systematic kinetic approach of the effect of HHP on different quality indexes (not only microbial spoilage) immediately after processing, as well as during a long term storage of the processed orange juice is needed, in order to achieve an optimal process design and a successful application of the new technology in orange juice industry. Such kinetic data for parameters related to the quality and nutritional value of fresh orange juice were gathered in the present work providing therefore industry with useful information for the HHP stabilization of orange juice and the production of a high quality product. Due to the great benefits of HHP compared to the conventional pasteurization that emerged from this work regarding the quality, shelf life and nutritional characteristics of fresh orange juice, HHP technology is an advantageous alternative process for high valued products like orange juice.     

Factors Affecting Bacterial Inactivation during High Hydrostatic Pressure Processing of Foods: A Review

Although, the High Hydrostatic Pressure (HHP) technology has been gaining gradual popularity in food industry since last two decades, intensive research is needed to explore the missing information. Bacterial inactivation in food by using HHP applications can be enhanced by getting deeper insights of the process. Some of these aspects have been already studied in detail (like pressure, time, and temperature, etc.), while some others still need to be investigated in more details (like pH, rates of compression, and decompression, etc.). Selection of process parameters is mainly dependent on type of matrix and target bacteria. This intensive review provides comprehensive information about the variety of aspects that can determine the bacterial inactivation potential of HHP process indicating the fields of future research on this subject including pH shifts of the pressure treated samples and critical limits of compression and decompression rates to accelerate the process efficacy.     

Recent advances in gelatinisation and retrogradation of starch by high hydrostatic pressure

Starch is the major polysaccharide following cellulose, but native starch has limited application due to physicochemical and functional properties. To handle such problems, starch is usually modified with either thermal or more recently by non-thermal technologies such as high hydrostatic pressure (HHP). HHP is a non-thermal technique that can be applied to a variety of food materials with minimum effect on nutritional quality. High-pressure levels can cause physicochemical changes in starch such as partial/completely gelatinisation, reduction in solubility and swelling power, increasing pasting temperature and content of slowly digestible starch (SDS) and retention of retrogradation. These physicochemical changes depend on the starch type, pressurisation level, treatment time and temperature. This review has evaluated and synthesised the current research about the effect of HHP on starch gelatinisation, retrogradation and physicochemical properties of starch.     

Effect of high hydrostatic pressure (HHP) on structure and activity of phytoferritin

High hydrostatic pressure (HHP) has drawn considerable attention because of its potential application in food industry. Ferritin, an iron storage protein, is widely distributed in food made from legume seeds, which is highly stable due to its shell-like structure. Therefore, it is of special interest to know whether or not high HHP treatment has effect on this protein. In this study, the structure and activity of soybean seed ferritin (SSF) were examined by circular dichroism spectrum (CD), UV–VIS and fluorescence spectrophotometry in conjunction with stopped-flow light scattering upon treatment with HHP at 400 MPa for 10 min. Results revealed that such treatment has little effect on the primary and secondary structure of SSF, but pronouncedly altered its tertiary and quaternary structure. As a result, the protein aggregation property and iron release activity were dramatically changed, while its activity of iron oxidative deposition was kept unchanged.     

软包装太湖白虾超高压杀菌效果及动力学研究

以熟制太湖白虾包装产品中残存菌为研究对象,探讨超高压(High hydrostatic pres-sure,HHP)用于灭菌的可行性,对影响超高压灭菌效果参数(压力、时间)进行考察与评价,并分别用Weibull和Log-Logistic模型对不同处理条件下的杀菌效果进行拟合。结果表明:压力大小和保压时间是影响杀菌效果的主要因素,而压力的影响更加显著;两种模型均有较好的拟合度,且Log-Logistic模型拟合度更高。     

Effect of High Hydrostatic Pressure (HHP) Treatment on Edible Flowers’ Properties

Edible flowers are increasing worldwide because they can improve the appearance, taste, and aesthetic value of food, aspects that the consumer appreciates. However, some of these are highly perishable and have a short shelf-life. To overcome these problems, high hydrostatic pressure (HHP) food processing might be applied, allowing producing high-quality food with enhanced safety and increased shelf-life. The application of HHP to vegetables has been extensively discussed and is already an industrial reality, but information on edible flowers is scarce and incomplete. Thus, in order to summarize the current knowledge on potential applications of HHP treatment in edible flowers and to determine the effect of this treatment on physical (e.g., color and texture) and nutritional characteristics as well as on microbial and enzymatic inactivation, a literature review was performed. It was stated that broccoli and cauliflower (inflorescences, usually not considered by consumers as flowers) have been the most studied, existing few information for other edible flowers. Thus, much more works are needed to better understand the effect and mechanisms behind HHP, and to define the adequate technological conditions for each flower.     

High hydrostatic pressure treatment: An artificial accelerating aging method which did not change the region and variety non-colored phenolic characteristic of red wine

The effect of high hydrostatic pressure (HHP) treatment on the region and variety non-colored phenolic characteristics of red wine was investigated in this study. After HHP treatment, many changes occurred in the non-colored phenolic compounds in red wines. Changes in total phenolic acids and the contents of eleven phenolic acids among different regions and varieties varied and showed an overall upward trend, while chlorogenic acid decreased in several wines. The total flavan-3-ols and five flavan-3-ols largely decreased among the different regions and different varieties, while EGC slightly increased. In addition, HHP treatment did not change the grape variety and grape geographic origin discrimination based on phenolic acids and flavan-3-ols, which suggests that HHP treatment had no effect on the region and variety of non-colored phenolic characteristics of red wine. These results could expedite the use of HHP processing in the wine industry.Industrial relevanceHHP is an important technology which could simulate the traditional aging process in wine industry and could shorten a lot of time and save great economic costs. However, no HHP-treated wine has been introduced in the market throughout the world so far. This is due, in large part, to the lack of correlation studies. In this study, we proved that HHP didn't change grape variety and grape geographic origin phenolic characteristics, hence it could be used in geographic indication wines and varietal wines. With these results, we hope HHP technology could be successfully used in wine industry as early as possible.     

Effect of high hydrostatic pressure on physicochemical and biochemical properties of milk

Interest in high hydrostatic pressure (HHP) applications on milk and dairy products has recently increased as HHP offers a new technology for food preservation to the food industry. Although HHP-induced microbial destruction, rennet or acid coagulation of milk and increase in cheese yield has been reported, the actual effect of HHP application on milk constituents still remains to be unexplained. Therefore, we have analyzed the effect of HHP on physicochemical and biochemical properties such as turbidity, pH and especially protein micelle surface hydrophobicity of milk proteins. To serve for this purpose, milk samples with different fat contents were pressurized from 110 to 440 MPa at 25 °C for 10 and 20 min. Turbidity decreased with pressure increase and there was a slight change in pH. In order to measure the extent of exposure of hydrophobic groups of proteins to HHP, the method described by Bonomi et al. [1], based on use of a fluorescent probe, was utilized. In the light of the results obtained, it can be concluded that HHP has an effect on non-covalent interactions and especially hydrophobic bonds in milk. As the pressure is increased from 110 to 440 MPa, the micelles possibly decompose into sub-micelles and the embedded hydrophobic areas inside these micelles re-position in such a way that they can readily interfere with the fluorescent marker, ANS. These results may lead to practical applications of HHP treatment in the dairy industry to produce microbiologically safe, minimally processed products with high nutritional and sensory quality and novel texture.     

Biochemical Changes during the Storage of High Hydrostatic Pressure Processed Avocado Paste

Abstract: High hydrostatic pressure (HHP) processing improves the shelf life of avocado paste without a significant impact on flavor; however, scarce information is available on biochemical modifications during its extended storage period. The present study focused on the changes in oxidative enzyme activities of pressurized avocado paste (600 MPa for 3 min) during refrigerated storage (45 d at 4 °C). Aerobic plate counts (APC), lactic acid bacteria counts (LAB), pH, and instrumental color were also evaluated during storage. Processing with HHP caused a decrease in polyphenol oxidase (PPO) and lipoxygenase (LOX) activities, resulting in residual enzyme levels of 50.72% and 55.16%, respectively. Although instrumental color values didn't change significantly during the evaluated storage period, both enzymes (PPO and LOX) recuperated their activities at 10 to 15 d of storage, reached the original values observed in the fresh paste, and then started a declining phase until the end of the storage period. Pulp pH presented a consistent decline during the first 20 d of storage. LAB counts were very low during storage, discarding lactic acid production as responsible for the observed pH decline. Enzyme reactivation, cell disruption, and a gradual migration of intracellular components such as organic acids are herein proposed as the main mechanisms for the deterioration of HHP treated avocado paste during its refrigerated storage. Practical Application: At the present, HHP is the most effective commercial nonthermal technology to process avocado paste when compared to thermal and chemical alternatives. Although it has proven to be an excellent product-technology match, little information is known on the biochemical changes that take place in the product during its refrigerated shelf life. Biochemical reactions during storage are important, since they can influence avocado paste nutritional and flavor qualities at the time of product consumption. The present study reports for the first time the re-activation of PPO and LOX during storage of avocado paste under commercial and economically feasible processing conditions (600 MPa and 3 min). The reactivation of oxidative enzymes observed in the present study is relevant for future studies on the HHP stability of food systems in general, and it is considered an important finding for the food industry and researchers seeking to deliver products with superior nutritional and flavor characteristics.     

Changes induced by high hydrostatic pressure in acidified and non-acidified milk during Oaxaca cheese production

Oaxaca cheese, produced using the pasta filata method, is a very popular Mexican dairy products. In this work, the effect of high hydrostatic pressure (HHP) and the acidification process before and after HHP treatment of raw cow milk was studied at different pressure levels (150, 300 and 500 MPa) and holding times (10 and 30 min). Clotting time, proximal composition, microstructure, secondary protein structure and electrophoretic profile were evaluated. HHP did not influence clotting time in samples acidified before HHP, but it appears to have a positive effect at lower pressure treatments on non-acidified milk. Moisture, protein and fat were similar in cheeses treated at most HHP conditions regardless of the acidification. HHP did not influence the microstructure of cheese and the secondary structure of proteins. The use of HHP during the manufacture of Oaxaca cheese allowed preserving quality parameters evaluated without advantages in processing time and the product's proximal composition.     

超高静压对蜂蜜主要品质的影响

为探讨超高静压(high hydrostatic pressure,HHP)对蜂蜜主要品质的影响,该研究以荔枝蜂蜜为原料,研究了不同压力(300、450、600 MPa)和保压时间(5、10、20 min)对蜂蜜中果糖和葡萄糖含量、淀粉酶和蔗糖转化酶酶活性、5-羟甲基糠醛(5-hydroxymethylfurfural,5-HMF)和二羰基化合物含量的影响。结果表明,蜂蜜中果糖和葡萄糖质量分数分别为(50.5±0.8)%和(37.1±0.9)%,果糖和葡萄糖比率(F/G)为1.35～1.39,HHP未对其含量和比值产生影响。HHP处理造成淀粉酶和蔗糖转化酶活性分别损失了17.1%～40.4%和17.2%～56.3%,压力和时间对两种酶活都具有显著性影响(P> 0.05)。蜂蜜中5-HMF含量在(1.12±0.04) mg/kg,经HHP处理后其含量有下降。3-脱氧葡萄糖醛酮是该文蜂蜜中主要的二羰基化合物,经HHP处理后其浓度显著增加22.3%～31.2%。研究结果可为HHP在蜂蜜加工中的应用提供参考。     

High Hydrostatic Pressure Pasteurization of Red Wine

ABSTRACT:  Pasteurization of low-alcohol wine using a high hydrostatic pressure (HHP) process was studied. A total of 10 mL grape wine sealed in a nylon/LLDPE bag was placed inside the HHP chamber. The pressure applied to the treatment chamber was maintained at 1000 to 3500 atm for 0 to 30 min. The effects of HHP treatments on the physiochemical properties (alcohol, pH, acidity, total sugar) and microbes (aerobic bacteria, yeast, and lactic acid bacteria) were examined. The HHP treatments had little impact on the physiochemical properties. The pasteurization effect of the HHP treatments increased with treatment pressure and time. A total of 2 different stages in the microbial inactivation were noticed when the 1st-order reaction model was used to fit the inactivation data. The inactivation rate was higher in the initial stages than in the later stages, suggesting that might be 2 different groups of the microorganisms, a more HHP-susceptible group and a less HHP-susceptible group.     

Impact of high pressure treatment and intramuscular fat content on colour changes and protein and lipid oxidation in sliced and vacuum-packaged Iberian dry-cured ham

The effect of high hydrostatic pressure (HHP) (600 MPa) and intramuscular fat content (IMF) on colour parameters and oxidative stability of lipids and proteins in sliced vacuum-packaged Iberian dry-cured ham during refrigerated storage (120 days at 2 °C) was investigated. Several studies have investigated the influence of HHP on lipid oxidation of meat products. However, its effects on protein carbonylation, as also the influence of IMF content on this carbonylation are poorly understood. HHP treatment had a significant effect on lean lightness after 0 and 120 days of storage while IMF content increased lightness and yellowness over time. Regarding oxidative stability, the effect of HHP treatment depended on IMF content samples with a high IMF having greater lipid instability while samples with a low IMF underwent more protein carbonylation.     

High hydrostatic pressure treatment for manufacturing of garlic powder with improved microbial safety and antioxidant activity

The traditional method of manufacturing garlic powder (GP) that includes simple grinding of air-dried garlic slices has problems of microbial safety and a pungent flavour for this product. Microbiologically safe GP with a less pungent flavour and better antioxidant activities was manufactured using high hydrostatic pressure (HHP), wet grinding and freeze-drying process. The numbers of total aerobic bacteria and yeasts and molds in untreated (without HHP) GP were 3.64 and 2.47 log CFU/g respectively. Garlic powder treated with 600 MPa HHP for 5 min exhibited a total aerobes count of 1.62 CFU/g and a yeasts and molds count of 1.43 log CFU/g. The diallyl disulfide content, which is responsible for the pungent odour of garlic, was also significantly reduced by HHP due to a decrease in the alliinase activity. Hence, a novel process using HHP can help to produce GP with improved microbial safety, flavour and nutrition.     

The effects of high hydrostatic pressure at subzero temperature on the quality of ready-to-eat cured beef carpaccio

We compared the application of high hydrostatic pressure (HHP) on unfrozen carpaccio (HHP at 20°C) and on previously-frozen carpaccio (HHP at -30°C). HHP at 20°C changed the color. The pressure increase from 400 to 650MPa and the time increment from 1 to 5min at 400MPa increased L* and b*. a* decreased only with 650MPa for 5min at 20°C. The prior freezing of the carpaccio and the HHP at -30°C minimized the effect of the HHP on the color and did not change the shear force, but increased expressible moisture as compared to the untreated carpaccio. HHP at 20°C was more effective in reducing the counts of microorganisms (aerobic total count at 30°C, Enterobacteriaceae, psychrotrophs viable at 6.5°C and lactic acid bacteria) than HHP at -30o C. With HHP at 20°C, we observed a significant effect of pressure and time on the reduction of the counts.     

High hydrostatic pressure treatment of Arthrospira (Spirulina) platensis extracts and the baroprotective effect of sugars on phycobiliproteins

The effect of High Hydrostatic Pressure (HHP) (600 MPa; 300 s) upon phycobiliproteins from Spirulina platensis extract, in aqueous systems, has been investigated along with the potential baroprotective ability of several sugars (sucrose, trehalose and glucose) at different concentrations (20%, 40% w/w). Phycobiliproteins stability and technological functionality were assessed through spectroscopical and colour analysis, and radical scavenging ability.HHP treatment resulted in a decrease of the phycobiliproteins concentration with allophycocyanin being the most sensitive towards HHP stress (p ≤ 0.05). Addition of saccharides had a positive effect on phycocyanin stability with a higher residual concentration after HHP treatment (p ≤ 0.05) irrespective of the type and concentration of sugars added in the system, whilst baroprotective effects on allophycocyanin and phycoerythrin were observed only at the highest (40%) concentrations tested (p ≤ 0.05). After the HHP treatment, colouring ability of Spirulina platensis extract resulted in being directly correlated to phycocyanin concentration variation (R² = 0.75). Addition of sugars preserved the antioxidant activity of the extract subject to high pressure regardless of the sugar type.Industrial relevanceSpirulina platensis has become a popular ingredient among manufacturers and consumers, especially for its technological functionality and nutritional properties. Nevertheless, processing and storage may result detrimental for its performance in foods. High hydrostatic pressure is a successful, non-thermal technology that is finding increasing applications in the food industry though processing costs of food products stabilized by HHP result, nowadays, being 7 to 15-fold higher than thermal pasteurization. However, consumers today are willing to pay higher prices for higher quality products with better sensory profiles and nutritional properties. Moreover, compared to thermal pasteurization, HHP is a rather new technology whose cost-effectiveness and environmental impact is expected to improve over time, with a consequent reduction of the gap among performance of these two technologies. Hence, this study focused on the effects of HHP treatments on aqueous Spirulina platensis extracts, alone or added with small saccharides to evaluate their potential baroprotective abilities, providing results of interest for application in food product design and development.