Jinying Zhang, Chaofeng Zhu, Juan Li, Luyan Wu, Yuying Zhang, Huapin Huang, Wanhui Lin
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Patients were categorized into DRE and non-DRE groups. All patients were randomly divided into training and testing sets. Lasso regression combined with Stepglm [both] algorithms was used to screen independent risk factors for DRE. These risk factors were used to construct models to predict the DRE. Three models were constructed: a clinical feature model, an EEG microstate model, and a comprehensive prediction model (combining clinical-EEG microstates). A series of evaluation methods was used to validate the accuracy and reliability of the prediction models. Finally, these models were visualized for display.</p><p><strong>Results: </strong>In the training and testing sets, the comprehensive prediction model achieved the highest area under the curve values, registering 0.99 and 0.969, respectively. It was significantly superior to other models in terms of the C-index, with scores of 0.990 and 0.969, respectively. Additionally, the model recorded the lowest Brier scores of 0.034 and 0.071, respectively, and the calibration curve demonstrated good consistency between the predicted probabilities and observed outcomes. Decision curve analysis revealed that the model provided significant clinical net benefit across the threshold range, underscoring its strong clinical applicability. We visualized the comprehensive prediction model by developing a nomogram and established a user-friendly website to enable easy application of this model (https://fydxh.shinyapps.io/CE_model_of_DRE/).</p><p><strong>Conclusion: </strong>A comprehensive prediction model for DRE was developed, showing excellent discrimination and calibration in both the training and testing sets. 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引用次数: 0
摘要
背景:癫痫是一种慢性神经系统疾病,其特点是反复发作,严重影响患者的生活质量。确定预测因素对早期干预至关重要:脑电图(EEG)微状态利用多通道脑电图有效地描述了人脑的静息状态活动。本研究旨在开发一种综合预测模型,将临床特征与脑电图微状态相结合,预测药物难治性癫痫(DRE):设计:回顾性研究:本研究涵盖了2020年10月至2023年5月期间在一家三甲医院癫痫中心接受治疗的226名癫痫患者。患者被分为 DRE 组和非 DRE 组。所有患者被随机分为训练集和测试集。采用Lasso回归结合Stepglm[两种]算法筛选DRE的独立风险因素。这些风险因素被用来构建预测 DRE 的模型。共构建了三个模型:临床特征模型、脑电图微状态模型和综合预测模型(结合临床和脑电图微状态)。通过一系列评估方法验证了预测模型的准确性和可靠性。最后,对这些模型进行了可视化展示:在训练集和测试集中,综合预测模型的曲线下面积值最高,分别为 0.99 和 0.969。在 C 指数方面,该模型明显优于其他模型,分别为 0.990 和 0.969。此外,该模型的布赖尔得分最低,分别为 0.034 和 0.071,校准曲线显示预测概率与观察结果之间具有良好的一致性。决策曲线分析表明,该模型在整个阈值范围内都能提供显著的临床净获益,突出了其强大的临床适用性。我们通过开发提名图将综合预测模型可视化,并建立了一个用户友好型网站(https://fydxh.shinyapps.io/CE_model_of_DRE/),以方便应用该模型:结论:我们开发了一个 DRE 综合预测模型,该模型在训练集和测试集中均显示出卓越的区分度和校准性。该模型为评估癫痫患者罹患 DRE 的风险提供了一种直观的方法。
A comprehensive prediction model of drug-refractory epilepsy based on combined clinical-EEG microstate features.
Background: Epilepsy is a chronic neurological disorder characterized by recurrent seizures that significantly impact patients' quality of life. Identifying predictors is crucial for early intervention.
Objective: Electroencephalography (EEG) microstates effectively describe the resting state activity of the human brain using multichannel EEG. This study aims to develop a comprehensive prediction model that integrates clinical features with EEG microstates to predict drug-refractory epilepsy (DRE).
Design: Retrospective study.
Methods: This study encompassed 226 patients with epilepsy treated at the epilepsy center of a tertiary hospital between October 2020 and May 2023. Patients were categorized into DRE and non-DRE groups. All patients were randomly divided into training and testing sets. Lasso regression combined with Stepglm [both] algorithms was used to screen independent risk factors for DRE. These risk factors were used to construct models to predict the DRE. Three models were constructed: a clinical feature model, an EEG microstate model, and a comprehensive prediction model (combining clinical-EEG microstates). A series of evaluation methods was used to validate the accuracy and reliability of the prediction models. Finally, these models were visualized for display.
Results: In the training and testing sets, the comprehensive prediction model achieved the highest area under the curve values, registering 0.99 and 0.969, respectively. It was significantly superior to other models in terms of the C-index, with scores of 0.990 and 0.969, respectively. Additionally, the model recorded the lowest Brier scores of 0.034 and 0.071, respectively, and the calibration curve demonstrated good consistency between the predicted probabilities and observed outcomes. Decision curve analysis revealed that the model provided significant clinical net benefit across the threshold range, underscoring its strong clinical applicability. We visualized the comprehensive prediction model by developing a nomogram and established a user-friendly website to enable easy application of this model (https://fydxh.shinyapps.io/CE_model_of_DRE/).
Conclusion: A comprehensive prediction model for DRE was developed, showing excellent discrimination and calibration in both the training and testing sets. This model provided an intuitive approach for assessing the risk of developing DRE in patients with epilepsy.
期刊介绍:
Therapeutic Advances in Neurological Disorders is a peer-reviewed, open access journal delivering the highest quality articles, reviews, and scholarly comment on pioneering efforts and innovative studies across all areas of neurology. The journal has a strong clinical and pharmacological focus and is aimed at clinicians and researchers in neurology, providing a forum in print and online for publishing the highest quality articles in this area.