PI Kang Kim
Co-Investigators William Wagner
Title Non-invasive Monitoring of Tissue-Engineered Construct by US Elasticity Imaging
Description Non-invasively monitoring the extent of tissue scaffold degradation, cellular growth, and tissue development will greatly help tissue engineers to non-destructively evaluate candidate scaffold performance in vivo. Biodegradable polymer scaffolds are used to support cells and growing tissues until they are replaced by the body’s own extracellular matrix (ECM). Two main challenges in creating the ideal biodegradable polymer scaffold are: (1) the scaffold must have a defined shape and porous internal architecture suitable for direct tissue ingrowth but with appropriate mechanical and degradation properties and (2) the scaffold must have the right surface properties to provide favorable conditions for cells to attach, differentiate, and lay down ECM. To design scaffolds which appropriately transfer their mechanical load over time to the ingrowing tissue, temporal data are required that verify the mechanical viability of the remodeling construct. Current analysis methods are destructive, requiring animal euthanasia and explanting the construct for histological and direct mechanical characterization. In addition, different samples are prepared and measured at varying times, but high growth deviation between specimens makes analysis difficult. Ideally, tissue engineers need a system that can noninvasively monitor growth in the same specimen over time. Other imaging methods, such as magnetic resonance imaging (MRI) and computed tomography (CT), provide internal scaffold structural information, but they are limited to providing only morphological information. Ultrasound easticity imaging (UEI) based on phase-sensitive speckle tracking can characterize the mechanical, structural, and functional change of the implanted engineered tissues at very high resolution and sensitivity. Local UEI offers the potential to radically improve the biomaterial scaffold design and engineered tissue growth techniques. The long term goal of this research program is to develop a novel noninvasive functional imaging modality in the field of tissue engineering and regenerative medicine. The objective of the current project is to evaluate UEI as noninvasive imaging tool to assess mechanical, structural, and functional characteristics of the scaffold degradation and tissue ingrowth. The specific aims are: (1) Establish the in vitro relationship between noninvasive UEI and the mechanical and structural characteristics of the biomaterial scaffold degradation. (2) Establish the in vivo relationship between noninvasive UEI and the mechanical, structural, and functional characteristics of simultaneous tissue growing and scaffold degradation. These specific aims will be evaluated using novel polyurethane-based soft tissue scaffolds with three different degradation rates. In vivo feasibility will also be demonstrated using the rat abdominal repair model. If successful, UEI integrated into a commercial ultrasound scanner can also be rapidly translated into clinical practice since it is based upon novel processing of ultrasound data that can be obtained conveniently and non-invasively from human subjects.
Source National Science Foundation
Term 04/01/11 – 03/31/13
Amount Year 1 Direct: $30,340
Year 1 IDC: $15,625
Total Direct: $61,197
Total IDC: $31,516