Abstract
The supply of oxygen to proliferating cells within a scaffold is a key factor for the successful building of new tissue in soft tissue engineering applications. A recent in vivo model, where an arteriovenous loop is placed in a scaffold, allows a vascularising network to form within a scaffold, establishing an oxygen source within, rather than external, to the scaffold. A one-dimensional model of oxygen concentration, cell proliferation and cell migration inside such a vascularising scaffold is developed and investigated. In addition, a vascularisation model is presented, which supports a vascularisation front which moves at a constant speed. The effects of vascular growth, homogenous and heterogenous seeding, diffusion of cells and critical hypoxic oxygen concentration are considered. For homogenous seeding, a relationship between the speed of the vascular front and a parameter defining the rate of oxygen diffusion relative to the rate of oxygen consumption determines whether a hypoxic region exists at some time. In particular, an estimate of the length of time that a fixed point in the scaffold will remain under hypoxic conditions is determined. For heterogenous seeding, a Fisher-like travelling wave of cells is established behind the vascular front. These findings provide a fundamental understanding of the important interplay between the parameters and allows for a theoretical assessment of a seeding strategy in a vascularising scaffold.
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References
Agrawal, C.M., Ray, R.B., 2001. Biodegradable polymeric scaffolds for musculoskeletal tissue engineering. J. Biomed. Mater. Res. 55, 141–50.
Balding, D., McElwain, D.L.S., 1985. A mathematical model of tumour-induced capillary growth. J. Theor. Biol. 114, 53–3.
Boutilier, R.G., St-Pierre, J., 2000. Surviving hypoxia without really dying. Comp. Biochem. Physiol. Molecular Integr. Physiol. 126, 481–90.
Cassell, O.C.S., Morrison, W.A., Messina, A., Penington, A.J., Thompson, E.W., Stevens, G.W., Perera, J.M., Kleinman, H.D., Hurley, J.V., Romeo, R., Knight, K.R., 2001. The influence of extracellular matrix on the generation of vascularized, engineered, transplantable tissue. Ann. New York Acad. Sci. 944, 429–42.
Croll, T.I., Gentz, S., Müller, K., Davison, M., O’Connor, A.J., Stevens, G.W., Cooper-White, J., 2005. Modelling oxygen diffusion and cell growth in a porous, vascularising scaffold for soft tissue engineering applications. Chem. Eng. Sci. 60, 4924–934.
Edelstein, L., 1982. The propagation of fungal colonies: a model for tissue growth. J. Theor. Biol. 98, 679–01.
Galban, C.J., Locke, B.R., 1997. Analysis of cell growth in a polymer scaffold using a moving boundary approach. Biotechnol. Bioeng. 56, 422–32.
Galban, C.J., Locke, B.R., 1999a. Analysis of cell growth kinetics and substrate diffusion in a polymer scaffold. Biotechnol. Bioeng. 65, 121–32.
Galban, C.J., Locke, B.R., 1999b. Effects of spatial variation of cells and nutrient and product concentrations coupled with product inhibition on cell growth in a polymer scaffold. Biotechnol. Bioeng. 64, 633–43.
Hasirci, V., Berthiaume, F., Bondre, S.P., Gresser, J.D., Trantolo, D.J., Toner, M., Wise, D.L., 2001. Expression of liver-specic functions by rat hepatocytes seededin treatedpoly (lactic-co-glycolic) acid biodegradable foams. Tissue Eng. 7, 385–94.
Kellner, K., Liebsch, G., Klimant, I., Wolfbeis, O.S., Blunk, T., Schulz, M.B., Göpferich, A., 2002. Determination of oxygen gradients in engineered tissue using a fluorescent sensor. Biotechnol. Bioeng. 80, 73–3.
Langer, R., Vacanti, J.P., 1993. Tissue engineering. Science 260, 920–26.
Lewis, M.C., MacArthur, B.D., Malda, J., Pettet, G., Please, C.P., 2005. Heterogeneous proliferation within engineered cartilaginous tissue: the role of oxygen tension. Biotechnol. Bioeng. 91, 607–15.
Malda, J., Woodfield, T.B.F., van der Vloodt, F., Kooy, F.K., Martens, D.E., Tramper, J., van der Blitterswijk, C.A., Riesle, J., 2004. The effect of PEGT/PBT scaffold architecture on oxygen gradients in tissue engineered cartilaginous constructs. Biomaterials 25, 5773–780.
Murray, J.D., 2002. Mathematical Biology, vol. 1, 3rd edn. Springer, New York.
Patrick, C.W., 2000. Adipose tissue engineering: the future of breast and soft tissue reconstruction following tumor resection. Sem. Surg. Oncol. 19, 302–11.
Patrick, C.W., 2001. Tissue engineering strategies for adipose tissue repair. Anat. Rec. 263, 361–66.
Pettet, G.J., Byrne, H.M., McElwain, D.L.S., Norbury, J., 1996a. A model of wound-healing angiogenesis in soft tissue. Math. Biosci. 136, 35–3.
Pettet, G.J., Chaplain, M.A.J., McElwain, D.L.S., Byrne, H.M., 1996b. On the role of angiogenesis in wound-healing. Proc. Roy. Soc. Lond. B 263, 1487–493.
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Landman, K.A., Cai, A.Q. Cell Proliferation and Oxygen Diffusion in a Vascularising Scaffold. Bull. Math. Biol. 69, 2405–2428 (2007). https://doi.org/10.1007/s11538-007-9225-x
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DOI: https://doi.org/10.1007/s11538-007-9225-x