FABRICATION CORN COB-BASED CELLULOSE HYDROGEL USING THE FREEZE-THAW METHOD AND CHARACTERIZATION PHYSICOCHEMICAL PROPERTIES AND ANTIBACTERIAL ACTIVITY
Indonesia is one of the largest corn producers in the world, with a corn production of 21.441.943 tons. Out of the total corn waste, corn cobs contribute at least 20% of the total waste. Corn cobs have several components, namely lignin (15.08%), cellulose (34.33%), and hemicellulose (20.17%). The...
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| Format: | Theses |
| Language: | Indonesia |
| Online Access: | https://digilib.itb.ac.id/gdl/view/79615 |
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| Institution: | Institut Teknologi Bandung |
| Language: | Indonesia |
| Summary: | Indonesia is one of the largest corn producers in the world, with a corn production of 21.441.943
tons. Out of the total corn waste, corn cobs contribute at least 20% of the total waste. Corn cobs
have several components, namely lignin (15.08%), cellulose (34.33%), and hemicellulose
(20.17%). The cellulose content has the potential to be reused as a biodegradable material.
Cellulose is an abundant natural polymer that is biocompatible, environmentally friendly, easily
degradable, and contains many hydroxyl groups that allow it to interact with water molecules
through hydrogen bonding, making it suitable for encapsulation in hydrogels. A hydrogel is a
three-dimensional network structure made from a polymer that can absorb water. Cellulose is
extracted from corn cobs through delignification, bleaching, and acid hydrolysis processes. The
produced cellulose content reached 70.43%. Cellulose was transformed into a hydrogel using the
freeze-thaw method to establish a stable and non-toxic hydrogel structure. In this study, the impact
of adding NaOH concentrations of 2%, 3%, 4%, 5%, 6%, and 7% was identified to examine the
physicochemical characteristics of cellulose hydrogels. SEM-EDS images revealed that cellulose
powder had purer elemental content compared to corn cob powder. The hydrogel with a 3% NaOH
concentration exhibited abundant cross-linking and the largest pore size. Additionally, at this
concentration, the hydrogel achieved the highest degree of expansion at 48 hours, measuring
524,77 ± 8,56 %, with superior compressive and tensile strengths. As the NaOH concentration
increased, the hydrogel experienced greater weight loss, indicating a decline in integrity. FTIR
analysis showed the absence of hemicellulose and lignin groups, confirming the formation of
cellulose groups in the hydrogel. XRD results indicated semicrystalline properties in cellulose
powder with a crystallinity degree of 61.48%, while cellulose hydrogel exhibited an amorphous
structure. TGA testing demonstrated that low NaOH concentration in cellulose hydrogel resulted
in better thermal stability compared to cellulose powder due to cross-linking effects. Higher NaOH
concentrations led to increased residue at 600°C, attributed to the substantial residue of NaOH
itself. DSC findings revealed the melting point and heat required to break bonds, with cellulose
powder having a melting heat of 383.75 J/g. In contrast, cellulose hydrogel exhibited significantly
lower heat due to its amorphous structure. Antibacterial tests indicated that cellulose powder
inhibited the growth of Staphylococcus aureus and Pseudomonas aeruginosa by 24.67% and
4.32%, respectively. Cellulose hydrogel, with its NaOH solvent, demonstrated bactericidal activity. Cytotoxicity tests revealed an IC50 > 900 µg/mL for all hydrogels, confirming their nontoxic and biocompatible nature towards normal cells. However, the use of NaOH on the body
should not exceed 4% as it may cause irritation. Therefore, the safe hydrogel formulations for use
are hydrogel with concentration of NaOH 2% and 3%. |
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