Item Details

title

The Mechanical Properties of Individual Electrospun Fibers and Fibrin Fibers

author

Carlisle, Christine

abstract

Nanofibers play important mechanical roles in the body. Collagen, the most abundant protein in humans, forms fibers which comprise part of the extracellular matrix and tissues such as bone, cartilage and blood vessels, to name a few. Fibrinogen, a plasma protein, is converted into fibrin fibers which form the mechanical and structural support for blood clots. Biomimetic nanofibers can be synthesized outside of the body through the process of electrospinning. The mechanical properties of electrospun collagen and fibrinogen fibers are important because of their potential for tissue engineering, due to their biocompatibility. We studied the mechanical properties of individual electrospun collagen and fibrinogen fibers using a combined atomic force microscopy and optical microscopy technique. Using the same technique we also studied the mechanical properties of individual fibrin fibers, as the mechanical properties of blood clots have been shown to be related to diseases and disorders yet the mechanisms responsible for their mechanical properties are relatively unknown. Electrospun type I collagen and electrospun fibrinogen fibers both showed viscoelastic properties. The extensibility of electrospun fibrinogen in buffer is 130% and its average modulus is 10 MPa. Electrospun collagen in ambient conditions has an extensibility of 33% and a bending modulus of 7.5 GPa. Both fibers show strain softening, however, collagen shows extreme strain softening and therefore only a bending modulus is given. Native crosslinked fibrin fibers have similar properties to electrospun fibrinogen fibers. Crosslinked fibers have an extensibility of 130% and a modulus of 14 MPa. Uncrosslinked fibers are more extensible at 226% strain and softer with a modulus of 4 MPa. Crosslinked fibers rupture more often than crosslinked joints while uncrosslinked fibers rupture less often than uncrosslinked joints. Fibrin fibers with only alpha crosslinks are as extensible as uncrosslinked fibrin fibers but have a modulus in between crosslinked and uncrosslinked fibrin, of 10 MPa. Alpha crosslinked fibrin fibers have a larger elastic limit, 95% strain, than both uncrosslinked and crosslinked. Lastly, individual fibrin fibers from plasma samples were studied. Fibers from patients with type 2 diabetes show no difference in modulus or extensibility when compared with control patient samples.

subject

AFM

Modulus

Fibrin

Electrospinning

contributor

Hantgan, Roy R (committee chair)

Guthold, Martin (committee member)

Bonin, Keith D (committee member)

Macosko, Jed C (committee member)

Salsbury, Fred R (committee member)

date

2010-05-07T19:01:09Z (accessioned)

2010-06-18T19:00:08Z (accessioned)

2010-05-07T19:01:09Z (available)

2010-06-18T19:00:08Z (available)

2010-05-07T19:01:09Z (issued)

degree

Physics (discipline)

identifier

http://hdl.handle.net/10339/14928 (uri)

language

en_US (iso)

publisher

Wake Forest University

rights

Release the entire work for access only to the Wake Forest University system for one year from the date below. After one year, release the entire work for access worldwide. (accessRights)

type

Dissertation