Tomihata K, Ikada Y
Research Center for Biomedical Engineering, Kyoto University, Japan.
Biomaterials. 1997 Apr;18(7):567-75. doi: 10.1016/s0142-9612(96)00167-6.
Chitin was deacetylated to various extents with NaOH to obtain partially and thoroughly deacetylated chitins. The specimens used in this study were deacetylated by 0 (chitin), 68.8, 73.3, 84.0, 90.1 and 100 mol% (chitosan). Films with a thickness of 150 microns were prepared from these specimens by the solution casting method. The equilibrated water contents of the films were 52.4 (chitin), 73.8 (68.8 mol%), 64.2 (73.3 mol%), 61.8 (84.0 mol%), 57.8 (90.1 mol%) and 49.7 wt% (chitosan), while the tensile strengths of the water-swollen films were 244 (chitin), 197 (68.8 mol%), 232 (73.3 mol%), 320 (84.0 mol%), 293 (90.1 mol%) and 433 g mm-2 (chitosan). The maximum water content and the minimum tensile strength observed for a specimen deacetylated between 0 and 68.8 mol% may be ascribed to the lowered crystallinity by deacetylation of chitin, since both chitin and chitosan are crystalline polymers. Unlike their physical properties, in vitro and in vivo degradations of these films occurred less rapidly without passing a maximum or minimum, as their degree of deacetylation became higher. The in vitro degradation was carried out by immersing the films in buffered aqueous solution of pH 7 containing lysozyme at 37 degrees C, while the in vivo degradation was studied by subcutaneously implanting the films in the back of rats. It was found that the rate of in vivo biodegradation was very high for chitin and 68.8 mol% deacetylated chitin, compared with that for the 73.3 mol% deacetylated chitin. The films which were more than 73.3 mol% deacetylated showed slower biodegradation. Interestingly, the tissue reaction towards highly deacetylated derivatives including chitosan was very mild, although they had cationic primary amines in the molecule.
用氢氧化钠将几丁质脱乙酰化至不同程度,以获得部分脱乙酰化和完全脱乙酰化的几丁质。本研究中使用的样品脱乙酰化程度分别为0(几丁质)、68.8、73.3、84.0、90.1和100 mol%(壳聚糖)。通过溶液浇铸法由这些样品制备了厚度为150微米的薄膜。薄膜的平衡含水量分别为52.4(几丁质)、73.8(68.8 mol%)、64.2(73.3 mol%)、61.8(84.0 mol%)、57.8(90.1 mol%)和49.7 wt%(壳聚糖),而水溶胀薄膜的拉伸强度分别为244(几丁质)、197(68.8 mol%)、232(73.3 mol%)、320(84.0 mol%)、293(90.1 mol%)和433 g mm-2(壳聚糖)。在0至68.8 mol%之间脱乙酰化的样品观察到的最大含水量和最小拉伸强度,可能归因于几丁质脱乙酰化导致结晶度降低,因为几丁质和壳聚糖都是结晶聚合物。与它们的物理性质不同,随着脱乙酰化程度的提高,这些薄膜的体外和体内降解发生得较慢,且没有出现最大值或最小值。体外降解是通过将薄膜浸泡在37℃含溶菌酶的pH 7缓冲水溶液中进行的,而体内降解是通过将薄膜皮下植入大鼠背部进行研究的。发现几丁质和68.8 mol%脱乙酰化几丁质的体内生物降解速率比73.3 mol%脱乙酰化几丁质的高。脱乙酰化程度超过73.3 mol%的薄膜显示出较慢的生物降解。有趣的是,尽管壳聚糖等高脱乙酰化衍生物分子中含有阳离子伯胺,但组织对它们的反应非常轻微。
