Immunophysical analysis of corneal neovascularization: mechanistic insights and implications for pharmacotherapy

Youness Azimzade,Jiaxu Hong,Alireza Mashaghi

doi:10.1038/s41598-017-12533-x

Youness Azimzade, Jiaxu Hong + Show 1 more

Open Access

https://doi.org/10.1038/s41598-017-12533-x

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Abstract

The cornea lacks adaptive immune cells and vasculature under healthy conditions, but is populated by both cell types under pathologic conditions and after transplantation. Here we propose an immunophysical approach to describe postoperative neovascularization in corneal grafts. We develop a simple dynamic model that captures not only the well-established interactions between innate immunity and vascular dynamics but also incorporates the contributions of adaptive immunity to vascular growth. We study how these interactions determine dynamic changes and steady states of the system as well as the clinical outcome, i.e. graft survival. The model allows us to systematically explore the impact of pharmacological inhibitors of vascular growth on the function and survival of transplanted corneas and search for the optimal time to initiatetherapy. Predictions from our models will help ongoing efforts to design therapeutic approaches to modulate alloimmunity and suppress allograft rejection.

Highlights

Life of a multicellular organism is a relationship among cells and not a property of any one cell[1]
Dynamics of the immune system have been subject to many previous studies[15,16,17]; vascular growth and regression has been modeled previously[18,19,20]; yet the interactions between immunity and vasculature have not been thoroughly studied in the past and in particular the recently discovered contribution of adaptive immunity and associated inflammation to vascular dynamics[21] has not been integrated into previous models
We find that systems with larger pre-existing blood vessels, VBI (or VL(0)) have larger amounts of blood vessels, VB when evaluated several weeks post-transplantation

Summary

Introduction

Life of a multicellular organism is a relationship among cells and not a property of any one cell[1]. We take modeling approaches that incorporate the interactions between vessels and immune cells to develop a mechanistic understanding of the non-monotonic dynamics observed in various corneal graft settings. Pre-existing vessels are known to increase the risk of corneal graft rejection by the immune system[22].

Results

Conclusion