Abstract

While skeletal tissue engineering is ideally based on transition from scaffold function to shared bone/scaffold function to completely natural bone, almost no information exists on designing scaffolds to optimize this transition. A simplified starting point is to associate scaffold function with mechanical modulus and tissue regeneration with scaffold porosity/permeability. The fundamental scaffold design question becomes """"""""What is the right balance between modulus and interconnected porosity/permeability such that the scaffold can bear load until the regenerate tissue can bear load?"""""""". To answer this critical question we must be able to design scaffold architectures with specific modulus porosity relationships, fabricate these complex scaffolds from bone engineering materials, and test these scaffolds in a well characterized in vivo load bearing model. Our global hypothesis is that a minimally stiff scaffold (stiff equates to modulus) capable of load bearing coupled with the highest interconnected porosity/permeability will achieve optimal bone regeneration. Our goal is to define """"""""minimally stiff' and """"""""highest porosity/permeability"""""""" in an in vivo functional load bearing site. We will test this hypothesis through the following three specific aims:
Specific Aim 1. Use computational topology optimization techniques to design scaffold architectures with four modulus/porosity ratios that span the theoretical Hashin-Shtrikman bounds initially and after degradation.
Specific Aim 2. Fabricate designed scaffold architectures from PPF/TCP using Solid Free-Form Fabrication techniques. Micro-CT scaffolds to examine architecture and measure scaffold permeability.
Specific Aim 3. Test scaffolds in minipig mandibular condyle load bearing site that has known bone regeneration dynamics. Determine how modulus/porosity ratios correlate with bone regeneration at 4 and 8 weeks using 3D quantitative micro-CT, mechanical testing, and histology. The results will provide quantitative information as to what modulus is necessary for load bearing and how designed porosity/permeability influence bone regeneration. This information will provide guidelines for designing scaffolds to optimize transition from scaffold load bearing to bone regeneration and load bearing.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Institute of Dental & Craniofacial Research (NIDCR)
Type
Research Project (R01)
Project #
5R01DE016129-04
Application #
7492136
Study Section
Special Emphasis Panel (ZRG1-MOSS-A (04))
Program Officer
Lumelsky, Nadya L
Project Start
2005-09-01
Project End
2010-06-30
Budget Start
2008-07-01
Budget End
2009-06-30
Support Year
4
Fiscal Year
2008
Total Cost
$483,877
Indirect Cost

  Institution

Name
University of Michigan Ann Arbor
Department
Biomedical Engineering
Type
Schools of Engineering
DUNS #
073133571
City
Ann Arbor
State
MI
Country
United States
Zip Code
48109

  Publications

Hollister, Scott J; Murphy, William L (2011) Scaffold translation: barriers between concept and clinic. Tissue Eng Part B Rev 17:459-74
Hollister, Scott J (2009) Scaffold engineering: a bridge to where? Biofabrication 1:012001
Hollister, Scott J (2009) Scaffold design and manufacturing: from concept to clinic. Adv Mater 21:3330-42
Kim, Kang; Jeong, Claire G; Hollister, Scott J (2008) Non-invasive monitoring of tissue scaffold degradation using ultrasound elasticity imaging. Acta Biomater 4:783-90
Mao, J J; Giannobile, W V; Helms, J A et al. (2006) Craniofacial tissue engineering by stem cells. J Dent Res 85:966-79