Search Results (38)

The growing emphasis on sustainability and circular economy strategies has driven increasing interest in the valorization of agro-industrial by-products. Among these, the peel and seed of avocado (Persea americana), typically discarded during processing, have emerged as promising sources of bioactive compounds, particularly phenolic constituents with recognized antioxidant capacity. This review critically examines the current scientific literature on the phytochemical composition, antioxidant activity, and potential health benefits associated with avocado peel and seed. In addition, it explores recent technological advances in extraction methods and highlights the applicability of these by-products in the formulation of functional foods, nutraceuticals, and other health-related products. Challenges related to safety, bioavailability, and regulatory aspects are also discussed. By consolidating available evidence, this work supports the potential of avocado peel and seed as valuable functional ingredients and contributes to sustainable innovation in the food and health industries. Full article

This research analyzes the innovative development of carnauba wax coatings enriched with essential oils (EOs: lemon, orange, grapefruit, clove, oregano, and cinnamon) or fruit by-products (FBPs: avocado, tomato, carrot, orange, lemon, and grapefruit) to improve postharvest preservation of organic oranges and lemons. Six EOs and six FBPs were evaluated for total phenolic content (TPC) and in vitro antifungal activity against Penicillium digitatum. Based on results, grapefruit, oregano, and clove EOs were selected for lemons, while avocado, orange, and grapefruit FBPs were selected for oranges. An in vivo test at 20 °C for 15 days with carnauba wax coatings assessed antifungal performance. Clove EO and avocado FBP showed strong in vitro inhibition and consistent hyphal suppression (~100 and ~82%, respectively). In vivo, coatings with grapefruit EO and avocado FBP significantly reduced fungal decay and sporulation (~75%) in lemons and oranges, respectively. Coated fruits also retained weight losses by ~25% compared to uncoated ones. These findings suggest that phenolic-rich natural extracts, especially from agro-industrial residues like avocado peels, offer a promising and sustainable strategy for postharvest citrus disease control. Further studies should test coating effectiveness in large-scale trials under refrigeration combined with other preservation strategies. Full article

Rheumatoid arthritis (RA) is a chronic autoimmune inflammatory disease characterized by the inflammation of synovial fluid. The incidence of cardiovascular diseases (CVDs) is increasing in RA patients. This research is the first report to investigate the anti-arthritic effect of avocado peel nutraceutical (APN) and its potential in mitigating the cardiovascular risk associated with RA. The antioxidant activity and phytochemical composition of APN were assessed. The potential interaction of APN’s active compounds with protein tyrosine phosphatase non-receptor type 22 (PTPN22) was studied using molecular docking. The impact of APN on the plasma lipid profile, oxidative and inflammatory markers, and the indices of coronary risk and atherogenicity as CVD markers were evaluated. The gene expression of COX-2, IL-6, IL-1β, IL-10, and TNF-α in liver and spleen tissues were measured. The rat gut microbiota profile was investigated using 16S rRNA amplicon sequencing. APN exhibited high antioxidant activity, low atherogenicity and thrombogenicity indices, and a high ratio of hypocholesterolemic to hypercholesterolemic fatty acids indicating its cardioprotective potential. The administration of APN led to a reduction in oxidative stress markers, inflammatory markers, dyslipidemia, and CVD markers. APN administration downregulated the expression of COX-2, IL-6, IL-1β, and TNF-α genes, while the IL-10 gene was significantly upregulated in the liver and spleen. Treatment with APN was favorable in restoring eubiosis in the gut by modulating RA-associated bacterial taxa linked to impaired immune function and cardiometabolic diseases. In molecular docking, β-amyrin and ellagic acid showed the highest binding affinity for PTPN22. APN may represent a promising approach to ameliorating the cardiovascular risk of RA. The present results will be offering a foundation for future in-depth research in nutraceuticals from agriculture by-products. Additionally, they will be supporting the public health policies aimed at preventing and controlling rheumatoid arthritis. Full article

Avocado landraces have gained great interest due to their importance in maintaining biodiversity and the presence of bioactive compounds in their fruit, depending on fruit tissues or ripening stages. This study aimed to evaluate the morpho-physicochemical and nutritional components of the peel, pulp, and seed tissues from Lagunero (LA) and Criollo (CA) avocado landraces at different ripening stages. Additionally, phenolic profiles were analyzed by using UPLC-DAD/ESI-MS, and a principal component analysis (PCA) was constructed to determine variations among the determined contents from avocado landraces, fruit tissues, and ripening stages. The CA showed a 30% higher fruit weight and higher percentages of seed (0.52%) and peel (3.62%) weight yields as compared to the LA. Ripening significantly affected the physical characteristics of LA and CA, and a substantial decrease in hardness (83%) after 4 days of storage. In LA, ripening resulted in an increase in fat content in both the peel and pulp. In contrast, CA showed an increase in protein content in the peel and pulp but a decrease in seeds; fat content increased significantly in the pulp of CA and carbohydrates remained the predominant component in all tissues, though they decreased slightly in CA peels during ripening. The ripe LA peel presented approximately 50% more total phenolic compounds than other tissues. The unripe CA peel showed a higher antioxidant capacity according to DPPH (3831.97 µMol Eq Trolox/g dw) and ABTS+ (3674.70 µMol Eq Trolox/g dw) assays. The main phenolic compounds identified in the avocado peel were chlorogenic acid, catechin, quercetin-3-O-hexoside, quercetin-3-O-pentoside, coumaric acid, caffeic acid, neochlorogenic acid, ferulic acid, kaempferol-3-O rhamnoside, and quercetin-3-O-rhamnoside. The PCA analysis revealed a strong correlation between chlorogenic acid and caffeic acid with TPC, while catechin was more closely related to antioxidant activity. These findings suggest that peel and seed tissues of avocado landraces, often considered byproducts, are valuable sources of bioactive compounds with high antioxidant potential. Full article

The antioxidant, antithrombotic and anti-inflammatory effects of the amphiphilic compounds extracted from both avocado juice and by-products, were evaluated. All extracts were assessed for their total phenolic content (TPC) and total carotenoid content (TCC), and for their antioxidant activities by DPPH, ABTS and FRAP assays as well as for their anti-inflammatory and antithrombotic potency in human platelets. The extracts rich in TAC (Total Amphiphilic Content) showed much higher content in phenolics and carotenoids from the extracts of total lipophilic content (TLC), which was reflected by the much stronger antioxidant capacities of TAC extracts. ATR-FTIR spectroscopy revealed the presence of not only phenolics and carotenoids, but also of bioactive polar lipids (PLs) in avocado TAC extracts, the LC-MS based structural analysis of which further revealed a fatty acid composition favourable for unsaturated fatty acids (UFAs) versus saturated ones (SFAs), including monounsaturated fatty acids (MUFAs) like the oleic acid (C18:1n9) and omega-3 (n3) polyunsaturated fatty acids (PUFAs) like the alpha linolenic acid (C18:3n3), with the subsequent anti-inflammatory low values of the n6/n3 PUFA ratio. The presence of such bioactive PLs that are rich in UFA within the TAC extracts of avocado juice and its by-products provide an explanation for the observed potent anti-inflammatory and antithrombotic activities of avocado TAC against thrombo-inflammatory mediators like platelet activating factor (PAF) and against standard platelet agonists like ADP, offering promise for such avocado TAC extracts, as ingredients in functional products for health/promoting applications either in cosmetics or in functional foods and nutraceuticals, or even drugs. Full article

Avocado (Persea americana Mill.) is a widely cultivated fruit known for its nutritional benefits, with the seed representing a significant portion of the fruit that is often discarded as waste. In the Dominican Republic, the cultivar Semil 34 represents 58% of the national production. This study aimed to explore the potential of Semil 34 avocado seed (AS) as a source of bioactive compounds with applications in the food industry. We conducted the chemical characterization of the seed extract, focusing on its total phenolic content, total flavonoids, and antioxidant capacity. High-performance liquid chromatography–quadrupole time-of-flight mass spectrometry (HPLC-QTOF-MS) was employed to identify key phytochemicals, including phenolic acids and flavonoids, that were responsible for the antioxidant properties of the extract. The hydroalcoholic extract of the Semil 34 seeds exhibited an antioxidant capacity of 1743.3 ± 52.3 µM Trolox/g extract, total phenolic content of 25.86 ± 2.17 mg gallic acid equivalents/g extract, and total flavonoid content of 2.09 ± 0.10 mg quercetin equivalents/g extract. However, the extract’s antioxidant capacity was found to be sensitive to pH changes, suggesting the need for stabilization when used in acidic or basic food matrices. The present work identified 53 compounds in the Semil 34 seed extracts; among these, 23 are being reported for the first time in avocado seeds. This study demonstrates the potential of the avocado seed as a source of bioactive compounds and hence a functional ingredient, supporting its value in sustainable production and its possible contribution to environmental goals by reducing waste in the avocado industry. Full article

Virgin avocado oil (VAO), treasured for its nutritional and sensory properties, is susceptible to oxidation. To improve its oxidative stability, the feasibility of enrichment with antioxidants from avocado or olive-processing by-products via ultrasound-assisted maceration was explored. Dried, milled avocado (AL), olive leaves (OL), or olive pomace (OP) were ultrasound-macerated with laboratory-extracted VAO at 5, 10, and 20% w/w levels. Induction-period (IP) values, determined via Rancimat (110 °C, 20 L/h), increased by 1.1–1.6-fold. Maceration with AL and OL added pigments (β-carotene, lutein, α-chlorophyll, and α-pheophytin) but only AL significantly boosted α-tocopherol levels (up to 3.7-fold). Extraction of major polar phenols (chlorogenic acid, oleuropein, and hydroxytyrosol) was poor (<42 mg/kg oil). Oleanolic and maslinic acids, from OL and OP, reached up to 650 and 260 mg/kg. The IP values correlated (r = 0.796, p = 0.002) only with total polar phenol content. Maceration with OP resulted in superior antioxidant activity, extending the predicted shelf-life from 14 to 22.3 months, reaching that of a hydroxytyrosol-rich extra-virgin olive oil (24.9 months). GC-MS revealed the dominance of volatile acids in OL- and OP-VAOs, and estragole in AL-VAO highlighting some organoleptic and safety challenges to be considered, particularly when aiming to exploit these materials for the enhancement of the oxidative stability of VAOs to sustain its production. Full article

The growing global population has led to increased food consumption and a significant amount of food waste, including the non-consumed parts of fruits (e.g., stems, rinds, peels, seeds). Despite their nutrient richness, these by-products are often discarded. With the rising interest in nutrient-dense foods for health benefits, fruit by-products have potential as nutritious ingredients. Upcycling, which repurposes waste materials, is one solution. White flour, which is common in food products like bread and pasta, has good functional properties but poor nutritional value. This can be enhanced by blending white flour with fruit by-product flours, creating functional, nutrient-rich mixtures. This review explores using flours from common Brazilian fruit by-products (e.g., jaboticaba, avocado, guava, mango, banana, jackfruit, orange, pineapple, and passion fruit) and their nutritional, physical–chemical properties, quality and safety, and applications. Partially replacing wheat flour with fruit flour improves its nutritional value, increasing the amount of fiber, protein, and carbohydrates present in it. However, higher substitution levels can alter color and flavor, impacting the sensory appeal and acceptability. While studies showed the potential of fruit by-product flours in food formulation, there is limited research on their long-term health impacts. Full article

In recent years, the global production and industrialization of avocados has led to the generation of large numbers of peel, seeds, and leaf by-products with significant environmental implications. Current efforts, including the Sustainable Development Goals, aim towards the development of sustainable operations through the valorization of waste. Previous research has focused on studying the rich chemical composition of these avocado by-products. Current studies are working on the isolation of polyphenols, flavonoids, phenolic acids and other bioactive compounds found in avocado peel, seeds and leaves for applications in nutraceutical products in the food, pharmaceuticals and cosmetics industries. The inclusion of these extracts in industrial matrices often requires stabilization technologies such as encapsulation emulsions to ensure the delivery and bioactivity of these target compounds. This review will discuss the global production volumes of avocado and its by-products as well as the potential inclusion in various industries based on their chemical compositions. Additionally, this work addresses the various applications that have been previously proposed for the wastes and their extracts. This review also covers the stabilization techniques previously employed in avocado extract treatment, their applications, and the current challenges and opportunities associated with avocado by-products. Full article

In recent years, the consumption of avocado, both fresh and processed, has experienced a significant worldwide increase due to its recognized nutritional value and beneficial health effects. However, this industrial processing generates a substantial amount of underutilized byproducts, primarily the peel and seed, leading to significant environmental and economic challenges. Fortunately, these residues are rich in bioactive phytochemicals, making their recovery an excellent opportunity to enhance the sustainability and profitability of the modern avocado industry. This bibliometric analysis utilizes data from the Scopus platform to explore the comprehensive utilization of avocado waste. By employing a biorefinery approach and computational tools, the study aims to identify and extract value-added compounds with potential applications in the food, pharmaceutical, chemical, and cosmetic industries. The results highlight that the most relevant research topics are currently focused on sustainable and comprehensive biotransformation of avocado byproducts. Additionally, there is a growing emphasis on methods for extracting valuable products, characterizing their properties, and identifying potentially exploitable active compounds. Furthermore, research is increasingly exploring the environmental and economic factors associated with new research advancements, such as emerging environmental regulations, certifications, substitutes, and technological applications. One key gap identified in recent research advancements is the lack of a sustainable diagnostic framework for avocado utilization processes in a cascade system (multiple high-value consumer products and by-products such as bioplastic). This suggests a crucial area for future research efforts. Full article

Biopolymers derived from biomass can provide the advantages of both biodegradability and functional qualities from a circular economy point of view, where waste is transformed into raw material. In particular, avocado seeds can be considered an interesting residue for biobased packaging applications due to their high starch content. In this work, avocado seed starch (ASS)-based films containing different glycerol concentrations were prepared by solvent casting. Films were also reinforced with starch nanocrystals (SNCs) obtained through the acid hydrolysis of ASS. The characterization of the extracted starch and starch nanocrystals by scanning electron microscopy, X-ray diffraction, and thermogravimetric analysis has been reported. Adding 1% of SNCs increased elastic modulus by 112% and decreased water vapor permeability by 30% with respect to neat matrix. Interestingly, the bioactive compounds from the avocado seed provided the films with high antioxidant capacity. Moreover, considering the long time required for traditional plastic packaging to degrade, all of the ASS-based films disintegrated within 48 h under lab-scale composting conditions. The results of this work support the valorization of food waste byproducts and the development of reinforced biodegradable materials for potential use as active food packaging. Full article

Extraction techniques are continuously developed by the scientific community. Meanwhile, avocado peel is a by-product of avocado processing and a source of bioactive compounds. The purpose of this review was to summarize the use of advanced techniques for extracting bioactive compounds from avocado peel to help understand which techniques have and have not been applied to avocado peel. Three primary databases were used to collect the information, including Google Scholar, Scopus, and Web of Science, by using the keywords “avocado”, “peel”, and “extraction”. Additional keywords related to the extraction technique were also used, including “Microwave-Assisted Extraction”, “Ultrasound-Assisted Extraction”, “Enzyme-Assisted Extraction”, “Pressurized Liquid Extraction”, “Supercritical Fluid Extraction”, “Natural Deep Eutectic Solvents”, “Three-phase partitioning (TPP)”, “Pulsed-Electric Field”, “High Voltage Electric Discharge Plasma”, “Centrifugal Partition Extraction”, and “Surfactant-Mediated Extraction”. The results show that microwave-assisted extraction, ultrasound-assisted extraction, enzyme-assisted extraction, pressurized liquid extraction, supercritical fluid extraction, TPP, and natural deep eutectic solvent extraction have been used to retrieve bioactive compounds from avocado peel. Other techniques have not yet been applied for the extraction of bioactive compounds from avocado peel. This article is the first review discussing the advanced extraction technique for retrieving bioactive compounds from avocado peel. This article creates a paradigm for future studies. Full article

Avocado (Persea americana) is a unique fruit with exceptional nutritional and technological characteristics, as well as proposed health benefits. Moreover, the commercial utilization of avocado to make guacamole and/or to extract its oil for several applications generates massive amounts of avocado bio-wastes, including peels and seeds by-products, which further impact the environment and waste management costs. Within this article, the proposed health benefits of moderate avocado consumption, as a functional component of a balanced diet against inflammation-related chronic disorders, and its potential applications are fully addressed. The numerous bioactive compounds present in avocado fruit and its by-products, such as its bioactive phenolics, dietary fiber, and lipid bioactives like unsaturated fatty acids and polar lipids, are also thoroughly outlined. The functional anti-inflammatory, antithrombotic, and antioxidant properties of each of these bioactives and avocado extracts, are then thoroughly reviewed. Emphasis is given to these avocado-derived bioactives and extracts that have the potential to be utilized in various industrial applications, such as in functional foods, supplements, nutraceuticals, and cosmetics related health-promoting applications. The limitations and future perspectives of these applications based on avocado bioactives are also discussed. Full article

The aim of this study was to analyze the content of fatty acids and tocopherols in various components (pulp, seeds, peel) of avocado (Persea americana), which are often neglected as by-products. In addition, the effects of different drying processes on these components were investigated and the health benefits of the main fatty acids contained in avocados were highlighted. The samples were subjected to three drying processes: hot air (HAD), vacuum (VD), and hot-air microwave (HAMD). In all parts of fresh avocado, oleic acid was the most abundant (41.28–57.93%), followed by palmitic acid (19.90–29.45%) and linoleic acid (8.44–14.95%). Drying led to a significant reduction in the oleic acid content, with palmitic acid showing the greatest stability. HAD resulted in higher levels of oleic acid and linoleic acid in dried pulp and peel samples compared with VD and HAMD, while HAMD had the highest content of α-linolenic acid in all parts. In addition, HAMD had the shortest drying time. HAMD duration was 35 min, which was 76.7% shorter than HAD (150 min) and 82.5% shorter than VD (200 min). Considering fatty acid retention and drying efficiency, HAMD appears to have been the most effective method, especially for the avocado peel. Remarkably, the avocado peel consistently contained higher total tocopherol, with δ-tocopherol generally being the most abundant form. The high content of tocopherols, oleic acid, and linoleic acid in the avocado peel suggests promising health benefits. Full article

Bioconversion in biorefineries is a way to valorize residues from agriculture and food processing. Pretreatment is an important step in the bioconversion of lignocellulosic materials, including crop residues. This Special Issue includes nine articles on several pretreatment and bioconversion approaches applied to different agricultural residues and food-processing by-products. The materials addressed in this collection cover straw from wheat, rye, and miscanthus, olive tree pruning residue, almond shells and husks, avocado waste, sweet sorghum bagasse, soybean meal, and residues of non-edible oilseeds. Full article