Optimal villi density for maximal oxygen uptake in the human placenta

A. S. Serov; C. M. Salafia; P. Brownbill; D. S. Grebenkov; M. Filoche

doi:10.1016/j.jtbi.2014.09.022

Optimal villi density for maximal oxygen uptake in the human placenta

A. S. Serov
, C. M. Salafia
, P. Brownbill
, D. S. Grebenkov
, M. Filoche

Placental Analytics, LLC
University of Manchester
St Mary's Hospital

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

We present a stream-tube model of oxygen exchange inside a human placenta functional unit (a placentone). The effect of villi density on oxygen transfer efficiency is assessed by numerically solving the diffusion-convection equation in a 2D+1D geometry for a wide range of villi densities. For each set of physiological parameters, we observe the existence of an optimal villi density providing a maximal oxygen uptake as a trade-off between the incoming oxygen flow and the absorbing villus surface. The predicted optimal villi density 0.47±0.06 is compatible to previous experimental measurements. Several other ways to experimentally validate the model are also proposed. The proposed stream-tube model can serve as a basis for analyzing the efficiency of human placentas, detecting possible pathologies and diagnosing placental health risks for newborns by using routine histology sections collected after birth.

langue originale	Anglais
Pages (de - à)	383-396
Nombre de pages	14
journal	Journal of Theoretical Biology
Volume	364
Les DOIs	https://doi.org/10.1016/j.jtbi.2014.09.022
état	Publié - 7 janv. 2015

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10.1016/j.jtbi.2014.09.022

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title = "Optimal villi density for maximal oxygen uptake in the human placenta",

abstract = "We present a stream-tube model of oxygen exchange inside a human placenta functional unit (a placentone). The effect of villi density on oxygen transfer efficiency is assessed by numerically solving the diffusion-convection equation in a 2D+1D geometry for a wide range of villi densities. For each set of physiological parameters, we observe the existence of an optimal villi density providing a maximal oxygen uptake as a trade-off between the incoming oxygen flow and the absorbing villus surface. The predicted optimal villi density 0.47±0.06 is compatible to previous experimental measurements. Several other ways to experimentally validate the model are also proposed. The proposed stream-tube model can serve as a basis for analyzing the efficiency of human placentas, detecting possible pathologies and diagnosing placental health risks for newborns by using routine histology sections collected after birth.",

keywords = "Diffusion-convection, Human placenta model, Oxygen transfer",

author = "Serov, \{A. S.\} and Salafia, \{C. M.\} and P. Brownbill and Grebenkov, \{D. S.\} and M. Filoche",

note = "Publisher Copyright: {\textcopyright} 2014 Elsevier Ltd.",

year = "2015",

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doi = "10.1016/j.jtbi.2014.09.022",

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AU - Serov, A. S.

AU - Salafia, C. M.

AU - Brownbill, P.

AU - Grebenkov, D. S.

AU - Filoche, M.

PY - 2015/1/7

Y1 - 2015/1/7

N2 - We present a stream-tube model of oxygen exchange inside a human placenta functional unit (a placentone). The effect of villi density on oxygen transfer efficiency is assessed by numerically solving the diffusion-convection equation in a 2D+1D geometry for a wide range of villi densities. For each set of physiological parameters, we observe the existence of an optimal villi density providing a maximal oxygen uptake as a trade-off between the incoming oxygen flow and the absorbing villus surface. The predicted optimal villi density 0.47±0.06 is compatible to previous experimental measurements. Several other ways to experimentally validate the model are also proposed. The proposed stream-tube model can serve as a basis for analyzing the efficiency of human placentas, detecting possible pathologies and diagnosing placental health risks for newborns by using routine histology sections collected after birth.

AB - We present a stream-tube model of oxygen exchange inside a human placenta functional unit (a placentone). The effect of villi density on oxygen transfer efficiency is assessed by numerically solving the diffusion-convection equation in a 2D+1D geometry for a wide range of villi densities. For each set of physiological parameters, we observe the existence of an optimal villi density providing a maximal oxygen uptake as a trade-off between the incoming oxygen flow and the absorbing villus surface. The predicted optimal villi density 0.47±0.06 is compatible to previous experimental measurements. Several other ways to experimentally validate the model are also proposed. The proposed stream-tube model can serve as a basis for analyzing the efficiency of human placentas, detecting possible pathologies and diagnosing placental health risks for newborns by using routine histology sections collected after birth.

KW - Diffusion-convection

KW - Human placenta model

KW - Oxygen transfer

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DO - 10.1016/j.jtbi.2014.09.022

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SN - 0022-5193

VL - 364

SP - 383

EP - 396

JO - Journal of Theoretical Biology

JF - Journal of Theoretical Biology

ER -

Optimal villi density for maximal oxygen uptake in the human placenta

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