一种通过支持向量回归预测重症监护病房肝移植患者他克莫司血药浓度的新方法。

A novel approach for prediction of tacrolimus blood concentration in liver transplantation patients in the intensive care unit through support vector regression.

作者信息

Van Looy Stijn, Verplancke Thierry, Benoit Dominique, Hoste Eric, Van Maele Georges, De Turck Filip, Decruyenaere Johan

机构信息

Ghent University, Department of Information Technology, Gaston Crommenlaan 8, Ghent, Belgium.

出版信息

Crit Care. 2007;11(4):R83. doi: 10.1186/cc6081.

DOI:10.1186/cc6081

PMID:17655766

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2206504/

Abstract

INTRODUCTION

Tacrolimus is an important immunosuppressive drug for organ transplantation patients. It has a narrow therapeutic range, toxic side effects, and a blood concentration with wide intra- and interindividual variability. Hence, it is of the utmost importance to monitor tacrolimus blood concentration, thereby ensuring clinical effect and avoiding toxic side effects. Prediction models for tacrolimus blood concentration can improve clinical care by optimizing monitoring of these concentrations, especially in the initial phase after transplantation during intensive care unit (ICU) stay. This is the first study in the ICU in which support vector machines, as a new data modeling technique, are investigated and tested in their prediction capabilities of tacrolimus blood concentration. Linear support vector regression (SVR) and nonlinear radial basis function (RBF) SVR are compared with multiple linear regression (MLR).

METHODS

Tacrolimus blood concentrations, together with 35 other relevant variables from 50 liver transplantation patients, were extracted from our ICU database. This resulted in a dataset of 457 blood samples, on average between 9 and 10 samples per patient, finally resulting in a database of more than 16,000 data values. Nonlinear RBF SVR, linear SVR, and MLR were performed after selection of clinically relevant input variables and model parameters. Differences between observed and predicted tacrolimus blood concentrations were calculated. Prediction accuracy of the three methods was compared after fivefold cross-validation (Friedman test and Wilcoxon signed rank analysis).

RESULTS

Linear SVR and nonlinear RBF SVR had mean absolute differences between observed and predicted tacrolimus blood concentrations of 2.31 ng/ml (standard deviation [SD] 2.47) and 2.38 ng/ml (SD 2.49), respectively. MLR had a mean absolute difference of 2.73 ng/ml (SD 3.79). The difference between linear SVR and MLR was statistically significant (p < 0.001). RBF SVR had the advantage of requiring only 2 input variables to perform this prediction in comparison to 15 and 16 variables needed by linear SVR and MLR, respectively. This is an indication of the superior prediction capability of nonlinear SVR.

CONCLUSION

Prediction of tacrolimus blood concentration with linear and nonlinear SVR was excellent, and accuracy was superior in comparison with an MLR model.

摘要

引言

他克莫司是器官移植患者重要的免疫抑制药物。其治疗窗窄，有副作用，且血药浓度在个体内和个体间存在较大差异。因此，监测他克莫司血药浓度至关重要，可确保临床疗效并避免副作用。他克莫司血药浓度预测模型可通过优化这些浓度的监测来改善临床护理，尤其是在移植后重症监护病房（ICU）停留的初始阶段。这是在ICU进行的第一项研究，其中研究并测试了支持向量机作为一种新的数据建模技术对他克莫司血药浓度的预测能力。将线性支持向量回归（SVR）和非线性径向基函数（RBF）SVR与多元线性回归（MLR）进行比较。

方法

从我们的ICU数据库中提取50例肝移植患者的他克莫司血药浓度以及其他35个相关变量。这产生了一个包含457个血样的数据集，每位患者平均有9至10个样本，最终形成了一个包含超过16000个数据值的数据库。在选择临床相关输入变量和模型参数后，进行非线性RBF SVR、线性SVR和MLR。计算观察到的和预测的他克莫司血药浓度之间的差异。在五重交叉验证（Friedman检验和Wilcoxon符号秩分析）后比较三种方法的预测准确性。

结果

线性SVR和非线性RBF SVR观察到的和预测的他克莫司血药浓度之间的平均绝对差异分别为2.31 ng/ml（标准差[SD] 2.47）和2.38 ng/ml（SD 2.49）。MLR的平均绝对差异为2.73 ng/ml（SD 3.79）。线性SVR和MLR之间的差异具有统计学意义（p < 0.001）。与线性SVR和MLR分别需要的15个和16个变量相比，RBF SVR进行此预测仅需要2个输入变量。这表明非线性SVR具有卓越的预测能力。

结论

线性和非线性SVR对他克莫司血药浓度的预测效果极佳，与MLR模型相比准确性更高。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/dbf4/2206504/b220dd08853d/cc6081-1.jpg

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一种通过支持向量回归预测重症监护病房肝移植患者他克莫司血药浓度的新方法。

A novel approach for prediction of tacrolimus blood concentration in liver transplantation patients in the intensive care unit through support vector regression.

作者信息

机构信息

出版信息

INTRODUCTION

METHODS

RESULTS

CONCLUSION

引言

方法

结果

结论

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