合作客戶/
拜耳公司 |
同濟(jì)大學(xué) |
聯(lián)合大學(xué) |
美國保潔 |
美國強(qiáng)生 |
瑞士羅氏 |
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采用殼聚糖-三聚磷酸酯-百里香納米顆粒經(jīng)熱噴墨打印而成的新型活性包裝材料——結(jié)論、致謝!
來源:Unisense 瀏覽 1214 次 發(fā)布時間:2021-09-13
結(jié)論
與對照薄膜相比,印刷薄膜表現(xiàn)出改善的水蒸氣阻隔性能。 Qo 印刷薄膜比混合薄膜更有效。 與對照薄膜相比,印刷的 Qo 薄膜的斷裂伸長率降低,拉伸強(qiáng)度增加,而印刷的混合薄膜的伸長率和拉伸強(qiáng)度均增加。
Th 納米封裝印刷的效率取決于印刷層數(shù)、接觸角、添加到分散體中的甘油量和薄膜類型。 兩種薄膜中 Th 的傳遞都在 8 天時完成,表明這些薄膜是傳遞活性化合物的良好平臺。 然而,NQoThs 在薄膜中的分布表現(xiàn)出不同的釋放曲線; Qo 薄膜在第一階段表現(xiàn)出突釋,而混合薄膜表現(xiàn)出較慢的釋放。
與使用 NQos 印刷的薄膜相比,使用 NQoThs 印刷的薄膜對革蘭氏陽性菌(L. innocua 和 S. aureus)和革蘭氏陰性菌(S. typhimurium、E. aerogenes、P. aeruginosa 和 E. coli)表現(xiàn)出更高的 AM和對照膜。 革蘭氏陰性菌(鼠傷寒沙門氏菌、產(chǎn)氣大腸桿菌和大腸桿菌)獲得了最佳結(jié)果。
這些發(fā)現(xiàn)表明,可印刷納米技術(shù)的使用可以改善由可再生生物聚合物制備的薄膜的功能,因為這些薄膜可以提高水蒸氣阻隔性,作為傳遞活性化合物的良好平臺,并增加抗菌活性。 因此,這些薄膜可能有助于開發(fā)新的食品包裝材料。
致謝
作者要感謝 INNOVA-CORFO N度 12IDL2-13621 的財政支持。 我們感謝智利圣地亞哥大學(xué)的 Fernando Osorio 博士和 Ricardo Andrade 博士對接觸角測量的幫助。 我們還要感謝 Conicyt 授予 Nelson Caro 的博士獎學(xué)金。
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采用殼聚糖-三聚磷酸酯-百里香納米顆粒經(jīng)熱噴墨打印而成的新型活性包裝材料——摘要、簡介
采用殼聚糖-三聚磷酸酯-百里香納米顆粒經(jīng)熱噴墨打印而成的新型活性包裝材料——材料和方法