Abstract
Among prevalent food allergies, cow milk allergy (CMA) is most common and may persist throughout the life. The allergic individuals are exposed to a constant threat due to milk proteins’ presence in uncounted food products like yogurt, cheese, and bakery items. The problem can be more severe due to cross-reactivity of the milk allergens in the food products due to homologous milk proteins of diverse species. This problem can be overcome by proper and reliable food labeling in order to ensure the life quality of allergic persons. Therefore, highly sensitive and accurate analytical techniques should be developed to detect the food allergens. Here, significant research advances in biosensors (specifically immunosensors and aptasensors) are reviewed for detection of the milk allergens. Different allergic proteins of cow milk are described here along with the analytical standard methods for their detection. Additionally, the commercial status of biosensors is also discussed in comparison to conventional techniques like enzyme-linked immunosorbent assay (ELISA). The development of novel biosensing mechanisms/kits for milk allergens detection is imperative from the perspective of enforcement of labeling regulations and directives keeping in view the sensitive individuals.
Highlights
In recent decades, the increased prevalence of food allergy has posed challenges to both food industry and clinical allergology
This review presents development of aptamers, biosensors, aptasensors for determination of allergen concentration in food matrix
Biosensors in combination with novel nanomaterials and sensing platform fabrication are offering a cheaper, facile, rapid, and multiplex detection of milk allergens in comparison to conventional techniques like enzyme-linked immunosorbent assay (ELISA), liquid chromatography-mass spectrometry (LC-MS), and real-time polymerase chain reaction (PCR)
Summary
The increased prevalence of food allergy has posed challenges to both food industry and clinical allergology. The accountability of two disulphide bonds has been reported for high stability against acidic hydrolysis and proteases [8] This property of β-LG enables preserving the structural integrity after digestion that allows its absorption via intestinal mucosa as well as further presentation to immunocompetent cells with high allergenic potential. This protein is majorly responsible for food allergy in approximately 60 to 80% of CMA patients [7]. The present review is designed to consider the cow milk allergens that can cause life-threatening anaphylactic reactions. The commercially available biosensors are summarized here as along with consideration of emerging challenges
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