CN113185714B - 一种高粘附性抗菌促愈合水凝胶及其制备方法 - Google Patents
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Abstract
本发明公开了一种高粘附性抗菌促愈合水凝胶及其制备方法,属于生物医用材料技术领域。本发明以三聚氰胺为原料制备体相石墨相氮化碳,采用酸蚀和超声处理将体相石墨相氮化碳剥离成超薄的氮化碳纳米片,然后将银原位沉积在氮化碳纳米片上,获得银/氮化碳纳米片;将胶原和壳聚糖分别溶解在银/氮化碳纳米片醋酸分散液和醋酸中,并将胶原溶液和壳聚糖溶液混合,再加入多巴胺和氧化剂,然后用将水凝胶溶液的pH调节至中性,获得抗菌粘附自愈水凝胶。本发明所得水凝胶不仅具有优异的可见光响应的光催化抗菌效果,而且具有良好的组织粘附性、生物相容性以及溶胀性能,可吸收多余组织液,为伤口修复提供湿润环境,从而达到促进伤口愈合的效果。
Description
技术领域
本发明属于生物医用材料技术领域,具体涉及一种高粘附性抗菌促愈合水凝胶及其制备方法。
背景技术
伤口愈合过程中的细菌感染通常会导致严重的伤口发炎甚至死亡,对人类健康产生巨大威胁。因此,必须制定有效且快速的伤口愈合策略来治疗细菌感染并加速伤口愈合过程。目前,已开发出许多具有良好生物相容性的天然聚合物作为促进伤口愈合的生物医学材料,例如胶原蛋白,透明质酸,壳聚糖,藻酸盐等。在上述天然聚合物中,由于具有良好生物相容性,低抗原性,胶原基水凝胶得到了广泛的研究,而其中大多数都缺乏多功能性。为了解决上述问题,迫切需要开发具有多功能的高效水凝胶用于感染伤口修复。具有粘附性的水凝胶可以牢固地粘附在皮肤上,也是水凝胶用作伤口敷料的理想特性之一。
发明内容
本发明首次将银/氮化碳纳米片结合应用到水凝胶中,所得水凝胶具有优异的可见光响应的光催化抗菌效果,除了具有优异的抗菌效果,本发明的水凝胶具有优异的组织粘附性、生物相容性,在减轻细菌感染同时可吸收多余组织液,给伤口提供湿润的修复环境,促进成纤维细胞增殖,从而促进伤口愈合。
本发明的第一个目的是提供一种制备高粘附性抗菌促愈合水凝胶的方法,所述方法是在胶原-壳聚糖-银/氮化碳纳米片溶液中加入多巴胺溶液,混匀后加入氧化剂,获得混合液;将混合液进行胶凝,即得水凝胶;
所述胶原-壳聚糖-银/氮化碳纳米片溶液的制备过程如下:将胶原、银/氮化碳纳米片分散在醋酸溶液中,获得胶原-银/氮化碳纳米片溶液;将壳聚糖溶于醋酸溶液中,获得壳聚糖溶液;然后将所得的胶原-银/氮化碳纳米片溶液与壳聚糖溶液混合,即得胶原-壳聚糖-银/氮化碳纳米片溶液。
在本发明的一种实施方式中,银/氮化碳纳米片在水凝胶中的质量浓度为0.25-1mg/mL。
在本发明的一种实施方式中,胶原-银/氮化碳纳米片溶液中银/氮化碳纳米片的浓度为0.8mg/mL-3.3mg/mL。具体可优选1.65mg/mL。
在本发明的一种实施方式中,胶原-壳聚糖-银/氮化碳纳米片溶液中胶原与壳聚糖的质量比为1:(2-5);具体可优选1:3。
在本发明的一种实施方式中,胶原-银/氮化碳纳米片溶液中胶原的质量浓度为8-15mg/mL;具体可优选10mg/mL;醋酸溶液是指质量浓度为1-3wt%的醋酸水溶液。
在本发明的一种实施方式中,壳聚糖溶液中壳聚糖质量浓度为25-40mg/mL;具体可优选30mg/mL。
在本发明的一种实施方式中,多巴胺溶液的浓度为20-30mg/mL;具体可优选24mg/mL。
在本发明的一种实施方式中,多巴胺相对银/氮化碳纳米片的质量比为(0.8-3.3):(1-15);优选(0.8-3.3):12;进一步优选1.65:12。
在本发明的一种实施方式中,所述氧化剂可选如下任意一中或多种:过硫酸铵、过硫酸钠、过硫酸钾、高碘酸钠、高碘酸钾。
在本发明的一种实施方式中,所述氧化剂通过预先配制成20-30mg/mL的溶液进行添加。具体可选27mg/mL的过硫酸铵溶液。
在本发明的一种实施方式中,所述方法还包括:用碱试剂将混合液的pH调节至中性;所述碱试剂为1M的氢氧化钠或者氢氧化钾溶液浓度。
在本发明的一种实施方式中,所述方法包括如下步骤:
(1)将银/氮化碳纳米片分散在醋酸溶液中,超声处理,得银/氮化碳纳米片醋酸分散液;
(2)将胶原充分溶于银/氮化碳纳米片醋酸分散液中获得胶原-银/氮化碳纳米片溶液;将壳聚糖溶于醋酸溶液中,得壳聚糖溶液;
(3)在搅拌条件下,把步骤(2)中的胶原-银/氮化碳溶液加到步骤(2)中的壳聚糖溶液中,充分搅拌,得胶原-壳聚糖-银/氮化碳纳米片溶液;
(4)向步骤(3)中胶原-壳聚糖-银/氮化碳纳米片溶液中加入多巴胺溶液,充分混合后,加入氧化剂,用氢氧化钠溶液调节凝胶pH,制得可见光响应的光催化抗菌粘附促愈合水凝胶。
在本发明的一种实施方式中,步骤(1)中所用的银/氮化碳纳米片通过如下方法制得:
1)制备氮化碳纳米片:以三聚氰胺为原料,在500-700℃下焙烧,获得体相石墨相氮化碳;将所得体相石墨相氮化碳溶于浓硫酸中,然后加入水,静置、固液分离,收集沉淀,洗涤至中性;再分散在水中配制成分散液,超声,蒸除溶剂,收集得到白色粉末,干燥,即得氮化碳纳米片;
2)将所得氮化碳纳米片分散在水中,并加入可溶性银盐,混匀,然后后缓慢滴加硼氢化钠溶液,充分反应后,离心、洗涤、干燥,获得银/氮化碳纳米片。
在本发明的一种实施方式中,可溶性银盐可选硝酸银。
在本发明的一种实施方式中,所述银/氮化碳纳米片的具体制备过程如下:
氮化碳纳米片是以三聚氰胺为原料,具体制备过程为:将三聚氰胺放置于坩埚中,将其放置于马弗炉中在520℃下焙烧2h,研磨得到黄色粉末,即为体相石墨相氮化碳粉末;称取体相石墨相氮化碳粉末溶于浓硫酸中,搅拌2h后,缓慢地向浓硫酸中加入50mL去离子水,静置1-2h,离心洗涤至上清呈中性后取沉淀;将沉淀分散在去离子水中,制成0.2mg/mL的分散液,分批超声破碎30min。将超声处理后的分散液旋蒸,收集得白色粉末,放置于真空干燥箱中干燥48h,获得氮化碳纳米片。将氮化碳纳米片分散在水中,并加入硝酸银,充分混合后缓慢滴加硼氢化钠溶液,充分反应后,离心、洗涤、干燥,获得银/氮化碳纳米片。
本发明利用上述方法提供一种高粘附性抗菌促愈合水凝胶。
本发明还提供将上述高粘附性抗菌促愈合水凝胶应用于制备医用敷料中。
本发明的有益效果在于:
本发明的方法简单,条件温和可控;所得水凝胶拥有三维网络结构,能够吸除组织渗出液,同时提供湿润的伤口修复环境。
本发明的水凝胶对革兰氏阳性和革兰氏阴性菌均表现出优异的可见光响应的光催化抗菌效果(抗菌率可达100%),且具有优异的组织粘附性,以及良好的生物相容性,可促进成纤维细胞增殖,有助于促进伤口愈合。
附图说明
图1为制备的银/氮化碳纳米片透射电子显微镜照片;
图2为实施例2制备的水凝胶扫描电子显微镜照片;
图3为实施例2制备的水凝胶粘附组织照片;
图4为实施例1-3制备的水凝胶在可见光催化下对大肠杆菌进行抗菌实验所得平板菌落结果图;
图5为实施例1-3制备的水凝胶在可见光催化下对表皮葡萄球菌进行抗菌实验所得平板菌落结果图。
具体实施方式
以下结合具体实施例和附图来进一步说明本发明,但实施例并不对本发明做任何形式的限定。除非特殊说明,本发明采用的试剂、方法和设备为本技术领域常规试剂、方法和设备。
下述过程涉及的银/氮化碳纳米片通过如下方法制得:
称取10g三聚氰胺放置于坩埚中,将其放置于马弗炉中在520℃下焙烧2h,研磨得到黄色粉末,即为体相石墨相氮化碳粉末;称取200mg体相石墨相氮化碳粉末溶于8mL浓硫酸中,搅拌2h后,缓慢地向浓硫酸中加入50mL去离子水,静置1-2h,离心洗涤至上清呈中性后取沉淀;将沉淀分散在去离子水中,制成0.2mg/mL的分散液,分批超声破碎30min。将超声处理后的分散液旋蒸,收集得白色粉末,放置于真空干燥箱中干燥48h,获得石墨相氮化碳纳米片。通过温和超声处理30分钟,将60mg石墨相氮化碳纳米片分散在30mL去离子水,将17mg硝酸银加入上述悬浮液中,充分混合后,加入1mM硼氢化钠溶液,充分反应后,离心、洗涤、干燥,获得银/氮化碳纳米片。
实施例1:
将银/氮化碳纳米片分散在1wt%醋酸溶液中,超声处理,得均匀的银/氮化碳纳米片醋酸分散液;将10mg胶原溶解在1mL银/氮化碳纳米片醋酸分散液中,获得胶原-银/氮化碳纳米片溶液,其中,银/氮化碳纳米片的浓度为0.825mg/mL,银/氮化碳纳米片与胶原的质量比为0.825:10。将30mg壳聚糖溶解在1mL乙酸中,得壳聚糖溶液。
在搅拌条件下,将所得的胶原-银/氮化碳纳米片溶液加到壳聚糖溶液中,充分搅拌,得胶原-壳聚糖-银/氮化碳纳米片溶液;再加入0.5mL 24mg/mL多巴胺溶液,混匀后加入0.5mL 27mg/mL过硫酸铵溶液,形成混合体系,然后用1M NaOH溶液将混合体系的pH调节至中性,获得混合液。将混合液保持在室温下进行胶凝,即得可见光响应的光催化抗菌粘附促愈合水凝胶。
实施例2:
将银/氮化碳纳米片分散在1wt%醋酸溶液中,超声处理,得均匀的银/氮化碳纳米片醋酸分散液;将10mg胶原溶解在1mL银/氮化碳纳米片醋酸分散液中,获得胶原-银/氮化碳纳米片溶液,其中,银/氮化碳纳米片的浓度为1.65mg/mL,银/氮化碳纳米片与胶原的质量比为1.65:10。将30mg壳聚糖溶解在1mL乙酸中,得壳聚糖溶液。
在搅拌条件下,将获得的胶原-银/氮化碳纳米片溶液加到壳聚糖溶液中,充分搅拌,得胶原-壳聚糖-银/氮化碳纳米片溶液;再加入0.5mL 24mg/mL多巴胺溶液,混匀后加入0.5mL 27mg/mL过硫酸铵溶液,形成混合体系,然后用1M NaOH溶液将混合体系的pH调节至中性,获得混合液。将溶液保持在室温下进行胶凝,获得可见光响应的光催化抗菌粘附促愈合水凝胶。
实施例3:
将银/氮化碳纳米片分散在1wt%醋酸溶液中,超声处理,得均匀的银/氮化碳纳米片醋酸分散液。将10mg胶原溶解在1mL银/氮化碳纳米片醋酸分散液中,,获得胶原-银/氮化碳纳米片溶液,其中,银/氮化碳纳米片的浓度为3.3mg/mL,银/氮化碳纳米片与胶原的质量比为3.3:10。将30mg壳聚糖溶解在1mL乙酸中,获得壳聚糖溶液。
在搅拌条件下,将所得胶原-银/氮化碳纳米片溶液加到壳聚糖溶液中,充分搅拌,得胶原-壳聚糖-银/氮化碳纳米片溶液;再加入0.5mL 24mg/mL多巴胺溶液,混匀后加入0.5mL 27mg/mL过硫酸铵溶液,形成混合体系,然后用1M NaOH溶液将水凝胶溶液的pH调节至中性,获得混合液。将溶液保持在室温下进行胶凝,获得可见光响应的光催化抗菌粘附促愈合水凝胶。
性能测定:
(一)可见光响应的光催化抗菌性能:
将实施例1-3中制备得到的可见光响应的光催化抗菌促愈合水凝胶分别命名为hydrogel1、hydrogel 2、hydrogel 3,并进行抗菌性能研究,以未用水凝胶处理的细菌作为空白对照。
1、实验方法:
分别培养大肠杆菌、表皮葡萄球菌至对数期,用无菌生理盐水溶液洗涤细菌,然后将水凝胶加到2mL调好浓度的细菌悬液中,可见光照射10min后取一定量的菌液稀释后涂布于LB固体培养基上,放入37℃生化培养箱中培养16h,用计数法统计不同光照时间后菌液中的菌群数。
2、实验结果:
可见光响应的光催化抗菌促愈合水凝胶在可见光催化下对大肠杆菌和表皮葡萄球菌进行抗菌实验结果见图4、图5及表1。结果表明,可见光照射后,相对于空白对照组,实施例1-3的凝胶对大肠杆菌和表皮葡萄球菌均具有100%的杀伤作用。
表1实施例1-3所得水凝胶的抗菌实验结果
水凝胶 | 抗菌率(大肠杆菌) | 抗菌率(表皮葡萄球菌) |
对照 | 0% | 0% |
实施例1 | 100% | 100% |
实施例2 | 100% | 100% |
实施例3 | 100% | 100% |
(二)溶胀性能测试:
将实施例1-3制备得到的可见光响应的光催化抗菌促愈合水凝胶分别命名为hydrogel 1、hydrogel 2、hydrogel 3,并进行溶胀性能测试。
1、实验方法:
称取10mg左右的干燥凝胶样品,记录凝胶质量(W0)将其浸泡在PBS缓冲液(pH7.4)中,12h后取出,用吸水纸吸干凝胶表面的水分后称重,得凝胶的湿重Wt,溶胀率(SR)按下式计算:SR(%)=(Wt-W0)×100/W0。
2、实验结果:
可见光响应的光催化抗菌粘附促愈合水凝胶溶胀性能测试见表2。
表2实施例1-3所得水凝胶的凝胶溶胀性能结果
水凝胶 | 溶胀率 |
实施例1 | 791.45% |
实施例2 | 782.46% |
实施例3 | 697.90% |
结果表明,所有凝胶都可以急剧溶胀,作为伤口敷料,可快速吸收组织渗出液,避免伤口进一步感染,同时为维持伤口环境湿润。
(三)细胞毒性测试:
将实施例1-3中制备得到的可见光响应的光催化抗菌促愈合水凝胶分别命名为hydrogel1、hydrogel 2、hydrogel 3,并进行细胞毒性测试。
1、实验方法:
使用NIH-3T3细胞通过MTT方法确定水凝胶的体外细胞毒性。首先,将灭菌的水凝胶浸入DMEM培养基中24h以产生条件培养基。然后,将5×103个NIH-3T3细胞与条件培养基在37℃含5%CO2和95%空气的加湿培养箱中培养一天。之后,将噻唑基蓝溶液(MTT,0.5mg/mL,100μL)添加到细胞培养板中,对活细胞染色4h。之后,将MTT溶液替换为100μL二甲基亚砜(DMSO),待甲瓒完全溶解后,测量570nm处的光密度(OD)。用平均值±标准偏差测试细胞生存力,并且将用无条件培养基培养的细胞测试为对照组。
细胞存活率(%)=实验组OD/对照组OD×100%。
2、实验结果:
可见光响应的光催化抗菌促愈合水凝胶细胞毒性测试结果见表3。
表3实施例1-3所得水凝胶的细胞毒性测试结果
水凝胶 | 培养1天细胞存活率 |
对照 | 100% |
实施例1 | 110.74% |
实施例2 | 105.07% |
实施例3 | 101.19% |
其中,对照是指用无条件培养基培养的细胞。
与对照组相比,实施例1-3凝胶对NIH-3T3细胞无明显毒性,一定程度上促进NIH-3T3细胞生长,证实所制备的可见光响应的光催化抗菌粘附促愈合水凝胶具有良好的生物相容性。
(四)粘附性测试:
将实施例1-3制备得到的可见光响应的光催化抗菌促愈合水凝胶分别命名为hydrogel 1、hydrogel 2、hydrogel 3,并进行组织粘合强度测试。
1、实验方法:
选用猪皮测试水凝胶对宿主组织的粘附能力。将猪皮组织切成10mm×40mm的长方形,浸泡在PBS中备用。将50μL水凝胶前体溶液加到一张猪皮的表面,并将另一张猪皮覆盖在上面。粘合面积为10mm×10mm。随后,将猪皮置于室温下放置4h,用电子万能试验机进行搭接剪切试验,配备50N传感器。
2、实验结果:
可见光响应的光催化抗菌粘附促愈合水凝胶组织粘合强度测试见表4。
表4实施例1-3所得水凝胶的凝胶溶胀性能结果
水凝胶 | 粘合强度(KPa) |
实施例1 | 19.39 |
实施例2 | 30.36 |
实施例3 | 21.26 |
结果表明,水凝胶的粘合强度从19.39KPa增加到30.36KPa,表明掺杂ACN可增强水凝胶的对组织的粘附性,但当水凝胶中ACN浓度过高时,粘合强度出现降低。
Claims (9)
1.一种制备抗菌促愈合水凝胶的方法,所述方法是在胶原-壳聚糖-银/氮化碳纳米片溶液中加入多巴胺溶液,混匀后加入氧化剂,获得混合液;将混合液进行胶凝,即得水凝胶;
所述胶原-壳聚糖-银/氮化碳纳米片溶液的制备过程如下:将胶原、银/氮化碳纳米片分散在醋酸溶液中,获得胶原-银/氮化碳纳米片溶液;将壳聚糖溶于醋酸溶液中,获得壳聚糖溶液;然后将所得的胶原-银/氮化碳纳米片溶液与壳聚糖溶液混合,即得胶原-壳聚糖-银/氮化碳纳米片溶液;
所述银/氮化碳纳米片通过如下方法制得:
1)制备氮化碳纳米片:以三聚氰胺为原料,在500-700℃下焙烧,获得体相石墨相氮化碳;将所得体相石墨相氮化碳溶于浓硫酸中,然后加入水,静置、固液分离,收集沉淀,洗涤至中性;再分散在水中配制成分散液,超声,蒸除溶剂,收集得到白色粉末,干燥,即得氮化碳纳米片;
2)将所得氮化碳纳米片分散在水中,并加入可溶性银盐,混匀,然后缓慢滴加硼氢化钠溶液,充分反应后,离心、洗涤、干燥,获得银/氮化碳纳米片。
2.根据权利要求1所述的方法,其特征在于,银/氮化碳纳米片在水凝胶中的质量浓度为0.25-1mg/mL。
3.根据权利要求1所述的方法,其特征在于,胶原-银/氮化碳纳米片溶液中银/氮化碳纳米片的浓度为0.8mg/mL-3.3mg/mL。
4.根据权利要求1所述的方法,其特征在于,胶原-壳聚糖-银/氮化碳纳米片溶液中胶原与壳聚糖的质量比为1:(2-5)。
5.根据权利要求1所述的方法,其特征在于,胶原-银/氮化碳纳米片溶液中胶原的质量浓度为8-15mg/mL。
6.根据权利要求1所述的方法,其特征在于,壳聚糖溶液中壳聚糖质量浓度为25-40mg/mL。
7.根据权利要求1所述的方法,其特征在于,多巴胺溶液的浓度为20-30mg/mL。
8.权利要求1-7任一项所述方法制备得到的一种抗菌促愈合水凝胶。
9.权利要求8所述的抗菌促愈合水凝胶在制备医用敷料中的应用。
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