Personalized signaling models for personalized treatments
Dynamic mechanistic models, that is, those that can simulate behavior over time courses, are a cornerstone of molecular systems biology. They are being used to model molecular mechanisms with varying degrees of granularity—from elementary reactions to causal links—and to describe these systems by various dynamic mathematical frameworks, such as Boolean networks or systems of differential equations. The models can be based exclusively on experimental data, or on prior knowledge of the underlying biological processes. The latter are typically generic, but can be adapted to a certain context, such as a particular cell type, after training with context‐specific data. Dynamic mechanistic models that are based on biological knowledge have great potential for modeling specific systems, because they require less data for training to provide biological insight in particular into causal mechanisms, and to extrapolate to scenarios that are outside the conditions they have been trained on.
- Location
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Deutsche Nationalbibliothek Frankfurt am Main
- Extent
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Online-Ressource
- Language
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Englisch
- Bibliographic citation
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Personalized signaling models for personalized treatments ; volume:16 ; number:1 ; year:2020 ; extent:3
Molecular systems biology ; 16, Heft 1 (2020) (gesamt 3)
- Creator
- DOI
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10.15252/msb.20199042
- URN
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urn:nbn:de:101:1-2022070611352839485116
- Rights
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Open Access; Der Zugriff auf das Objekt ist unbeschränkt möglich.
- Last update
- 15.08.2025, 7:24 AM CEST
Data provider
Deutsche Nationalbibliothek. If you have any questions about the object, please contact the data provider.
Associated
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Modeling intra- and intercellular communication in the context of human cancer from high-throughput data
Data-driven reverse engineering of signaling pathways using ensembles of dynamic models
Transforming Boolean models to continuous models: methodology and application to T-cell receptor signaling
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Modular analysis of signal transduction networks
Patient‐specific logic models of signaling pathways from screenings on cancer biopsies to prioritize personalized combination therapies
Integrating knowledge and omics to decipher mechanisms via large‐scale models of signaling networks
Multi-scale molecular descriptions of human heart failure using single cell, spatial, and bulk transcriptomics
Enablers and challenges of spatial omics, a melting pot of technologies
Bridging the gap between signalling and metabolism through functional and mechanistic analysis of multi-omic data
Modeling intra- and intercellular communication in the context of human cancer from high-throughput data
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Transforming Boolean models to continuous models: methodology and application to T-cell receptor signaling
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