Abstract

In this study, we utilized a mandrel rotating collector consisting of two parallel, electrically conductive pieces of tape to fabricate aligned electrospun polycaprolactone/gelatin (PG) and carbon nanotube/polycaprolactone/gelatin (PGC) nanofibrous matrices. Furthermore, we examined the biological performance of the PGC nanofibrous and film matrices using an in vitro culture of RT4-D6P2T rat Schwann cells. Using cell adhesion tests, we found that carbon nanotube inhibited Schwann cell attachment on PGC nanofibrous and film matrices. However, the proliferation rates of Schwann cells were higher when they were immobilized on PGC nanofibrous matrices compared to PGC film matrices. Using western blot analysis, we found that NRG1 and P0 protein expression levels were higher for cells immobilized on PGC nanofibrous matrices compared to PG nanofibrous matrices. However, the carbon nanotube inhibited NRG1 and P0 protein expression in cells immobilized on PGC film matrices. Moreover, the NRG1 and P0 protein expression levels were higher for cells immobilized on PGC nanofibrous matrices compared to PGC film matrices. We found that the matrix topography and composition influenced Schwann cell behavior.

1. Introduction

Nerve autografts are considered the “gold standard” for the repair of long gaps caused by nerve damage. These materials are harvested from another site in the body and are typically not rejected by the immune system. Nevertheless, the harvesting step requires an additional surgical procedure that can cause donor site morbidity and patient discomfort. Allografts, obtained from human cadavers or living donors, often are rejected by the host; thus, their efficiency, application, and availability are limited [13]. Nerve grafts made of natural and synthetic materials are thus a promising alternative for promoting successful nerve regeneration because they have the potential to overcome many of the drawbacks associated with autologous and allogeneic nerve grafting.

Polycaprolactone (PCL) has recently been used in a variety of tissue engineering applications because of its high toughness and cost efficiency [4]. However, cells exposed to PCL do not behave favorably because PCL has lower hydrophilicity than natural ECM. Gelatin is obtained by partial hydrolysis of native collagen in acidic or alkaline environments. Gelatin exhibits excellent biocompatibility and biodegradability, and it has been widely used as a component in many biomedical materials, including wound dressings, drug release structures, and tissue-engineered bone, skin, cartilage, and nerve [5, 6]. Carbon nanotubes (CNTs) are promising for use in regenerative medicine due to their unique electrical, mechanical, chemical, and biological properties and their ease of combination with various biological compounds [7, 8]. When CNTs are incorporated into biopolymers, electrically conductive scaffolds that can support both Schwann cells and neurons can be synthesized [9].

Electrospinning can be readily utilized to fabricate ultrafine fibers with average diameters ranging from the submicrometer to nanometer scale. Advantageously, fibrous matrices that have been synthesized using electrospinning display high specific surface areas, high aspect ratios, and high porosity surfaces. More importantly, the topological structures of these matrices can mimic that of the extracellular matrix and enhance cell migration, proliferation, and differentiation [10, 11].

Aligned fibers prepared via electrospinning enhance Schwann cell maturation to a greater degree compared to randomly oriented fibers [12]. In the past, aligned fibers have been produced using a variety of methods [13, 14]. Li et al. fabricated aligned nanofibers using a collector consisting of two parallel, electrically conductive substrates separated by a gap [15]. Matthews et al. collected circumferentially aligned electrospun fibers on a mandrel rotating at a high speed [16]. In this paper, we discuss the fabrication of electrospun nanofibrous matrices in which the fibers are aligned along the longitudinal axis of a mandrel using a rotating collector containing two parallel, electrically conductive pieces of tape.

It is challenging and difficult to promote nervous system regeneration. However, the peripheral nervous system has an intrinsic ability to repair and regenerate axons; Schwann cells enhance such regeneration after damage occurs [17]. The aim of this study was to fabricate aligned carbon nanotube/polycaprolactone/gelatin nanofibrous matrices and investigate their potential as neurografts for peripheral nerve repair.

2. Materials and Methods

2.1. Reagents

Gelatin (type A) and polycaprolactone were purchased from the Sigma Aldrich Chemical Company (St. Louis, MO, USA). Carbon nanotubes were purchased from the Golden Innovation Business Co. Ltd. (New Taipei City, Taiwan). RT4-D6P2T rat Schwann cells were purchased from the BCRC (Bioresource Collection and Research Center, Hsinchu, Taiwan). Dulbecco’s modified Eagle medium (DMEM), fetal bovine serum (FBS), and trypsin were purchased from GIBCO (Grand Island, NY, USA). All of the other chemicals used herein were of reagent grade unless stated otherwise.

2.2. Acid-Oxidized CNTs

The surfaces of the CNTs were functionalized according to the method delineated by Xiao et al. [18]. Briefly, 0.1 g of pristine CNTs was added to 20 mL of hydrochloric acid (36.5 wt%) and stirred for 2 hours at a moderate speed. Then, the CNTs were diluted with water, filtered, washed with deionized water, and dried under vacuum at 60°C overnight. Afterward, the pretreated CNTs were put into 15 mL of nitric acid (HNO3) (65 wt%) and heated at 140°C for 4 hours. The CNTs were subsequently cooled to room temperature; then the entire of acid-oxidized CNT process was repeated one time.

2.3. Characterization of Acid-Oxidized CNTs

ATR-FTIR spectra of pristine and acid-oxidized CNTs were obtained using a Bruker spectrometer. The spectra were obtained using 64 scans with a resolution of 4 cm−1 in the range of 600–4000 cm−1.

2.4. Preparation of CNT/Polycaprolactone/Gelatin Nanofibrous Matrices

Gelatin and polycaprolactone powders (42.5 mg of each) were dissolved in 1 mL 1,1,1,3,3,3-hexafluoro-2-propanol (HFIP). Acid-oxidized CNTs were then added to the HFIP solution of polycaprolactone/gelatin and dissolved using vortexing until the solution became homogeneous. In preparation for electrospinning, the polymer solution was placed into a 5 mL syringe fitted with a needle (tip diameter = 0.96 mm) and attached to a syringe pump that provided a steady solution flow rate. A voltage was applied to the needle using a high voltage power supply; the tip-to-collector distance was fixed.

2.5. Preparation of CNT/Polycaprolactone/Gelatin Films

CNT/polycaprolactone/gelatin (PGC) thin films were prepared using the spin-coating method. The PGC solution was spin-coated onto cover glass (diameter = 10 mm) at 4000 rpm for 3 seconds. The films were dried in air at room temperature.

2.6. Characterization of the Electrospun Nanofibers

The morphologies of the PG and PGC fibers were examined by scanning electron microscopy (Hitachi S-4800). Briefly, the electrospun matrices were sputter-coated with gold and then visualized using a scanning electron microscope (accelerating voltage = 5 kV). The diameters of the fibers were determined manually from the SEM images using ImageJ (ImageJ software 1.42, National Institutes of Health, USA).

2.7. Schwann Cell Culture on PG and PGC Matrices

PG and PGC matrices were placed in 24-well tissue culture plates containing a suspension of RT4-D6P2T rat Schwann cells (BCRC no. 60508) (5  104 cells/well) in DMEM supplemented with 10% v/v FBS, 100 U/mL of penicillin, and 100 g/mL of streptomycin. The cultures of these cell-seeded matrices were harvested after 4 hours so that cell attachment assays could be completed and on days 1, 3, 5, and 7 so that cell proliferation assays could be performed. Cell viabilities were determined using MTT assays. In each experiment, the amount of dye formed was immediately measured using a microplate reader (Biotek uQuant) (wavelength = 570 nm). At each time point, the number of cells attached to three matrices was measured.

2.8. Fluorescent Staining of the Cytoskeleton

The morphologies of the cells were examined by fluorescently staining their F-actin cytoskeletons with fluorescein isothiocyanate- (FITC-) conjugated phalloidin and their nuclei with DAPI. Cells were cultured for 1 day, fixed with 3.7% paraformaldehyde in phosphate buffer for 10 minutes, and washed twice with 0.02 M PBS (pH 7.4). The cells were then rinsed in PBS containing 0.1% Triton X-100 for 5 minutes. The samples were blocked with 1% bovine serum albumin (BSA) in PBS for 1 hour to reduce nonspecific background staining. After blocking, the BSA solution was aspirated, and the samples were incubated with 6.4 M FITC-conjugated phalloidin for 20 minutes. The cells were then incubated with a solution of DAPI for 5 minutes to stain the DNA in the cells. The samples were washed three times with PBS (for 5 minutes each) and analyzed using a fluorescence microscope.

2.9. Immunoblotting Analysis

Cells were seeded on PG and PGC matrices (3  104 cells/cm2, in media). Immunoblotting was performed to detect the Schwann cell-specific proteins neuregulin 1 (NRG1) and myelin protein zero (P0) after 3 days of culture. Cells were collected and lysed in lysis buffer. The supernatants were obtained by centrifugation (15,000 g for 10 minutes) at 4°C. The concentration of protein was analyzed using a Bradford Coomassie assay. The proteins (30 g/L) were fractionated by electrophoresis and electrotransferred to a polyvinylidene difluoride film (PVDF). Blocking was performed using 5% w/v nonfat milk, and primary antibodies were applied to the membrane overnight at 4°C. The primary antibodies were diluted with fresh blocking buffer to the designated concentration and applied to the membrane at 4°C overnight. Antibodies specific to NRG1 (Santa Cruz Biotechnology, Inc., sc-28916), P0 (Santa Cruz Biotechnology, Inc., sc-18531), and nucleophosmin B23 (Invitrogen 325200) were used. After incubation with a secondary antibody, the immunoreactive bands were visualized using enhanced chemiluminescence detection (Millipore WBKLS0500). Nucleophosmin B23 was used as the internal control.

3. Results and Discussion

The pristine CNTs were quite hydrophobic. Hence, the pristine CNTs precipitated from the HFIP solution. Nitric acid was used to introduce oxygen-containing functional groups, such as carboxylic acids and hydroxyls, onto the ends and defect sites of the CNT surfaces [19]. Figure 1 shows the ATR-FTIR spectra of pristine CNTs and acid-oxidized CNTs. The absorption peaks centered at 1594 cm−1 correspond to the asymmetric –COO– stretching bands. The absorption peaks at 3443 cm−1 correspond to the –OH stretch. We found that the acid-oxidized CNTs have better dispersibility in HFIP. The zeta potentials of the pristine CNTs and acid-oxidized CNTs were measured to be −5.05  0.56 mV and −23.8  0.87 mV, respectively.

Figure 2 shows transmission electron microscopy images of nanofibers containing PG and PGC. Individual CNTs were successfully embedded in the polycaprolactone/gelatin nanofibers, indicating that the original dispersion contained individual CNTs rather than CNT aggregates.

Under the same electrospinning conditions, the fiber diameters were 671  145 nm, 331  111 nm, and 440  140 nm for PG, PG3C, and PG5C matrices, respectively (Table 1 and Figure 3). The diameters of the fibers decreased and then increased as the concentration of CNTs was increased. The conductivity of the polymer was increased when the CNTs were added. Previously, we found that when the charge density on the surface of the electrospinning jet was increased, higher electrostatic forces were induced, resulting in the formation of smaller diameter fibers [20]. In addition, the viscosity of the polymer solution also affects the diameter of the nanofibers. The diameters of the electrospun fibers increased as the viscosity of the polymer solution increased [21]. The viscosity of the polymer solution also increased when CNTs were added. These factors likely explain why the mean fiber diameters decrease when lower CNTs concentrations are used and increase when higher CNTs concentrations are used.

A schematic of the experimental setup used to align the fibers is shown in Figure 4(a). A cylinder collector was used to gather the aligned nanofibers. The radius of the cylinder collector was 7.6 cm, and the rotation speed of the mandrel was set to 13 rpm. The distance between the two pieces of parallel conductive carbon tape was 2 cm. A cross section of the cylinder collector is shown in Figure 4(b). The literature has demonstrated that the diameters of the electrospun fibers can affect cell behavior [2224]. We fabricated aligned PG and aligned PGC fibers with similar diameters by adjusting the parameters of the experiment. The diameters of the synthesized fibers were 785  155 nm, 828  169 nm, and 710  156 nm for the PG, PG3C, and PG5C systems, respectively (Figure 5 and Table 2). The diameters of these fibers were not significantly different (). The average orientation angles of the nanofibers were measured using SEM. The angular distributions of the nanofibers were determined by fitting the relative frequencies of the angle between the long axes of the fibers and their expected direction for each sample to a Gaussian curve. The full width at half maximum (FWHM) values of these curves was 26°, 21°, and 43° for the PG, PG3C, and PG5C samples, respectively (Figure 5). In the past, researchers have used high-speed (500 rpm) rotating cylinder collectors to fabricate aligned electrospun nanofibers [25, 26]. In this study, we fabricated aligned electrospun nanofibrous matrices at much slower speeds; the alignment direction of the nanofibers is along the longitudinal axis of the mandrel. However, we found that the CNTs influenced the alignment of the nanofibers.

Cell behaviors, including adhesion, spreading, proliferation, and differentiation, are sensitive to the surface topography and molecular composition of the matrix. To evaluate the effect of the CNTs on cell behavior, we incubated RT4-D6P2T rat Schwann cells on PG and PGC nanofiber and film matrices. The attachment and proliferation rates of the Schwann cells gradually decreased when the amount of CNTs was gradually increased when either PGC nanofiber matrices or PGC film matrices were used (Figure 6). Behan et al. [9] found that although CNTs have little effect on Schwann cell viability, they do inhibit their ability to proliferate. Kaiser et al. [27, 28] also demonstrated that CNTs can attach to integrin receptors and can therefore affect cell functions, such as adhesion, spreading, focal adhesion, and cytoskeletal development. Schwann cells proliferated more actively on PGC nanofiber matrices than on PGC film matrices. The CNTs likely disperse on the surface of the PGC film matrices and directly interfere with cell proliferation (Figure 7). However, the CNTs are embedded in the nanofibers of the PGC nanofibrous matrices, reducing their interaction with the Schwann cells.

The morphologies of the Schwann cells that adhered to the PG and PGC nanofiber and film matrices were investigated. Their actin cytoskeletons were stained with FITC-phalloidin and visualized using a fluorescence microscope. The Schwann cells aligned along the direction of the nanofibers with typical bipolar morphologies (Figures 8(a)8(c)). However, Schwann cells attached to the film matrices in random directions (Figures 8(d)8(f)).

Schwann cells are heavily involved in the peripheral nerve repair process. These cells synthesize and secrete important substances, such as myelin protein zero (P0) and neuregulin 1 (NRG1). NRG1 is essential for the myelination of axons and the development of Schwann cells [29]. P0 is expressed by myelinating Schwann cells, and it is the major adhesive and structural protein of the myelin sheath surrounding peripheral nerves [30, 31]. Some studies have demonstrated that P0 promotes the regeneration of injured axons [32]. Using western blot analysis, we found that the NRG1 and P0 protein expression levels were higher for cells immobilized on the PGC nanofibrous matrices than for those immobilized on the PG nanofibrous matrices. However, the CNTs inhibited NRG1 and P0 protein expression in Schwann cells immobilized on the PGC film matrices. Moreover, the NRG1 and P0 protein expression levels were higher for cells immobilized on the PGC nanofibrous matrices than for those immobilized on the PGC film matrices (Figure 9). These results suggest that Schwann cell maturation is favored on fibrous matrices, as opposed to film matrices, and that CNTs enhance Schwann cell maturation on PGC fibrous matrices.

4. Conclusion

Schwann cells grown on aligned CNT/polycaprolactone/gelatin nanofibrous matrices show higher cell proliferation levels, align along the directionality of the nanofibres with typical bipolar morphologies, and exhibit higher levels of P0 protein expression compared to those grown on CNT/polycaprolactone/gelatin film matrices. These findings suggest that the CNT/polycaprolactone/gelatin nanofibrous matrices could potentially be used for the repair of injured peripheral nerves.

Conflict of Interests

The authors declare that there is no conflict of interests regarding the publication of this paper.