Title: Modeling Tumor Growth and Angiogenesis
1- Modeling Tumor Growth and Angiogenesis
Rui Travasso
Centro de FÃsica Computacional Universidade de
Coimbra
2 Cancer
- Group of diseases presenting
- Uncontrolled cell growth
- Invasion (and metastasis)
- Computer simulation in cancerprognostic and
control - Complex problem
- Interaction between different cellular types
- Processes at different scales
- Microscopic protein reaction networks, mutations
- Macroscopic cell diffusion
- Focus Solid tumors
3 Tumor growth
- Phase 1 Genetic mutations
- Cellular cycle and apoptosis disruption
- Uncontrolled reproduction, no cell death
- Phase 2 Interaction with immune system
- Cancer cells inhibit immune system
- Phase 3 Solid tumor
- Cancer cell diffusion
- Necrotic zones
- Solid tumor diameter 1-2 mm
4 Angiogenesis and Metastasis
- Tumor growth requires nutrients
- Active nutrient search
- Phase 4 Angiogenesis
- Segregation of proteins which promoteblood
vessel growth - Aberrant vascular network
- Phase 5 Metastasis
- Cancer cells enter in blood network
- New colonies in healthy regions
5 Tumor Topics
- Cancer cells uncontrolled reproduction
- Genetic material diversity
- Large adaptability
- Tumor surroundings are extremely hostile
- Host destruction is adaptation victory
- Fragile blood vessels
- A tumor bleeds
- Continuous angiogenesis
- A tumor is a wound which does not heal
6 Tumor Growth - Spheroids
- Tumor growth in vitro
- 106 cells
- 2 mm diameter
- Many different models
Nutrients Elasticity Pressure gradients
Interstitial fluid flow ECM and other cells
Multiphase models Many constitutive
equations Cell based
7 Tumor Growth - Cadherin Switch - Permeable
Phenotype
- E-Cadherin connect nearby cells of epithelium
- Proliferation regulated by E-cadherinsignal
pathway - In case of failure may lead to uncontrolledprolif
eration - Cadherin switch at the onset of solid tumor
growth - Motile tumor cells
- Move in search for nutrients
- Metastasis
8 Tumor Growth - Angiogenesis Switch - Vascular
Phase
- The tumor promotes thedevelopment of
nearbyvessels to have oxygen - Challenging simulations
- Many parameters
- Cell based
- Continuous
- Hybrid
9 Tumor Growth - Competition - Evolution
- Deregulated proliferation
- Mutations
- Darwin selection
- Metabolism and migration
- Anaerobic matabolism
- 2 ATP instead of 36
- No need of Oxygen
- Produces acid
- Helps migration
- Prevailing phenotype
- Acid resistant
Acid
10 Angiogenesis
- Sprouting of new blood vessels from existing ones
- Relevant in varied situations
- Morphogenesis
- Inflammation
- Wound healing
- Neoplasms
- Diabetic Retinopathy
- For tumors
- Altered vessel network
- Dense, no hierarchical structure
- Capillaries are fragile, permeable, with variable
diameter - Capillary network carries both nutrients and
drugs
11 Two types of cells
- Tip cells are special
- Have filopodia
- Produce MMPs which degrade ECM
- Construct path
- Do not proliferate
- Stalk cells
- Proliferation regulated by VEGF
- Not diggers
- Follow tip cell created pathway
Gerhardt et al, Cell (2003)
12 Angiogenesis in a Nutshell
- Capillaries are constituted by
- Endothelial cells
- Pericites, muscle cells
? VEGF weakens capillary wall ?
Endothelial cells may divide
? Cells follow VEGF gradient ? The first
cell is activated and opens way in ECM
? Cells organize to form lumen
? Blood flows when capillaries form loops
? Blood reorganizes network
13 Tip cells Notch and Dll-4
- New branches do not form everywhere
- Tip cells regulated by Notch pathway
- VEGF activates cell receptor (VEGFR2)
- Many pathways (reproduction, survival, cell
activation) - Promotes Dll-4
- Dll-4 activates Notch in neighboring cell
- Notch represses VEGFR2
- Tip cells are not neighbors (salt and pepper
pattern)
VEGFR2
14 The Way to Look at it
- Capillary walls divide space
- Inside/Outside considered as different phases
- Different phases separated by interfaces
- Interfaces grow and move
- Phase field models
- Describe interface dynamics
- Applied to different problems
- Solidification
- Biological membranes
- Fluid interfaces
15 Phase-Field Models
- Approach to moving boundary problems
- Phases associated with value of f
- Interface implies ? 0
- Diffuse interface
- Original problem obtained when e ? 0
- Correct interface physics in varied situations
- Interfaces in elastic, viscoelastic or fluid
media - Fracture dynamics
- Can be derived from a free energy F?,?
- Computationally effective since no frontier
conditions at interface
16 Examples
17 The Model
- Two equations
- Diffusion concentration of VEGF, T
- Phase-Field order parameter dynamics
- Tip cell
- Characteristic radius Rc
- Perfect Notch signaling
- Introduced when T gt Tc
- Velocity
- ?? regulates the proliferation and D? the
chemotaxis
The penetration length ??of T inside the
capillary is given by ?????D????
? 1 inside capillary ? -1 outside capillary
18 Simulation
- Starting configuration
- Artery close to tissue in hypoxia
- Concentration at cells Ts
? A blood vessel network emerges ? D?
250 and ?? 3.0
19 Proliferation
- Varying ???for D? 250
- Higher proliferation rate leads to thicker and
ramified vessels
?? 1.0
?? 3.0
?? 4.0
20 Chemotaxis
- Varying D??for ?? 3.0
- Higher tip cell velocity leads to thinner and
more ramified vessels
D? 100
D? 300
D? 400
21 VEGF Prodution
- Varying Ts,?for ?? and D2 constants
- Higher production of VEGF leads to more vessels
but not thicker vessels
Ts 1.0
Ts 1.2
Gerhardt et al., Develop. Biol. (2003)
22 Matrix Metalloproteinase
- MMPs implementation
- Heavy VEGF isoforms getbound to matrix if cMMP
high - cMMP high in a radius RMMP of tumor cell
- Diffusion in function of Th
- Formation of thick vessels
- Thin vessel merging
MMP-9 Inhibition
MMP-9 Overexpressed
Rodriguez-Manzaneque et al, PNAS (2001)
23 Conclusion
- Introduced phase-field model for angiogenesis
- Able to be extended in order to describe tissue
dynamics - Delicate balance between proliferation and
chemotaxis - High proliferation leads to thick and ramified
vessels - Strong chemotaxis leads to thin and ramified
vessels - High production VEGF levels lead to increased
vessel density - Experimental agreement
- Future work
- Anastomosis
- Incorporation of experimental results
Gerhardt et al, Cell (2003)
24 A Pretty One
25 Coimbra Group
- Susana Silva
- Pedro Oliveira
- Inês Lopes
- Fernando Nogueira
- Claudia Cardoso
- Apostolos Marinopoulos
- Duan-Jun Cai
- Paulo Abreu
- Bruce Milne
- Myrta Grünning