A Perspective on the Role of Computational Models in Immunology.

IF 26.9 1区 医学 Q1 IMMUNOLOGY
Annual review of immunology Pub Date : 2017-04-26 Epub Date: 2017-02-06 DOI:10.1146/annurev-immunol-041015-055325
Arup K Chakraborty
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引用次数: 33

Abstract

This is an exciting time for immunology because the future promises to be replete with exciting new discoveries that can be translated to improve health and treat disease in novel ways. Immunologists are attempting to answer increasingly complex questions concerning phenomena that range from the genetic, molecular, and cellular scales to that of organs, whole animals or humans, and populations of humans and pathogens. An important goal is to understand how the many different components involved interact with each other within and across these scales for immune responses to emerge, and how aberrant regulation of these processes causes disease. To aid this quest, large amounts of data can be collected using high-throughput instrumentation. The nonlinear, cooperative, and stochastic character of the interactions between components of the immune system as well as the overwhelming amounts of data can make it difficult to intuit patterns in the data or a mechanistic understanding of the phenomena being studied. Computational models are increasingly important in confronting and overcoming these challenges. I first describe an iterative paradigm of research that integrates laboratory experiments, clinical data, computational inference, and mechanistic computational models. I then illustrate this paradigm with a few examples from the recent literature that make vivid the power of bringing together diverse types of computational models with experimental and clinical studies to fruitfully interrogate the immune system.

计算模型在免疫学中的作用展望。
对于免疫学来说,这是一个激动人心的时刻,因为未来有望充满激动人心的新发现,这些发现可以转化为改善健康和以新颖的方式治疗疾病。免疫学家正试图回答越来越复杂的问题,涉及从遗传、分子和细胞尺度到器官、整个动物或人类、人类种群和病原体的各种现象。一个重要的目标是了解许多不同的成分是如何在这些尺度内和尺度之间相互作用以产生免疫反应的,以及这些过程的异常调节是如何导致疾病的。为了帮助实现这一目标,可以使用高通量仪器收集大量数据。免疫系统各组成部分之间相互作用的非线性、合作性和随机性,以及海量的数据,使我们很难凭直觉判断数据中的模式,也很难对正在研究的现象有一个机械的理解。计算模型在面对和克服这些挑战方面越来越重要。我首先描述了一个迭代的研究范式,它集成了实验室实验、临床数据、计算推理和机械计算模型。然后,我用最近文献中的几个例子来说明这个范例,这些例子生动地展示了将不同类型的计算模型与实验和临床研究结合起来,以有效地询问免疫系统的力量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Annual review of immunology
Annual review of immunology 医学-免疫学
CiteScore
57.20
自引率
0.70%
发文量
29
期刊介绍: The Annual Review of Immunology, in publication since 1983, focuses on basic immune mechanisms and molecular basis of immune diseases in humans. Topics include innate and adaptive immunity; immune cell development and differentiation; immune control of pathogens (viruses, bacteria, parasites) and cancer; and human immunodeficiency and autoimmune diseases. The current volume of this journal has been converted from gated to open access through Annual Reviews' Subscribe to Open program, with all articles published under a CC BY license.
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