A Patient-Specific in silico Model of Inflammation and Healing Tested in Acute Vocal Fold Injury

Li, Nicole Y. K.; Verdolini, Katherine; Clermont, Gilles; Mi, Qi; Rubinstein, Elaine N.; Hebda, Patricia A.; Vodovotz, Yoram

doi:10.1371/journal.pone.0002789

Cited by 100 publications

(125 citation statements)

References 82 publications

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“…A complementary in silico approach has the unique advantage of providing focused and time-efficient integration and analysis of the available literature data, with the capability of generating experimentally testable hypotheses to expedite the investigative process. Although a number of mathematical models recently have been developed and applied to study inflammation (23)(24)(25)(26)(27)(28)(29)(30)(31)(32)(33), their limited scope and focus predominantly on qualitative representations of inflammation dynamics generally restrict their ability to provide accurate interpretations of existing data sets and generate (semi)quantitative hypotheses. In this article, we introduce a kinetic, inherently quantitative computational model of inflammation whose parameters were derived directly from in vitro data.…”

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confidence: 99%

Computational Approach To Characterize Causative Factors and Molecular Indicators of Chronic Wound Inflammation

Nagaraja

Wallqvist

Reifman

et al. 2014

The Journal of Immunology

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Chronic inflammation is rapidly becoming recognized as a key contributor to numerous pathologies. Despite detailed investigations, understanding of the molecular mechanisms regulating inflammation is incomplete. Knowledge of such critical regulatory processes and informative indicators of chronic inflammation is necessary for efficacious therapeutic interventions and diagnostic support to clinicians. We used a computational modeling approach to elucidate the critical factors responsible for chronic inflammation and to identify robust molecular indicators of chronic inflammatory conditions. Our kinetic model successfully captured experimentally observed cell and cytokine dynamics for both acute and chronic inflammatory responses. Using sensitivity analysis, we identified macrophage influx and efflux rate modulation as the strongest inducing factor of chronic inflammation for a wide range of scenarios. Moreover, our model predicted that, among all major inflammatory mediators, IL-6, TGF-β, and PDGF may generally be considered the most sensitive and robust indicators of chronic inflammation, which is supported by existing, but limited, experimental evidence.

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confidence: 99%

Computational Approach To Characterize Causative Factors and Molecular Indicators of Chronic Wound Inflammation

Nagaraja

Wallqvist

Reifman

et al. 2014

The Journal of Immunology

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“…39 A NetLogo-based ABM of the inflammatory reaction to acute phonotrauma was generated and calibrated to individual subjects' mediator levels (from laryngeal secretions) before and after acute phonotrauma. 36 Subjects then underwent one of several treatment strategies: rest, resonant voice exercises, or spontaneous speech. The ABM was able to recapitulate observed dynamics and to accurately predict mediator levels at time points beyond those used for calibration.…”

Section: Resultsmentioning

confidence: 99%

“…After validating the behaviors observed in the models, they have been used to make predictions [36][37][38] and as a surrogate system for testing potential wound-healing strategies and products. Sensitivity analysis, a measure of which parameters account for the greatest amount of the variance in the model's output, allowed both pressure ulcer models to identify areas of high vulnerability in each model, thus suggesting mechanisms that might be particularly susceptible to interventions.…”

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confidence: 99%

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Computational Modeling of Inflammation and Wound Healing

Ziraldo

et al. 2013

Advances in Wound Care

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Objective: Inflammation is both central to proper wound healing and a key driver of chronic tissue injury via a positive-feedback loop incited by incidental cell damage. We seek to derive actionable insights into the role of inflammation in wound healing in order to improve outcomes for individual patients. Approach: To date, dynamic computational models have been used to study the time evolution of inflammation in wound healing. Emerging clinical data on histo-pathological and macroscopic images of evolving wounds, as well as noninvasive measures of blood flow, suggested the need for tissue-realistic, agent-based, and hybrid mechanistic computational simulations of inflammation and wound healing. Innovation: We developed a computational modeling system, Simple Platform for Agent-based Representation of Knowledge, to facilitate the construction of tissue-realistic models. Results: A hybrid equation-agent-based model (ABM) of pressure ulcer formation in both spinal cord-injured and -uninjured patients was used to identify control points that reduce stress caused by tissue ischemia/reperfusion. An ABM of arterial restenosis revealed new dynamics of cell migration during neointimal hyperplasia that match histological features, but contradict the currently prevailing mechanistic hypothesis. ABMs of vocal fold inflammation were used to predict inflammatory trajectories in individuals, possibly allowing for personalized treatment. Conclusions: The intertwined inflammatory and wound healing responses can be modeled computationally to make predictions in individuals, simulate therapies, and gain mechanistic insights. INTRODUCTIONWound healing is a complex process that is initiated and driven by inflammation.1,2 The first phase of the wound healing response involves the degranulation of platelets and infiltration of inflammatory cells, followed by proliferation of fibroblasts and epithelial cells that deposit collagen and cause contraction of wounds. Inflammatory mediators such as tumor necrosis factor alpha (TNF-a), 3 interferon-c, 4 interleukin (IL)-6, 5 IL-10, 6 transforming growth factor beta-1 (TGF-b1), 7 and nitric oxide 8,9 modulate the wound-healing response. Wound healing is well studied in animal systems. 10,11 However, even though some experimental methodologies are emerging that may allow for the study of time courses of wound healing in humans, 11 it is difficult to collect time courses of primary samples from humans suffering from chronic wound-healing diseases without disturbing the very process which is being measured. An alternative method for studying such a complex, clinically realistic system is to use a mechanistic computational model based on literature knowledge, which could be validated experimentally or clinically, which, in turn, may have applications in diagnosing/predicting wound healing trajectories of individuals or possibly in the design of novel therapeutic modalities for wound healing. Extensive work has gone into computational studies of wound healing, spanning many stages of this proces...

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“…While systems pharmacology approaches have been successfully applied to tackle key issues in oncology, for instance, with the use of an integrative systems approach to quantify anticancer drug synergy in imatinib‐resistant chronic myeloid leukemia,25 clinical trials in oncology still have the highest failure rate in comparison to other therapeutic areas 26. In complex processes such as tumor formation, probing targetable mechanisms can be difficult owing to variability arising on multiple scales; cancerous cells adapt at genetic and molecular scales to survive in ever‐changing environments, altering cellular phenotypes and therefore treatment efficacy, as documented in studies of the hypoxic environment in tumor centers 27, 28, 29.…”

Section: Agent‐based Models: Introduction and Applicationsmentioning

confidence: 99%

Agent-Based Modeling in Systems Pharmacology

Cosgrove

Butler

Alden

et al. 2015

CPT Pharmacometrics Syst. Pharmacol.

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Modeling and simulation (M&S) techniques provide a platform for knowledge integration and hypothesis testing to gain insights into biological systems that would not be possible a priori. Agent‐based modeling (ABM) is an M&S technique that focuses on describing individual components rather than homogenous populations. This tutorial introduces ABM to systems pharmacologists, using relevant case studies to highlight how ABM‐specific strengths have yielded success in the area of preclinical mechanistic modeling.

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A Patient-Specific in silico Model of Inflammation and Healing Tested in Acute Vocal Fold Injury

Cited by 100 publications

References 82 publications

Computational Approach To Characterize Causative Factors and Molecular Indicators of Chronic Wound Inflammation

Computational Approach To Characterize Causative Factors and Molecular Indicators of Chronic Wound Inflammation

Computational Modeling of Inflammation and Wound Healing

Agent-Based Modeling in Systems Pharmacology

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