Detail publikace

Comparison of the ATH and 2CXM models using low- and high-molecular-weight contrast agents in DCE-MRI

Originální název

Comparison of the ATH and 2CXM models using low- and high-molecular-weight contrast agents in DCE-MRI

Anglický název

Comparison of the ATH and 2CXM models using low- and high-molecular-weight contrast agents in DCE-MRI

Jazyk

en

Originální abstrakt

In DCE-MRI, tissue contrast-agent (CA) concentration curves are modeled as a convolution of the arterial input function (AIF) and the impulse residue function (IRF). The 2CXM and ATH models are the most widely used advanced IRF models that provide separate estimates of blood flow, Fb, and permeability-surface area product, PS, contrary to the commonly applied Tofts models. No consensus exists on which advanced pharmacokinetic model is better. Simulation-based and blind-deconvolution-based preclinical model comparisons are published. This contribution presents a new model-evaluation method based on high- and low-molecular weight (MW) contrast-agents administered within one examination. Some perfusion parameters are expected to be MW-independent (namely Fb and blood volume—vb), while PS should decrease with increasing MW.

Anglický abstrakt

In DCE-MRI, tissue contrast-agent (CA) concentration curves are modeled as a convolution of the arterial input function (AIF) and the impulse residue function (IRF). The 2CXM and ATH models are the most widely used advanced IRF models that provide separate estimates of blood flow, Fb, and permeability-surface area product, PS, contrary to the commonly applied Tofts models. No consensus exists on which advanced pharmacokinetic model is better. Simulation-based and blind-deconvolution-based preclinical model comparisons are published. This contribution presents a new model-evaluation method based on high- and low-molecular weight (MW) contrast-agents administered within one examination. Some perfusion parameters are expected to be MW-independent (namely Fb and blood volume—vb), while PS should decrease with increasing MW.

BibTex


@inproceedings{BUT142781,
  author="Radovan {Jiřík} and Torfinn {Taxt} and Jiří {Kratochvíla} and Ondřej {Macíček} and Eva {Dražanová} and Zenon {Starčuk}",
  title="Comparison of the ATH and 2CXM models using low- and high-molecular-weight contrast agents in DCE-MRI",
  annote="In DCE-MRI, tissue contrast-agent (CA) concentration curves are modeled as a convolution of the arterial input function (AIF) and the impulse residue function (IRF). The 2CXM and ATH models are the most widely used advanced IRF models that provide separate estimates of blood flow, Fb, and permeability-surface area product, PS, contrary to the commonly applied Tofts models. No consensus exists on which advanced pharmacokinetic model is better. Simulation-based and blind-deconvolution-based preclinical model comparisons are published. This contribution presents a new model-evaluation method based on high- and low-molecular weight (MW) contrast-agents administered within one examination. Some perfusion parameters are expected to
be MW-independent (namely Fb and blood volume—vb), while PS should decrease with increasing MW.",
  booktitle="MAGMA",
  chapter="142781",
  doi="10.1007/s10334-016-0571-2",
  howpublished="online",
  number="S1",
  year="2016",
  month="january",
  pages="447--448",
  type="conference paper"
}