Investigating the effects of cellulose nanocrystals and genipin on upcycled keratin films for packaging applications
The global production of plastic waste has been steadily increasing over the years with a reported 460 million metric tonnes of plastic generated in 2019. Of this, only an average 9% of plastics get recycled annually while over 22% of plastics gets mismanaged and ends up in natural environments c...
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| Format: | Final Year Project |
| Language: | English |
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Nanyang Technological University
2024
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| Online Access: | https://hdl.handle.net/10356/176112 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | The global production of plastic waste has been steadily increasing over the years with
a reported 460 million metric tonnes of plastic generated in 2019. Of this, only an
average 9% of plastics get recycled annually while over 22% of plastics gets
mismanaged and ends up in natural environments causing detrimental effects to the
environment and its residing ecosystems.
In this study, upcycled keratin is obtained using human hair waste via a modified
Shindai method which isolates keratin intermediate filaments. The isolated keratin is
then combined with reinforcing agents such as cellulose nanocrystals, and crosslinkers
such as genipin. Keratin composite films are then fabricated via drop casting on to
PTFE fibre mats and left at room temperature and pressure to dry. Fabricated films are
then analysed using characterisation techniques to determine its chemical composition,
mechanical properties, and hydrophobicity. The addition of CNCs have shown to
improve the mechanical stability of the keratin film and increased the hydrophobicity
of the film by reducing the amount of free volume within the composite. The 6CNC
sample was shown to possess the highest mechanical strength and hydrophobicity
(sample details can be found in table 1.) The addition of genipin as a crosslinker did
not highlight any significant crosslinking based on FTIR analysis. However, there was
a slight increase in hydrophobicity observed with the addition of genipin which can be
attributed to the presence of non-covalent molecular interactions between the genipin
molecules and the keratin chains.
Biodegradation tests in soil and seawater environments were used to confirm
biodegradability of the fabricated film samples, which revealed that the rate of
degradation can be controlled by varying the amounts of cellulose nanocrystals and
genipin. A higher concentration of CNCs allows for an increased rate of soil and
seawater degradation. Additionally, the addition of genipin has shown to retard the rate
of degradation in both setups. In summary, the degradability of keratin composite films,
coupled with its potential to improve its mechanical properties, provides a greener
alternative to current conventional packaging solutions. |
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