Prospective validation of a model‐informed precision dosing tool for vancomycin in intensive care patients

Heine, Rob ter; Keizer, Ron J.; Steeg, Krista van; Smolders, Elise J; Luin, Matthijs van; Derijks, Hieronymus J.; Jager, Cornelis P.C. de; Frenzel, Tim; Brüggemann, Roger

doi:10.1111/bcp.14360

Cited by 27 publications

(46 citation statements)

References 28 publications

(34 reference statements)

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“…A number of barriers toward the implementation of MIPD have been identified, including the lack of clinically oriented training in MIPD, the lack of acceptance of more complex dosing strategies (by prescribers), 7 unclear reimbursement, or the lack of pharmaceutical industry support 8 . Another challenge associated with MIPD is the selection of an appropriate pharmacometric model and the related fit‐for‐purpose validation required 9 …”

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confidence: 99%

A Model Averaging/Selection Approach Improves the Predictive Performance of Model‐Informed Precision Dosing: Vancomycin as a Case Study

Uster

Stocker

Carland

et al. 2020

Clin Pharma and Therapeutics

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Many important drugs exhibit substantial variability in pharmacokinetics and pharmacodynamics leading to a loss of the desired clinical outcomes or significant adverse effects. Forecasting drug exposures using pharmacometric models can improve individual target attainment when compared with conventional therapeutic drug monitoring (TDM). However, selecting the 'correct' model for this model-informed precision dosing (MIPD) is challenging. We derived and evaluated a model selection algorithm (MSA) and a model averaging algorithm (MAA), which automates model selection and finds the best model or combination of models for each patient using vancomycin as a case study, and implemented both algorithms in the MIPD software 'TDMx'. The predictive performance (based on accuracy and precision) of the two algorithms was assessed in (i) a simulation study of six distinct populations and (ii) a clinical dataset of 180 patients undergoing TDM during vancomycin treatment and compared with the performance obtained using a single model. Throughout the six virtual populations the MSA and MAA (imprecision: 9.9-24.2%, inaccuracy: less than ±8.2%) displayed more accurate predictions than the single models (imprecision: 8.9-51.1%; inaccuracy: up to 28.9%).In the clinical dataset the predictive performance of the single models applying at least one plasma concentration varied substantially (imprecision: 28-62%, inaccuracy:-16-25%), while the MSA or MAA utilizing these models simultaneously, resulted in unbiased and precise predictions (imprecision: 29% and 30%, inaccuracy:-5% and 0%, respectively). MSA and MAA approaches implemented in 'TDMx' might thereby lower the burden of fit-for-purpose validation of individual models and streamline MIPD.

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confidence: 99%

A Model Averaging/Selection Approach Improves the Predictive Performance of Model‐Informed Precision Dosing: Vancomycin as a Case Study

Uster

Stocker

Carland

et al. 2020

Clin Pharma and Therapeutics

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“…The observed precision (50% prediction error interval ranging from −5.0 mg/L (−59%) to 1.2 mg/L (32%)) was judged to be acceptable for a critically ill patient population based on retrospective data from clinical routines. Compared to a prospective dataset collected in a controlled clinical trial, retrospective data collected during clinical routine is associated with a higher degree of uncertainty [ 32 ], which can inflate the observed imprecision in the model evaluation. The comparison of our results to previously published evaluations of meropenem models in critically ill patients further confirms the suitability of the investigated PK model: D’Haese et al evaluated eight meropenem population PK models in critically ill patients receiving meropenem as continuous infusion [ 31 ].…”

Section: Discussionmentioning

confidence: 99%

Evaluation of the MeroRisk Calculator, A User-Friendly Tool to Predict the Risk of Meropenem Target Non-Attainment in Critically Ill Patients

et al. 2021

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Background: The MeroRisk-calculator, an easy-to-use tool to determine the risk of meropenem target non-attainment after standard dosing (1000 mg; q8h), uses a patient’s creatinine clearance and the minimum inhibitory concentration (MIC) of the pathogen. In clinical practice, however, the MIC is rarely available. The objectives were to evaluate the MeroRisk-calculator and to extend risk assessment by including general pathogen sensitivity data. Methods: Using a clinical routine dataset (155 patients, 891 samples), a direct data-based evaluation was not feasible. Thus, in step 1, the performance of a pharmacokinetic model was determined for predicting the measured concentrations. In step 2, the PK model was used for a model-based evaluation of the MeroRisk-calculator: risk of target non-attainment was calculated using the PK model and agreement with the MeroRisk-calculator was determined by a visual and statistical (Lin’s concordance correlation coefficient (CCC)) analysis for MIC values 0.125–16 mg/L. The MeroRisk-calculator was extended to include risk assessment based on EUCAST-MIC distributions and cumulative-fraction-of-response analysis. Results: Step 1 showed a negligible bias of the PK model to underpredict concentrations (−0.84 mg/L). Step 2 revealed a high level of agreement between risk of target non-attainment predictions for creatinine clearances >50 mL/min (CCC = 0.990), but considerable deviations for patients <50 mL/min. For 27% of EUCAST-listed pathogens the median cumulative-fraction-of-response for the observed patients receiving standard dosing was < 90%. Conclusions: The MeroRisk-calculator was successfully evaluated: For patients with maintained renal function it allows a reliable and user-friendly risk assessment. The integration of pathogen-based risk assessment substantially increases the applicability of the tool.

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“…Jasmine H. Hughes 1, *, Dominic M. H. Tong 1 , Sarah Scarpace Lucas 2 , Jonathan D. Faldasz 1 , Srijib Goswami 1 and Ron J. Keizer 2 Model-informed precision dosing (MIPD) leverages pharmacokinetic (PK) models to tailor dosing to an individual patient's needs, improving attainment of therapeutic drug exposure targets and thus potentially improving drug efficacy or reducing adverse events.…”

Section: Continuous Learning In Model-informed Precision Dosing: a Camentioning

confidence: 99%

“…Naive application of a previously published model could introduce bias or imprecision in dose selection. Developing a new model or validating existing models for each new patient population requires a sufficiently large prior data set collected from a sufficiently diverse group of patients and ideally from multiple institutions, and is time‐consuming 1,18 . These efforts could delay implementation of MIPD in a particular clinical site, which comes with its own risks of drug overexposure or underexposure.…”

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confidence: 99%

“…Pharmacokinetic (PK) models have been brought to the point of care, aided by development and deployment of software tools that allow clinicians to estimate their patients’ PK parameters and simulate dosing regimens 1–3 . Preliminary studies suggest that this model‐informed precision dosing (MIPD) facilitates attainment of therapeutic targets, reduces drug‐induced adverse events, and improves clinical outcomes 4–6 .…”

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confidence: 99%

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Continuous Learning in Model‐Informed Precision Dosing: A Case Study in Pediatric Dosing of Vancomycin

Hughes¹,

Tong²,

Lucas

et al. 2020

Clin Pharma and Therapeutics

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Prospective validation of a model‐informed precision dosing tool for vancomycin in intensive care patients

Cited by 27 publications

References 28 publications

A Model Averaging/Selection Approach Improves the Predictive Performance of Model‐Informed Precision Dosing: Vancomycin as a Case Study

A Model Averaging/Selection Approach Improves the Predictive Performance of Model‐Informed Precision Dosing: Vancomycin as a Case Study

Evaluation of the MeroRisk Calculator, A User-Friendly Tool to Predict the Risk of Meropenem Target Non-Attainment in Critically Ill Patients

Continuous Learning in Model‐Informed Precision Dosing: A Case Study in Pediatric Dosing of Vancomycin

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