期刊
JOURNAL OF MATERIALS CHEMISTRY B
卷 9, 期 18, 页码 3826-3837出版社
ROYAL SOC CHEMISTRY
DOI: 10.1039/d0tb02987d
关键词
-
资金
- NIH NIDCR [1R01DE025886-01A1]
- National Science Foundation [DBI-0116835]
Research has shown that self-fitting shape memory polymer scaffolds prepared with star-polymer structures have lower fitting temperatures and faster degradation rates, potentially offering advantages for the treatment of irregular craniomaxillofacial bone defects.
Self-fitting shape memory polymer (SMP) scaffolds prepared as semi-interpenetrating networks (semi-IPNs) with crosslinked linear-poly(epsilon-caprolactone)-diacrylate (PCL-DA, M-n similar to 10 kg mol(-1)) and linear-poly(l-lactic acid) (PLLA, M-n similar to 15 kg mol(-1)) [75/25 wt%] exhibited robust mechanical properties and accelerated degradation rates versus a PCL-DA scaffold control. However, their potential to treat irregular craniomaxillofacial (CMF) bone defects is limited by their relatively high fitting temperature (T-fit similar to 55 degrees C; related to the T-m of PCL) required for shape recovery (i.e. expansion) and subsequent shape fixation during press fitting of the scaffold, which can be harmful to surrounding tissue. Additionally, the viscosity of the solvent-based precursor solutions, cast over a fused salt template during fabrication, can limit scaffold size. Thus, in this work, analogous semi-IPN SMP scaffolds were formed with a 4-arm star-PCL-tetracryalate (star-PCL-TA) (M-n similar to 10 kg mol(-1)) and star-PLLA (M-n similar to 15 kg mol(-1)). To assess the impact of a star-polymer architecture, four semi-IPN compositions were prepared: linear-PCL-DA/linear-PLLA (L/L), linear-PCL-DA/star-PLLA (L/S), star-PCL-TA/linear-PLLA (S/L) and star-PCL-TA/star-PLLA (S/S). Two PCL controls were also prepared: LPCL (i.e. 100% linear-PCL-DA) and SPCL (i.e. 100% star-PCL-TA). The S/S semi-IPN scaffold exhibited particularly desirable properties. In addition to achieving a lower, tissue-safe T-fit (similar to 45 degrees C), it exhibited the fastest rate of degradation which is anticipated to more favourably permit neotissue infiltration. The radial expansion pressure exerted by the S/S semi-IPN scaffold at T-fit was greater than that of LPCL, which is expected to enhance osseointegration and mechanical stability. The intrinsic viscosity of the S/S semi-IPN macromer solution was also reduced such that larger scaffold specimens could be prepared.
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