Flow diagram of the proposed model.

Flow diagram of the proposed model.

<div><p>Machine learning models are increasingly applied to assisted reproductive technologies (ART), yet most studies rely on conventional algorithms with limited optimization. This proof-of-concept study investigates whether a hybrid Logistic Regression–Artificial Bee Colony (LR–ABC) f...

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Bibliografiske detaljer
Hovedforfatter: Uğur Ejder (22683228) (author)
Andre forfattere: Pınar Uskaner Hepsağ (22683231) (author)
Udgivet: 2025
Fag:
Biotechnology
Ecology
Cancer
Biological Sciences not elsewhere classified
Mathematical Sciences not elsewhere classified
Information Systems not elsewhere classified
small sample size
lr &# 8211
evaluated using 5
assisted reproductive technologies
artificial bee colony
art ), yet
address class imbalance
support vector machine
pharmaceutical supplement use
enhance predictive performance
abc hybrids outperformed
abc hybrid counterparts
local interpretable model
abc hybrid model
model performance
supplement variables
producing interpretable
dietician support
vitro fertilization
synthetic minority
studies rely
sampling technique
retrospective dataset
regression tree
random forest
observed improvements
nearest neighbors
limited optimization
influential features
individual predictions
improving prediction
implemented alongside
future studies
four algorithms
folic acid
fold cross
exploratory rather
dietary data
conventional algorithms
concept study
clinically directive
binary representation
baseline models
algorithm models
agnostic explanations
accuracy ).
21 predictors
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Summary:<div><p>Machine learning models are increasingly applied to assisted reproductive technologies (ART), yet most studies rely on conventional algorithms with limited optimization. This proof-of-concept study investigates whether a hybrid Logistic Regression–Artificial Bee Colony (LR–ABC) framework can enhance predictive performance in in vitro fertilization (IVF) outcomes while producing interpretable, hypothesis-driven associations with nutritional and pharmaceutical supplement use. A retrospective dataset of 162 women undergoing IVF was analyzed. Clinical, demographic, and supplement variables were preprocessed into 21 predictors. Four algorithms (K-Nearest Neighbors, Classification and Regression Tree, Support Vector Machine, and Random Forest) were implemented alongside their LR–ABC hybrid counterparts. Model performance was evaluated using 5-fold cross-validation with Synthetic Minority Over-sampling Technique (SMOTE) to address class imbalance. Local Interpretable Model-agnostic Explanations (LIME) were applied to improve interpretability. Across all algorithm models, LR–ABC hybrids outperformed their baseline models (e.g., Random Forest: 85.2% → 91.36% accuracy). LIME explanations identified omega-3, folic acid, and dietician support as influential features in individual predictions. However, given the small sample size, binary representation of supplements, and absence of external validation, the observed improvements and associations should be regarded as exploratory rather than definitive. The LR–ABC hybrid model demonstrates methodological potential for improving prediction and interpretability in IVF research. Findings regarding supplement associations are hypothesis-generating, not clinically directive. Future studies with larger, multi-center datasets including detailed dosage and dietary data are needed to validate and extend this framework.</p></div>

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