Post-treatments of polydopamine coatings influence cellular response.

Polydopamine (PDA) is the final oxidation product of dopamine or other catecholamines. Since the first reports of PDA coatings starting around 2007, these coatings have been widely studied as a versatile and inexpensive one-step coating option for biomaterial functionalization. The coating attach to a wide range of materials and can subsequently be modified with biomolecules or nanoparticles. However, as a strong candidate for biomaterial research and even clinical use, it is important to unravel the changes in physico-chemical properties and the cell-PDA interaction as a function of heat sterilization procedures and shelf storage periods. Four groups were examined in this study: titanium (Ti), PDA-coated Ti samples and PDA-coated Ti samples either stored for up to two weeks at room temperature or heated at 121 °C for 24 h, respectively. We used X-ray Photoelectron Spectroscopy (XPS), Time-of-Flight Secondary Ion Mass Spectrometry (ToF-SIMS) and Water contact angle (WCA) to characterize chemical composition and surface properties of the groups. Cell adhesion and proliferation was examined by three different cell types: human primary dermal fibroblasts (hDF), human epidermal keratinocytes (HaCaTs) and a murine preosteoblastic cell line (MC3T3-E1), respectively. Cells were cultured on PDA coated samples for 4 h, 3 days and 5 days. Both thermal treatment of PDA at 121℃ for 24 h and storage of the samples for 2 weeks increased the amount of quinone groups at the surface and decreased the amount of primary amine groups as detected by XPS and ToF-SIMS. Even though these surface reactions increased the WCA of the PDA coating, we found that the post-treatments increased cell proliferation for both hDFs, HaCaTs and MC3T3-E1 s as compared to pristine PDA. This emphasizes the importance of post-treatment and shelf-time for PDA coatings.

Electrospun PCL/PEO coaxial fibers for basic fibroblast growth factor delivery.

The poor innate healing capacity of fibroblastic tissues, such as pelvic floor fascia, is attributed to the scarcity of fibroblasts to produce collagen, as the main collagen producing cells. Coaxial electrospun PCL/PEO fibers containing basic fibroblast growth factor (FGF-2) were evaluated for the local and temporal delivery of FGF-2 for promoting fibroblast proliferation. PCL/PEO coaxial fibers with a highly porous surface were successfully developed using coaxial electrospinning. The diameter of the PCL/PEO microfibers produced by coaxial electrospinning could be tuned by the electrospinning parameters. XPS surface chemistry probing and CA wettability analysis confirmed that the outer surface of the coaxial fibers is PCL. The protein was successfully encapsulated and a sustained release was observed over more than 9 days. In vitro, PCL/PEO coaxial fibers supported fibroblast cell adhesion. In addition, PCL/PEO coaxial fibers containing FGF-2 significantly enhanced fibroblast cell viability and proliferation. Further, Coll-I expression was significantly expressed after day 1 while down-regulated after day 9 compared to the control group. These results indicate that coaxial polymeric fibers allow local and sustained growth factor delivery with prolonged efficacy and longevity for connective tissue regeneration.