Enhanced lymphatic transport of bioactive lipids: cell culture study of polymethoxyflavone incorporation into chylomicrons

Yao, Mingfei; Chen, Jingjing; Zheng, Jinkai; Song, Mingyue; McClements, David Julian

doi:10.1039/c3fo60335k

Cited by 29 publications

(24 citation statements)

References 30 publications

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“…of fatty acids were prepared using a method described previously (Mingfei Yao, 2013). Three 120 types of mixed micelles were prepared: oleic acid-sodium taurocholate (C18:1-TC); linoleic 121 acid-sodium taurocholate (C18:2-TC) and linolenic acid-sodium taurocholate (C18:3-TC), with 122 the same fatty acid-to-TC molar ratio of 1.6:0.5.…”

Section: Preparation Of Mixed Micelle Systems Mixed Micelles Systemsmentioning

confidence: 99%

“…The purpose of the current study was to examine the 90 influence of fatty acid type (C18:1, C18:2, C18:3) on the formation and structure of mixed 91 micelles, lipid droplets, and chylomicrons, as well as on the incorporation of a bioactive 92 lipophilic agent, 5DN into the chylomicrons. 5DN is high lipophilic nutraceutical mainly found 93 in the citrus fruits and has been reported to have various beneficial biological effects (Mingfei 94 Yao, 2013). The current study is particularly important as polyunsaturated fatty acids have been 95 increasingly utilized in the human diet due to their potential beneficial health effects in human 96 (Nelson, 2005) Inc., MA, USA) containing polyester filters (3 m pore size and 4.7 cm 2 surface area) and grown 113 for 21 days.…”

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confidence: 96%

“…Our previous research using a Caco-2 cell culture model demonstrated that mixed micelles, 87 consisting of oleic acid and sodium taurocholate, increased the trans-intestinal transport of an 88 encapsulated lipophilic nutraceutical, 5-demethylnobiletin (5DN), by promoting its incorporation 89 into chylomicrons (Mingfei Yao, 2013). The purpose of the current study was to examine the 90 influence of fatty acid type (C18:1, C18:2, C18:3) on the formation and structure of mixed 91 micelles, lipid droplets, and chylomicrons, as well as on the incorporation of a bioactive 92 lipophilic agent, 5DN into the chylomicrons.…”

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confidence: 99%

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Controlling the gastrointestinal fate of nutraceutical and pharmaceutical-enriched lipid nanoparticles: From mixed micelles to chylomicrons

et al. 2017

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The oral bioavailability of lipophilic nutraceuticals can be greatly enhanced by lipid nanoparticle‐based delivery systems. These lipid nanoparticles are dissembled in the gastrointestinal tract to form mixed micelles that are then reassembled into chylomicrons within enterocytes and secreted into the lymph. In this study, we examined the influence of fatty acid type on the properties of mixed micelles and chylomicrons, and on the uptake of a highly lipophilic nutraceutical 5‐demethylnobiletin (5‐DN, found in citrus fruits). There were distinct differences in the structural properties of chylomicrons formed depending on fatty acid unsaturation. Oleic acid (C18:1) was most effective at enhancing transport of 5‐DN and led to the formation of the largest chylomicrons. Linoleic acid (C18:2) and linolenic acid (C18:3) also promoted 5‐DN incorporation into chylomicrons, but they were less efficient than oleic acid. The metabolism of 5‐DN within the epithelium cells was greatly reduced when they were incorporated into chylomicrons, presumably because they were isolated from metabolic enzymes in the cytoplasm. These results have important implications for the design of lipid nanoparticle‐based delivery systems for lipophilic nutraceuticals by targeting them to the lymphatic circulation.

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Section: Preparation Of Mixed Micelle Systems Mixed Micelles Systemsmentioning

confidence: 99%

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confidence: 96%

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confidence: 99%

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Controlling the gastrointestinal fate of nutraceutical and pharmaceutical-enriched lipid nanoparticles: From mixed micelles to chylomicrons

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“…The type of lipid phase used has been shown to influence the nature of the mixed micelles formed under simulated small intestinal conditions, as well as the nature of the oil bodies and chylomicrons formed in epithelium cells (Figure 9). Consequently, lipid type may influence the absorption of bioactive components, and their subsequent GIT fate (Yao et al, 2013;Yao et al, 2014). The nature of the lipid phase in nanoemulsions has been shown to influence the absorption of pterostilbene using a cell culture model (Sun et al, 2015).…”

Section: Increased Absorptionmentioning

confidence: 99%

Boosting the bioavailability of hydrophobic nutrients, vitamins, and nutraceuticals in natural products using excipient emulsions

McClements

Saliva-Trujillo

Zhang

et al. 2016

Food Research International

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Many highly hydrophobic bioactives, such as non-polar nutrients, nutraceuticals, and vitamins, have a relatively low or variable oral bioavailability. The poor bioavailability profile of these bioactives may be due to limited bioaccessibility, poor absorption, and/or chemical transformation within the gastrointestinal tract (GIT). The bioavailability of hydrophobic bioactives can be improved using specially designed oil-in-water emulsions consisting of lipid droplets dispersed within an aqueous phase. The bioactives may be isolated from their natural environment and then incorporated into the lipid phase of emulsion-based delivery systems. Alternatively, the bioactives may be left in their natural environment (e.g., fruits or vegetables), and then ingested with emulsion-based excipient systems. An excipient emulsion may have no inherent health benefits itself, but it boosts the biological activity of bioactive ingredients co-ingested with it by altering their bioaccessibility, absorption, and/or chemical transformation. This review discusses the design and fabrication of excipient emulsions, and gives some examples of recent research that demonstrates their potential efficacy for improving the bioavailability of hydrophobic bioactives. The concept of excipient emulsions could be used to formulate emulsion-based food products (such as excipient sauces, dressings, dips, creams, or yogurts) specifically designed to increase the bioavailability of bioactive agents in natural foods, such as fruits and vegetables.

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“…As discussed above, what is needed is development of in vitro and in vivo methods for studying transformations of iENMs in the GIT, and identifying structure activity relationships that influence absorption and accumulation. Methods such as simulated GIT models that include mouth, stomach, and small intestine phases that mimic the fluid compositions, incubation times, and flow/pressure conditions of the GIT are crucial for assessing ENM transformations and interactions with food matrices (Arroyo-Maya and McClements, 2016; Cho et al , 2014; Lopez-Pena et al , 2016; Mun et al , 2007; Mun et al , 2006; Ozturk et al , 2015; Park et al , 2007; Qiu et al , 2015; Sandra et al , 2008; Yao et al , 2013; Yao et al , 2015a; Yao et al , 2014; Zou et al , 2015a; Zou et al , 2015b). In future work, it may be useful to employ the newly developing “omic” approaches to better understand the potential toxicity of nanoparticles, e.g., metabolomics, proteomics, and transcriptomics.…”

Section: Assessing the Git Fate And Toxicity Of Ienms: Challenges mentioning

confidence: 99%

The role of the food matrix and gastrointestinal tract in the assessment of biological properties of ingested engineered nanomaterials (iENMs): State of the science and knowledge gaps

et al. 2016

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Many foods contain appreciable levels of engineered nanomaterials (ENMs) (diameter < 100 nm) that may be either intentionally or unintentionally added. These ENMs vary considerably in their compositions, dimensions, morphologies, physicochemical properties, and biological responses. From a toxicological point of view, it is often convenient to classify ingested ENMs (iENMs) as being either inorganic (such as TiO2, SiO2, Fe2O3, or Ag) or organic (such as lipid, protein, or carbohydrate), since the former tend to be indigestible and the latter are generally digestible. At present there is a relatively poor understanding of how different types of iENMs behave within the human gastrointestinal tract (GIT), and how the food matrix and biopolymers transform their physico-chemical properties and influence their gastrointestinal fate. This lack of knowledge confounds an understanding of their potential harmful effects on human health. The purpose of this article is to review our current understanding of the GIT fate of iENMs, and to highlight gaps where further research is urgently needed in assessing potential risks and toxicological implications of iENMs. In particular, a strong emphasis is given to the development of standardized screening methods that can be used to rapidly and accurately assess the toxicological properties of iENMs.

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Enhanced lymphatic transport of bioactive lipids: cell culture study of polymethoxyflavone incorporation into chylomicrons

Cited by 29 publications

References 30 publications

Controlling the gastrointestinal fate of nutraceutical and pharmaceutical-enriched lipid nanoparticles: From mixed micelles to chylomicrons

Controlling the gastrointestinal fate of nutraceutical and pharmaceutical-enriched lipid nanoparticles: From mixed micelles to chylomicrons

Boosting the bioavailability of hydrophobic nutrients, vitamins, and nutraceuticals in natural products using excipient emulsions

The role of the food matrix and gastrointestinal tract in the assessment of biological properties of ingested engineered nanomaterials (iENMs): State of the science and knowledge gaps

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