Table 2.
Bioactive compounds, and potential biological effects of Amazonian oilseeds on health.
| Food | Used part | Bioactive compound | Assay/ study type | Potential health benefits | References |
|---|---|---|---|---|---|
| Açaí (Euterpe oleracea) | Lyophilized fruit pulp, tablet and jam. | Anthocyanins and phenolic compounds | In vitro | Antioxidant activity | Aliaño-González et al. (2020); |
| Fruit pulp juice | Anthocyanins, phenolic compounds, unsaturated fatty acids. | Randomized cross-over study | ↑ HDL-c concentration; ↑ total antioxidant capacity; ↓ oxidative stress index |
Liz et al. (2020) | |
| Freeze-dried hydroalcoholic extract | Different phenolic compounds (orientin, p-coumaric acid, apigenin, cyanidyn, luteolin, epicatechin, and others). | In vitro | ↓ pro-inflammatory; ↑ anti-inflammatory cytokines; modulation of NLRP3 inflammasome protein expression | Machado et al. (2019) | |
| Fruit pulp | Anthocyanins and phenolic compounds | Clinical study with forty healthy volunteer women | ↑ concentration of apolipoprotein A-I; ↓ radical oxidative stress, ox-LDL and malondialdehyde; ↑ total antioxidant capacity. | Pala et al. (2018) | |
| Fruit pulp | Anthocyanins and phenolic compounds | Cross-sectional, retrospective, and analytical study | Suggests a reduction of occurrence of diabetes and hypertension in women | Silva et al. (2020); | |
| Bacaba (Oenocarpus ssp.) | Fruit powder | Total phenolics and anthocyanins | In vitro | Antioxidant activity | Nascimento et al. (2019) |
| Fruit pulp oil | Total phenolics and PUFAs | In vitro | Antioxidant activity | Pinto et al. (2018) | |
| Fruit pulp | Phenolics and flavonoids | In vitro | Antioxidant properties | Carvalho et al. (2016) | |
| Fruit pulp extract | Phenolic compounds | Cell culture of MCF-7 cells and cell proliferation | Antiproliferative capacities; induced apoptosis in MCF-7 breast cancer cells through the mitochondrial pathway; highest activation caspase-9. | Finco et al. (2016) | |
| Aqueous, methanolic and acetonic pulp extracts | Phenolic compounds | In vitro | Antioxidant properties; protective against DNA damage. | Leba et al. (2014) | |
| Pulp phenolic extract | Phenolic compounds | In vitro cell culture (3T3-L1 preadipocytes) | Reduced accumulation of intracellular lipids and protein expression of adipogenic markers including PPARγ, C/EBPα, FABP4, IR-β, and adiponectin; decreased lipid accumulation; adipogenesis inhibition. | Lauvai et al. (2017) | |
| Buriti (Mauritia flexuosa) | Freeze–dried pulp | Carotenoids | In vitro | Antioxidant properties. | Berni et al. (2020) |
| Leaves extracts | Flavonoids: tricin-7-O-rutinoside, apigenin-6-C-arabinoside, 8-Cglucoside, kaempferol-3-O-rutinoside, quercetin-3-O-rutinoside, luteolin-8-C-glucoside and luteolin-6-C-glucoside. | In vitro | Not applied | Oliveira, Siqueira, Nunes, & Cota (2013) | |
| Freeze–dried pulp | Carotenoids | In vitro | Antioxidant properties. | Cândido, Silva, & Agostini-Costa (2015) | |
| Pulp oil | Carotenoids and unsaturated fatty acids | In vitro | Non-toxic to human blood mononuclear phagocytes; increased rate of cellular phagocytosis in enteropathogenic Escherichia coli | Cruz et al. (2020) | |
| Fruit pulp and sweet dessert | Phenolic compounds and carotenoids | In vitro | Antioxidant properties. | Nascimento-Silva, Silva, & Silva, (2020) | |
| Pulp, peel and endocarp extracts | Phenolic compounds | In vitro bioaccessibility against rat blood cells; in vitro antioxidant assays | The buriti extracts protected rat blood cells against lysis induced by peroxyl radicals, and antioxidant properties. | Pereira-Freire et al., 2018 | |
| Methanolic pulp extract | Phenolic compounds and carotenoids | In vitro evaluation of lipid oxidative damage of red blood cell (RBC) membranes | Antioxidant properties, and the IC50 related to the lipid peroxidation suggests that the extract could be useful in counteracting pathologies associated with reactive oxygen species. | Abreu-Naranjo, Paredes-Moreta, Granda-Albuja, Iturralde, González-Paramás, & Alvarez-Suarez (2020) | |
| Fruit pulp extract | Phenolic compounds and carotenoids | In vitro assay in breast tumor cells line (MDA – MB − 231) | High antioxidant capacity; no changes of MDA – MB – 231 cells viability at 20 a 320 μg /mL extract concentration after 24/48 h. | Pelosi et al. (2020). | |
| Brazil nuts (Bertholletia excelsa) | Intake of Brazilian nuts | Macronutrients and selenium content | Population study and biochemical assays | The intake of Brazil nuts improved the Se deficient; increased the blood concentration of high-density lipoprotein cholesterol, thus reducing cardiovascular risks. | Cominetti, de Bortoli, Garrido, & Cozzolino (2012) |
| Brazil nuts in daily meals | Macronutrients and selenium content | Population study and biochemical assays | The addition of Brazil nuts in children meals elevated Se levels in their blood, without selenosis symptoms. | Martens et al. (2015). | |
| Microencapsulated cake extract powder | Phenolic compounds | In vitro | High selenium content; phenolics stability up to 120 days; potential ingredient for functional foods. | Gomes et al. (2019) | |
| Daily nut intake (1 nut/day for 60 days) | Macronutrients, phenolics and selenium content (1 Brazil nut (approximately 1261 μg/Se) | Randomized controlled trial and in vitro assays | Increased expression levels of 2 miRNAs (miR-454-3p and miR-584-5p) after Brazil nut intake; the study suggest a linkage between Se intake, vitamin D metabolism, and calcium homeostasis. | Reis et al. (2019) | |
| Brazil nut aqueous extract | Phenolics and selenium content | In vitro modulation of cell growth and pro-oxidative and antioxidant markers | The extract at 75 ng Se/mL increased cell growth and decreased oxidative metabolism indicators; minimized negative effects in both directions of the superoxide and hydrogen peroxide imbalance. | Schott et al. (2018) | |
| Daily nuts intake | Macronutrients, phenolics and selenium content | Systematic review and meta-analysis of randomized controlled trials | The intake of Brazil nuts does not change body weight, reduces triglyceride and cholesterol levels, Low Density Lipoprotein but not C-reactive protein | Hou et al. (2020) | |
| Daily nuts intake | Macronutrients, phenolics and selenium content | Systematic review and meta-analysis of randomized controlled trials | The intake of Brazil nuts increased the effect on plasma selenium levels and glutathione peroxidase but had no significant effect on T3 a thyroid hormone. | Li et al., (2020) | |
| Peach palm fruit or pupunha (Bactris gasipaes) | Stem portion of peach palm by-product | Phenolic compounds and sugars | In vitro | High values of antioxidant activity, which could be related to phenolics, gallic, hydroxy benzoic and chlorogenic acids. | Giombelli et al. (2020); |
| Fruit peels | Carotenoids | In vitro | High carotenoid sources, superior to those found in the Pulp; β-carotene was the major carotenoid; high potential to be used as bioactive ingredient. | Matos et al. (2019); | |
| Fruit pulp oil | Phenolic compounds, carotenoids and unsaturated fatty acids | In vitro | The oil displayed good antiatherogenic, antithrombogenic and hypocholesterolemic indices, which could decrease the risk of cardiovascular diseases. | Santos et al. (2020). | |
| Fruit pulp extracts | Phenolic compounds | In vitro | The fruit exhibited good antioxidant properties; IC50 < 65 μg/mL of the vitro inhibitory activities for pancreatic lipase (obesity) and α-glucosidase and α-amylase (type 2 diabetes). | Faria et al. (2021) | |
| Extracts from peach palm biomass | Phenolic compounds and carotenoids | In vitro and in vivo studies | The peach palm carotenoids displayed antioxidant activity on the kidney; anti-inflammatory effect, and the Wistar rats supplemented with carotenoids had lower weight. | Santamarina et al. (2022). | |
| Sapucaia (Lecythis pisonis) | Ethanolic leaves extract | Phenolic compounds | In vitro studies | High antioxidant activity associated to the high level of phenols and flavonoids. | Ferreira et al. (2014) |
| Sapucaia nut flours | Macronutrients, fibers and phenolics | In vitro studies | The sapucaia flours is is a source of proteins (31–49%) and carbohydrates (17–31%). | Teixeira et al. (2018). | |
| Sapucaia nut cake milk | Macronutrients and phenolics | In vitro studies | Good antioxidant activity due to phenolic compounds (gallic, vanillic, ferulic, sinapic and salicylic acids, catechin, taxifolin and sinapaldehyde); promising bioactive food ingredient. | Demoliner et al. (2018) | |
| Sapucaia nut oil | Macronutrients, Omega-3 and omega-6 fatty acids and phenolics | In vitro studies | The oil displayed good antiatherogenic, antithrombogenic and hypocholesterolemic indices, which could decrease the risk of cardiovascular diseases. | Santos, Carvalho, Costa, & Lannes (2019). | |
| Tucumã (Astrocaryum vulgare) | Tucumã oil | Macronutrients, Omega-3 and omega-6 fatty acids and phenolics | In vitro and in vivo studies | Tucumã oil is able to modulate cholinergic neurotransmission of neurons by modulating enzymatic antioxidant defenses, improving or avoiding memory deficits. | Baldissera et al. (2017) |
| Tucumã extracts | Phenolic compounds | In vitro studies | The extract inhibited macrophage proliferation, increased antioxidant defenses, reduced oxidative stress, and modulated genes from inflammatory responses. | Cabral et al. (2020); | |
| Ethanolic tucumã extracts | Phenolic compounds | In vitro studies | Tucumã extract improved cell viability, stimulating cell proliferation, and did not cause oxidative damage. | Ongaratto et al. (2020); | |
| Nano-structured lipid carrier containing tucuma butter/oil | Macronutrients, Omega-3 and omega-6 fatty acids and phenolics | In vitro studies | The nano-structured lipid carrier showed anti- and pro-inflammatory and healing activity. | Rossato et al. (2020); |