Browsing by Author "Lin, Tiantian"

Now showing 1 - 4 of 4
  • Thumbnail Image
    Bulk and interfacial interactions between hydroxypropyl-cellulose and bile salts: Impact on the digestion of emulsified lipids
    Zornjak, Jennifer; Liu, Jianzhao; Esker, Alan R.; Lin, Tiantian; Fernández-Fraguas, Cristina (2020-09)
    Hydroxypropyl-cellulose (HPC) is a surface-active, non-digestible polysaccharide, commonly used in food emulsions as thickener and/or emulsifier. Due to these dual characteristics, HPC is a potential ingredient to modulate lipid digestion. Since bile salts (BS) are key players during lipid digestion, the aim of this work was to investigate the impact that interactions of HPC with BS has on the digestion of emulsified lipids. We studied the effect of two BS species differing in bile-acid moiety, sodium-taurocholate (NaTC) and sodium-taurodeoxycholate (NaTDC). A Quartz-Crystal-Microbalance (QCM-D) was used to evaluate HPC-BS interfacial interactions during the sequential and simultaneous adsorption of both components at a hydrophobic surface, while microDifferential-Scanning-Calorimetry was used to examine bulk interactions. In vitro lipid digestion was studied by using a pH-stat method. Results showed that, under fed-state conditions, NaTDC micelles were more effective at displacing a pre-adsorbed HPC layer from the surface than NaTC monomers. Nevertheless, HPC was resistant to complete displacement by both BS. Additionally, HPC was more susceptible to interact with NaTDC in the bulk, compared to NaTC, which made the adsorption more competitive for NaTDC. The reduced amount of free NaTDC in solution could explain the delayed lipolysis shown by HPC-stabilized emulsions when NaTDC was used to simulate duodenal conditions. These findings show that the delay of lipid digestion by HPC is due to the combined effect of HPC-BS interfacial and bulk interactions, with BS-binding in solution mostly contributing to this effect, and the BS molecular and micellar structure playing essential roles on both situations.
  • Thumbnail Image
    Chemical Compositions of Edamame Genotypes Grown in Different Locations in the US
    Yu, Dajun; Lin, Tiantian; Sutton, Kemper L.; Lord, Nick; Carneiro, Renata C. V.; Jin, Qing; Zhang, Bo; Kuhar, Thomas P.; Rideout, Steven L.; Ross, W. Jeremy; Duncan, Susan E.; Yin, Yun; Wang, Hengjian; Huang, Haibo (2021-02-12)
    The consumption of edamame [Glycine max (L.) Merr.] in the US has rapidly increased due to its nutritional value and potential health benefits. In this study, 10 edamame genotypes were planted in duplicates in three different locations in the US-Whitethorne, Virginia (VA), Little Rock, Arkansas (AR), and Painter, VA. Edamame samples were harvested at the R6 stage of the bean development when beans filled 80-90% of the pod cavity. Afterward, comprehensive chemical composition analysis, including sugars, alanine, protein, oil, neutral detergent fiber (NDF), starch, ash, and moisture contents, were conducted on powdered samples using standard methods and the total sweetness was calculated based on the measured sugars and alanine contents. Significant effects of the location were observed on all chemical constituents of edamame (p < 0.05). The average performance of the genotypes was higher in Whitethorne for the contents of free sucrose (59.29 mg/g), fructose (11.42 mg/g), glucose (5.38 mg/g), raffinose (5.32 mg/g), stachyose (2.34 mg/g), total sweetness (78.63 mg/g), and starch (15.14%) when compared to Little Rock and Painter. The highest soluble alanine (2.67 mg/g), NDF (9.00%), ash (5.60%), and moisture (70.36%) contents were found on edamame planted in Little Rock while edamame planted in Painter had the highest crude protein (43.11%) and oil (20.33%) contents. Significant effects of genotype were observed on most of the chemical constituents (p < 0.05) except NDF and raffinose. Among the 10 genotypes, R13-5029 consistently had high sucrose content and total sweetness across the three locations, meanwhile it had relatively high protein and fiber contents. Overall, the results indicate that to breed better edamame genotypes in the US, both genotype and planting location should be taken into considerations.
  • Thumbnail Image
    A fast and simple ion-pair high performance liquid chromatography method for analysis of primary bile salts in in vitro digested bean samples
    Lin, Tiantian; O'Keefe, Sean F.; Fernández-Fraguas, Cristina (Elsevier, 2021-05-15)
    Bile salts (BS) play a key role in cholesterol and lipid metabolism as well as in many other key metabolic pathways. High performance liquid chromatography (HPLC) is the most common technique used to analyze BS in diverse type of samples. However, current HPLC analysis methods used to analyze and quantify single BS in in vitro digested samples showed poor separation of a complex mixture of BS. In this article, we improved a standard method originally used for quantifying individual BS in food samples subjected to in vitro digestion. We also adapted a method previously developed for BS examination in human blood samples to the analysis of these molecules in chyme samples obtained during simulated gastrointestinal digestion. Our method was simple and achieved a fast and successful separation and quantification of four primary BS (sodium salts of taurocholic, glycocholic, taurochenodeoxycholic and glycochenodeoxycholic acids). •A method used to analyze bile salts in human blood samples has been adapted to separate and quantify four primary bile salts in in vitro digested bean samples. •Addition of an ion-pair reagent led to complete separation of glycine and taurine conjugates of chenodeoxycholic and cholic acids within 10 min, and achieved good peak symmetry. •The minimum BS concentration that could be measured was as low as 0.03125mM.
  • Thumbnail Image
    Role of dry beans (Phaseolus vulgaris L.) in binding bile salts and modulating lipid digestion: Impact of the bean matrix and high-hydrostatic pressure processing
    Lin, Tiantian (Virginia Tech, 2020-05-05)
    According to the American Heart Association, cardiovascular disease (CVD) is the leading cause of death in the U.S., representing about 20-30% of all deaths every year in the U.S. Major risk factors for developing CVD include high blood lipid and LDL-cholesterol levels. A large number of heart attacks and strokes could be prevented by controlling these factors through lifestyle modifications and diet interventions. Epidemiological evidence shows that consumption of dry or common beans (Phaseolus vulgaris L.) has positive effects on reducing blood LDL-cholesterol and lipid levels. These health benefits are mainly attributed to the high content of dietary fiber (DF) of beans, including soluble and insoluble DF (SDF and IDF). Some proposed mechanisms to explain the cholesterol and lipid-lowering effects of DF are related to the physico-chemical properties (e.g. viscosity) of DF, and involve binding to bile salts (BS) in the small intestinal to prevent BS re-absorption which further promote cholesterol catabolism and delay lipid digestion. Nevertheless, the precise mechanisms are not fully understood yet. In addition, cooking and processing operations, and in particular high-hydrostatic pressure (HHP) processing, can modify the composition, structure and functional properties of foods; however, whether HHP affects the ability of beans to interfere with different aspects of lipid digestion remains unknown. The overall goal of this research is to understand how common beans and HHP processing impact the ability of beans to bind BS and influence lipid digestion in vitro. The specific objectives are 1) to evaluate the effect of HHP treatments (and compared it with conventional cooking (HT)) on the thermo-rheological and functional properties of dry beans; 2) to identify the impact of major bean components on the in vitro BS-binding ability of beans, the role played by the bean matrix and how this is affected by HHP processing; 3) to investigate how bean (micro)structure and fiber fractions, as well as HHP processing of dry beans, influence lipid digestion in vitro. Results showed that HT caused complete starch gelatinization and protein denaturation of beans, while HHP treatments induced partial or no starch gelatinization and a lower degree of protein denaturation, which resulted in enhanced protein solubility and emulsifying activity/stability. It was observed that, while HT treatment reduced the capacity of bean flours to retain BS because of severe disruption of the bean cell wall integrity, protein matrices, and starch granules, HHP treatments maintained or enhanced BS retention, possibly by promoting the formation of starch/protein/fiber networks able to entrap BS. Furthermore, by using an in vitro dialysis-based digestion model combined with viscosity measurements and thermal analysis, it was shown that the interaction between bean tissue materials and primary BS was not only related to viscosity but also involved hydrophobic linkages. The contribution of IDF and proteins (other than SDF) to retain BS was also significant. There was a different binding preference of beans to four primary BS with sodium glycochenodeoxycholate, the more hydrophobic BS, showing the largest retention levels while sodium taurocholate being the least effectively retained BS by beans. Diverse sequences of the same processing operations showed distinct impacts on BS-retention by dry beans. By means of an in vitro digestion model simulating conditions in the upper gastrointestinal tract, bean flours delayed the digestion of extrinsic lipids to a higher extent, compared to isolated IDF and SDF. Furthermore, HHP treatment and less severe mechanical disintegration maintained the ability of beans to modulate lipid digestion, which suggests the importance of bean structural integrity in reducing the lipolysis rate and extent by beans. Overall, this research work shows that HHP processing is a promising minimal processing technology to produce bean flours with improved functionality. It also highlights the importance of considering the structure of foods, and not just their nutrient content, when evaluating potential health impacts. This knowledge could be applied to develop a range of bean-based ingredients and formulations with desirable health benefits. This work can be extended to research the influence of beans on the gut microbiota and profile of secondary BS and short-chain fatty acids, which are also closely related to cholesterol and lipid metabolism.