厦门大学学报(自然科学版)
廈門大學學報(自然科學版)
하문대학학보(자연과학판)
JOURNAL OF XIAMEN UNIVERSITY (NATURAL SCIENCE)
2009年
4期
547-553
,共7页
苄基壳聚糖%溶致液晶%取代基%临界浓度%氢键%分子模拟
芐基殼聚糖%溶緻液晶%取代基%臨界濃度%氫鍵%分子模擬
변기각취당%용치액정%취대기%림계농도%경건%분자모의
N-benzyl chitosan%lyotropic liquid crystalline%substituent%critical concentration%hydrogen bonding%molecular simulation
合成了4种N-苄基化壳聚糖衍生物,即N-(2-羟基苄基)壳聚糖、N-(3-羟基苄基)壳聚糖、N-(4-羟基苄基)壳聚糖和N-(3-甲氧基-4-羟基苄基)壳聚糖(分别简写为NOCS、NMCS、NPCS和NMPCS),它们的取代基上官能团的数目和位置不同.N-取代度相近,分别为0.72,0.62,0.71和0.68.衍生物溶解在甲酸溶液中均呈现胆甾型溶致液晶相.用偏光显微镜法和折射率法测得各衍生物的液晶临界浓度w分别为28%,37%,24%和27%,均比纯壳聚糖的12%有很大提高,因为取代基的引入破坏了壳聚糖分子内与分子间非常强烈的氢键作用.通过分子模拟,对4种壳聚糖衍生物分别从分子内氢键作用与分子间氢键作用两个方面进行了比较.在分子内氢键方面,NOCS较强,NMCS、NPCS和NMPCS均较弱.在分子间氢键方面,NOCS较弱,NMCS居中,NPCS与NMPCS较强.将分子内或分子间氢键作用与临界浓度相联系,可见分子内氢键强(如NOCS)或者分子间氢键强(如NPCS,NMPCS),都显著地提高了分子链的刚性,分子链的排列与取向更加规整,因而降低了壳聚糖衍生物的液晶临界浓度,这两个因素只要具备一个即可.若两者都不强(如NMCS),则分子链的刚性较小,临界浓度明显较高(37%).对于该体系,氢键的强弱对液晶临界浓度有着决定性的影响.
閤成瞭4種N-芐基化殼聚糖衍生物,即N-(2-羥基芐基)殼聚糖、N-(3-羥基芐基)殼聚糖、N-(4-羥基芐基)殼聚糖和N-(3-甲氧基-4-羥基芐基)殼聚糖(分彆簡寫為NOCS、NMCS、NPCS和NMPCS),它們的取代基上官能糰的數目和位置不同.N-取代度相近,分彆為0.72,0.62,0.71和0.68.衍生物溶解在甲痠溶液中均呈現膽甾型溶緻液晶相.用偏光顯微鏡法和摺射率法測得各衍生物的液晶臨界濃度w分彆為28%,37%,24%和27%,均比純殼聚糖的12%有很大提高,因為取代基的引入破壞瞭殼聚糖分子內與分子間非常彊烈的氫鍵作用.通過分子模擬,對4種殼聚糖衍生物分彆從分子內氫鍵作用與分子間氫鍵作用兩箇方麵進行瞭比較.在分子內氫鍵方麵,NOCS較彊,NMCS、NPCS和NMPCS均較弱.在分子間氫鍵方麵,NOCS較弱,NMCS居中,NPCS與NMPCS較彊.將分子內或分子間氫鍵作用與臨界濃度相聯繫,可見分子內氫鍵彊(如NOCS)或者分子間氫鍵彊(如NPCS,NMPCS),都顯著地提高瞭分子鏈的剛性,分子鏈的排列與取嚮更加規整,因而降低瞭殼聚糖衍生物的液晶臨界濃度,這兩箇因素隻要具備一箇即可.若兩者都不彊(如NMCS),則分子鏈的剛性較小,臨界濃度明顯較高(37%).對于該體繫,氫鍵的彊弱對液晶臨界濃度有著決定性的影響.
합성료4충N-변기화각취당연생물,즉N-(2-간기변기)각취당、N-(3-간기변기)각취당、N-(4-간기변기)각취당화N-(3-갑양기-4-간기변기)각취당(분별간사위NOCS、NMCS、NPCS화NMPCS),타문적취대기상관능단적수목화위치불동.N-취대도상근,분별위0.72,0.62,0.71화0.68.연생물용해재갑산용액중균정현담치형용치액정상.용편광현미경법화절사솔법측득각연생물적액정림계농도w분별위28%,37%,24%화27%,균비순각취당적12%유흔대제고,인위취대기적인입파배료각취당분자내여분자간비상강렬적경건작용.통과분자모의,대4충각취당연생물분별종분자내경건작용여분자간경건작용량개방면진행료비교.재분자내경건방면,NOCS교강,NMCS、NPCS화NMPCS균교약.재분자간경건방면,NOCS교약,NMCS거중,NPCS여NMPCS교강.장분자내혹분자간경건작용여림계농도상련계,가견분자내경건강(여NOCS)혹자분자간경건강(여NPCS,NMPCS),도현저지제고료분자련적강성,분자련적배렬여취향경가규정,인이강저료각취당연생물적액정림계농도,저량개인소지요구비일개즉가.약량자도불강(여NMCS),칙분자련적강성교소,림계농도명현교고(37%).대우해체계,경건적강약대액정림계농도유착결정성적영향.
Four N-benzyl chitosan derivatives,i.e.N-(2-hydroxyl-benzyl)chitosan (NOCS), N-(3-hydroxyl-benzyl)chitosan (NMCS),N-(4-hydroxyl-benzyl)chitosan (NPCS) and N-(3-methoxyl-4-hydroxyl-benzyl)chitosan (NMPCS),were synthesized,the number and position of the functional groups in the substituents of which were different.The degrees of NOCS,NMCS,NPCS and NMPCS were close to each other,which were 0.72,0.62, 0.71 and 0.68,respectively.The lyotropic cholesteic liquid crystalline phase was observed in the formic acid solutions of the four chitosan derivatives.The critical concentrations of NOCS,NMCS,NPCS and NMPCS were measured to be 28%,37%,24% and 27%,respectively,by means of both polarized optical microscopy and refractive index method.These values were all much higher than chitosan itself (12%),because the very strong hydrogen bonding interactions of chitosan were broken by the substituent groups.The molecular simulation approach was used to compare the intra-molecular hydrogen bonding interaction and the inter-molecular hydrogen bonding interaction of these four derivatives respectively.In the aspect of the intra-molecular hydrogen bonding,NOCS was stronger,but NMCS,NPCS and NMPCS were weaker.In the aspect of the inter-molecular hydrogen bonding,NOCS was weaker,NMCS was middle,but NPCS and NMPCS were stronger.Relating the critical concentration with the hydrogen bonding interaction,it can be seen that if the derivative have a stronger intra-molecular hydrogen bonding (such as NOCS) or a stronger inter-molecular hydrogen bonding (such as NPCS and NMPCS),the rigidity of the molecular chain is significantly improved,the arrangment and orientation of the molecular chain are more regular,as a results,the values of the critical concentration decrease.These two factors require just only one.On the contrary,if both of the two interactions are weaker (such as NMCS),the rigidity of the molecular chain is smaller,the value of the critical concentration becomes evidently higher (37%).For this system,the influence of the strength of the hydrogen bonding on the liquid crystalline critical concentration is definitive.