Process optimization, multi-gene genetic programming modeling and reliability assessment of bioactive extracts recovery from Phyllantus emblica
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- @Article{ALANZI:2024:jer,
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author = "Hamdan Alanzi and Hamoud Alenezi and Oladayo Adeyi and
Abiola J. Adeyi and Emmanuel Olusola and
Chee-Yuen Gan and Olusegun Abayomi Olalere",
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title = "Process optimization, multi-gene genetic programming
modeling and reliability assessment of bioactive
extracts recovery from Phyllantus emblica",
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journal = "Journal of Engineering Research",
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year = "2024",
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ISSN = "2307-1877",
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DOI = "doi:10.1016/j.jer.2024.02.020",
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URL = "https://www.sciencedirect.com/science/article/pii/S2307187724000476",
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keywords = "genetic algorithms, genetic programming, leaf,
bioactive extract, Heat-assisted technology, multi gene
genetic programming, reliability assessment",
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abstract = "This study investigates the feasibility of extracting
bioactive antioxidants from Phyllantus emblica leaves
using a combination of ethanol-water mixture
(0-100percent) and heat-assisted extraction technology
(HAE-T). Operating temperature (30-50degreeC),
solid-to-liquid ratio (1:20-1:60g/mL), and extraction
time (45-180min) were varied to determine their effects
on extract total phenolic content (TPC), yield (EY),
and antioxidant activity (AA). The Box-Behnken
experimental design (BBD) within response surface
methodology (RSM) was employed, with multi-objective
process optimization using the desirability function
algorithm to find the optimal process variables for
maximizing TPC, EY, and AA simultaneously. The
extraction process was modeled using BBD-RSM and
multi-gene genetic programming (MGGP) algorithm, with
model reliability assessed via Monte Carlo simulation.
HPLC characterization identified betulinic acid, gallic
acid, chlorogenic acid, caffeic acid, ellagic acid, and
ferulic acid as bioactive constituents in the extract.
The study found that a 50percent ethanol solution
yielded the best extraction efficiency. The optimal
process parameters for maximum EY (21.6565percent), TPC
(67.116mg GAE/g), and AA (3.68583uM AAE/g) were
determined as OT of 41.61degreeC, S:L of 1:60g/mL, and
ET of 180min. Both BBD-RSM and MGGP-based models
satisfactorily predicted the observed process
responses, with BBD-RSM models showing slightly better
performance. Reliability analysis indicated high
certainty in the predictions, with BBD-RSM models
achieving 99.985percent certainty for TPC,
97.569percent for EY, and 98.661percent for AA values",
- }
Genetic Programming entries for
Hamdan Alanzi
Hamoud Alenezi
Oladayo Adeyi
Abiola John Adeyi
Emmanuel Olusola
Chee-Yuen Gan
Olusegun Abayomi Olalere
Citations