Mathematical modelling of liver regeneration after intoxication with CCl(4)
Authored by Dirk Drasdo, Stefan Hoehme, Marc Brulport, Alexander Bauer, Rolf Gebhardt, Jan G Hengstler, Marc Schaefer
Date Published: 2007
DOI: 10.1016/j.cbi.2007.01.010
Sponsors:
German Federal Ministry of Education and Research (BMBF)
Platforms:
No platforms listed
Model Documentation:
Other Narrative
Mathematical description
Model Code URLs:
Model code not found
Abstract
Liver reaerteration is a complex process, having evolved to protect
animals from the consequences of liver loss caused by food toxins. In
this study, we established a mathematical spatial-temporal model of the
liver lobule regenerating after CCI(4) intoxication. The aim of
modelling the regeneration process by matching experimental observations
with those from a mathematical model is to gain a better understanding
of the process and to recognize which parameters are relevant for
specific phenomena. In order to set up a realistic minimal model, we
first reconstructed a schematised liver lobule after determination of:
(i) the mean number of hepatocytes between the central vein and the
periphery of the lobule, (ii) the mean size of the hepatocytes and (iii)
the mean number of hepatocyte columns in the inner, midzonal and
peripheral ring of the lobule. In a next step, we determined the time
course of cell death and BrdU incorporation after intoxication of male
Sprague Dawley rats with CCI(4), thereby differentiating between inner, midzonal and peripheral hepatocytes. These parameters were used to
construct a model. The basic unit of this model is the individual cell.
The detailed behaviour of the cells is studied, controlled by the model
parameters: (1) probability of cell division at defined positions of the
lobule at a given time, (2) `' coordinated cell orientation `', i.e., the ability of the cells to align during the regeneration process into
columns towards the central vein of a liver lobule, (3) cell cycle
duration, (4) the migration activity and (5) the polarity of the
hepatocytes resulting in polar cell-cell adhesion between them. In a
schematised lobule, the model shows that CCI(4) initially induced cell
death of a pericentral ring of hepatocytes, followed by a wave of
proliferation that starts in the surviving hepatocytes next to the inner
ring of dead cells and continues to the peripheral hepatocytes, finally
restoring the characteristic micro-architecture of the lobule in a 7-day
process. This model was used to systematically analyze the influence of
parameters 1-5. Interestingly, coordinated cell orientation and cell
polarity were identified to be the most critical parameters. Elimination
led to destruction of the characteristic micro-architecture of the
lobule and to a high degree of disorder characterized by hexagonal cell
structures. Our model suggests that the ability of hepatocytes to
realign after cell division by a process of coordinated cell orientation
(model parameter 2) in combination with cell polarity (model parameter
parameter 1) itself. (C) 2007 Elsevier Ireland Ltd. All rights reserved.
Tags
Tumor-growth
In-vitro
Cells
Accumulation
Dna-base damage
Partial-hepatectomy
Rat-liver
Hepatocytes
Mouse
Vivo