Fabrication of Material Extrusion‐Based Carbon Nanotubes/Zinc Oxide Core–Shell Polylactic Acid Nanocomposite Filaments for Advanced Biomedical Applications

Kumar, P V Ajay; Divakaran, Nidhin; Y, Alex; Mohapatra, Agneyarka; Mohanty, Smita

doi:10.1002/adem.202300058

Adv Eng Mater

2023

DOI: 10.1002/adem.202300058

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Fabrication of Material Extrusion‐Based Carbon Nanotubes/Zinc Oxide Core–Shell Polylactic Acid Nanocomposite Filaments for Advanced Biomedical Applications

P V Ajay Kumar

Nidhin Divakaran

Alex Y

et al.

Abstract: The rapid evolution of 3D‐printing (3DP) technologies has generated scope of developing advanced feedstock materials with excellent comprehensive properties. Material extrusion (ME) is one such 3DP technique with extensive range of commercial applications especially in aerospace applications. Herein, the current research focusses on developing ME‐based filaments with excellent functional characteristics by using polylactic acid (PLA) as the base polymer. The hybrid combination of carbon nanotubes and zinc oxid… Show more

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2024

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Augmented barrier properties of poly (lactic acid) composite packaging film reinforced by antibacterial hybrid bio‐filler: Extending the shelf life of fruits

Pradhan,

N R,

G S

et al. 2024

Polymer Composites

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This work investigates the construction of biodegradable packaging film based on polylactic acid (PLA) reinforced with a novel antibacterial hybrid nanofiller to improve barrier and mechanical properties. The study focuses on incorporating silver‐ingrained silica particles (Ag–In–Si) into PLA matrix to prepare the packaging film (Ag–In–SiPLA) that has superior antibacterial, and barrier property with negligible oxygen and water vapour penetration. The Ag was synthesized using natural neem leaf extract as a reducing agent. To ingrain silver over rice husk silica (Si) an in situ technique was adopted. Hence called Ag‐In‐Si bio‐filler. The Ag–In–SiPLA films were fabricated using melt blending and sheet extrusion methods by means of a micro‐compounder. The addition of rice husk silica served the purpose of cost‐effectiveness of the packaging film along with the enhancement of the oxygen and water barrier properties of the films. The optimized sample (PLA loaded with 3% Ag–In–Si), exhibited optimum transparency, moisture resistance, and barrier properties compared with control PLA film. The experiments on Muntingia calabura (Jamaica cherry) preservation have verified the remarkable effectiveness of Ag–In–SiPLA films in preserving their quality for an extended period. These biodegradable packaging films, composed of food‐grade materials and sustainable ingredients, have the potential to provide a compostable and environmentally friendly solution for various packaging applications. This research shed light on the antibacterial Ag–In–SiPLA film as a long‐term, high‐performance fruit packaging solution.Highlights Novel antibacterial PLA composite with enhanced barrier and mechanical properties. Silver‐ingrained silica particles improve antibacterial and barrier properties. Green synthesis of silver using neem leaf extract Melt blending and sheet extrusion used to create cost‐effective packaging films. Ag–In–SiPLA films extend Muntingia calabura preservation, proving effective.

show abstract

Augmented barrier properties of poly (lactic acid) composite packaging film reinforced by antibacterial hybrid bio‐filler: Extending the shelf life of fruits

Pradhan,

N R,

G S

et al. 2024

Polymer Composites

View full text Add to dashboard Cite

show abstract

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Fabrication of Material Extrusion‐Based Carbon Nanotubes/Zinc Oxide Core–Shell Polylactic Acid Nanocomposite Filaments for Advanced Biomedical Applications

Cited by 1 publication

References 32 publications

Augmented barrier properties of poly (lactic acid) composite packaging film reinforced by antibacterial hybrid bio‐filler: Extending the shelf life of fruits

Augmented barrier properties of poly (lactic acid) composite packaging film reinforced by antibacterial hybrid bio‐filler: Extending the shelf life of fruits

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