Response Surface Methodology : A Versatile Tool for the Optimization of Particle Sizes of Cellulose Beads

Synthesis parameters are of utmost importance for controlling the particle sizes of cellulose beads. This study aims to investigate the effects of synthesis parameters e.g., stirring speed (250–1250 rpm), surfactant concentrations (0.5–6.0% w/v), cellulose concentrations (1–5% w/v), and reaction tem...

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Bibliographic Details
Main Authors: Kimberly Tay, Wei Wei, Chin, Suk Fun, Mohd Effendi, Wasli, Zaki, Musa
Format: Article
Language:English
Published: UPM Press 2023
Subjects:
Online Access:http://ir.unimas.my/id/eprint/43582/3/Response.pdf
http://ir.unimas.my/id/eprint/43582/
http://www.pertanika.upm.edu.my/pjst/browse/regular-issue?article=JST-4016-2022
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Institution: Universiti Malaysia Sarawak
Language: English
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Summary:Synthesis parameters are of utmost importance for controlling the particle sizes of cellulose beads. This study aims to investigate the effects of synthesis parameters e.g., stirring speed (250–1250 rpm), surfactant concentrations (0.5–6.0% w/v), cellulose concentrations (1–5% w/v), and reaction temperature (30-100°C) on the particle sizes for micron-sized cellulose beads (μCBs) as well as other parameters e.g. the volume (1.0 mL) and concentration (0.1–1.0% w/v) of cellulose for nanosized (nCBs) cellulose beads using the response surface methodology (RSM). A total of 27 runs were conducted applying RSM based on the central composite design approach with Minitab-19. Cellulose concentrations were shown to have the most significant effect on both μCBs and nCBs. Under optimized conditions, the minimum and maximum mean particle size of μCBs that could be achieved were 15.3 μm and 91 μm, respectively. The predicted mean particle size for nCBs was obtained at 0.01 nm as the smallest and 200 nm as the biggest particle size under the optimum conditions. This study envisages that RSM and experiments for targeted applications such as biomedicine and agriculture could optimize the particle sizes of cellulose beads.