Notions of Similarity for Systems Biology Models

Overview

Journal Brief Bioinform

Publisher Oxford University Press

Specialty Biology

Date 2016 Oct 16

PMID 27742665

Citations 10

Authors

Ron Henkel

Robert Hoehndorf

Tim Kacprowski

Christian Knupfer

Wolfram Liebermeister

Dagmar Waltemath

Affiliations

Soon will be listed here.

Abstract

Systems biology models are rapidly increasing in complexity, size and numbers. When building large models, researchers rely on software tools for the retrieval, comparison, combination and merging of models, as well as for version control. These tools need to be able to quantify the differences and similarities between computational models. However, depending on the specific application, the notion of 'similarity' may greatly vary. A general notion of model similarity, applicable to various types of models, is still missing. Here we survey existing methods for the comparison of models, introduce quantitative measures for model similarity, and discuss potential applications of combined similarity measures. To frame model comparison as a general problem, we describe a theoretical approach to defining and computing similarities based on a combination of different model aspects. The six aspects that we define as potentially relevant for similarity are underlying encoding, references to biological entities, quantitative behaviour, qualitative behaviour, mathematical equations and parameters and network structure. We argue that future similarity measures will benefit from combining these model aspects in flexible, problem-specific ways to mimic users' intuition about model similarity, and to support complex model searches in databases.

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