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Topics. The Complexity ChallengeThe Genstruct Approach. Topics. The Complexity ChallengeSo much data, so little unified reasoningThe Genstruct Approach. Topics. The Complexity ChallengeSo much data, so little unified reasoningThe Genstruct ApproachA system that knows biological causes and c
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2. Topics The Complexity Challenge
The Genstruct Approach
3. Topics The Complexity Challenge
So much data, so little unified reasoning
The Genstruct Approach
4. Topics The Complexity Challenge
So much data, so little unified reasoning
The Genstruct Approach
A system that knows biological causes and can suggest reasons for effects seen in experiments
5. Systems Biology Systems Biology has as its ultimate goal, the development of a complete working model of the human body
the structure and function of subcellular structures
molecular networks in cells
cellular interactions in organs and tissues
the interactions of organs
and so on
Systems biology has been enabled by the ‘Omics revolution
The development of a ‘catalog’ of parts (genes, proteins, metabolites)
The ability to measure large numbers and types of molecules and their changes in a system
The ability to use a systems approach to biology relies upon the implementation of an integrating, systems framework that can:
Capture the complexity and richness of biology
Can integrate high-throughput measurements
Can generate testable biological hypotheses for experimentation
That can scale to the scope of complete biological systems
6. Drug Development Process Current drug discovery and development assess the activity of drugs at the organism level
By observing clinical phenotypes
Current drug discovery and development assess the activity of drugs at the organism level
By observing clinical phenotypes
7. Drug Development Process Drugs have their effects at the molecular level: agonism and antagonism of molecular targets
There is no real attempt to understand its molecular function beyond simple protein binding
We have little understanding of on and off target effects
Drugs have their effects at the molecular level: agonism and antagonism of molecular targets
There is no real attempt to understand its molecular function beyond simple protein binding
We have little understanding of on and off target effects
8. Drug Development Process Drug development can be improved through the understanding of the molecular mechanisms of drugs
Leading to less failures and more successesDrug development can be improved through the understanding of the molecular mechanisms of drugs
Leading to less failures and more successes
9. The Causal Modeling Approach Computer-aided causal analysis provides a practical means of modeling biology using very large data sets
The combination of comprehensive measurement with a causal model of biology will identify mechanisms of action, resistance and toxicity
Causal System Modeling is an efficient method of identifying evidence-driven hypotheses that define biological mechanisms and downstream activities Explaining the general Genstruct approachExplaining the general Genstruct approach
10. Causal vs. Mathematical Approaches Causal Modeling
Qualitative
Comprehensive
Scales to 100’s of thousands of concepts
Models biology as whole networks
Easily adapted and modified
Rapid lifecycle
Mathematical Modeling
Quantitative
Kinetic
Data limited and expensive
Difficult to scale to or beyond 100’s of concepts
Models biology as circuits
Time consuming
11. Causal Modeling of Molecular Mechanisms
12. Biological states can be predicted by reasoning through state changes
13. Biological States from panomic measurements enhance the predictive ability of the model
14. DEFINING THE HURDLES (and finding the right solutions)
15. The Problem of Complexity The more data you have, the worse the problem gets.The more data you have, the worse the problem gets.
16. The Challenge: Managing the Complexity of Knowledge Synthesis and Reasoning
17. A Matter of Scale
18. Genstruct Background Genstruct partners with pharmaceutical companies to advance their drug development programs.
Genstruct employs a systems biology methodology that combines computational modeling with experimental evidence to define mechanisms and biomarkers.
Genstruct has three top tier pharmaceutical partners and a developing pipeline.
derive maximum value from –omics data
generate novel, actionable scientific insights
solve critical problems in drug discovery and development
reducing or eliminating barriers to development of therapeutics
derive maximum value from –omics data
generate novel, actionable scientific insights
solve critical problems in drug discovery and development
reducing or eliminating barriers to development of therapeutics
19. The Genstruct Model Modeling
Causal Framework for representing biochemical reactions
Causal Reasoning methodology to define biological mechanisms
Manipulation
Large-scale omic’s experiments
Genes, Proteins, Metabolites
Measurement
Biological State Changes
Change in state of a biological process
Mining
Re-use causal relationships through Causal Knowledge Repository
20. The Genstruct Model A Computational Systems Modeling Platform
Incorporates all critical molecular components for a biological problem of interest
Maps qualitative functional relationships among the molecular components
Builds a graphical network that integrates those relationships and supports computational modeling of complex biological knowledge
A Hypothesis Generation Methodology
Utilizes a computational system of automated reasoning
Generates inferences through causal analysis
Produces actionable end products:
Testable Hypotheses
21. The Process Define specific scientific question
Given the problem statement, a plausible question could be:
Define the mechanism of action for compound X which will explain the observed glucose metabolism effects
Design experiments to monitor the specific effects of the compound
Identify state changes evidenced by the data as key readouts of molecular networks
Explore each of the identified state changes for their regulation and downstream effects
Define the key steps that lead to the different effects in different tissues
Capture and evaluate the defined biology through causal system modeling
Evaluate the Causal System Model for biomarkers for efficacy, resistance and toxicity The application of our approach in your problemThe application of our approach in your problem
22. REAL WORLD SUCCESSES
23. Summary of Successes Discovery
Molecular mechanisms for type II diabetes
Novel molecular switches controlling breast cancer tumor growth
Molecular mechanisms for prostate cancer proliferation
Safety / Tox
Molecular mechanisms controlling drug-induced vascular injury
Biomarkers for toxicity
Development
Molecular mechanisms for cancer drug resistance
Molecular mechanisms of cardiovascular drug action
24. Novel Target Identification
Mapping of disease networks and key control mechanisms
Identification of druggable control points
Lead Selection
Model compound activities and differentiate compound sets
Identify most efficacious compound with least adverse effects
Safety / Toxicity
Define response and toxicity mechanisms
Identify biomarkers for assessment and stratification
Clinical Development
Identify mechanisms and markers for efficacy
Identify mechanisms and markers for resistance
Identify mechanisms and markers for toxicity
Stratify patients and define early endpoints Commercial Successes Along the Value Chain
25. Commercial Projects Along the Value Chain
26. PDE-4 Inhibitor Toxicity: Mesenteric Vascular Injury & Inflammation in Rats
