Wolfson Centre for Mathematical Biology, Mathematical Institute, University of Oxford, Oxford, UK.
Pharmaceutical Sciences, Clinical Pharmacology, Roche Innovation Center, Basel, Switzerland.
Clin Exp Immunol. 2018 Sep;193(3):284-292. doi: 10.1111/cei.13182.
The application of in-silico modelling is beginning to emerge as a key methodology to advance our understanding of mechanisms of disease pathophysiology and related drug action, and in the design of experimental medicine and clinical studies. From this perspective, we will present a non-technical discussion of a small number of recent and historical applications of mathematical, statistical and computational modelling to clinical and experimental immunology. We focus specifically upon mechanistic questions relating to human viral infection, tumour growth and metastasis and T cell activation. These exemplar applications highlight the potential of this approach to impact upon human immunology informed by ever-expanding experimental, clinical and 'omics' data. Despite the capacity of mechanistic modelling to accelerate therapeutic discovery and development and to de-risk clinical trial design, it is not utilized widely across the field. We outline ongoing challenges facing the integration of mechanistic modelling with experimental and clinical immunology, and suggest how these may be overcome. Advances in key technologies, including multi-scale modelling, machine learning and the wealth of 'omics' data sets, coupled with advancements in computational capacity, are providing the basis for mechanistic modelling to impact on immunotherapeutic discovery and development during the next decade.
计算建模的应用开始成为深入了解疾病病理生理学和相关药物作用机制的关键方法,并在实验医学和临床研究的设计中得到应用。从这个角度出发,我们将对数学、统计和计算建模在临床和实验免疫学中的一些近期和历史应用进行非技术性的讨论。我们特别关注与人类病毒感染、肿瘤生长和转移以及 T 细胞激活相关的机制问题。这些范例应用突出了这种方法在不断扩展的实验、临床和“组学”数据的基础上对人类免疫学产生影响的潜力。尽管机制建模具有加速治疗发现和开发以及降低临床试验设计风险的能力,但它并没有在该领域得到广泛应用。我们概述了将机制建模与实验和临床免疫学相结合所面临的持续挑战,并提出了如何克服这些挑战的建议。关键技术的进步,包括多尺度建模、机器学习和丰富的“组学”数据集,以及计算能力的提高,为机制建模在未来十年对免疫治疗的发现和开发产生影响提供了基础。