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The purpose of this Special Issue “Cow’s Milk and Allergy” is to provide an overview of the association of cow’s milk with allergy. This topic has two quite different faces. On the one hand, we are all aware of the importance of cow’s milk allergy in early life. What is less known is that the consumption of raw, unprocessed milk is associated with a lower incidence of asthma and rhinitis. This Special Issue takes a closer look at all of these aspects of cow’s milk and allergy and focus on the following questions:

animal models --- milk allergen --- allergenicity --- camel milk --- immune regulation --- epigenetics --- human breast milk --- milk processing --- CAP-FEIA (Fluorescence Enzyme Immunoassay) --- immune system --- raw milk --- multiplex dot test --- Middle-East --- alkaline phosphatase --- cow’s milk allergy --- polygenic risk score --- tolerance --- hydrolysate --- CML --- infant formula --- miRNA-150 --- milk --- allergy --- casein --- asthma --- partial hydrolysate --- Immunoglubuline E --- molecular diagnosis --- allergic march --- delayed-type hypersensitivity --- allergenicity modulation --- prebiotics --- processing --- sRAGE --- histone acetylation --- dietary intervention --- probiotics --- cow’s milk --- Cow’s milk allergy (CMA) --- cow’s milk protein allergy --- farming effect --- protection --- anaphylaxis --- aggregation --- IgE binding --- natural history --- epidemiology --- prevalence --- infant allergy --- basophil activation test (BAT) --- ?-lactoglobulin --- step-down --- sensitization pattern --- extracellular vesicles --- cell-mediated reactions --- proteomics --- prevention of cow’s milk allergy --- therapy --- raw cow’s milk --- baked milk --- immune cells --- food allergy --- gut microbiota --- allergic diseases --- glycation --- bioactive peptides --- infant feeding --- cow’s milk allergens --- treatment of cow’s milk allergy --- formula --- genome-wide association --- diagnosis of cow’s milk allergy

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During cell metabolism, oxygen is partially reduced to reactive oxygen species (ROS) that play a physiological role in cellular processes. However, an imbalance between the production of ROS and the ability of defenses to detoxify the organism provokes oxidative stress. Oxidative stress and its subsequent damages to vital cellular components have been associated with numerous severe chronic disorders. In addition, oxidation reactions are responsible for food deterioration during processing and storage. Peptides from animal and vegetal food sources have attracted attention due to the large evidence of their in vitro antioxidant properties. In addition to their potential as safer alternatives to synthetic antioxidants used to prevent oxidative reactions in foods, antioxidant peptides can also act by reducing the risk of numerous oxidative stress-associated diseases. Furthermore, peptides can act synergistically with nonpeptide antioxidants, enhancing their protective effect. This Special Issue of the Foods journal includes outstanding papers illustrating examples of the most recent advances on antioxidant peptides from both vegetal and animal sources. The existing data on their bioactivities demonstrated by in silico, in vitro, and animal models are included as well as the mechanisms of action of identified antioxidant peptides.

food peptides --- reactive oxygen species --- antioxidant enzymes --- whey protein hydrolysate --- hydrolysis condition --- food antioxidant --- ORAC --- cellular ROS --- HepG2 --- peptides --- egg white --- egg yolk --- antioxidant peptides --- sarcopenia --- whey protein --- muscle --- C2C12 --- aged animals --- older adult --- exercise --- bioactive peptides --- animal protein --- multifunctionality --- antioxidant activity --- in silico --- cell models --- fruit residues --- antioxidant --- extraction --- albumin --- albumin peptide --- antioxidant peptide --- bioactive peptide --- mung bean --- mung bean albumin --- peptide sequencing --- Vigna radiata --- n/a

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Renewable fuels and chemicals derived from lignocellulosic biomass offer unprecedented opportunities for replacing fossil fuel derivatives, reducing our overdependence on imported oil, and mitigating current climate change trends. Despite technical developments and considerable efforts, breakthrough technologies are still required to overcome hurdles in developing sustainable biorefineries. In recent years, new biorefinery concepts including a lignin-first approach and a closed-loop biorefinery have been introduced to tackle technoeconomic challenges. Furthermore, researchers have advanced the development of new technologies which enable the utilization of biomass components for sustainable materials. It is now apparent that advanced processes are essential for ensuring the success of future biorefineries. This book presents processes for biomass fractionation, lignin valorization, and sugar conversion or introduces new bioproducts (chemicals and materials) from renewable resources, addressing the current status, technical/technoeconomic challenges, and new strategies.

Biomass --- two-step pretreatment --- steam explosion --- organosolv treatment --- empty fruit bunch --- pinewood --- green pretreatment --- enzymatic hydrolysis --- lignin structural features --- poplar --- FTIR --- contaminants --- by-products --- lignin valorization --- lignin applications --- 3D printing --- electrochemical material --- medical application --- drying effect --- cellulose --- hornification --- porosity --- bioethanol --- economic analysis --- hand sanitiser --- oil palm empty fruit bunch (OPEFB) --- simultaneous saccharification and fermentation --- SuperPro Designer® --- renewable fuel --- high-density fuel --- α-pinene dimerization --- turpentine --- stannic chloride molten salt hydrates --- xylooligosaccharides --- autohydrolysis --- sweet sorghum bagasse --- isobutanol --- biorefinery --- metabolic engineering --- biomass utilization --- aqueous biphasic system --- dilute acid hydrolysate --- furfural production --- solvent extraction --- response surface methodology --- biomass fractionation --- bioproducts

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This second edition of the Special Issue “Marine Bioactive Peptides: Structure, Function, and Therapeutic Potential - II” published papers on up-to-date information regarding isolation, structural elucidation, functional characterization, and therapeutic potential evaluation of peptides isolated from marine organisms. Chemical synthesis and biotechnological production of marine peptides and their mimetics will also be a focus of this Special Issue. In addition, this Special Issue will publish new results arising from a peptidomic approach. 24 Papers were accepted and included in the first issue, which we published as a Special Issue book (https://www.mdpi.com/books/pdfview/book/1742). Following the success of the first Special Issue, as Guest Editor, I invite researchers in the field to contribute to the second edition entitled " Marine Bioactive Peptides: Structure, Function, and Therapeutic Potential - II] ".

Spanish mackerel (Scomberomorous niphonius) --- muscle --- peptide --- antioxidant activity --- stability --- biological activity --- chemistry --- marine derived fungi --- peptides --- biotransformation --- laxaphycin --- autophagy --- apoptosis --- cyanobacteria --- bioactive peptides --- marine --- secondary structure --- proline --- mechanism of activity --- marine waste --- antimicrobial peptide --- polychaeta --- innate immunity --- BRICHOS domain --- recombinant peptide --- β-hairpin structure --- nuclear magnetic resonance (NMR) --- arenicin --- complement system --- complement regulation --- jellyfish --- Rhopilema esculentum --- Sanderia malayensis --- proteome --- venom --- toxin --- hydrolysate --- fish protein --- ageing --- physical function --- dietary assessment --- seafood intake --- healthy ageing --- marine organism --- anticancer medicine --- small peptide --- liner peptide --- cyclic peptide --- marine peptide --- dolastatin 10 --- antitumor --- lead exploration --- n/a

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Over the past decade, interest in plant biostimulants has been on the rise, compelled by the growing interest of researchers, extension specialists, private industries, and farmers in integrating these products in the array of environmentally friendly tools to secure improved crop performance, nutrient efficiency, product quality, and yield stability. Plant biostimulants include diverse organic and inorganic substances, natural compounds, and/or beneficial microorganisms such as humic acids, protein hydrolysates, seaweed and plant extracts, silicon, endophytic fungi like mycorrhizal fungi, and plant growth-promoting rhizobacteria belonging to the genera Azospirillum, Azotobacter, and Rhizobium. Other substances (e.g., chitosan and other biopolymers and inorganic compounds) can have biostimulant properties, but their classification within the group of biostimulants is still under consideration. Plant biostimulants are usually applied to high-value crops, mainly greenhouse crops, fruit trees and vines, open-field crops, flowers, and ornamentals to sustainably increase yield and product quality. The global biostimulant market is currently estimated at about $2.0 billion and is expected to reach $3.0 billion by 2021 at an annual growth rate of 13%. A growing interest in plant biostimulants from industries and scientists was demonstrated by the high number of published peer-reviewed articles, conferences, workshops, and symposia in the past ten years. This book compiles several original research articles, technology reports, methods, opinions, perspectives, and invited reviews and mini reviews dissecting the biostimulatory action of these natural compounds and substances and beneficial microorganisms on crops grown under optimal and suboptimal growing conditions (e.g., salinity, drought, nutrient deficiency and toxicity, heavy metal contaminations, waterlogging, and adverse soil pH conditions). Also included are contributions dealing with the effect as well as the molecular and physiological mechanisms of plant biostimulants on nutrient efficiency, product quality, and modulation of the microbial population both quantitatively and qualitatively. In addition, identification and understanding of the optimal method, time, rate of application and phenological stage for improving plant performance and resilience to stress as well as the best combinations of plant species/cultivar × environment × management practices are also reported. We strongly believe that high standard reflected in this compilation on the principles and practices of plant biostimulants will foster knowledge transfer among scientific communities, industries, and agronomists, and will enable a better understanding of the mode of action and application procedures of biostimulants in different cropping systems.

Crocus sativus L. --- biofertilization --- arbuscular mycorrhizal fungi --- antioxidant activity --- crocin --- picrocrocin --- polyphenols --- safranal --- Maize --- biostimulant --- root --- stress --- growth --- gene expression --- stem cuttings --- propagation --- root morphology traits --- indole-3-acetic acid (IAA) --- indole-3-butyric acid (IBA) --- gibberellins --- phenolic compounds --- nutrients --- nutraceutical potential --- soybean --- yield --- N organic fertilizer --- seaweed extract --- mycorrhizal inoculants --- phosphate-solubilizing microorganisms --- biofertilizers --- microorganism consortium --- biostimulants --- Crocus sativus --- Funneliformis mosseae --- glasshouse --- protected cultivation --- Rhizophagus intraradices --- substrate --- L-methionine --- L-tryptophan --- L-glycine --- lettuce --- nitrogen --- plant biostimulant --- environmental stress --- vegetables --- fruit quality --- plants biostimulants --- yielding --- Biostimulants --- Euglena gracilis --- algal polysaccharide --- β-glucan --- water stress --- tomato --- aeroponics --- Zea mays L --- lignohumate --- lignosulfonate --- biological activity --- nitrogen metabolism --- carbon metabolism --- proteins --- phenolics --- sugars --- Ascophyllum nodosum --- Solanum melongena --- heterostyly --- pollination efficiency --- soilless conditions --- abiotic stress --- alfalfa hydrolysate --- chitosan --- zinc --- ascorbic acid --- Fragaria x ananassa --- functional quality --- lycopene --- organic farming --- protein hydrolysate --- Solanum lycopersicum L. --- tropical plant extract --- fertilizer --- melatonin --- phytomelatonin --- plant protector --- plant stress --- Lactuca sativa L. --- legume-derived protein hydrolysate --- nitrate --- Septoria --- wheat --- Paraburkholderia phytofirmans --- thyme essential oil --- isotope --- phytoparasitic nematodes --- suppressiveness --- sustainable management --- anti-nutritional substances --- fat --- fibre --- morphotype --- protein --- corn --- imaging --- industrial crops --- maize --- next generation sequencing --- phenomics --- plant phenotyping --- row crops --- Bacillus subtilis --- carotenoids --- probiotics --- PGPR --- Mentha longifolia --- humic acid --- antioxidants --- arbuscular mycorrhizal symbiosis --- mycorrhizosphere --- AMF associated bacteria --- plant growth-promoting bacteria --- phosphate-solubilizing bacteria --- siderophore production --- soil enzymatic activity --- biological index fertility --- nitrogenase activity --- microelements fertilization (Ti, Si, B, Mo, Zn) --- seed coating --- cover crop --- vermicompost --- growth enhancement --- AM fungi --- PGPB --- water deficit --- common bean --- Glomus spp. --- organic acids --- pod quality --- seaweed extracts --- seed quality --- tocopherols --- total sugars --- bean --- amino acids --- phenols --- flavonoids --- microbial biostimulant --- non-microbial biostimulant --- Lactuca sativa L. var. longifolia --- mineral profile --- physiological mechanism --- photosynthesis --- biocontrol --- plant growth promotion --- soil inoculant --- Trichoderma --- Azotobacter --- Streptomyces --- deproteinized leaf juice --- fermentation --- lactic acid bacteria --- plant nutrition --- antioxidant capacity --- ornamental plants --- N fertilization --- nitrogen use efficiency --- leaf quality --- Spinacia oleracea L. --- sustainable agriculture --- Valerianella locusta L. --- isotopic labeling --- turfgrass --- humic acids --- leaf area index (LAI) --- specific leaf area (SLA) --- Soil Plant Analysis Development (SPAD) index --- tuber yield --- ultrasound-assisted water --- foliar spray --- Pterocladia capillacea --- bio-fertilizer --- growth parameters --- Jew’s Mallow --- CROPWAT model --- eco-friendly practices --- total ascorbic acid --- Mater-Bi® --- mineral composition --- SPAD index --- Bacillus thuringiensis --- Capsicum annuum --- microbiome --- strain-specific primer --- tracking --- sweet basil --- alfalfa brown juice --- biostimulation --- chlorophyll pigments --- histological changes --- humic substances --- protein hydrolysates --- silicon --- arbuscular mycorrhiza --- plant growth promoting rhizobacteria --- macroalgae --- microalgae --- abiotic stresses --- nutrient use efficiency --- physiological mechanisms