Effects of inhomogeneity on triglyceride digestion of emulsions using an in vitro digestion model (Tiny TIM)

Oosterveld, A.; Minekus, Mans; Bomhof, Esther; Zoet, Franklin D.; Aken, George A. van

doi:10.1039/c4fo01045k

Cited by 13 publications

(8 citation statements)

References 38 publications

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“…This result indicates that neither the presence of alginate, nor the encapsulation of the emulsion in alginate beads affects the homogeneity within the gastric compartment, and thus gastric emptying can be considered homogeneous. This finding differs from results obtained with a tiny-TIM system for dynamic digestion of WPI-stabilized emulsions, showing non-homogeneous emptying (Oosterveld et al, 2016).…”

Section: Lipid Distribution In the Different Compartmentscontrasting

confidence: 99%

“…We are aware of the fact that in vivo digestion is even more complex than the system we used, including physiological regulation mechanisms such as back-control, and for example an intestinal mucus layer (Arranz, Corredig, & Guri, 2016), which cannot be included in the DIDGI. So as stated by Oosterveld and co-workers: care must be taken to translate these results to the in vivo reality (Oosterveld et al, 2016), but the great differences found make us hopeful that we have identified an encapsulation method that could induce an ileal brake after ingestion, and that can also be tuned further if needed.…”

Section: Fatty Acid Incorporation In Mixed Micelles In the Intestinalmentioning

confidence: 94%

“…Several in vitro equipment are available to take into account part of the dynamic aspect of human digestion (Guerra et al, 2012;Oosterveld, Minekus, Bomhof, Zoet, & van Aken, 2016;. The most used dynamic in vitro model of the upper GI tract is the TNO gastrointestinal model 1 (TIM-1), which contains four compartments: stomach, duodenum, jejunum, and ileum.…”

Section: Introductionmentioning

confidence: 99%

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Encapsulation of lipids to delay lipolysis and reduce food intake

Corstens¹

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the in vitro model is cause for extensive scientific debate, as will be discussed in more detail in Chapter 2.2.5. Static models mostly are used, since they are cheap and easy to implement, perform and interpret, and are a good tool for screening experiments. Models that are more valid include part of the dynamics and kinetics that occur in the human body: dynamic in vitro models. A relatively easy-to-use dynamic model is the DIDGI system, which includes a series of reactors with computer-controlled transit and secretion (Ménard, Picque, & Dupont, 2015), Alginate beads loaded with lipid have very limitedly been studied in vivo. In rat, such beads delayed lipid absorption compared to free emulsion droplets (about 65-times lower serum levels) and emulsions clusered by an alginate matrix (about 12-times lower serum levels for 4.7 µm clusers, and 5-times for 200 µm clusters) (Li, Kim, Park, & McClements, 2012). These findings were confirmed in a human trial in which oil-core alginate-shell capsules (0.5 cm) fastened gastric emptying, and delayed lipolysis and absorption (Hoad et al., 2011). In summary, there are interesting positive leads, but in order to be able to design a food product that can be used in non-invasive weight management strategies, various important questions need to be answered and steps need to be made. This will be explained in the next sections.

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Section: Lipid Distribution In the Different Compartmentscontrasting

confidence: 99%

Section: Fatty Acid Incorporation In Mixed Micelles In the Intestinalmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 99%

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Encapsulation of lipids to delay lipolysis and reduce food intake

Corstens¹

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“…The intragastric behaviour and extent of lipolysis of various emulsions stabilised by different stabilisers was studied. 122,123 For that, the authors used the tiny-TIM with a specifically designed gastric compartment. It consisted of a main body and lower antral part with an L-shape, in contrast to the tubular shape of the TIM-1.…”

Section: Reviewmentioning

confidence: 99%

Simulating human digestion: developing our knowledge to create healthier and more sustainable foods

2020

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“…There was a significant increase in MB release in all emulsions resulting from degradation of the interfacial film by the bile salts. 51,71,73,84 Bile extract contains glycodeoxycholic acid, taurodeoxycholic acid, deoxycholic acid, and phospholipids 77 , all of which interact with emulsions. 18,77 Phospholipids, in particular, are known to compete for the oil-water interface, which may have resulted in displacement of interfacial crystals or other surface-active species.…”

Section: Effect Of Environment On Mb Releasementioning

confidence: 99%

In-vitro Digestion Of Fat Crystal-Stabilized Water-In-Oil Emulsions

Patel¹

2021

Preprint

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The purpose of this research was to investigate the effect of surfactant type and presence of solid fat on the stability and release characteristics of water-in-oil (W/O) emulsions subjected to simulated gastrointestinal conditions. Emulsions consisting of a 20 wt% aqueous phase dispersed in canola oil were stabilized in one of four different ways: core-shell stabilization with glycerol monostearate (GMS), network stabilization using polyglycerol polyricinoleate and solid fat added to the continuous phase (PGPR-F), combined core-shell and network stabilization using glycerol monooleate and a continuous phase fat crystal network (GMO-F) and finally, a PGPR-based liquid emulsion with no added fat. The dispersed aqueous phase of all emulsions contained 1mM methylene blue (MB), which was used as a marker to quantify emulsion breakdown and release of aqueous phase cargo. Quiescent storage at 25 °C for 30 days revealed no phase separation for the GMS, GMO-F, and PGPR-F emulsions whereas the PGPR emulsion began to phase-separate 16 h following preparation. When subjected to gastric conditions, the PGPR-F emulsion showed the lowest MB release after 60 min (0.3 % of initial load) with the other emulsions showing ~ 12 % release. In duodenal conditions, the PGPRF and GMS emulsions showed the lowest MB release after 120 min of exposure (~ 0.5 %) followed by the PGPR (9.4 %) and GMO-F (14.6 %) emulsions, respectively. Emulsion photomicrographs taken prior to, and after, contact with simulated gastric and intestinal fluids showed that emulsion microstructure was an important contributor to emulsion stability. Overall, the PGPR-F emulsion was the most stable in both gastric and intestinal fluids. These results have shown that fat phase structuring is an important contributor to W/O emulsion breakdown behaviour in simulated gastrointestinal conditions.

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Effects of inhomogeneity on triglyceride digestion of emulsions using an in vitro digestion model (Tiny TIM)

Cited by 13 publications

References 38 publications

Encapsulation of lipids to delay lipolysis and reduce food intake

Encapsulation of lipids to delay lipolysis and reduce food intake

Simulating human digestion: developing our knowledge to create healthier and more sustainable foods

In-vitro Digestion Of Fat Crystal-Stabilized Water-In-Oil Emulsions

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