Modeling principles for a physiology-based whole-body model of human metabolism

Laura Hjort Blicher; Peter Emil Carstensen; Jacob Bendsen; Henrik Linden; Bjørn Hald; Kim Kristensen; John Bagterp Jørgensen

doi:10.1016/j.ifacol.2024.10.014

Modeling principles for a physiology-based whole-body model of human metabolism

Laura Hjort Blicher, Peter Emil Carstensen, Jacob Bendsen, Henrik Linden, Bjørn Hald, Kim Kristensen, John Bagterp Jørgensen

Novo Nordisk A/S

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Abstract

Physiological whole-body models are valuable tools for the development of novel drugs where understanding the system aspects is important. This paper presents a generalized model that encapsulates the structure and flow of whole-body human physiology. The model contains vascular, interstitial, and cellular subcompartments for each organ. Scaling of volumes and blood flows is described to allow for investigation across populations or specific patient groups. The model equations and the corresponding parameters are presented along with a catalog of functions that can be used to define the organ transport model and the biochemical reaction model. A simple example illustrates the procedure.

Original language	English
Book series	IFAC-PapersOnLine
Volume	58
Issue number	23
Pages (from-to)	79-84
ISSN	2405-8971
DOIs	https://doi.org/10.1016/j.ifacol.2024.10.014
Publication status	Published - 2024
Event	10th IFAC Conference on Foundations of Systems Biology in Engineering - Corfu Island, Greece Duration: 8 Sept 2024 → 11 Sept 2024

Conference

Conference	10th IFAC Conference on Foundations of Systems Biology in Engineering
Country/Territory	Greece
City	Corfu Island
Period	08/09/2024 → 11/09/2024

Bibliographical note

Publisher Copyright:
© 2024 The Authors.

Keywords

Differential equations
Human Physiology
PBPK
Quantitative Systems Biology (QSB)
Quantitative Systems Pharmacology (QSP)
Simulation
Whole-body model

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10.1016/j.ifacol.2024.10.014Licence: CC BY-NC-ND

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title = "Modeling principles for a physiology-based whole-body model of human metabolism",

abstract = "Physiological whole-body models are valuable tools for the development of novel drugs where understanding the system aspects is important. This paper presents a generalized model that encapsulates the structure and flow of whole-body human physiology. The model contains vascular, interstitial, and cellular subcompartments for each organ. Scaling of volumes and blood flows is described to allow for investigation across populations or specific patient groups. The model equations and the corresponding parameters are presented along with a catalog of functions that can be used to define the organ transport model and the biochemical reaction model. A simple example illustrates the procedure.",

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doi = "10.1016/j.ifacol.2024.10.014",

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AU - Blicher, Laura Hjort

AU - Carstensen, Peter Emil

AU - Bendsen, Jacob

AU - Linden, Henrik

AU - Hald, Bjørn

AU - Kristensen, Kim

AU - Jørgensen, John Bagterp

PY - 2024

Y1 - 2024

N2 - Physiological whole-body models are valuable tools for the development of novel drugs where understanding the system aspects is important. This paper presents a generalized model that encapsulates the structure and flow of whole-body human physiology. The model contains vascular, interstitial, and cellular subcompartments for each organ. Scaling of volumes and blood flows is described to allow for investigation across populations or specific patient groups. The model equations and the corresponding parameters are presented along with a catalog of functions that can be used to define the organ transport model and the biochemical reaction model. A simple example illustrates the procedure.

AB - Physiological whole-body models are valuable tools for the development of novel drugs where understanding the system aspects is important. This paper presents a generalized model that encapsulates the structure and flow of whole-body human physiology. The model contains vascular, interstitial, and cellular subcompartments for each organ. Scaling of volumes and blood flows is described to allow for investigation across populations or specific patient groups. The model equations and the corresponding parameters are presented along with a catalog of functions that can be used to define the organ transport model and the biochemical reaction model. A simple example illustrates the procedure.

KW - Differential equations

KW - Human Physiology

KW - PBPK

KW - Quantitative Systems Biology (QSB)

KW - Quantitative Systems Pharmacology (QSP)

KW - Simulation

KW - Whole-body model

U2 - 10.1016/j.ifacol.2024.10.014

DO - 10.1016/j.ifacol.2024.10.014

M3 - Conference article

AN - SCOPUS:85208553099

SN - 2405-8971

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SP - 79

EP - 84

JO - IFAC-PapersOnLine

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T2 - 10th IFAC Conference on Foundations of Systems Biology in Engineering

Y2 - 8 September 2024 through 11 September 2024

ER -

Modeling principles for a physiology-based whole-body model of human metabolism

Abstract

Conference

Bibliographical note

Keywords

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