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Abstract
Biodegradable polymers have been widely used as scaffolding materials to regenerate
new tissues. To mimic natural extracellular matrix architecture, a novel highly porous
structure, which is a three-dimensional interconnected fibrous network with a fiber
diameter ranging from 50 to 500 nm, has been created from biodegradable aliphatic
polyesters in this work. A porosity as high as 98.5% has been achieved. These nano-fibrous
matrices were prepared from the polymer solutions by a procedure involving thermally
induced gelation, solvent exchange, and freeze-drying. The effects of polymer concentration,
thermal annealing, solvent exchange, and freezing temperature before freeze-drying
on the nano-scale structures were studied. In general, at a high gelation temperature,
a platelet-like structure was formed. At a low gelation temperature, the nano-fibrous
structure was formed. Under the conditions for nano-fibrous matrix formation, the
average fiber diameter (160-170 nm) did not change statistically with polymer concentration
or gelation temperature. The porosity decreased with polymer concentration. The mechanical
properties (Young's modulus and tensile strength) increased with polymer concentration.
A surface-to-volume ratio of the nano-fibrous matrices was two to three orders of
magnitude higher than those of fibrous nonwoven fabrics fabricated with the textile
technology or foams fabricated with a particulate-leaching technique. This synthetic
analogue of natural extracellular matrix combined the advantages of synthetic biodegradable
polymers and the nano-scale architecture of extracellular matrix, and may provide
a better environment for cell attachment and function.