Machine Learning Algorithm for Predicting Warfarin Dose in Caribbean Hispanics Using Pharmacogenetic Data

Roche-Lima, Abiel; Roman-Santiago, Adalis; Feliu-Maldonado, Roberto; Rodríguez-Maldonado, Jovaniel; Nieves-Rodriguez, Brenda G.; Carrasquillo-Carrión, Kelvin; Ramos, Carolina; Sant’Ana, Istoni da Luz; Massey, Steven E.; Duconge, Jorge

doi:10.3389/fphar.2019.01550

Cited by 26 publications

(12 citation statements)

References 20 publications

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“…There are various warfarin dose suggestion models that use artificial intelligence (AI) 17 , 20 , 21 However, these models are all limited in that they were constructed to predict optimum initial starting or maintenance warfarin doses using only cross-sectional data. However, this approach does not reflect the actual human decision-making process.…”

Section: Discussionmentioning

confidence: 99%

“…The algorithm developed in this study was trained to adapt to individual pharmacokinetic and pharmacodynamic characteristics by examining how fluctuations in a person’s PT INR correlated with their warfarin doses over the 4 days. Several other studies divided patients according to dose ranges and developed a separate algorithm for each and so could not cover a wide dose range 11 , 17 , 21 . However, the algorithm developed in this study does not require patients to be classified by dose because it was trained on the whole warfarin dose range and PT INR responses.…”

Section: Discussionmentioning

confidence: 99%

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Development of a system to support warfarin dose decisions using deep neural networks

Lee

Kim

Chang

et al. 2021

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The first aim of this study was to develop a prothrombin time international normalized ratio (PT INR) prediction model. The second aim was to develop a warfarin maintenance dose decision support system as a precise warfarin dosing platform. Data of 19,719 inpatients from three institutions was analyzed. The PT INR prediction algorithm included dense and recurrent neural networks, and was designed to predict the 5th-day PT INR from data of days 1–4. Data from patients in one hospital (n = 22,314) was used to train the algorithm which was tested with the datasets from the other two hospitals (n = 12,673). The performance of 5th-day PT INR prediction was compared with 2000 predictions made by 10 expert physicians. A generator of individualized warfarin dose-PT INR tables which simulated the repeated administration of varying doses of warfarin was developed based on the prediction model. The algorithm outperformed humans with accuracy terms of within ± 0.3 of the actual value (machine learning algorithm: 10,650/12,673 cases (84.0%), expert physicians: 1647/2000 cases (81.9%), P = 0.014). In the individualized warfarin dose-PT INR tables generated by the algorithm, the 8th-day PT INR predictions were within 0.3 of actual value in 450/842 cases (53.4%). An artificial intelligence-based warfarin dosing algorithm using a recurrent neural network outperformed expert physicians in predicting future PT INRs. An individualized warfarin dose-PT INR table generator which was constructed based on this algorithm was acceptable.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Development of a system to support warfarin dose decisions using deep neural networks

Lee

Kim

Chang

et al. 2021

Sci Rep

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“…We selected the percentage within 20% because this range has been widely accepted and applied to assess models for predicting the dosages of such drugs as warfarin and tacrolimus (see Table 1) [19][20][21][22] . Moreover, ignoring problems of adherence and pharmacokinetic alteration, the intra-individual variation in the C/D ratio is generally considered to not be above 20% 7 .…”

Section: Methodsmentioning

confidence: 99%

“…The application of ML to clinical drug therapies has garnered considerable research interest in recent years, and is playing an increasingly important role in the development of personalized dosing, especially in drug dose selection 17 . A few studies have been published on the application of ML to predict either drug doses or blood concentrations [18][19][20][21][22][23] . Jovanović et al 18 explored the application of ML as an alternative to pharmacokinetics analysis.…”

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confidence: 99%

A machine learning approach to personalized dose adjustment of lamotrigine using noninvasive clinical parameters

Zhu

Huang

et al. 2021

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The pharmacokinetic variability of lamotrigine (LTG) plays a significant role in its dosing requirements. Our goal here was to use noninvasive clinical parameters to predict the dose-adjusted concentrations (C/D ratio) of LTG based on machine learning (ML) algorithms. A total of 1141 therapeutic drug-monitoring measurements were used, 80% of which were randomly selected as the "derivation cohort" to develop the prediction algorithm, and the remaining 20% constituted the "validation cohort" to test the finally selected model. Fifteen ML models were optimized and evaluated by tenfold cross-validation on the "derivation cohort,” and were filtered by the mean absolute error (MAE). On the whole, the nonlinear models outperformed the linear models. The extra-trees’ regression algorithm delivered good performance, and was chosen to establish the predictive model. The important features were then analyzed and parameters of the model adjusted to develop the best prediction model, which accurately described the C/D ratio of LTG, especially in the intermediate-to-high range (≥ 22.1 μg mL−1 g−1 day), as illustrated by a minimal bias (mean relative error (%) = + 3%), good precision (MAE = 8.7 μg mL−1 g−1 day), and a high percentage of predictions within ± 20% of the empirical values (60.47%). This is the first study, to the best of our knowledge, to use ML algorithms to predict the C/D ratio of LTG. The results here can help clinicians adjust doses of LTG administered to patients to minimize adverse reactions.

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“…Recommended warfarin stable dose algorithms are based on multiple linear regression models (Johnson et al, 2017). Given that the relationship between warfarin dose and predictor variables is complex, nonlinear modeling strategies have been tested in warfarin dose prediction (Grossi et al, 2014;Liu et al, 2015;Roche-Lima et al, 2020). Non-parametric machine learning models are potentially powerful alternatives to linear parametric models in that they lack many of the assumptions of linear regression and they are flexible enough to fit virtually any curve in the data.…”

Section: Introductionmentioning

confidence: 99%

Machine Learning for Prediction of Stable Warfarin Dose in US Latinos and Latin Americans

et al. 2021

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Populations used to create warfarin dose prediction algorithms largely lacked participants reporting Hispanic or Latino ethnicity. While previous research suggests nonlinear modeling improves warfarin dose prediction, this research has mainly focused on populations with primarily European ancestry. We compare the accuracy of stable warfarin dose prediction using linear and nonlinear machine learning models in a large cohort enriched for US Latinos and Latin Americans (ULLA). Each model was tested using the same variables as published by the International Warfarin Pharmacogenetics Consortium (IWPC) and using an expanded set of variables including ethnicity and warfarin indication. We utilized a multiple linear regression model and three nonlinear regression models: Bayesian Additive Regression Trees, Multivariate Adaptive Regression Splines, and Support Vector Regression. We compared each model’s ability to predict stable warfarin dose within 20% of actual stable dose, confirming trained models in a 30% testing dataset with 100 rounds of resampling. In all patients (n = 7,030), inclusion of additional predictor variables led to a small but significant improvement in prediction of dose relative to the IWPC algorithm (47.8 versus 46.7% in IWPC, p = 1.43 × 10−15). Nonlinear models using IWPC variables did not significantly improve prediction of dose over the linear IWPC algorithm. In ULLA patients alone (n = 1,734), IWPC performed similarly to all other linear and nonlinear pharmacogenetic algorithms. Our results reinforce the validity of IWPC in a large, ethnically diverse population and suggest that additional variables that capture warfarin dose variability may improve warfarin dose prediction algorithms.

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Machine Learning Algorithm for Predicting Warfarin Dose in Caribbean Hispanics Using Pharmacogenetic Data

Cited by 26 publications

References 20 publications

Development of a system to support warfarin dose decisions using deep neural networks

Development of a system to support warfarin dose decisions using deep neural networks

A machine learning approach to personalized dose adjustment of lamotrigine using noninvasive clinical parameters

Machine Learning for Prediction of Stable Warfarin Dose in US Latinos and Latin Americans

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