Sustainable Ultrasound Assisted Extractions and Valorization of Coffee Silver Skin (CS)

The Sustainable Development Goals (SDG) encourage the efficient use of sustainable technologies. Ultrasound-assisted extraction (UAE) is one of the extraction process techniques, which are also directed towards sustainability as a goal. Coffee silver skin (CS), being a healthy raw material as well as a waste, could be utilized in the manufacturing process of new dietary products. The goal of this research was to isolate proteins and polyphenols from CS using UAE and to employ spectrophotometry to determine the yields. Three parts of the research were conducted: ultrasonic extraction, the optimization of UAE conditions for the isolation of proteins and polyphenols from CS, and the analysis of the amino acid extract obtained with the optimal use of UAE. According to the results, it was reported that the highest yields of total polyphenols isolated from the CS using UAE were obtained by applying an amplitude of 75% and a time interval of 9 min. The optimal parameters of UAE, when considering the proportions of total polyphenols and proteins, are an amplitude of 100% and a time of 9 min. The most abundant amino acids in isolated proteins (Asp, Glu, Pro, Gly, and Ala) were defined as well. Based on the use of energy, it was obvious that UAE is a promising technology. This concurs with the proposed practice that when non-thermal technologies are analyzed from an environmental point of view, the first common denominator is the use of electricity to run the equipment, in relation to resource depletion. As expected, CS poses a great waste to be recycled, being a nutritionally rich raw material with great potential. Quantitative consideration on the environmentally friendly applicability of CS in mass production should be carried out to validate the entire process of developing a new product from both economic and environmental aspects. © 2023 by the authors

State of the art of nonthermal and thermal processing for inactivation of micro-organisms

peer-reviewedDespite the constant development of novel thermal and nonthermal technologies, knowledge on the mechanisms of microbial inactivation is still very limited. Technologies such as high pressure, ultraviolet light, pulsed light, ozone, power ultrasound and cold plasma (advanced oxidation processes) have shown promising results for inactivation of micro-organisms. The efficacy of inactivation is greatly enhanced by combination of conventional (thermal) with nonthermal, or nonthermal with another nonthermal technique. The key advantages offered by nonthermal processes in combination with sublethal mild temperature (<60°C) can inactivate micro-organisms synergistically. Microbial cells, when subjected to environmental stress, can be either injured or killed. In some cases, cells are believed to be inactivated, but may only be sublethally injured leading to their recovery or, if the injury is lethal, to cell death. It is of major concern when micro-organisms adapt to stress during processing. If the cells adapt to a certain stress, it is associated with enhanced protection against other subsequent stresses. One of the most striking problems during inactivation of micro-organisms is spores. They are the most resistant form of microbial cells and relatively difficult to inactivate by common inactivation techniques, including heat sterilization, radiation, oxidizing agents and various chemicals. Various novel nonthermal processing technologies, alone or in combination, have shown potential for vegetative cells and spores inactivation. Predictive microbiology can be used to focus on the quantitative description of the microbial behaviour in food products, for a given set of environmental conditions

Use of Spectroscopic Techniques to Monitor Changes in Food Quality during Application of Natural Preservatives: A Review

Consumer demand for food of high quality has driven research for alternative methods of food preservation on the one hand, and the development of new and rapid quality assessment techniques on the other hand. Recently, there has been a growing need and interest in healthier food products, which has led to an increased interest in natural preservatives, such as essential oils, plant extracts, and edible films and coatings. Several studies have shown the potential of using biopreservation, natural antimicrobials, and antioxidant agents in place of other processing and preservation techniques (e.g., thermal and non-thermal treatments, freezing, or synthetic chemicals). Changes in food quality induced by the application of natural preservatives have been commonly evaluated using a range of traditional methods, including microbiology, sensory, and physicochemical measurements. Several spectroscopic techniques have been proposed as promising alternatives to the traditional time- consuming and destructive methods. This review will provide an overview of recent studies and highlight the potential of spectroscopic techniques to evaluate quality changes in food products following the application of natural preservatives

The fourth industrial revolution in the food industry—part II: Emerging food trends

The food industry has recently been under unprecedented pressure due to major global challenges, such as climate change, exponential increase in world population and urbanization, and the worldwide spread of new diseases and pandemics, such as the COVID-19. The fourth industrial revolution (Industry 4.0) has been gaining momentum since 2015 and has revolutionized the way in which food is produced, transported, stored, perceived, and consumed worldwide, leading to the emergence of new food trends. After reviewing Industry 4.0 technologies (e.g. artificial intelligence, smart sensors, robotics, blockchain, and the Internet of Things) in Part I of this work (Hassoun, Aït-Kaddour, et al. 2022. The fourth industrial revolution in the food industry—Part I: Industry 4.0 technologies. Critical Reviews in Food Science and Nutrition, 1–17.), this complimentary review will focus on emerging food trends (such as fortified and functional foods, additive manufacturing technologies, cultured meat, precision fermentation, and personalized food) and their connection with Industry 4.0 innovations. Implementation of new food trends has been associated with recent advances in Industry 4.0 technologies, enabling a range of new possibilities. The results show several positive food trends that reflect increased awareness of food chain actors of the food-related health and environmental impacts of food systems. Emergence of other food trends and higher consumer interest and engagement in the transition toward sustainable food development and innovative green strategies are expected in the future.The fourth industrial revolution in the food industry—part II: Emerging food trendssubmittedVersio

Application of High Pressure in Food Processing

Obrada visokim tlakom podrazumijeva podvrgavanje tekuće ili čvrste hrane, s ambalažom ili bez nje, djelovanju tlaka od 100 do 800 MPa (1200 MPa). Temperatura obrade može se kretati od ispod 0 °C do iznad 100 °C, a vrijeme izloženosti djelovanju tlaka, ovisno o cilju obrade, može varirati od nekoliko sekundi do preko 20 minuta. Zbog djelovanja visokog tlaka dolazi do smanjenja obujma sustava i pospješivanja onih reakcija koje vode smanjenju obujma. Potencijal primjene visokog tlaka u obradi hrane je u inaktivaciji mikroorganizama, modifikaciji funkcionalnih svojstava biopolimera, postizanju funkcionalnosti proizvoda te zadržavanju čimbenika kvalitete (boja, aroma, nutritivni sastav). Komponente odgovorne za specifičnu nutritivnu vrijednost i organoleptičke značajke hrane praktički su neosjetljive na djelovanje tlaka. Cilj rada je, polazeći od teorijskih principa djelovanja visokog tlaka, uzimajući u obzir njegove prednosti i nedostatke, prikazati mogućnosti primjene u postupcima obrade hrane. U radu su također opisani tipovi uređaja za tretiranje visokim tlakom koji se mogu primijeniti u obradi hrane. Osim sposobnosti uništavanja mikroorganizama pri sobnoj temperaturi što ovu tehnologiju čini danas jedinom komercijalno primjenjivom alternativom termičkom tretiranju, u radu su prikazane i specifične mogućnosti primjene visokog tlaka u preradi mlijeka, mesa te voća i povrća. S obzirom na trend rastuće potražnje za hranom bez dodataka koja u velikoj mjeri ima zadržane značajke kvalitete (boja, aroma, nutritivni sastav, tekstura), uz ujedno zajamčenu mikrobiološku stabilnost, može se očekivati da će metoda obrade hrane visokim tlakom u budućnosti naći svoju širu primjenu i to upravo za proizvode koji zahvaljujući svojoj dodanoj vrijednosti imaju istaknuto mjesto na tržištu.In high pressure processing, foods are subjected to pressures generally in the range of 100 – 800 (1200) MPa. The processing temperature during pressure treatments can be adjusted from below 0 °C to above 100 °C, with exposure times ranging from a few seconds to 20 minutes and even longer, depending on process conditions. The effects of high pressure are system volume reduction and acceleration of reactions that lead to volume reduction. The main areas of interest regarding high-pressure processing of food include: inactivation of microorganisms, modification of biopolymers, quality retention (especially in terms of flavour and colour), and changes in product functionality. Food components responsible for the nutritive value and sensory properties of food remain unaffected by high pressure. Based on the theoretical background of high-pressure processing and taking into account its advantages and limitations, this paper aims to show its possible application in food processing. The paper gives an outline of the special equipment used in highpressure processing. Typical high pressure equipment in which pressure can be generated either by direct or indirect compression are presented together with three major types of high pressure food processing: the conventional (batch) system, semicontinuous and continuous systems. In addition to looking at this technology’s ability to inactivate microorganisms at room temperature, which makes it the ultimate alternative to thermal treatments, this paper also explores its application in dairy, meat, fruit and vegetable processing. Here presented are the effects of high-pressure treatment in milk and dairy processing on the inactivation of microorganisms and the modification of milk protein, which has a major impact on rennet coagulation and curd formation properties of treated milk. The possible application of this treatment in controlling cheese manufacture, ripening and safety is discussed. The opportunities for its application within the meat processing sector are also discussed, particularly the specific effects of high pressure on the colour, texture, nutritive value and functional properties of fresh and processed meat. This paper also considers the possibilities of implementing high-pressure technology in fruit and vegetable processing with the aim to maintain microbiological safety, nutritive value, “fresh-like” appearance and antimutagenic properties. The intention of this paper is to broaden the knowledge of experts and technologists regarding implementation possibilities of high pressure, as one of the emerging technologies in the various food-processing sectors. Given the trend of growing consumer preferences for fresh-like, additive-free and microbiologically safe food, high pressure processing is likely to find its future application in food processing for niche products with added value

Application of high power ultrasound in drying of fruits and vegetables

Ultrazvuk iskazuje frekvenciju zvuka koja se nalazi između 18 i 100 kHz, što je iznad čujnosti ljudskog uha. Ultrazvuk visoke snage znači primjenu intenziteta višeg od I=1Wcm-2(uobičajeno u rasponu od I=10 - 1000Wcm-2). Ultrazvuk visoke snage i niskih frekvencija (f=20 do 100 kHz) smatra se "snažnim ultrazvukom" jer uzrokuje pojavu kavitacije te ima primjenu u prehrambenoj industriji. Primjenjuje se kod odzračivanja tekuće hrane, za induciranje reakcija oksidacije/redukcije, za ekstrakciju enzima i proteina, za inaktivaciju enzima i za indukciju nukleacije kod kristalizacije. Nadalje, ultrazvuk pospješuje prijenos topline, primjenjuje se kod emulgiranja, sterilizacije, ekstrakcije, odzračivanja, filtriranja, sušenja i pojačavanja oksidacije. Konvencionalno sušenje toplim zrakom je energetski veoma zahtjevno i posljedično zahtijeva veća financijska izdvajanja. Primjene različitih predtretmana kao što su osmotska dehidratacija, ultrazvuk i ultrazvukom potpomognuta osmodehidratacija pokazale su različite učinke na voće i povrće. Prolaskom akustičke energije visokog intenziteta kroz čvrsti medij zvučni val uzrokuje serije brzih i sukcesivnih kompresija i opuštanja s brzinama koje ovise o njegovoj frekvenciji. Zbog toga je materijal izložen brzim serijama promjenjivih stezanja i širenja, vrlo nalik neprekidnom stiskanju i opuštanju spužve. Ovaj mehanizam, poznat kao "rektificirana difuzija", vrlo je važan u akustičkom sušenju i migraciji vlage. Primjena ultrazvuka kao prethodne obrade pokazala je velik utjecaj na skraćivanje kasnijeg trajanja sušenja vrućim zrakom, te samim time i ukupna operacija sušenja. Pokazano je da obrada prije provedbe sušenja omogućava bolji prijelaz mase i difuzivnost vode od osmotske dehidratacije. Kvaliteta proizvoda koji se stavlja na sušenje je veća jer se prethodna obrada ultrazvukom primjenjuje pri sobnoj temperaturi čime se smanjuju nepoželjne promjene na strukturi, senzorskim karakteristikama, te gubitci nutritivnih komponenta voća i povrća.Ultrasound is a sound frequency in the range between 18 and 100 kHz that is above hearing of the human ear. High power ultrasound means application of intensities higher than 1 W cm–2 (usually in the range between I=10–1000Wcm–2). High power and low frequency ultrasound (f = 20 to 100 kHz) is considered as “power ultrasound” because its application causes cavitation and is applied in the food industry. High power ultrasound is applied for degassing of liquid food, for induction of oxidation/reduction reactions, for extraction of enzymes and proteins, for inactivation of enzymes and induction of nucleation for crystallization. Ultrasound is anticipating heat transfer; it is used for emulsifying, sterilization, extraction, degassing, filtrating, drying and induction of oxidation. Conventional hot air drying is a very energy- and cost-intensive process. Drying is a simultaneous operation of heat and mass exchange that is followed by phase changes. Application of different pretreatments, like osmotic dehydration, ultrasound and ultrasound assisted osmotic dehydration has shown different effects on fruits and vegetables. When the high intensity acoustic energy is passing through solid material, it causes several fast and successive compressions and rarefactions with speeds that depend on the frequency applied. Thus, material is exposed to a series of exchangeable squeezing and relaxations, very like continuous squeezing and releasing of the sponge. This mechanism known as "rectified diffusion" is very important in acoustic drying and migration of water. Application of ultrasound as a pretreatment has shown great influence on reducing afterward hot air drying thereby reducing total drying time. It is also shown that pretreatment before drying facilitates better mass transfer and water diffusivity than osmotic dehydration. Quality of the product after drying is better because ultrasound pretreatment is applied at room temperature thus reducing deteriorating alterations and nutritive loss of compounds in fruits and vegetables. In this paper, the basic theory of ultrasound has been described. In the figures, the range of sound by frequency is described, as is the amplitude of ultrasound and its effect on the material also l, the wavelength and attenuation coefficient have been explained. The most common usage of power ultrasound as probe type of high intensity ultrasound set system with piezoelectric transducer have been introduced as a system for ultrasound drying. When the ultrasound wave passes through material the basic effect occurs. It is called cavitation and is divided generally in two types: stable and transient cavitation. Also, when imploding cavitation bubble causes elevated temperatures and pressures several chemical reactions can happen. In the figure one can see the visualisation of sonochemical reactions that occur around the decomposed bubble. Several reactions of decomposition, polymerisations, formation of aggregates, breaking of aggregates, bonding, breaking of bonds, formation of radicals, hydroxyl radicals etc. The main aim of this paper was to introduce the new non-thermal pre-treatment or direct treatment of ultrasound probe, or set of probes in the drying of vegetables and fruits. The basic target of the paper was to improve the knowledge of experts in the food industry and technologists in the chemical and other industries to learn of the possibility of implementing new techniques in their facilities. One can observe the modern scheme of the system for drying of materials with direct contact and also the example of the ultrasound treatment of fruits, water diffusivity in fruit and total processing time of applying ultrasound. The most important thing is to conduct the drying process in the best way to reduce treatment time, and to optimize the system. The most commonly used mathematical models for determination of drying kinetics have been pointed out. The lack of information is about energy input, and the total quality of dried fruits and vegetables and for that purpose in the future several scientific projects need to be conducted to surely claim the benefit of ultrasound accelerated drying of foodstuffs

The fourth industrial revolution in the food industry—part II: Emerging food trends

The food industry has recently been under unprecedented pressure due to major global challenges, such as climate change, exponential increase in world population and urbanization, and the worldwide spread of new diseases and pandemics, such as the COVID-19. The fourth industrial revolution (Industry 4.0) has been gaining momentum since 2015 and has revolutionized the way in which food is produced, transported, stored, perceived, and consumed worldwide, leading to the emergence of new food trends. After reviewing Industry 4.0 technologies (e.g. artificial intelligence, smart sensors, robotics, blockchain, and the Internet of Things) in Part I of this work (Hassoun, Aït-Kaddour, et al. 2022. The fourth industrial revolution in the food industry—Part I: Industry 4.0 technologies. Critical Reviews in Food Science and Nutrition, 1–17.), this complimentary review will focus on emerging food trends (such as fortified and functional foods, additive manufacturing technologies, cultured meat, precision fermentation, and personalized food) and their connection with Industry 4.0 innovations. Implementation of new food trends has been associated with recent advances in Industry 4.0 technologies, enabling a range of new possibilities. The results show several positive food trends that reflect increased awareness of food chain actors of the food-related health and environmental impacts of food systems. Emergence of other food trends and higher consumer interest and engagement in the transition toward sustainable food development and innovative green strategies are expected in the future