Chinese Journal of Tissue Engineering Research ›› 2014, Vol. 18 ›› Issue (3): 470-475.doi: 10.3969/j.issn.2095-4344.2014.03.023
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Antibacterial mechanism and safety of zinc oxide
Xiang Rong 1, 2, Ding Dong-bo1, Fan Liang-liang1, Huang Xiao-zhong 3, Xia Kun 1, 2
- 1 School of Life Science, Central South University, Changsha 410013, Hunan Province, China; 2 State Key Laboratory of Medical Genetics, Central South University, Changsha 410078, Hunan Province, China; 3 School of Physics and Electronics, Central South University, Changsha 410083, Hunan Province, China
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Online:2014-01-15Published:2014-01-15 -
Contact:Xia Kun, Professor, School of Life Science, Central South University, Changsha 410013, Hunan Province, China -
About author:Xiang Rong, Doctor, School of Life Science, Central South University, Changsha 410013, Hunan Province, China; State Key Laboratory of Medical Genetics, Central South University, Changsha 410078, Hunan Province, China
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Cite this article
Xiang Rong, Ding Dong-bo, Fan Liang-liang, Huang Xiao-zhong, Xia Kun. Antibacterial mechanism and safety of zinc oxide[J]. Chinese Journal of Tissue Engineering Research, 2014, 18(3): 470-475.
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2.1 氧化锌抗菌机制研究进展 2.1.1 光催化作用抗菌 氧化锌是一种宽禁带半导体氧化物,具有和TiO2相近的禁带宽度,具有较强的光催化作用,光照条件可影响其抗菌性能。研究表明,无光条件下纳米氧化锌对枯草芽孢杆菌(Bacillus subtilis)的抑菌率达到98%,比光照条件下好;而光照条件下纳米氧化锌对大肠杆菌(Escherichia coli)的抗菌效果比无光条件下好,且氧化锌的抗菌效果优于TiO2和SiO2;用抑菌环法检测普通氧化锌、纳米氧化锌、四针状氧化锌晶须3种氧化锌的抗菌能力,结果表明:四针状氧化锌晶须对大肠杆菌的抗菌效果最好,其次为普通氧化锌,抗菌活性最低的是普通氧化锌,而四针状氧化锌晶须独特的结构和形貌是其具有优异抗菌效果的原因之一;光照条件对氧化锌的抗菌性能也有一定的影响,3种氧化锌在模拟日光下的抗菌效果均比无光条件下好;此外,同种氧化锌对不同菌种的抗菌效果也有差异,3种氧化锌对大肠杆菌的抗菌效果均优于金黄色葡萄球菌,这些说明光照条件影响氧化锌的抗菌种类和性能[3,14]。 当以光子能量等于或大于氧化锌禁带宽度能量(3.37 eV)的光照射下,处于价带上的电子就会激发跃迁到导带上,从而分别在价带和导带上产生高活性的光生空穴(h+)和光生电子(e-)。h+具有氧化性,而e-则具有还原性。在一定条件下,分布在氧化锌表面的h+则可将吸附在氧化锌表面的OH-和H2O氧化成·OH,·OH作为强氧化剂可进一步与大多数有机污染物、细菌、病毒及部分无机污染物作用,最终使其氧化分解为CO2和H2O及无机物等无害物质。而如果h+和e-发生复合,就会将吸收的光能以热的形式释放,使光催化效率降低,改性剂的加入也可以改变催化剂微观结构,抑制光生电子与空穴的复合,从而提高光催化性能。因此,在氧化锌抗菌材料的过程中会加入表面改性剂[15]。 另外氧化锌在水中可以产生超氧根离子自由基(O2-)和羟基自由基(-OH)等具有高反应活性的物质,这一特性使其可应用于水体中,对有机污染物进行光催化降 解[16-17]。 2.1.2 锌离子溶出抗菌 锌离子(Zn2+)溶出杀菌机制认为,氧化锌通过破坏细菌细胞膜导致细胞内容物的溶出,阻碍有利于细菌新陈代谢酶的合成,破坏遗传因子,从而使细菌丧失其生物学活性等而完成杀菌过程。氧化锌在含水介质中可缓慢释放出Zn2+,而细菌表面由于游离-COOH的存在而带负电,Zn2+凭借库仑引力被吸附到细菌表面,使细菌细胞壁受损;此外,氧化锌还可以干扰肽聚糖的合成,阻碍细胞壁的形成,抑止细胞的繁殖与生长;之后,Zn2+进一步穿透细胞壁,取代细胞膜表面阳离子的位置,与蛋白质或其他阴离子基团结合,破坏膜的代谢和结构;氧化锌与壳聚糖末端的-NH2结合,还可造成细胞膜的通透性增大;在细菌生长适宜的pH条件下,纳米氧化锌带正电荷,氧化锌和细菌之间的静电作用导致两者紧密结合,造成细菌细胞膜的损伤;这些都会使细胞膜丧失原有的生物功能,进而导致细菌细胞质外流,最终导致细胞死亡而达到抗菌的目 的[18-22]。 与此同时,过剩的Zn2+还能穿透细胞膜渗入到细胞的内部:①与细菌体内的蛋白质、核酸中存在的巯基(-SH)、氨基(-NH:)等含硫、氮的官能团反应,使蛋白质变性,细胞合成酶丧失活性。而酶是一切生物的催化剂,控制着微生物生化反应,酶一旦失活,将引起催化性能丧失,使其所催化的生化反应无法正常进行,并影响其他相关的生化反应,导致微生物的能量代谢和物质代谢受阻,抑制细菌的正常繁殖、生长、发育等过程。②与DNA反应,破坏细胞中一些功能系统(如呼吸系统、电子传输系统、物质传输系统)的正常活动,妨碍代谢作用的正常进行。通过上述的种种方式,氧化锌作用于细菌,造成细菌的死亡或产生功能障碍,最终达到抗菌目的。但当细菌被杀死后,Zn2+又会从菌体中游离出来,再与其他细菌接触,重复进行上述抗杀菌活动,再次显示出优异的抗菌性能,因此氧化锌的抗菌效果可以延续下来,展现出持久性。Zn2+溶出杀菌不需要光照,而且锌与硫、氮的结合力特别强,故氧化锌显示出高的抗菌活性[23]。 但是,有研究表明,5 mmol/L浓度的氧化锌纳米颗粒极具有很好的抑菌效果,抑菌率可以达到90%;而 5 mmol/L的ZnCl2则几乎不表现出抑菌作用,并没有获得更理想的抗菌效果,说明Zn2+溶出浓度对氧化锌抗菌能力的影响并不明显。而较低浓度的Zn2+不但没有抑制细菌的生长,有时还会促进细菌的生长,则可能是因为Zn2+是细菌生长所必需的辅助因子[24]。因此,锌离子的溶出抗菌机制可能不是氧化锌抗菌的主要机制,只是一种辅助效应。 2.1.3 氧化锌产生的活性氧抗菌 通过电子自旋共振测定发现,在氧化锌溶液中氧化锌可激发产生活性羟基,而活性羟基可进一步通过多步反应产生H2O2等其他活性氧基团。活性氧最为显著的特点就是可以造成氧化压力,可以造成DNA、细胞膜、蛋白质的损伤,甚至可以引起细胞死亡。其中,活性羟基是目前已知的最强的活性氧基团,可以与活细胞中几乎每一种分子产生反应。其中最为主要的反应是两个活性羟基相互反应生成H2O2[25]。 而氧化锌的抗菌能力随着氧化锌比表面积、浓度的增大而增大,随着氧化锌粒径的增大而降低,且浓度对氧化锌抗菌能力的影响程度超过了粒径;氧化锌的抗菌性能和H2O2的产量研究表明,氧化锌浆液中的H2O2含量与氧化锌的抗菌性能呈正比;而氧化锌的晶体取向、比表面积,以及复合改性等因素对氧化锌的溶液中H2O2产量及抗菌性能均具有较大影响[19,26-28]。由此可见不同形态与性质氧化锌的抗菌能力不同与产生的活性氧有关。 另外,研究表明,活性氧的产生与光照有关,基于氧化锌的半导体特性,在光照作用下会导致自由电子和电子空穴的产生。而水分子在氧化锌的作用下产生了-OH和H+的产生,之后在溶解的O2作用下,在纳米氧化锌表面经过多步反应产生H2O2等多种活性氧集团,这使氧化锌的活性氧抗菌与光催化作用抗菌相互联 系[29-30]。 自制的两种纳米氧化锌和普通的氧化锌对纯棉织物进行抗菌研究发现:纳米氧化锌的抗菌机制是由光催化和金属离子溶出共同作用的结果[31]。另外,通过甲基蓝降解活性氧测定发现在无紫外激发条件下,氧化锌依然表现出抗菌活性,说明除了活性氧抗菌机制之外,氧化锌确实存在其他抗菌机制[27],氧化锌的抑菌作用还可由其他过氧基团引起的[32]。 总体而言,氧化锌抗菌可能是有几种不同机制共同作用的结果,而深入的机制探究及何种机制占据主要地位还需要进一步研究证实。同时,也正是由于氧化锌的抗菌机制尚不十分明确,其大量使用后在环境中的残存,对人类的生活环境存在着一定的威胁,使得对氧化锌的安全性研究使得十分必要[17]。 2.2 氧化锌安全性研究进展 氧化锌特别是纳米氧化锌应用已迅猛发展,已被广泛应用于纺织、医疗、化妆品、食品包装等领域[9-12,29]。同时,由于氧化锌的大量使用,使自然环境中的氧化锌存在量越来越大,但氧化锌的抗菌机制并不十分明确,因此在使用氧化锌作为抗菌材料时应当对其安全性加以关注[33]。另外,已有报道指出,纳米TiO2对藻类、高等植物、水生无脊椎动物、陆生无脊椎动物以及鱼类均具有一定的毒害作用,甚至可以导致鱼类的呼吸以及生长受到抑制[34-36]。那么,氧化锌是否会产生类似的毒性作用呢? 研究结果显示,氧化锌在一定浓度范围内对细胞、小鼠皮肤均不表现出刺激性:将0.25 g 氧化锌悬浊于10 mL细胞培养基中36 h后,提取上清,发现其对细胞生长不具有明显的抑制作用;小鼠经口灌喂半数致死量(LD50)大于2 000 mg/kg[37]。将纳米氧化锌和其他物质混合制成绷带,绷带表现出了很好的抗菌效果,并且与人类皮肤成纤维细胞具有很好的细胞相容性,对小鼠的受损皮肤的恢复能力具有一定的提升,并且使皮肤表面的胶原凝集能力提升[38]。通过体外的沙门氏菌基因突变试验和V79微核染色体突变试验,体内的小鼠骨髓微核试验和小鼠暴露吸入氧化锌后肺细胞DNA损伤彗星试验发现,氧化锌对遗传物质并没有影响[39]。 在体外实验中,11.5 mg/L的纳米氧化锌对结肠癌细胞具有很好的杀伤作用,可以通过活性氧的产生引起结肠癌细胞的凋亡,500 μmol/L的纳米氧化锌可以引起前列腺癌细胞的凋亡,凋亡率可以达到98%;与正常细胞相比,纳米氧化锌可以对髓性白血病细胞进行选择性杀伤;纳米氧化锌还可以作为抗癌药物的载体,可以有效地可以使抗癌药物在肿瘤细胞中的浓度明显增大,从而提高抗癌药物对癌细胞的杀伤作用[40-43]。从这一层面来看,氧化锌在治疗肿瘤方面具有较好的生物安全性,在医疗方面具有一定的应用前景。 然而,有研究表明,如果将含有92.5μg的纳米氧化锌灌入大鼠肺部,可以引起大鼠嗜曙红血球增多、呼吸道上皮细胞增殖、杯状细胞肥大、肺部纤维化等症状;在肺纤维化的过程中伴随着肌纤维母细胞聚集和转化生长因子β浓度升高,直接向大鼠肺部灌注锌离子,大鼠表现与灌入纳米氧化锌相似的性状;同时,体外培养的巨噬细胞的溶酶体稳定性在20 mg/L的纳米氧化锌作用下降低,造成以上这些结果的原因可能是纳米氧化锌进入吞噬体后随着pH的急剧变化而迅速溶解造成 的[44]。纳米氧化锌对肾脏细胞也具有一定的毒性作用,超过一定浓度还可能会对正常细胞的DNA造成损 伤[29, 45]。 另外,用普通氧化锌和纳米氧化锌分别对硅藻、甲壳类浮游动物和鱼类的毒性作用结果显示,纳米氧化锌比普通氧化锌有着更强的毒性,这可能与纳米氧化锌可以向水体中释放更高浓度的Zn2+有关;另外,对鱼的毒性结果显示,虽然纳米氧化锌不能够导致超氧化物岐化酶、金属硫蛋白表达量发生变化,但是普通氧化锌却可以使超氧岐化酶和金属硫蛋白的表达量明显上升,热休克蛋白70在两种氧化锌作用下表达量均有二到四倍的上升,这可能与氧化锌引起导致氧化压力变化后导致细胞损伤有关[46]。1 mg/L的纳米氧化锌溶液和0.6 mg/L的Zn2+溶液还能够降低斑马鱼胚胎谷胱甘肽含量,抑制过氧化氢酶和超氧岐化酶活性,引起胚胎脂质过氧化水平增大,说明纳米氧化锌会通过氧化应激抑制斑马鱼胚胎孵化[47]。5.6 mg/L纳米氧化锌还对斑马鱼肝组织中与斑马鱼肝组织自身免疫、细胞膜转运功能及氧化应激有关基因多药耐药性基因mdrl、Na+-K+-ATP酶基因nka、高亲和铜转运蛋白基因ctrl、低氧诱导因子基因hif表达过程中mRNA的合成有影响[48]。 将斑马鱼受精卵置于不同浓度的直径为30 nm的纳米氧化锌悬浊液中孵育,结果显示:50 mg/L和 100 mg/L的质量浓度条件下,可以杀死斑马鱼胚胎;在1-25 mg/L的质量浓度下,可以延缓胚胎发育的过程,孵育96 h后发现并幼鱼体长降低、尾部畸形等现象;而0.598 mg/L至6.305 mg/L的Zn2+溶液则不会导致胚胎死亡,但是可以延缓胚胎发育;10 mg/L的纳米氧化锌条件下,斑马鱼的发育速率明显低于3.629 mg/L的Zn2+溶液,说明氧化锌可以导致胚胎发育延缓,而且并不是由于其中的Zn2+引起的[49]。另外,通过与TiO2和Al2O3两种物质相比发现,氧化锌对斑马鱼的胚胎和幼鱼的毒性最大,孵育96 h,纳米氧化锌和块状氧化锌的LC50分别为1.793 mg/L和1.550 mg/L,84 h对斑马鱼胚胎的发育抑制半最大效应浓度(EC50)分别为 2.065 mg/L和2.066 mg/L,并且氧化锌对斑马鱼的毒性存在剂量依赖关系;但无论是纳米级还是块状的TiO2和Al2O3均没有对斑马鱼胚胎和幼鱼表现出明显的毒 性[50]。 另外,分别用含有普通氧化锌和纳米氧化锌的饲料喂养淡水螺,结果发现:含有普通氧化锌的饲料喂养后不会引起生物利用率的降低或是其他毒性反应,但是含有纳米氧化锌的饲料喂养后会引起淡水螺的消化能力减退,食物摄入量减少,排便量减少,摄入食物利用率低下等症状[51]。 同时还有研究指出,纳米氧化锌在食品包装领域的使用,使其有机会转移到食品本身,进而被人体摄入,引起一系列健康问题的潜在威胁[29,52-53]。由此可见,对于氧化锌的安全性研究有待进一步加强,特别是对于纳米氧化锌的安全性研究需要进行更多的关注。"
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