AI Article Synopsis
- Cornstalks can be used to produce polysaccharides effectively with the help of an enzyme called xylanase, and accurate prediction of yield can streamline production processes, reducing costs and time.
- The study introduces a machine learning framework that identifies the best methods for predicting polysaccharide yields and determining optimal enzyme conditions, with Random Forest and eXtreme Gradient Boost showing high accuracy rates.
- An analysis of influential factors reveals that the enzyme solution volume significantly impacts yield, and the research highlights the complexity of enzyme interactions, paving the way for improved methodologies in utilizing agricultural waste.
Article Abstract
Cornstalks show promise as a raw material for polysaccharide production through xylanase. Rapid and accurate prediction of polysaccharide yield can facilitate process optimization, eliminating the need for extensive experimentation in actual production to refine reaction conditions, thereby saving time and costs. However, the intricate interplay of enzymatic factors poses challenges in predicting and optimizing polysaccharide yield accurately. Here, we introduce an innovative data-driven approach leveraging multiple artificial intelligence techniques to enhance polysaccharide production. We propose a machine learning framework to identify highly accurate polysaccharide yield prediction modeling methods and uncover optimal enzymatic parameter combinations. Notably, Random Forest (RF) and eXtreme Gradient Boost (XGB) demonstrate robust performance, achieving prediction accuracies of 93.0% and 95.6%, respectively, while an independently developed deep neural network (DNN) model achieves 91.1% accuracy. A feature importance analysis of XGB reveals the enzyme solution volume's dominant role (43.7%), followed by time (20.7%), substrate concentration (15%), temperature (15%), and pH (5.6%). Further interpretability analysis unveils complex parameter interactions and potential optimization strategies. This data-driven approach, incorporating machine learning, deep learning, and interpretable analysis, offers a viable pathway for polysaccharide yield prediction and the potential recovery of various agricultural residues.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10661693 | PMC |
| http://dx.doi.org/10.1016/j.ese.2023.100321 | DOI Listing |
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