posted on 2023-07-10, 14:05authored byJun Shen, Weihao Yuan, Maryam Badv, Alireza Moshaverinia, Paul S. Weiss
The use of poly(ε-caprolactone)
(PCL) for biomedical
applications
is well established, particularly for permanent implants, due to its
slow degradation rate, suitable mechanical properties, and biocompatibility.
However, the slow degradation rate of PCL limits its application for
short-term and temporary biomedical applications where bioabsorbability
is required. To enhance the properties of PCL and to expand its biomedical
applications, we developed an approach to produce PCL membranes with
tunable degradation rates, mechanical properties, and biofunctional
features. Specifically, we utilized electrospinning to create fibrous
PCL membranes, which were then chemically modified using potassium
permanganate to alter their degradability while having minimal impact
on their fibrous morphology. The effects of the chemical treatments
were investigated by treating the samples for different time periods
ranging from 6 to 48 h. After the 48 h treatment, the membrane degraded
by losing 25% of its mass over 12 weeks in degradation studies, while
maintaining its mechanical strength and exhibiting superior biofunctional
features. Our results suggest that this approach for developing PCL
with tailored properties could have significant potential for a range
of biomedical applications.