The Potential of Cell-Free Supernatant As a Preservative in Food Packaging Materials

Overview

Journal Foods

Specialty Biotechnology

Date 2024 Mar 13

PMID 38472756

Authors

Katherine Kho

Adinda Darwanti Kadar

Mario Donald Bani

Ihsan Tria Pramanda

Leon Martin

Matthew Chrisdianto

Ferren Pratama

Putu Virgina Partha Devanthi

Affiliations

Soon will be listed here.

Abstract

This study delves into the production and antimicrobial characteristics of cell-free supernatants from (CFSs-Pa). Antimicrobial activity was initially observed in CFS-Pa harvested after 12 h of incubation and increased up to the late stationary phase at 48 h. The increase in antimicrobial activity did not align with total protein content, pointing to other factors linked to the accumulation of organic acids, particularly lactic acid. The SDS-PAGE analysis also indicated that the expected proteinaceous compound (pediocin) was not observed in CFS-Pa. Further investigations suggested that the antimicrobial properties of CFS-Pa were exclusively due to organic acids. The MIC values confirmed potent antimicrobial activity, particularly at a 10% dilution of CFS-Pa in MRS broth. The time-kill assays demonstrated bactericidal activity against EHEC, and by 12 h, 18 h, and 24 h using a 10% dilution of CFS-Pa. Additionally, CFS-Pa exhibited dose-dependent antioxidant activity, requiring a 70% (/) concentration to inhibit DPPH scavenging activity by 50%. All the experimental results suggested potential applications of CFS-Pa in food preservation. An attempt to incorporate CFS-Pa into bacterial cellulose (BC) for edible food packaging demonstrated promising antimicrobial results, particularly against and , with room for optimization.

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