Process Algebra with Layers: Multi-scale Integration Modelling Applied to Cancer Therapy

Research output: Chapter in Book/Report/Conference proceedingChapter

1 Citation (Scopus)

Abstract

We present a novel Process Algebra designed for multi-scale integration modelling: Process Algebra with Layers (PAL). The unique feature of PAL is the modularisation of scale into integrated layers: Object and Population. An Object can represent a molecule, organelle, cell, tissue, organ or any organism. Populations hold specific types of Object, for example, life stages, cell phases and infectious states. The syntax and semantics of this novel language are presented. A PAL model of the multi-scale system of cell growth and damage from cancer treatment is given. This model allows the analysis of different scales of the system. The Object and Population levels give insight into the length of a cell cycle and cell population growth respectively. The PAL model results are compared to wet laboratory survival fractions of cells given different doses of radiation treatment [1]. This comparison shows how PAL can be used to aid in investigations of cancer treatment in systems biology.
LanguageEnglish
Title of host publicationProcess Algebra with Layers: Multi-scale Integration Modelling Applied to Cancer Therapy
PublisherSpringer
Pages118-133
ISBN (Electronic)978-3-319-67834-4
ISBN (Print)978-3-319-67833-7
DOIs
Publication statusPublished - 17 Oct 2017

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Neoplasms
Population
Systems Biology
Population Growth
Therapeutics
Semantics
Organelles
Cell Survival
Cell Cycle
Language
Radiation
Growth

Cite this

Coulter, J. (2017). Process Algebra with Layers: Multi-scale Integration Modelling Applied to Cancer Therapy. In Process Algebra with Layers: Multi-scale Integration Modelling Applied to Cancer Therapy (pp. 118-133). Springer. https://doi.org/10.1007/978-3-319-67834-4_10
Coulter, Jonathan. / Process Algebra with Layers: Multi-scale Integration Modelling Applied to Cancer Therapy. Process Algebra with Layers: Multi-scale Integration Modelling Applied to Cancer Therapy. Springer, 2017. pp. 118-133
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Coulter, J 2017, Process Algebra with Layers: Multi-scale Integration Modelling Applied to Cancer Therapy. in Process Algebra with Layers: Multi-scale Integration Modelling Applied to Cancer Therapy. Springer, pp. 118-133. https://doi.org/10.1007/978-3-319-67834-4_10

Process Algebra with Layers: Multi-scale Integration Modelling Applied to Cancer Therapy. / Coulter, Jonathan.

Process Algebra with Layers: Multi-scale Integration Modelling Applied to Cancer Therapy. Springer, 2017. p. 118-133.

Research output: Chapter in Book/Report/Conference proceedingChapter

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Coulter J. Process Algebra with Layers: Multi-scale Integration Modelling Applied to Cancer Therapy. In Process Algebra with Layers: Multi-scale Integration Modelling Applied to Cancer Therapy. Springer. 2017. p. 118-133 https://doi.org/10.1007/978-3-319-67834-4_10