Quantification of Barley Contaminants in Gluten-Free Oats by Four Gluten ELISA Kits

Rapid Gluten Allergen Detection Using an Integrated Photoimaging Assay and Ionic Liquid Extraction Sensor

In recent years, food allergies and food sensitivities have remained critical public health problems that affect approximately 15% of the global population. Wheat is a major food source worldwide, but it is also a common food allergen. Celiac disease is chronic immune-mediated enteropathy triggered by exposure to dietary gluten in genetically predisposed individuals; it can be treated only through strict gluten avoidance. Therefore, rapid gluten detection is crucial for protecting the health of patients. Gluten contains two primary water-insoluble proteins: gliadin and glutenin. Gliadin is a key contributor to celiac disease and poses challenges for sample pretreatment owing to its insolubility, thereby reducing the accuracy and sensitivity of detection systems. Rapid sample processing is a critical problem in gliadin detection. In this report, we developed a gliadin sensor system called the integrated food allergy and microorganism sensor (iFAMs). The iFAMs comprises a gliadin lateral flow chip, a one-pot extraction solution, and an image assay app. The iFAMs enables gliadin extraction and detection in under 2 min with high sensitivity (0.04 mg/kg for gliadin, lower than the regulatory limit of 20 mg/kg). Users can easily measure gluten concentrations in samples and quantify gliadin levels using the smartphone-based image assay app. In samples collected from restaurants, the iFAMs successfully detected hidden gluten within "gluten-free" food items. The compact size and user-friendly design of the iFAMs render it suitable for not only consumers but also clinicians, food industries, and regulators to enhance food safety.

Does sourdough bread provide clinically relevant health benefits?

During the last decade, scientific interest in and consumer attention to sourdough fermentation in bread making has increased. On the one hand, this technology may favorably impact product quality, including flavor and shelf-life of bakery products; on the other hand, some cereal components, especially in wheat and rye, which are known to cause adverse reactions in a small subset of the population, can be partially modified or degraded. The latter potentially reduces their harmful effects, but depends strongly on the composition of sourdough microbiota, processing conditions and the resulting acidification. Tolerability, nutritional composition, potential health effects and consumer acceptance of sourdough bread are often suggested to be superior compared to yeast-leavened bread. However, the advantages of sourdough fermentation claimed in many publications rely mostly on data from chemical and in vitro analyzes, which raises questions about the actual impact on human nutrition. This review focuses on grain components, which may cause adverse effects in humans and the effect of sourdough microbiota on their structure, quantity and biological properties. Furthermore, presumed benefits of secondary metabolites and reduction of contaminants are discussed. The benefits claimed deriving from in vitro and in vivo experiments will be evaluated across a broader spectrum in terms of clinically relevant effects on human health. Accordingly, this critical review aims to contribute to a better understanding of the extent to which sourdough bread may result in measurable health benefits in humans.

Validated multiplex-competitive ELISA using gluten-incurred yogurt calibrant for the quantitation of wheat gluten in fermented dairy products

Currently, there are no available methods for accurate quantitation of gluten in fermented or hydrolyzed foods. In this study, gluten-incurred yogurt was used as a calibrant with a multiplex-competitive ELISA to quantitate gluten in fermented dairy products such as yogurt, kefir, and buttermilk, followed by a single-laboratory validation of the method. Four-parameter logistic calibration curves using five gluten-specific antibodies (R5, G12, 2D4, MIoBS, and Skerrit) were constructed, and averaging of the antibody responses was used as a strategy to get a single quantitative value. The lower limits of detection (LLOD) and quantitation (LLOQ) of the method were 1.9 and 5.5 µg/mL (ppm), respectively. Analysis of wheat gluten-incurred fermented dairy products (5, 8, 20, 100, and 500 µg/mL) prepared with multiple starter cultures and fermented for 24 or 48 h resulted in average gluten recoveries of 69-165%, 57-167%, and 54-148% for yogurt, kefir, and buttermilk, respectively. Only a few samples exceeded 150% recovery. The average coefficient of variation (CV) ranged from 10 to 34%, with the majority of the samples having a CV of < 30%. Experimental variations such as long-term refrigerated storage, spiking gluten after initial fermentation, using higher than recommended starter culture concentrations, or using wheat flour for contamination resulted in acceptable gluten recovery (50-150%) for the majority of the samples. Comparison of the performance of this method with a commercial competitive ELISA showed that the method has greater quantitative accuracy. This newly developed and validated method appears sufficiently sensitive and accurate to quantitate the amount of wheat gluten before fermentation, in select fermented dairy products.

How does a celiac iceberg really float? The relationship between celiac disease and gluten

Celiac disease (CD) is an autoimmune intestinal disease caused by intolerance of genetically susceptible individuals after intake of gluten-containing grains (including wheat, barley, etc.) and their products. Currently, CD, with "iceberg" characteristics, affects a large population and is distributed over a wide range of individuals. This present review summarizes the latest research progress on the relationship between CD and gluten. Furthermore, the structure and function of gluten peptides related to CD, gluten detection methods, the effects of processing on gluten and gluten-free diets are emphatically reviewed. In addition, the current limitations in CD research are also discussed. The present work facilitates a comprehensive understanding of CD as well as gluten, which can provide a theoretical reference for future research.