In Silico Augmentation of the Drug Development Pipeline: Examples from the Study of Acute Inflammation

Overview

Journal Drug Dev Res

Specialty Pharmacology

Date 2011 May 10

PMID 21552346

Citations 25

Authors

Gary An

John Bartels

Yoram Vodovotz

Affiliations

Soon will be listed here.

Abstract

The clinical translation of promising basic biomedical findings, whether derived from reductionist studies in academic laboratories or as the product of extensive high-throughput and -content screens in the biotechnology and pharmaceutical industries, has reached a period of stagnation in which ever higher research and development costs are yielding ever fewer new drugs. Systems biology and computational modeling have been touted as potential avenues by which to break through this logjam. However, few mechanistic computational approaches are utilized in a manner that is fully cognizant of the inherent clinical realities in which the drugs developed through this ostensibly rational process will be ultimately used. In this article, we present a Translational Systems Biology approach to inflammation. This approach is based on the use of mechanistic computational modeling centered on inherent clinical applicability, namely that a unified suite of models can be applied to generate in silico clinical trials, individualized computational models as tools for personalized medicine, and rational drug and device design based on disease mechanism.

Citing Articles

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Cockrell C, Vodovotz Y, Zamora R, An G bioRxiv. 2024; .

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Digital twin mathematical models suggest individualized hemorrhagic shock resuscitation strategies.

Cannon J, Gruen D, Zamora R, Brostoff N, Hurst K, Harn J Commun Med (Lond). 2024; 4(1):113.

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In-Silico Approaches for the Screening and Discovery of Broad-Spectrum Marine Natural Product Antiviral Agents Against Coronaviruses.

Boswell Z, Verga J, Mackle J, Guerrero-Vazquez K, Thomas O, Cray J Infect Drug Resist. 2023; 16:2321-2338.

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Vodovotz Y Trends Immunol. 2023; 44(5):345-355.

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Utilizing the Heterogeneity of Clinical Data for Model Refinement and Rule Discovery Through the Application of Genetic Algorithms to Calibrate a High-Dimensional Agent-Based Model of Systemic Inflammation.

Cockrell C, An G Front Physiol. 2021; 12:662845.

PMID: 34093225 PMC: 8172123. DOI: 10.3389/fphys.2021.662845.

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