We've updated our Privacy Policy to make it clearer how we use your personal data.

We use cookies to provide you with a better experience. You can read our Cookie Policy here.


Portable Color-Changing Food Spoilage Sensor Developed

A box of dead fish at a fish market.
Credit: tookapic, Pixabay.

Want a FREE PDF version of this news story?

Complete the form below and we will email you a PDF version of "Portable Color-Changing Food Spoilage Sensor Developed"

Listen with
Register for free to listen to this article
Thank you. Listen to this article using the player above.
Read time:

Ingesting biogenic amines released from spoiled food is harmful for the human body. Thus, it is important to detect these compounds during food storage and distribution to track spoilage. To this end, researchers have now combined polydiacetylene liposome and alginate solution to create hydrogel for developing a colorimetric food spoilage sensor. This novel sensor easily detects biogenic amines in liquid or vapor form by changing color from blue to red, without any complicated machinery.

When foods like fish, meat, and cheese decompose, they release a variety of low molecular weight organic nitrogen compounds known as biogenic amines (BAs). While the body uses BAs in small amounts in processes like hormone synthesis, ingesting large amounts of BAs from spoiled food can cause serious health problems. Therefore, it is important to detect BAs during food storage and distribution. This motivated a team of researchers, including Prof. Sungbaek Seo, Associate Professor of Biomaterials Science at Pusan National University, to develop a portable molecular sensor that quickly detects the presence of BAs by changing colors. “The rapid and easy monitoring of deleterious BAs released from spoiled foods could x-x-alert us, prevent consumption of spoiled meat, maintain food quality, and establish further effective food storage and distribution conditions in the logistic chain”, notes Prof. Seo.

The researchers have detailed this novel development in a recent article published in Food Chemistry. This paper was made available online on 20 September 2022 and was published in Volume 403, Issue 1 of the journal in March 2023. The team combined the distinct color-changing property of polydiacetylene (PDA)-based hydrogel beads upon binding with BAs with an alginate solution that rendered a three-dimensional porous structure with a large surface area to fabricate this novel sensor. The researchers demonstrated that the developed sensor beads easily detect biogenic amines like cadaverine and propylamine both in solution and vapor forms via distinct changes in color from blue to red. The team further put the sensor to test the spoilage of pork meat samples left at room temperature across 4 days. They showed that the sensor beads could efficiently track the gradual spoilage over time by showing a distinct shift in the shade of color.

Want more breaking news?

Subscribe to Technology Networks’ daily newsletter, delivering breaking science news straight to your inbox every day.

Subscribe for FREE

The sensor is made of portable, light-weight beads and does not require complicated analytical equipment or skilled personnel. It offers rapid and seamless visual detection via colorimetric change in the beads from blue to red. As Prof. Seo observes, “The portable beads could be utilized on sites for monitoring whether the food quality is okay during storage and logistic chain. Further, the beads could be applied in evaluating whether ideal food storage and distribution conditions are well-preserved”.

Taken together, this portable PDA-based colorimetric sensor would facilitate the seamless monitoring of food spoilage during storage and distribution, and prevent health hazards arising from the ingestion of BAs.

Reference: Jang S, Son SU, Kim J, et al. Polydiacetylene-based hydrogel beads as colorimetric sensors for the detection of biogenic amines in spoiled meat. Food Chem. 2023;403:134317. doi:10.1016/j.foodchem.2022.134317

This article has been republished from the following materials. Note: material may have been edited for length and content. For further information, please contact the cited source.