3.2. Molecular weight distribution

3.2. Molecular weight distribution of the extracted AmS using
different extraction methods การกระจายน้ำหนักโมเลกุลของ AMS สกัดโดยใช้วิธีการสกัดที่แตกต่างกัน
There is no doubt that the molecular weight of a polymer is one of the important factors that affect its physical properties. The molecular weight distribution (MWD) of sericin depends on the extraction method for the B. mori sericin and AmS. Therefore, it is important to examine the MWD of the extracted AmS from the above described extraction methods. The MWD of the native AmS collected directly from the silk gland has been reported. Similarlyto the B. mori sericin, AmS consist of more than 200 kDa, 200 kDa and 70 kDa polypeptides in addition to some low molecular weight polypeptides [23]. Fig. 2 shows the MWDs of the AmS that was extracted using the hot-water, NaCl, urea and urea–mercaptoethanol methods; all of the extracted AmS exhibited similar MWDs. There were two distinct regions: a small peak at the elution volume of approximately 7 ml and a broad band, for which the highest peak was observed at the elution volume of 14 ml. The molecular weight of the former was approximately
200 kDa, and the highest peak of the broad band was approximately 70 kDa. In these cases, the main AmS molecules had molecular weights of between 40 and 100 kDa. These results are consistent
with previous studies, in which a 70 kDa sericin has been isolated from NaCl extracts after ethanol precipitation. In the case of the urea–mercaptoethanol extraction, the 200 kDa AmS was
extracted in limited quantities from the A. mylitta cocoons, although this extraction method is most effective for the extraction of the 200 kDa sericin from B. mori cocoons [17]. The hot-water extraction
of the B. mori sericin also successfully yielded the 200 kDa sericin [18]. It appears that these extraction methods are inefficient for the extraction of the 200 kDa AmS. As described in the previous section, the degumming ratios from these methods are relatively low; therefore, these low degumming ratios might be due to a failure to extract the high-molecular weight sericin. As mentioned previously, these low ratios might be due to the structural differences between the B. mori and A. mylitta sericin. In contrast,
the Na2CO3 method was effective for the extraction of the 200 kDa AmS and the mid-range-molecular weight AmS. The relatively high degumming ratio of the Na2CO3 extraction was the result of the
successful extraction of the 200 kDa AmS. Apparently, Na2CO3 is effective for removing sericin from the AmS cocoon. The highest degumming ratio was obtained when the soap-alkaline extraction method was adopted. Here, Na2CO3 was used as the alkaline source. Because the role of the soap is limited to the isolation of the removed sericin, thereby preventing the re-adsorption of sericin, it is Na2CO3 that separates sericin from the cocoon. Furthermore, the MWD of the AmS extracted by this method is very similar to that of the B. mori sericin from the hot-water extraction. From these results, we conclude that the Na2CO3 extraction satisfies the requirements regarding the extraction efficiency and the MWD for
the polymeric application of AmS – most likely demonstrating the reason Na2CO3 is widely used for the extraction of AmS. However, no standard method for the Na2CO3 extraction has been previously
reported, as in the case of B. mori. Various concentrations of Na2CO3 are used, and the treatment times and temperatures also differ [9,10,13–15]. Therefore, we more closely considered the extraction
conditions when using Na2CO3 as the agent to extract sericin from A militta