Abstract:
Petroleum-based plastics are poorly biodegradable, and their widespread use has
caused serious environmental pollution. Agro-industrial residues containing
cellulose, hemicellulose, and pectin offer a promising alternative for sustainable
packaging materials. This study aimed to develop biodegradable foam cups from
mango peel and banana stem fiber using baking mold technology. Three
formulations were prepared with different mango peel-cassava starch fiber ratios:
T1 (2:1), T2 (1:1), and T3 (2:3), with a constant amount of banana fiber, glycerol,
and citric acid. The ingredients were mixed with warm water to form slurries,
poured into molds, and baked at 120°C for 40 minutes. Physical properties,
including thickness, moisture content, and water absorption, were evaluated,
while mechanical properties (hardness, adhesiveness, and springiness) were
measured using a texture profile analyzer. Results showed significant differences
among the treatments. Thickness increased with starch content, with T3 exhibiting
the highest (2.99±0.20mm) and T1 the lowest (1.57±0.08mm). Moisture content
(9.73%-5.63%) and water absorption (28.0%-40.33%) also increased with starch
due to enhanced gelatinization and hydrophilicity. Hardness ranged from 5.0 N
(T3) to 19 N (T1), indicating a stronger structure in T1, while adhesiveness
remained low (0-0.5 mJ) and springiness slightly decreased in harder foams (0.77-
0.86). Overall, T1 produced harder, thinner, and less water-absorbing cups, T3
produced softer, thicker, and highly hydrophilic cups, and T2 provided a balanced
combination of structural integrity and water resistance, indicating potential
suitability for functional applications. These findings suggest that mango peel
powder and banana stem fiber can be effectively valorized for biodegradable
packaging.