From Therapeutic Drug Monitoring to Model‐Informed Precision Dosing for Antibiotics

Therapeutic drug monitoring (TDM) and model‐informed precision dosing (MIPD) have evolved as important tools to inform rational dosing of antibiotics in individual patients with infections. In particular, critically ill patients display altered, highly variable pharmacokinetics and often suffer from...

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Veröffentlicht in:Clinical pharmacology and therapeutics Jg. 109; H. 4; S. 928 - 941
Hauptverfasser: Wicha, Sebastian G., Märtson, Anne‐Grete, Nielsen, Elisabet I., Koch, Birgit C.P., Friberg, Lena E., Alffenaar, Jan‐Willem, Minichmayr, Iris K.
Format: Journal Article
Sprache:Englisch
Veröffentlicht: United States 01.04.2021
ISSN:0009-9236, 1532-6535, 1532-6535
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Abstract Therapeutic drug monitoring (TDM) and model‐informed precision dosing (MIPD) have evolved as important tools to inform rational dosing of antibiotics in individual patients with infections. In particular, critically ill patients display altered, highly variable pharmacokinetics and often suffer from infections caused by less susceptible bacteria. Consequently, TDM has been used to individualize dosing in this patient group for many years. More recently, there has been increasing research on the use of MIPD software to streamline the TDM process, which can increase the flexibility and precision of dose individualization but also requires adequate model validation and re‐evaluation of existing workflows. In parallel, new minimally invasive and noninvasive technologies such as microneedle‐based sensors are being developed, which—together with MIPD software—have the potential to revolutionize how patients are dosed with antibiotics. Nonetheless, carefully designed clinical trials to evaluate the benefit of TDM and MIPD approaches are still sparse, but are critically needed to justify the implementation of TDM and MIPD in clinical practice. The present review summarizes the clinical pharmacology of antibiotics, conventional TDM and MIPD approaches, and evidence of the value of TDM/MIPD for aminoglycosides, beta‐lactams, glycopeptides, and linezolid, for which precision dosing approaches have been recommended.
AbstractList Therapeutic drug monitoring (TDM) and model-informed precision dosing (MIPD) have evolved as important tools to inform rational dosing of antibiotics in individual patients with infections. In particular, critically ill patients display altered, highly variable pharmacokinetics and often suffer from infections caused by less susceptible bacteria. Consequently, TDM has been used to individualize dosing in this patient group for many years. More recently, there has been increasing research on the use of MIPD software to streamline the TDM process, which can increase the flexibility and precision of dose individualization but also requires adequate model validation and re-evaluation of existing workflows. In parallel, new minimally invasive and noninvasive technologies such as microneedle-based sensors are being developed, which-together with MIPD software-have the potential to revolutionize how patients are dosed with antibiotics. Nonetheless, carefully designed clinical trials to evaluate the benefit of TDM and MIPD approaches are still sparse, but are critically needed to justify the implementation of TDM and MIPD in clinical practice. The present review summarizes the clinical pharmacology of antibiotics, conventional TDM and MIPD approaches, and evidence of the value of TDM/MIPD for aminoglycosides, beta-lactams, glycopeptides, and linezolid, for which precision dosing approaches have been recommended.Therapeutic drug monitoring (TDM) and model-informed precision dosing (MIPD) have evolved as important tools to inform rational dosing of antibiotics in individual patients with infections. In particular, critically ill patients display altered, highly variable pharmacokinetics and often suffer from infections caused by less susceptible bacteria. Consequently, TDM has been used to individualize dosing in this patient group for many years. More recently, there has been increasing research on the use of MIPD software to streamline the TDM process, which can increase the flexibility and precision of dose individualization but also requires adequate model validation and re-evaluation of existing workflows. In parallel, new minimally invasive and noninvasive technologies such as microneedle-based sensors are being developed, which-together with MIPD software-have the potential to revolutionize how patients are dosed with antibiotics. Nonetheless, carefully designed clinical trials to evaluate the benefit of TDM and MIPD approaches are still sparse, but are critically needed to justify the implementation of TDM and MIPD in clinical practice. The present review summarizes the clinical pharmacology of antibiotics, conventional TDM and MIPD approaches, and evidence of the value of TDM/MIPD for aminoglycosides, beta-lactams, glycopeptides, and linezolid, for which precision dosing approaches have been recommended.
Therapeutic drug monitoring (TDM) and model‐informed precision dosing (MIPD) have evolved as important tools to inform rational dosing of antibiotics in individual patients with infections. In particular, critically ill patients display altered, highly variable pharmacokinetics and often suffer from infections caused by less susceptible bacteria. Consequently, TDM has been used to individualize dosing in this patient group for many years. More recently, there has been increasing research on the use of MIPD software to streamline the TDM process, which can increase the flexibility and precision of dose individualization but also requires adequate model validation and re‐evaluation of existing workflows. In parallel, new minimally invasive and noninvasive technologies such as microneedle‐based sensors are being developed, which—together with MIPD software—have the potential to revolutionize how patients are dosed with antibiotics. Nonetheless, carefully designed clinical trials to evaluate the benefit of TDM and MIPD approaches are still sparse, but are critically needed to justify the implementation of TDM and MIPD in clinical practice. The present review summarizes the clinical pharmacology of antibiotics, conventional TDM and MIPD approaches, and evidence of the value of TDM/MIPD for aminoglycosides, beta‐lactams, glycopeptides, and linezolid, for which precision dosing approaches have been recommended.
Author Wicha, Sebastian G.
Minichmayr, Iris K.
Märtson, Anne‐Grete
Friberg, Lena E.
Nielsen, Elisabet I.
Koch, Birgit C.P.
Alffenaar, Jan‐Willem
Author_xml – sequence: 1
  givenname: Sebastian G.
  surname: Wicha
  fullname: Wicha, Sebastian G.
  email: sebastian.wicha@uni-hamburg.de
  organization: University of Hamburg
– sequence: 2
  givenname: Anne‐Grete
  surname: Märtson
  fullname: Märtson, Anne‐Grete
  organization: University of Groningen
– sequence: 3
  givenname: Elisabet I.
  surname: Nielsen
  fullname: Nielsen, Elisabet I.
  organization: Uppsala University
– sequence: 4
  givenname: Birgit C.P.
  surname: Koch
  fullname: Koch, Birgit C.P.
  organization: University Medical Center Rotterdam
– sequence: 5
  givenname: Lena E.
  surname: Friberg
  fullname: Friberg, Lena E.
  organization: Uppsala University
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  surname: Alffenaar
  fullname: Alffenaar, Jan‐Willem
  organization: Westmead Hospital
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  givenname: Iris K.
  surname: Minichmayr
  fullname: Minichmayr, Iris K.
  organization: Uppsala University
BackLink https://www.ncbi.nlm.nih.gov/pubmed/33565627$$D View this record in MEDLINE/PubMed
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2011; 33
2006
2018; 62
2020; 33
2003
2020; 77
2007; 51
2012; 34
2016; 16
1976; 4
2016; 12
2015; 350
2017; 50
1991; 27
2020; 75
2019; 41
2019; 85
2013; 32
2019; 44
2020
2004; 58
2017; 56
2020; 26
2016; 63
2017; 19
2020; 24
2016; 60
2017; 101
2021; 60
2007; 44
2016; 8
2014; 77
2014; 33
2018; 57
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Snippet Therapeutic drug monitoring (TDM) and model‐informed precision dosing (MIPD) have evolved as important tools to inform rational dosing of antibiotics in...
Therapeutic drug monitoring (TDM) and model-informed precision dosing (MIPD) have evolved as important tools to inform rational dosing of antibiotics in...
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Title From Therapeutic Drug Monitoring to Model‐Informed Precision Dosing for Antibiotics
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fcpt.2202
https://www.ncbi.nlm.nih.gov/pubmed/33565627
https://www.proquest.com/docview/2488199720
Volume 109
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