Abstract
The design of efficient combination therapies is a difficult key challenge in the treatment of complex diseases such as cancers. The large heterogeneity of cancers and the large number of available drugs renders exhaustive in vivo or even in vitro investigation of possible treatments impractical. In recent years, sophisticated mechanistic, ordinary differential equation-based pathways models that can predict treatment responses at a molecular level have been developed. However, surprisingly little effort has been put into leveraging these models to find novel therapies. In this paper we use for the first time, to our knowledge, a large-scale state-of-the-art pan-cancer signaling pathway model to identify candidates for novel combination therapies to treat individual cancer cell lines from various tissues (e.g., minimizing proliferation while keeping dosage low to avoid adverse side effects) and populations of heterogeneous cancer cell lines (e.g., minimizing the maximum or average proliferation across the cell lines while keeping dosage low). We also show how our method can be used to optimize the drug combinations used in sequential treatment plans—that is, optimized sequences of potentially different drug combinations—providing additional benefits. In order to solve the treatment optimization problems, we combine the Covariance Matrix Adaptation Evolution Strategy (CMA-ES) algorithm with a significantly more scalable sampling scheme for truncated Gaussian distributions, based on a Hamiltonian Monte-Carlo method. These optimization techniques are independent of the signaling pathway model, and can thus be adapted to find treatment candidates for other complex diseases than cancers as well, as long as a suitable predictive model is available.
Highlights
Rational design of combination therapies is a difficult but important challenge in the treatment of complex diseases such as cancers [1,2,3,4,5,6]
We evaluate the effectiveness of the combination therapy candidates identified by the modified Covariance Matrix Adaptation Evolution Strategy (CMA-ES) algorithm for the three treatment settings
The objective function defined by Eq (4) is used to find drug combinations that minimize the maximum relative proliferation value predicted by the pathway model over sets of cell lines originating from skin (CMelanoma), large-intestine (CColorectal), pancreas (CPancreatic), and breast (CBreast) tissues, respectively
Summary
Rational design of combination therapies is a difficult but important challenge in the treatment of complex diseases such as cancers [1,2,3,4,5,6]. Computational models that enable—even individualized—prediction of drug sensitivity have to be employed [7]. To this end, sophisticated mechanistic, ordinary differential equation (ODE) models for drug sensitivity prediction have been developed [8,9,10,11,12,13,14]. Little effort has been put towards using these models to design treatments. Only the temporal aspect of when to administer drugs [15, 16] is considered, but not which drugs to pick
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