NMA-HTCC is a kind of water soluble, strong cationic and highly reactive chitosan derivative. 2-hydroxypropyltrimethyl ammonium chloride chitosan (short for HTCC) is synthesized by the chemical reaction of chitosan and 2,3-epoxypropyltrimethyl ammonium chloride, and then NMA-HTCC is synthesized by the chemical reaction of HTCC and N-(hydroxymethyl) –acrylamide [6–9]. NMA-HTCC has a good antibacterial property, and can be used as cationic surface-active agent, metal ion flocculant, and so on. Some scholars observed that NMA–HTCC had excellent antimicrobial activity against both
Cationic modification of silk fabric may change the microstructure of silk fiber, and further affect its properties. Thus NMA-HTCC was used for the modification of
Chitosan, 2,3-epoxy propyl trimethyl ammonium chloride and isopropanol were put into a 4-mouth flask. The solutions were reacted at 80 °C for 12 h in a water bath, washed with ethanol and acetone after cooling, then filtrated, dried, and the yellow product obtained was HTCC. After that, HTCC, N-methylol acrylamide, 4-methoxyphenol and NH4Cl were put into the flask and stirred evenly until dissolution. The solutions were reacted at 140 °C for 15 min in the oil bath. Ethyl alcohol and acetone were put into the reaction solutions and stirred to precipitate the product [6,8]. The product was washed in the mixture of ethyl alcohol-acetone and dried. Finally, the white product obtained was NMA-HTCC. The reaction equation was as follows.
NMA-HTCC contains reactive groups, such as methacrylamide groups. The side double bond of this group can undergo a crosslinking reaction with hydroxyl groups on silk fiber molecules under alkaline conditions. Alkaline sodium bicarbonate as a catalyst can not only catalyze crosslinking reactions but also facilitate effective permeation of NMA-HTCC into fiber by reducing the hydrolysis of NMA-HTCC and promoting the swelling of silk fiber. NMA-HTCC solution was prepared with a bath solution ratio of 1:50 and mass percent of NMA-HTCC, and NaHCO3 was 6 % and 8 %, respectively [1,4,6,13]. The treatment process was as follows: silk fiber→ treated in NMA-HTCC solution at 60°C in the water bath for 1h→ pre-baked in an oven at 80°C for 5 min→ baked in the oven at 160°C for 3 min→ washed with deionized water→ dried at 80 °C. The reaction equation was as follows.
A Nicolet 5700 FT-IR spectrophotometer was used to observe the infrared spectra of the silk fiber with the traditional transmission technique of KBr pellets. The measurements were performed at 20°C and a relative humidity of 65 %.
The surface morphology of the silk fibers before and after being treated with NMA-HTCC was observed by a Quanta 200 scanning electron microscope. The measurements were performed at 20°C and a relative humidity of 65 %.
XRD patterns of silk powder samples were obtained by D/MAX-IIIC type X-ray diffraction with a tube voltage of 40 kV, tube current of 30 mA, and scan speed of 2°/min. The X-ray diffraction intensity curves of the three kinds of silk fibers were fitted by peakfit software, and their crystallinity was calculated by the peak separation method.
XPS spectra were observed by an XSAM 800 electron spectrometer. The samples were analyzed using MgKα radiation (1253.6 eV) operating under a working pressure of 2×10-7 Pa in 0.1 eV steps with 100 eV analyzer pass energy. The X-ray anode was run at 180 W and the high voltage was kept at 12.0 kV. The position of the carbon peak (284.8 eV) for C1s was used to calibrate the XPS scale for all substrates. XPS data fitting was performed using the software with 100 % Gaussian curve fitting.
Differential scanning calorimetry curves of silk powder samples were obtained by a CDR-4 type differential thermal analyzer with a heating rate of 5°C/min, a scanning temperature range from room temperature to 450°C, air with nitrogen, and a flow rate of 120 ml/min.
The breaking strength and breaking elongation of the silk yarn were determined on a YG020 type electronic single yarn strength tester at an effective gauge length of 250 mm and extension rate of 250 mm/min. The samples were put in a room with a temperature of 20°C and relative humidity of 65 % for more than 2 days before measurement. Each sample was tested 10 times and the result was averaged with 10 data.
AATCC 100-2012 (Assessment of antibacterial finishes on textile materials) was conducted to evaluate the antibacterial activities of the silk fibers before and after being treated with NMA-HTCC.
The longitudinal surfaces of the silk fibers before and after treatment with NMA-HTCC were morphologically observed by SEM. The longitudinal surface of the silk fiber before treatment, shown in Figure 1(a), was smooth, while many adhesive substances appeared on the surface when it was treated with NMA-HTCC, shown in Figure 1(b). This was mainly because NMA-HTCC had the fiber reactive methyl acrylamide group, whose side double bond could directly crosslink with the silk fiber under the alkaline condition. It indicated that NMA-HTCC had undergone a crosslinking reaction with the silk fibers[7–8].
FT-IR spectra of the silk fibers before and after being treated with NMA-HTCC solution are shown in Figure 2. Two new peaks at 1535 cm-1 and 1670 cm-1 appeared after treatment with NMA-HTCC, which corresponded to the N-H bending and C=O stretch of the secondary amide in the acrylamidomethyl group of the NMA-HTCC molecule, respectively. On the other hand, the peak at 1630 cm-1 corresponding to the C=C stretch of the conjugated vinyl group did not appear after treatment with NMA-HTCC, because the C=C bond was a reactive group of NMA-HTCC [6,8,14], which disappeared when NMA-HTCC reacted with the silk fibers. All of these displayed that NMA-HTCC had undergone a cross-linking reaction with the silk fiber and successfully entered into the fiber.
Figure 3 shows the XRD curves for the silk fibers before and after NMA-HTCC solution treatment. The 2θ of two characteristic absorption peaks on curve (a) was very close to that on curve (b), illustrating that treatment with NMA-HTCC could not change the crystalline structure of silk fiber. The crystallinity of silk samples before and after NMA-HTCC treatment were calculated by the peakfit method, with the results showing that the crystallinity of the silk fiber was 48.26 %, while it increased greatly to 61.37 % after treatment with NMA-HTCC [15]. It illustrated that the crystallinity of the silk fiber could be increased significantly by treatment with NMA-HTCC. The reason was that the high temperature baking provided more chances for silk fiber to react with the active group in the NMA-HTCC molecule, and it was easy for NMA-HTCC to enter into the silk fiber; thus, the internal structure of the silk fiber was enhanced, and the diffracted intensity of the characteristic absorption peak and the crystallinity of the silk fiber were both increased.
Figure 4 shows the DSC curves for the silk fibers before and after NMA-HTCC solution treatment. Similar characteristics are shown on two curves, where the thermal decomposition of the endothermic temperature was 322°C and 335°C, respectively, and the thermal decomposition and absorption of heat was 326.9 J/g and 351.6 J/g, respectively. It illustrated that the thermal decomposition of the endothermic temperature and absorption of heat of the silk fiber were significantly increased after the NMA-HTCC treatment [6]; thus, the internal aggregation structure of the silk fiber treated with NMA-HTCC was much closer and its thermal stability was obviously enhanced.
The chemical composition of the silk fiber surfaces was determined by X-ray photoelectron spectroscopy. The N1s XPS spectra of the silk fibers before and after being treated with NMA-HTCC are shown in Figure 5. From Figure 5(a), we observe that N1s XPS spectra of the silk fiber only had one peak at 399.7 eV, while that of the silk fiber after treatment had two peaks at 400.50eV and 399.50 eV in Figure 5(b). It implies that the nitrogen binding mode of the silk fiber had changed after treatment with NMA-HTCC, which was the result of the cross-linking reaction between the NMA-HTCC molecule and silk fibroin[16]. A composition analysis of N(1s) is shown in Table.1 from which we can calculate that the peak area of 399.50 eV accounted for 46.1 % and the peak area of 400.50 eV for 53.9 %.
Parameter of peak | Before treatment | After treatment | |
---|---|---|---|
0 peak | 1 peak | ||
Binding energy/eV | 399.70 | 399.50 | 400.50 |
Half peak width/eV | 2.13 | 1.89 | 1.99 |
Peak area | 251.67 | 68.16 | 79.68 |
Element content on the surface of the silk fiber before and after NMA-HTCC treatment is shown in Table.2, from which we observe that the content of the N element was significantly reduced. This is mainly because that the content of the N element in the NMA-HTCC macromolecule is obviously lower than that in the silk fiber. When a certain amount of NMA-HTCC reacts with silk fibroin fiber, the overall content of the N element will drop, which implies that the NMA-HTCC molecule has undergone a cross-linking reaction with the silk fibroin.
Element composition | Surface element content of silk fiber (%) | Change rate (%) | |
---|---|---|---|
Before treatment | After treatment | ||
C | 83.44 | 86.19 | + 3.30 |
O | 9.42 | 8.79 | -6.69 |
N | 5.20 | 2.19 | -57.88 |
Figure 6 shows the breaking strength and breaking elongation of silk fibers before and after NMA-HTCC treatment. Compared with the untreated sample, the breaking strength and elongation of silk fiber after being treated with NMA-HTCC were significantly increased. This is principally because when NMA-HTCC molecules enter into the internal structure of silk fiber, the binding force between the silk fibroin molecules is enhanced, and the internal structure of silk fibers is closer thus, the mechanical properties of silk fibers are improved.
Figure 7 shows the bacterial reduction rate of silk fibers treated by NMA-HTCC against
In order to prepare cationic silk fiber, NMA-HTCC, which is a kind of strong cationic chitosan derivative, was used for the modification of