Lemon Juice, Sesame Paste, and Autoclaving Influence Iron Bioavailability of Hummus: Assessment by an In Vitro Digestion/Caco-2 Cell Model

Overview

Journal Foods

Specialty Biotechnology

Date 2020 Apr 16

PMID 32290180

Citations 4

Authors

Nour Doumani

Isabelle Severin

Laurence Dahbi

Elias Bou-Maroun

Maya Tueni

Nicolas Sok

Marie-Christine Chagnon

Jacqueline Maalouly

Philippe Cayot

Affiliations

Soon will be listed here.

Abstract

Hummus, an iron-containing plant-based dish mainly made from chickpea purée, tahini, lemon juice and garlic, could be a valuable source of iron when bioavailable. Since the processing and formulation of food influence iron bioavailability, the present study investigated for the first time, their effects on hummus. Firstly, iron bioaccessibility was assessed on eight samples (prepared according to the screening Hadamard matrix) by in vitro digestion preceding iron dialysis. Then, iron bioavailability of four selected samples was estimated by the in vitro digestion/Caco-2 cell model. Total and dialyzable iron were determined by the atomic absorption spectrometry and ferritin formation was determined using an ELISA kit. Only autoclaving, among other processes, had a significant effect on iron bioaccessibility (+9.5, < 0.05). Lemon juice had the highest positive effect (+15.9, < 0.05). Consequently, the effect of its acidic components were investigated based on a full factorial 2 experimental design; no significant difference was detected. Garlic's effect was not significant, but tahini's effect was negative (-8.9, < 0.05). Despite the latter, hummus had a higher iron bioavailability than only cooked chickpeas (30.4 and 7.23 ng ferritin/mg protein, respectively). In conclusion, hummus may be a promising source of iron; further in vivo studies are needed for confirmation.

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