AI Article Synopsis
- Spinal conditions like fractures and herniated intervertebral discs (HIVDs) can be tough to diagnose due to similar symptoms, making accurate differentiation vital for treatment and anesthesia planning.
- A Support Vector Machine (SVM) model was developed to distinguish between spinal fractures and HIVDs using factors such as age, gender, and pain scores, analyzed on a dataset of 199 patients.
- The SVM model demonstrated high precision (92.1% for fractures, 91.2% for HIVDs) and overall accuracy of 92%, identifying age and pain scores as key predictors, suggesting the model's potential for enhancing preoperative evaluations.
Article Abstract
Spinal conditions, such as fractures and herniated intervertebral discs (HIVDs), are often challenging to diagnose due to overlapping clinical symptoms and the difficulty in assessing their functional impact. Accurate differentiation between these conditions is crucial for effective treatment, particularly in the context of preoperative anesthesia evaluation, where understanding the underlying condition can influence anesthesia planning and pain management. This study presents a Support Vector Machine (SVM) model designed to distinguish between spinal fractures and HIVDs using key clinical predictors, including age, gender, preoperative Visual Analog Scale (VAS) pain scores, and the number of spinal fractures. A retrospective analysis was conducted on a dataset of 199 patients diagnosed with these conditions. The SVM model, using a radial basis function (RBF) kernel, classified the conditions based on the selected predictors. Model performance was evaluated using precision, recall, accuracy, and the Kappa index, with Leave-One-Out (LOO) cross-validation applied to ensure robust results. The SVM model achieved a precision of 92.1% for fracture cases and 91.2% for HIVDs, with recall rates of 98.1% for fractures and 70.5% for HIVDs. The overall accuracy was 92%, and the Kappa index was 0.76, indicating substantial agreement. The analysis revealed that age and VAS pain scores were the most critical predictors for accurately diagnosing these conditions. These results highlight the potential of the SVM model with an RBF kernel to reliably differentiate between spinal fractures and HIVDs using routine clinical data. Future work could enhance model performance by incorporating additional clinical parameters relevant to preoperative anesthesia evaluation.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11545723 | PMC |
| http://dx.doi.org/10.3390/diagnostics14212456 | DOI Listing |
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