Chris Lach Reem Daher-Nahhas John Schoenbeck Lawrence

Chris Lach Reem Daher-Nahhas John Schoenbeck Lawrence

Chris Lach
Reem Daher-Nahhas
John Schoenbeck
Lawrence Technological University
BME Senior Capstone Project
Dr. Mansoor Nasir, Fall 2012
• Major Advantage: Significant reduction in
patient morbidity
• Tissue Engineering Triad
Scaffold should Resemble ECM (composition,
structure, surface chemistry, mechanical
properties, etc.)
Objective: Three-dimensional
biomimetic braiding design.
Characterization Methods:
•Biomimetic Structure
•Mechanical Properties
•Cellular Biocompatibility
Scaffold Model Fiber Identified Model
Benefits &
Limitations
Double-Triple Helix
+ Maximum Tensile Strength
‐ Reduced Toe Region
Twisted Triple Helix
+ Maximum Toe Region
‐ Hard to maintain fiber Alignment
Pleated Triple Helix
+ Tunnels for Cell Migration
‐ Minimal Tensile Strength
Research Study
Biomimetic
Structure
Mechanical
Properties
Biocompatibility
Parameter of Interest Testing Method
Braid Angle
Kinovea Video
Analysis
Braiding Tension
Force
Transducer/Custom
Guide
Fiber patterns
ESEM Imaging
Porosity
Porosimeter
Pore Size Distribution
Porosimeter
Ultimate Tensile Strength
Tensile Test using MTS
Elastic Modulus
Tensile Test using MTS
Maximum Strain
Tensile Test using MTS
Toe Region
Tensile Test using MTS
Cell Proliferation
Immunostaining,
alamar blue assay,
and confocal
microscopy
Cell Alignment
Confocal Microscopy
and ESEM
Month
Milestone
September Brainstorming & Research Analysis
October
Fiber Braiding Clamp Fabrication
November
Establish Experimental Protocols
December
Tension Measurement Guide Fabrication
January
Biomechanical Structure Analysis
February
Mechanical Testing & Cell Culturing
March
Cell Seeding & Biocompatibility Tests
April
Data Analysis & Publication Manuscript
May
Final Report & Presentations
• Electrospun poly(ε-caprolactone)
fibers provided by University of
Michigan
• Cells and testing equipment
provided by Beaumont, General
Motors, and Lawrence Tech
• Custom braiding tension
apparatus & Cell assay kits.
~$1000
• Variability in braids produced by hand.
• Braiding machines available but expensive
• Optimal pattern not yet characterized
• Designated Braiding Specialist: Chris Lach
• Custom Built Force Measurement Guide
• Find an optimized biomimetic braiding pattern
• An established set of protocols for evaluation of scaffold
structure, mechanical properties, and biocompatibility
•
•
•
•
Custom built fiber braiding machine
Future studies in bioreactor processes
More rational ACL scaffold designs
Applications in other fibrous tissues
Team Members
• Reem Daher-Nahhas
• Experimental protocols
• Data collection & analysis
• Reporting tables & appendices
• Christopher Lach
• Scaffold braiding & Sampling
• Cell culturing & staining
• Reporting figures & references
• John Schoenbeck
• Scheduling & documentation
• Scaffold & device design
• Reporting writer
Advisors & Collaborators
• Dr. Yawen Li (Faculty)
• Dr. Hsiao-Ping Moore
• Beaumont Orthopedics
Laboratory
• Dr. Kevin Baker
• Tristan Maerz (Technical)
• University of Michigan
• Dr. Joseph Corey
• Sam Tuck
• General Motors
[1] Lanza, Langer & Vacanti (ed.) 2007.
Academic Press, San Diego: 2007. ISBN:
9123206157
[2] Cooper, J. 2002. Drexel University, Thesis.
http://hdl.handle.net/1860/31
[3] Vaquette et. Al. 2009. J. Biomedical Materials
Research. 2010; 94(4): 1270-1282.
[4] Cooper et. Al. 2004. Biomaterials. 2005
May; 26(13):1523-32