Abstract

Tissue engineering offers the possibility of creating functional replacements for diseased human organs. A key factor in producing useful tissues is the availability of materials to promote and control cellular activity. Ideally suited would be materials that transmit biological signals (in a controlled manner) that induce cells to attach, spread, grow, differentiate, and eventually organize to form a tissue. Fibronectin is a matrix protein known to induce cell adhesion and growth through its cell binding site. For this reason, materials coated with fibronectin have found use as tissue engineering substrata. A problem is that current placement procedures often result in a distribution of protein orientations on the surface, leaving a large fraction of binding sites inaccessible to cells. Our hypothesis is that if fibronectin could be bound to a surface with a preferential orientation that directs the cell binding site away from the surface, cell attachment and growth would be enhanced and precise control over tissue growth would become possible. In this proposed work, affinity, electric field, and antibody linking techniques will be developed for engineering orientationally controlled fibronectin coatings. Initial work will investigate control of fibronectin orientation using affinity techniques. An affinity ligand will be attached to a material's surface and the bio-specific interaction between the ligand and fibronectin will be exploited to orient the protein so that its active segment faces upwards (towards contacting cells). Ligands investigated here will include monoclonal antibodies and metal chelates. An integrated optical biosensor will be used to provide continuous measurements of the density and thickness of the interfacial protein. Since extensive surface modification may be disfavored in some applications for cost or biocompatibility reasons, new techniques for controlling protein orientation will also be investigated. The application of a perpendicular electric field during chemical adsorption will be used to align the protein and induce its adsorption. Antibody- linking techniques will be used to induce the protein to chemically adsorb with the active site facing away from the surface. The ability of the engineered fibronectin layers in promote and control cellular activity will be measured by observing the attachment, spreading, and growth of endothelial cells using an optical microscope. To improve our understanding of affinity, electric field, and linked-antibody adsorption, and to assist in the rational design of fibronectin coated materials, an entropy sampling Monte Carlo computer simulation of a coarse grained model fibronectin will be performed.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Biomedical Imaging and Bioengineering (NIBIB)
Type
Research Project (R01)
Project #
7R01EB000258-06
Application #
6735297
Study Section
Surgery and Bioengineering Study Section (SB)
Program Officer
Kelley, Christine A
Project Start
1999-02-01
Project End
2004-01-31
Budget Start
2003-04-01
Budget End
2004-01-31
Support Year
6
Fiscal Year
2003
Total Cost
$88,841
Indirect Cost

  Institution

Name
Yale University
Department
Engineering (All Types)
Type
Schools of Engineering
DUNS #
043207562
City
New Haven
State
CT
Country
United States
Zip Code
06520

  Publications

Wittmer, Corinne R; Phelps, Jennifer A; Lepus, Christin M et al. (2008) Multilayer nanofilms as substrates for hepatocellular applications. Biomaterials 29:4082-90
Ngankam, A Pascal; Van Tassel, Paul R (2007) Continuous polyelectrolyte adsorption under an applied electric potential. Proc Natl Acad Sci U S A 104:1140-5
Wittmer, Corinne R; Phelps, Jennifer A; Saltzman, W Mark et al. (2007) Fibronectin terminated multilayer films: protein adsorption and cell attachment studies. Biomaterials 28:851-60
Wittmer, Corinne R; Van Tassel, Paul R (2005) Probing adsorbed fibronectin layer structure by kinetic analysis of monoclonal antibody binding. Colloids Surf B Biointerfaces 41:103-9
Castells, Victoria; Van Tassel, Paul R (2005) Conformational transition free energy profiles of an adsorbed, lattice model protein by multicanonical Monte Carlo simulation. J Chem Phys 122:84707
Calonder, Claudio; Matthew, Howard W T; Van Tassel, Paul R (2005) Adsorbed layers of oriented fibronectin: a strategy to control cell-surface interactions. J Biomed Mater Res A 75:316-23
Ngankam, A Pascal; Mao, Guangzhao; Van Tassel, Paul R (2004) Fibronectin adsorption onto polyelectrolyte multilayer films. Langmuir 20:3362-70
Tie, Yanrong; Ngankam, A Pascal; Van Tassel, Paul R (2004) Probing macromolecular adsorbed layer structure and history dependence via the interfacial cavity function. Langmuir 20:10599-603
Brusatori, Michelle A; Van Tassel, Paul R (2003) Biosensing under an applied voltage using optical waveguide lightmode spectroscopy. Biosens Bioelectron 18:1269-77
Tie, Yanrong; Calonder, Claudio; Van Tassel, Paul R (2003) Protein adsorption: kinetics and history dependence. J Colloid Interface Sci 268:1-11