Search Results (47)

Milk fat plays an important role in the flavor and texture of cheese. However, it contains high amounts of saturated fat and cholesterol, which have recently been reported to be unsuitable for maintaining good health. The aim of this study was to evaluate the effects of milk fat’s replacement with sacha inchi (Plukenetia volubilis) oil in fresh cheese processing on the coagulation properties, nutritional value, and sensory properties, aiming to obtain a hybrid fresh cheese rich in polyunsaturated fatty acids (PUFAs). Milk fat (3.8% in standardized milk) was partly replaced with Vietnamese sacha inchi oil at 20, 40, 60, and 80%. The coagulation time, curd formation, and cheese yield showed no significant differences among the treatments (p > 0.05), suggesting that sacha inchi oil did not adversely affect curd formation. The cholesterol levels decreased substantially, from 8.27 ± 0.53 mg/g in control samples to 2.63 ± 0.63 mg/g at 80% fat replacement. An increase in essential fatty acids in the fresh cheese was also found with an increase in the use of sacha inchi oil to replace milk fat, with the oleic acid concentration (OA, C18:1, cis ω-9) rising from 7.88 ± 0.36% to 23.44 ± 0.13% and the linoleic acid concentration (LA, C18:2, cis ω-6) from 6.44 ± 0.68% to 41.75 ± 2.50% at the highest substitution level. From a nutritional perspective, the replacement of milk fat with sacha inchi oil did not affect the macronutritional values (fat, protein), but it reduced the cholesterol levels and enhanced the overall nutritional value of the fresh cheese with increasing essential fatty acids. The milk fat alternative of sacha inchi oil for cheese processing contributed to a richer and creamier sensory experience of the final products, but no significant differences in the overall liking were found regarding the acceptance of customers. Thus, replacement with sacha inchi oil in PUFA cheese processing is a promising method to improve the nutritional value and sensory quality of fresh cheese. Full article

Sacha inchi (SI) oil press-cake (SIPC), a by-product of the sacha inchi oil extraction process, represents a novel protein source with potential bioactive applications in food. In this study, a sacha inchi protein concentrate (SPC) derived from SIPC was subjected to simulated gastrointestinal digestion (SGID) using the INFOGEST 2.0 protocol. The resulting digests were fractionated by ultrafiltration (<3, 3–10, and >10 kDa), and the bioactive properties of the peptide fractions were evaluated. In vitro α-amylase inhibition was assessed, along with immunomodulatory markers (NO, IL-6, and TNF-α), in an ex vivo RAW 264.7 cell model. Both gastric and intestinal digests exhibited significant α-amylase inhibition (20–45%), with the <3 kDa intestinal fraction showing the highest inhibition (45% at 20 mg/mL). Both gastric and intestinal <3 kDa fractions reduced NO production in RAW 264.7 macrophages subjected to a lipopolysaccharide challenge. HPLC-MS/MS analysis facilitated de novo sequencing of the peptide fractions, identifying 416 peptides resistant to SGID through the find-pep-seq script, which were further assessed in silico for toxicity, allergenicity, and bioavailability, revealing no significant risks and potential drug-likeness development. Molecular docking simulations of three peptides (RHWLPR, RATVSLPR, and QLSNLEQSLSDAEQR) with α-amylase and four peptides (PSPSLVWR, RHWLPR, YNLPMLR, and SDTLFFAR) with the TLR4/MD-2 complex suggesting potential roles in α-amylase inhibition and anti-inflammatory activity, respectively. The findings suggest that SI protein concentrates could be used in functional foods to prevent starch breakdown through α-amylase-inhibiting peptides released during digestion, reduce blood glucose, and mitigate inflammation and oxidative tissue damage. Full article

Sacha inchi (Plukenetia volubilis), or the Inca peanut, is a promising functional food and sustainable alternative to traditional oilseed crops like soybean. Its seeds are rich in omega-3, omega-6, and omega-9 fatty acids, high-quality protein, and bioactive compounds, offering significant nutritional and health benefits. Moreover, sacha inchi cultivation thrives on degraded soils with minimal agrochemical input, supporting biodiversity and reducing environmental impacts. Despite its potential, its large-scale cultivation faces challenges such as genetic variability, low seed viability, and susceptibility to pests and diseases, resulting in inconsistent yields and plant quality. In vitro propagation presents a viable solution, enabling the production of genetically uniform, disease-free seedlings under controlled conditions. Successful in vitro cultivation depends on factors like explant selection, plant growth regulator combinations, medium composition, and environmental control. Advances in these techniques have improved propagation outcomes in other oilseed crops, such as enhanced germination, oil yield, and genetic stability, and offer similar opportunities for sacha inchi. By integrating in vitro and field techniques, this review highlights the potential of sacha inchi as a nutritionally rich, sustainable agricultural solution. These findings provide a foundation for advancing its cultivation, ensuring enhanced productivity, improved oil quality, and greater accessibility to its health benefits around the world. Full article

Sacha inchi (Plukenetia volubilis L.), an oilseed native to the Peruvian rainforest, has garnered attention for its valuable components and its potential applications in the food, pharmaceutical, and nutraceutical industries. Sacha inchi oil is rich in fatty acids, particularly omega-3, omega-6, and omega-9, along with antioxidants such as tocopherols, which collectively contribute to cardiovascular health, antioxidant, anti-inflammatory, antiproliferative, and neuroprotective effects. The susceptibility of the oil to oxidation poses significant challenges for both storage and processing, making it essential to employ microencapsulation technologies to preserve its integrity and extend shelf life. This paper aims to provide a review of the therapeutic potential, extraction methods, and microencapsulation strategies for enhancing the oil’s stability and bioavailability. Optimizing both extraction processes and encapsulation strategies would enhance the oil’s stability and bioavailability, enabling it to be more effectively utilized in functional foods and therapeutic applications across the nutraceutical and pharmaceutical fields. Full article

Reactive oxygen species (ROS), commonly recognized as free radicals, significantly contribute to skin damage by disrupting defense and repair mechanisms, thereby accelerating the aging process. An effective strategy to prevent and alleviate skin aging involves the application of topical formulations enriched with powerful antioxidant compounds. Sacha inchi oil (Plukenetia volubilis L.) has been reported to possess significant antioxidant activity, while its oil contains a high content of omega-3 fatty acids, offering potential anti-aging benefits. This study aims to evaluate the stability, in vitro anti-aging activity, and skin irritation assessments of a facial serum containing Sacha inchi oil (SIO) formulated as a topical anti-aging agent. The stability of the serum was assessed by analyzing its organoleptic properties, homogeneity, viscosity, spreadability, pH, microbial contamination, and heavy metal content over a three-month period under controlled climatic conditions. The in vitro anti-aging activity was evaluated through enzyme inhibition assays for neutrophil elastase and collagenase, while skin irritation was assessed via human patch testing. The results indicated that the SIO facial serum exhibits excellent stability, significant anti-aging activity, and is safe for topical application, with no irritant effects observed during skin irritation assessments. Full article

Sacha Inchi oil (SIO) and hybrid palm oil (HPO) are potential sources of unsaturated fatty acids to improve the lipid profile of dairy products. This study evaluated, for the first time, the effects of the daily consumption of yogurts with enhanced fatty acid profiles on plasma lipids related to cardiovascular disease (CVD) risk factors. A pilot, randomized, double-blind, parallel-controlled trial was conducted with 47 participants assigned to three groups: SIO-enriched yogurt (Group A), HPO-enriched yogurt (Group B), and plain yogurt (Group C). Fasting blood samples were collected at baseline and after 1, 2, and 3 months to measure plasma lipids (TC, LDL-C, HDL-C, and TAG), ApoA1, and ApoB. While no significant changes were observed in the overall lipid profiles, notable within-group effects were identified. The total cholesterol (TC) dropped by 2.8%, 1.3%, and 3.3%, and LDL-C by 1.6%, 2.5%, and 2% in Groups A, B, and C, respectively. Additionally, the intake of monounsaturated fatty acids (MUFA), polyunsaturated fatty acids (PUFA), and vitamin E significantly increased in Groups A and B. These results suggest that SIO and HPO can be used as milk fat substitutes to enhance the nutritional profile of yogurts without affecting CVD biomarkers in healthy individuals. Full article

Sacha Inchi seeds (Plukenetia huayllabambana) are highly regarded for their nutritional richness, specifically their high omega-3 content. Chia seed (Salvia hispanica L.) mucilage is recognized for its emulsion abilities. There is growing demand for innovative mayonnaise formulations using healthier, plant-based alternatives. This study developed a plant-based mayonnaise (PBM) by replacing egg yolks with chia seed mucilage (CSM) and using Sacha Inchi seed oil (SIO), achieving sensory qualities similar to traditional mayonnaise. Five formulations of PBM were evaluated, with variations in CSM content (1% to 3%) and water content (43% to 45%) and using salt (0.5%), oil (48%), pepper (0.5%) and lemon juice (5%). PBM was evaluated based on omega-3 (%) content, total fat (%) content, stability of emulsion (%), rheology and physicochemical properties. Formulation with 3% of CSM was the optimal option due to its emulsion stability (98.56%) and rheology, very similar to those of traditional mayonnaise (99.13%). PBM formulation with 3% CSM showed the highest omega-3 fatty acid content of 55.36% for 100 g fat, compared with the 0.27% found in traditional mayonnaise. The PBM formulation with 3% CSM also showed important characteristics such as phenolic content (310.814 µg GAE/g ms), antioxidant activity (1991.79 µg Trolox/g ms), Ph (4.24), a peroxide index (11.92 meq-O₂/Kg oil), an acidity index (3.59 mg KOH/g), a shelf life study and proximal composition. This study underscores the potential of CSM and SIO in mayonnaise formulations, addressing concerns with traditional options. Full article

Plant-derived antioxidant peptides safeguard food against oxidation, helping to preserve its flavor and nutrients, and hold significant potential for use in functional food development. Sacha Inchi Oil Press-Cake (SIPC), a by-product of oil processing, was used to produce Sacha Inchi Protein Concentrate (SPC) in vitro, hydrolyzed by a standardized static INFOGEST 2.0 protocol. This study aimed to integrate in vitro, ex vivo, and in silico methods to evaluate the release of antioxidant peptides from SPC during gastrointestinal digestion. In vitro and ex vivo methods were used to investigate the antioxidant potential of SPC digests. Bioinformatics tools (find-pep-seq, AnOxPP, AnOxPePred-1.0, PepCalc, MLCPP 2.0, Pasta 2.0, PlifePred, Rapid Peptide Generator, and SwissADME) were employed to characterize antioxidant peptides. The gastric and intestinal digests exhibited higher ABTS and ORAC values than those of SPC. Under basal conditions, gastric digest fractions GD1, GD2, and GD3 (<3, 3–10, and >10 kDa, respectively), separated by ultrafiltration, significantly reduced the ROS levels in the RAW264.7 macrophages while, under LPS stimulation, GD1 (16 µg/mL) and GD2 (500 and 1000 µg/mL) reversed the induced damage. From the de novo peptidome determined, 416 peptides were selected based on their resistance to digestion. Through in silico tools, 315 resistant peptides were identified as antioxidants. Despite low predicted bioavailability, the peptides SVMGPYYNSK, EWGGGGCGGGGGVSSLR, RHWLPR, LQDWYDK, and ALEETNYELEK showed potential for extracellular targets and drug delivery. In silico digestion yielded the sequences SVMGPY, EW, GGGGCGGGGGVSS, PQY, HGGGGGG, GGGG, HW, and SGGGY, which are promising free radical scavengers with increased bioavailability. However, these hypotheses require confirmation through chemical synthesis and further validation studies. Full article

In Peru, 5 of every 10 children suffer from malnutrition, which increases the risk of developing non-communicable diseases (NCDs) at the early stages of their life. Sacha inchi (Plukenetia huayllabamana) cake is the by-product of the oil extraction process of the Amazon Peruvian seed and has high protein (56%) and fiber (5.9%) content. Tarwi (Lupinus mutabilis Sweet) is a Peruvian legume characterized by its high protein content (>50%) and high levels of tyrosine and tryptophan amino acids. Thus, the purpose of this research was to develop high-protein cookies enriched with defatted sacha inchi cake (DSIC) and defatted tarwi (DT) as an alternative snack to combat child malnutrition. Five types of cookies were developed, along with one control sample, containing corn flour (50% w/w), rice flour (20% w/w), and varying the content of quinoa flour, DSIC flour and DT flour (0, 10%, 30% w/w). The addition of DSIC and DT increased the content in protein from 12.13% to 20.30%, fat from 6.76% to 10.42%, and ash from 1.51% to 1.89% compared to the control sample. In contrast, the moisture content decreased from 10.21% to 10.78% and carbohydrates from 59.73% to 67.48%. Moreover, all cookies had high in vitro digestibility (70.91% to 74.17%) and relatively high antioxidant activity (346 to 469 μg GAE/g cookie) and phenolic content (1286 to 1755 μg trolox/g cookie). Sensory analysis showed that cookies enriched with DT were more appealing to the panelists than those enriched with DSIC and the control sample. Hence, these cookies could serve as a gluten-free nutritional food alternative to combat child malnutrition. Full article

Capsaicin has multiple applications such as analgesic for muscle pain, anti-inflammatory, anticancer, antidepressant, and others. It is a lipophilic compound that produces irritation, therefore, for its application, it is necessary to encapsulate it in emulsions or biopolymers. The objective of this work was to prepare a direct O/W emulsion containing capsaicin extracted from Charapita chili (Capsicum frutescens) with Sacha Inchi (Plukenetia volubilis) oil as the oil phase and encapsulated in calcium alginate beads, intending to increase the useful life of the capsaicin. Capsaicin was extracted from Charapita chili powder using ethanol, then the extract was dried for 40 min at 55 °C. To obtain the emulsion, the dry extract was dissolved in 100 mL of Sacha Inchi oil and mixed with sodium alginate by stirring at 14,000 rpm. Then, the emulsion was combined with sodium alginate by stirring at 14,000 rpm. This mixture was dripped onto 200 mL of a 0.2 M solution of calcium chloride, obtaining beads of a spherical shape. The experimental kinetic data are described with the Korsmeyer–Peppas model, where the maximum release was reached at 180 min, the value of the constant n was 0.7857, and the rate constant K was 2.95. As the constant n < 0.85, the release process was due to the diffusion and swelling of the beads. The emulsion obtained could be used to develop pharmaceutical products; moreover, the encapsulated emulsion in calcium alginate could be used in the formulation of functional foods to take advantage of the capsaicin from Charapita chili and the functional properties of the Sacha Inchi oil. Full article

Sacha Inchi (Plukenetia volubilis) oil press-cake (SIPC) represents a new source of proteins of high biological value, with promissory food applications. However, knowledge of these proteins remains limited. In this study, a Sacha Inchi protein concentrate (SPC) was extracted from the SIPC, and proteomic analysis was performed to identify the major alkaline-soluble proteins. The electrophoretic profile highlighted the efficacy of alkaline pH and moderate temperature to extract the major proteins, from which a group of proteins, not previously reported, were registered. LC-MS/MS analyses produced abundant high-quality fragmentation spectra. Utilizing the Euphorbiaceae database (DB), 226 proteins were identified, with numerous well-assigned spectra remaining unidentified. PEAKS Studio v11.5 software generated 1819 high-quality de novo peptides. Data are available via ProteomeXchange with identifier PXD052665. Gene ontology (GO) classification allowed the identification of sequenced proteins associated with biological processes, molecular functions, and cellular components in the seed. Consequently, the principal alkali-soluble proteins from SPC were characterized through derived functional analysis, covering 24 seed-storage-, 27 defense-, and 12 carbohydrate- and lipid-metabolism-related proteins, crucial for human nutrition due to their sulfur-containing amino acids, antioxidant properties, and oil yields, respectively. This research makes a significant contribution to the current understanding of the Sacha Inchi proteome and offers valuable insights for its potential applications in the food industry. Full article

Sacha inchi (Plukenetia volubilis) is a valuable oilseed crop with a high content of polyunsaturated fatty acids (PUFAs). However, there is a lack of in-depth understanding of the lipidomics in Sacha inchi seeds (SIDs). Saturated fatty acids occupied more than half of the proportion (59.31%) in early development, while PUFAs accounted for 78.92% at maturation. The main triacylglycerols were TAG(18:3/18:3/18:3), TAG(18:2/18:2/18:3), and TAG(16:0/18:2/18:2). The corresponding species (18:3/18:3, 18:2/18:2, and 16:0/18:2) were also the main ingredients in diacylglycerol and phosphatidic acid, indicating high PUFA composition in the sn-1 and sn-2 positions of TAG. Only LPC(18:3), LPC(18:2), and LPC(16:0) were identified in SIDs, implying that those PUFAs on the sn-2 positions of the PC(18:3/-), PC(18:2/-), and PC(16:0/-) categories were released into the acyl-CoA pool for the Kennedy pathway. Conversely, the PC(18:1/-) and PC(18:0/-) categories might be responsible for the generation of PC-derived DAG and TAG. The lipidomics data will contribute to understanding the TAG assembly in developing SIDs, especially for PUFAs. Full article

When looking for new ingredients to process red meat, poultry, and fish products, it is essential to consider using vegetable resources that can replace traditional ingredients such as animal fat and synthetic antioxidants that may harm health. The Amazon, home to hundreds of edible fruit species, can be a viable alternative for new ingredients in processing muscle food products. These fruits have gained interest for their use as natural antioxidants, fat replacers, colorants, and extenders. Some of the fruits that have been tested include açai, guarana, annatto, cocoa bean shell, sacha inchi oil, and peach palm. Studies have shown that these fruits can be used as dehydrated products or as liquid or powder extracts in doses between 250 and 500 mg/kg as antioxidants. Fat replacers can be added directly as flour or used to prepare emulsion gels, reducing up to 50% of animal fat without any detrimental effects. However, oxidation problems of the gels suggest that further investigation is needed by incorporating adequate antioxidant levels. In low doses, Amazon fruit byproducts such as colorants and extenders have been shown to have positive technological and sensory effects on muscle food products. While evidence suggests that these fruits have beneficial health effects, their in vitro and in vivo nutritional effects should be evaluated in muscle food products containing these fruits. This evaluation needs to be intended to identify safe doses, delay the formation of key oxidation compounds that directly affect health, and investigate other factors related to health. Full article

Cushuro (Nostoc sphaericum) polysaccharide was used to co-microencapsulate sacha inchi oil, natural antioxidant extracts from the oleoresin of charapita chili peppers (Capsicum frutescens L.) and grape orujo (Vitis vinifera L.). Encapsulation efficiency, moisture, particle size, morphology, oxidative stability, shelf-life, solubility, essential fatty acid profile, sterol content and antioxidant capacity were evaluated. The formulations with grape orujo extract showed higher oxidative stability (4908 ± 184 h), antioxidant capacity (4835.33 ± 40.02 µg Trolox/g ms), higher phenolic contents (960.11 ± 53.59 µg AGE/g ms) and a smaller particle size (7.55 µm) than the other formulations, as well as good solubility and a low moisture content. Therefore, grape orujo extracts can be used as natural antioxidants. The fatty acid composition (ω-3) remained quite stable in all the formulations carried out, which also occurred for sterols and tocopherols. In combination with gum arabic, grape orujo extract offered oxidative protection to sacha inchi oil during the first week of storage. Full article

The long-chain omega-3 fatty acids alpha linolenic acid (ALA), eicosapentaenoic acid (EPA), and docosahexaenoic acid (DHA) have proven health benefits, but it is not common to find them together in a processed food product. This could lead to healthier and more functional food products, which may have positive implications for consumer health and well-being. This work aimed to fortify a model burger manufactured with fillets of an Amazonian fish (boquichico, Prochilodus nigricans) by adding microencapsulated sacha inchi oil (Plukenetia volubilis, rich in ALA) (MSIO) produced by spray-drying. MSIO was incorporated into the burgers at different levels (0, 3, 4, 5, and 6%). The burgers were characterized by their proximal composition, cooking losses, texture profile, lipid oxidation, sensory profile, overall liking, and fatty acid profile. The results showed that adding MSIO up to concentrations of 5% or 6% increased the instrumental hardness, chewiness, and lipid oxidation in the burgers. However, fortifying the burgers with 3% MSIO was possible without affecting the burgers’ sensory properties and overall liking. Regarding the fatty acid profile, the burgers with 3% MSIO had a higher content of polyunsaturated fatty acids, with the ALA, EPA, and DHA types of fatty acids. Therefore, we recommend using this fortification concentration, but future studies should be carried out to improve the oxidative stability of MSIO and the burgers. Full article