clay and cinnamaldehyde

Using nanocarriers to load antimicrobial agent instead of direct incorporating into film matrix could avoid burst release. Halloysite nanotubes (HNTs) are natural clays with a unique tubular structure; therefore in many studies it served as carriers to achieve a controlled release of active agents. However, when HNTs biocomposites were loaded into packaging film, the antimicrobial activity was reduced too seriously to preserve the packaged food. This study aimed to improving preservation properties of the fabricated films from two perspectives: enlarging the loading capacity of the carrier, and increasing the concentration of HNTs biocomposites. Brunauer, Emmett, Teller's test (BET) and thermogravimetric analysis (TGA) were conducted to evaluate the performance of acid treated nanocomposites. Results showed that acid treatment expanded the lumen of HNTs, increasing the loading capacity of cinnamaldehyde (Cin) from 14.6 wt% to 25.0 wt%. Active packaging films were then fabricated by incorporating Cin loaded HNTs into poly(lactic acid) matrix, and it revealed bionanocomposites at 30 wt% achieved the optimum film, considering the mechanical performance and controlled release of Cin. Cumulative release rate of the films were further verified by the fumigant antimicrobial activity. This study demonstrates a solution for improving the antimicrobial properties of packaging film without comprising mechanical strength.

Topics: Anti-Infective Agents; Clay; Delayed-Action Preparations; Nanotubes

Linseed oil-based composite films were prepared with cinnamaldehyde (Cin) using a modified clay (organoclay) through in situ polymerization, which is the result of the interaction between Cin and organoclay. The incorporation of organoclay reduces the polymer chain's mobility and, therefore, increases the thermal stability of the composite films. In some experimental conditions, the clay is located both inside and on the surface of the film, thus, affecting the mechanical and thermal properties as well as the surface properties of the composite films. The incorporation of organoclay decreases the water contact angle of the composite film by more than 15%, whatever the amount of cinnamaldehyde. However, the incorporation of cinnamaldehyde has the opposite effect on film surface properties. Indeed, for the water vapor permeability (WVP), the effect of cinnamaldehyde on the film barrier properties is much higher in the presence of organoclay. The incorporation of hydrophobic compounds into the polymer films reduces the water content, which acts as a plasticizer and, therefore, decreases the WVP by more than 17%. Linseed oil has a natural antioxidant activity (~97%) due to the higher content of unsaturated fatty acids, and this activity increased with the amount of organoclay and cinnamaldehyde.

Topics: Clay; Linseed Oil; Polymerization; Polymers; Steam