1. Modelling Collagen Alignment in Dermal Wounds John Dallon, Jonathan Sherratt, Mark Ferguson and Philip K. Maini
2. Key Players Fibroblasts degrade fibrin
secrete collagen
Collagen slows down fibroblasts
Fibroblasts < ----------- > collagen
alignment
3. Alignment problems occur in a wide variety of applications:��crystals, ecology, developmental biology etc��Mathematical approaches: integro-partial-differential equations,��discrete orientation
4. The Orientation Model�� Variables��Cells discrete objects� paths given by f��Collagen continuous vector field denoted by c (x, t)
15. The Tissue Regeneration Model��fibrin network is represented by b (x,t)��
23. Altering the speed of fibroblasts: increasing the speed leads to greater alignment. Can be done using a chemoattractant (Knapp et al, 1999 can increase speed 3-fold (Ware et al, 1998)) or altering the integrin expression levels of the fibroblasts (Palecek et al, 1997)
24. Reducing contact guidance: inhibit the formation of microtubules with colcemid (Oakley et al, 1997); treatment with colchicine (causes rounder morphology (Mercier et al, 1996)
25. Effects of initial collagen orientation: transplant pieces of tendon (Matsumoto et al, 1998); place pieces of oriented gel (Guido and Tranquillo, 1993)
27. Altering the profile of transforming growth factor beta can have profound effects on the healing process, including significantly increasing or decreasing the degree of scarring (Shah et al, 1992, 1994, 1995, 1999)
28. Effects of TGF-beta Cell proliferation biphasic (depends on age)
Cell motility biphasic effect on directed cell movement (chemotaxis)
Collagen production increase collagen production and decrease collagenase production
Cell reorientation development of lamellipodia and filopodia depends on concentration levels
31. Model results Effects on cell proliferation, migration and extracellular matrix production influence collagen alignment in only a MINOR way
Regulation of filopodial extensions by TGF-beta could be the CRUCIAL property
32. Interpretation Adding TGF-beta-3 causes more cell reorientation, leads to less alignment and scarring is reduced
Antibodies to TGF-beta-1 and 2 would, in this interpretation, lead to more alignment and hence more scarring. CONTRADICTION
Both these isoforms bind to cells competitively (Altomonte et al, 1996, Piek et al, 1999)
34. Model considered wound is isolation.
If we embed it in tissue we find that the
time taken for the cells to enter and heal
the wound is too long.
35. McDougall and Sherratt Add a chemoattractant produced in the
wound (PDGF, IL-Ibeta, TNF-alpha)
Reaction-diffusion equation at steady state
Cells velocity now depends on size of
chemical gradient and is in the direction
of the gradient
36. Fibroblast density is low at top and high
at bottom (staining experiments)
37. RESULTS Wound heals in reasonable time
Widely dispersed chemoattractant prolife leads to greater degree of interdigitation (better linked)
Uniform cell distribution in the unwounded
skin leads to parallel alignment rather
than perpendicular alignment (w.r.t. bottom of wound)
38. Switching off the speed cue leads to fewer
cells entering the wound. Orientation not
altered
Switching off the directional cue (but not speed) is worse
Pattern of alignment depends crucially on
the form taken for velocity dependence
39. Therapeutic aspects Decrease the sensitivity of fibroblast
reorientation to chemoattractant gradients
(add agent that binds competitively to receptors mannose 6 phosphate acts in this way [Ferguson and OKane, 2004]
have shown this reduces scarring)
40. References J.C. Dallon, J.A. Sherratt, P.K. Maini, J.theor.Biol., 199, 449-471 (1999)
J.C. Dallon, J.A. Sherratt, P.K. Maini, M. Ferguson,
IMA J.Math.Appl.Biol.Med, 17, 379-393 (2000)
J.C. Dallon, J.A. Sherratt, P.K. Maini, Wound Repair and Regeneration, 9, 278-286 (2001)
S. McDougall, J. Dallon, J. Sherratt, PKM, (submitted)
