Introduction of a framework for dynamic knowledge representation of the control structure of transplant immunology: employing the power of abstraction with a solid organ transplant agent-based model
Authored by Gary An
Date Published: 2015
DOI: 10.3389/fimmu.2015.00561
Sponsors:
United States National Institutes of Health (NIH)
Platforms:
NetLogo
Model Documentation:
Other Narrative
Model Code URLs:
Model code not found
Abstract
Agent-based modeling has been used to characterize the nested control
loops and non-linear dynamics associated with inflammatory and immune
responses, particularly as a means of visualizing putative mechanistic
hypotheses. This process is termed dynamic knowledge representation and
serves a critical role in facilitating the ability to test and
potentially falsify hypotheses in the current data-and hypothesis-rich
biomedical research environment. Importantly, dynamic computational
modeling aids in identifying useful abstractions, a fundamental
scientific principle that pervades the physical sciences. Recognizing
the critical scientific role of abstraction provides an intellectual and
methodological counterweight to the tendency in biology to emphasize
comprehensive description as the primary manifestation of biological
knowledge. Transplant immunology represents yet another example of the
challenge of identifying sufficient understanding of the
inflammatory/immune response in order to develop and refine clinically
effective interventions. Advances in immunosuppressive therapies have
greatly improved solid organ transplant (SOT) outcomes, most notably by
reducing and treating acute rejection. The end goal of these transplant
immune strategies is to facilitate effective control of the balance
between regulatory T cells and the effector/cytotoxic T-cell populations
in order to generate, and ideally maintain, a tolerant phenotype.
Characterizing the dynamics of immune cell populations and the
interactive feedback loops that lead to graft rejection or tolerance is
extremely challenging, but is necessary if rational modulation to induce
transplant tolerance is to be accomplished. Herein is presented the
solid organ agent-based model (SOTABM) as an initial example of an
agent-based model (ABM) that abstractly reproduces the cellular and
molecular components of the immune response to SOT. Despite its abstract
nature, the SOTABM is able to qualitatively reproduce acute rejection
and the suppression of acute rejection by immunosuppression to generate
transplant tolerance. The SOTABM is intended as an initial example of
how ABMs can be used to dynamically represent mechanistic knowledge
concerning transplant immunology in a scalable and expandable form and
can thus potentially serve as useful adjuncts to the investigation and
development of control strategies to induce transplant tolerance.
Tags
Simulation
Immune-system
Clinical-trials
In-silico
Mesenchymal stromal cells
T-cells
Antithymocyte globulin
Graft-survival
Cyclosporine-a
Tumor-model