The relationship between microstructural features and macroscopic mechanical properties of engineered tissues was investigated in pure and mixed composite scaffolds consisting of collagen Type I and fibrin proteins containing embedded smooth muscle cells. In order to vary the matrix microstructure, fibrin polymerization in mixed constructs was initiated using either the blood-derived enzyme thrombin or the snake venom-derived enzyme ancrod, each at low and high concentrations. Microstructural features of the matrix were quantified by analysis of high resolution scanning electron micrographs. Mechanical properties of the scaffolds were assessed by uniaxial tensile testing as well as creep testing. Viscoelastic parameters were determined by fitting creep data to Burger’s four-parameter model. Oscillatory dynamic mechanical testing was used to determine the storage modulus, loss modulus, and phase shift of each matrix type. Mixed composite scaffolds exhibited improved tensile stiffness and strength, relative to pure collagen matrices, as well as decreased deformation and slower relaxation in creep tests. Storage and loss moduli were increased in mixed composites compared with pure collagen, while phase shift was reduced. A correlation analysis showed that the number of fiber bundles per unit volume was positively correlated with matrix modulus, strength, and dynamic moduli, though this parameter was negatively correlated with phase shift. Fiber diameter also was negatively correlated with scaffold strength. This study demonstrates how microstructural features can be related to the mechanical function of protein matrices and provides insight into structure-function relationships in such materials. This information can be used to identify and promote desirable microstructural features when designing biomaterials and engineered tissues.
Skip Nav Destination
Article navigation
June 2009
Research Papers
Microstructure and Mechanics of Collagen-Fibrin Matrices Polymerized Using Ancrod Snake Venom Enzyme
Shaneen L. Rowe,
Shaneen L. Rowe
Rensselaer Polytechnic Institute
, Troy, NY 12180
Search for other works by this author on:
Jan P. Stegemann
Jan P. Stegemann
Search for other works by this author on:
Shaneen L. Rowe
Rensselaer Polytechnic Institute
, Troy, NY 12180
Jan P. Stegemann
J Biomech Eng. Jun 2009, 131(6): 061012 (9 pages)
Published Online: May 8, 2009
Article history
Received:
November 19, 2008
Revised:
February 23, 2009
Published:
May 8, 2009
Citation
Rowe, S. L., and Stegemann, J. P. (May 8, 2009). "Microstructure and Mechanics of Collagen-Fibrin Matrices Polymerized Using Ancrod Snake Venom Enzyme." ASME. J Biomech Eng. June 2009; 131(6): 061012. https://doi.org/10.1115/1.3128673
Download citation file:
Get Email Alerts
Estimation of Joint Kinetics During Manual Material Handling Using Inertial Motion Capture: A Follow-Up Study
J Biomech Eng (February 2025)
Effect of Compressive Strain Rates on Viscoelasticity and Water Content in Intact Porcine Stomach Wall Tissues
J Biomech Eng (February 2025)
Eyelid Motion Tracking During Blinking Using High-Speed Imaging and Digital Image Correlation
J Biomech Eng (January 2025)
Related Articles
Mechanical Properties and Microstructure of Intraluminal Thrombus From Abdominal Aortic Aneurysm
J Biomech Eng (December,2001)
Charged Modification of Hydrogel for Nerve Regeneration
J. Med. Devices (June,2008)
Direct Measurement of Nonuniform Large Deformations in Soft Tissues During Uniaxial Extension
J Biomech Eng (June,2009)
Related Proceedings Papers
Related Chapters
Conclusions
Chitosan and Its Derivatives as Promising Drug Delivery Carriers
Introduction
Nanomaterials in Glucose Sensing: Biomedical & Nanomedical Technologies - Concise Monographs
Final Report
Applications Guide for Determining the Yield Strength of In-Service Pipe by Hardness Evaluation: Final Report