2024年 02期

摘要(Abstract)：

为了拓展纳米酶的应用，采用离子交换和高温热解法将均匀分散的锰原子掺杂到中空碳骨架中制备中空结构的锰纳米酶；提出一种基于锰纳米酶的比色法，用于检测电化学双电子氧还原原位产生的过氧化氢的浓度。结果表明，锰纳米酶具有优异的类过氧化物酶活性，可催化过氧化氢将无色3, 3’, 5, 5’-四甲基联苯胺(TMB)氧化为蓝色氧化态TMB;当过氧化氢浓度为0～6 mmol/L时，体系的吸光度与过氧化氢浓度具有良好的多段线性关系，锰纳米酶比色法具有极低的检出限(0.45μmol/L)和优异的抗干扰性能。

关键词(KeyWords)：电化学;纳米酶;比色分析;过氧化氢

基金项目(Foundation): 国家自然科学基金项目(22172063);; 泰山青年学者专家计划(tsqn201812080);; 济南市创新团队自主培养计划项目(2021GXRC052)

作者(Author): 董旭阳,李哲,夏明远,康革,袁振峰,逯一中

DOI: 10.13349/j.cnki.jdxbn.20230529.001

参考文献(References)：

[1] JIANG Y Y,NI P J,CHEN C X,et al.Selective electrochemical H2O2 production through two-electron oxygen electrochemistry[J].Advanced Energy Materials,2018,8(31):1801909.

[2] KIM H W,ROSS M B,KORNIENKO N,et al.Efficient hydrogen peroxide generation using reduced graphene oxide-based oxygen reduction electrocatalysts[J].Nature Catalysis,2018,1(4):282.

[3] SAMIRA S,DESHPANDE S,ROBERTS C A,et al.Nonprecious metal catalysts for tuning discharge product distribution at solid-solid interfaces of aprotic Li-O2 batteries[J].Chemistry of Materials,2019,31(18):7300.

[4] BEERS R F,Jr,SIZER I W.A spectrophotometric method for measuring the breakdown of hydrogen peroxide by catalase[J].The Journal of Biological Chemistry,1952,195(1):133.

[5] SONG Z G,KWOK R T K,DING D,et al.An AIE-active fluorescence turn-on bioprobe mediated by hydrogen-bonding interaction for highly sensitive detection of hydrogen peroxide and glucose[J].Chemical Communications,2016,52(65):10076.

[6] HUCKABA C,EKEYES F G.The accuracy of estimation of hydrogen peroxide by potassium permanganate titration[J].Journal of the American Chemical Society,1948,70(4):1640.

[7] GILL T M,ZHENG X L.Comparing methods for quantifying electrochemically accumulated H2O2[J].Chemistry of Materials,2020,32(15):6285.

[8] JIANG Y Y,LU Y Z,LYU X Y,et al.Enhanced catalytic performance of Pt-free iron phthalocyanine by graphene support for efficient oxygen reduction reaction[J].ACS Catalysis,2013,3(6):1263.

[9] LU Z Y,CHEN G X,SIAHROSTAMI S,et al.High-efficiency oxygen reduction to hydrogen peroxide catalysed by oxidized carbon materials[J].Nature Catalysis,2018,1(2):156.

[10] JIANG Y Y,DING Z Y,GAO M,et al.Spontaneous deposition of uniformly distributed ruthenium nanoparticles on graphitic carbon nitride for quantifying electrochemically accumulated H2O2[J].Chinese Journal of Chemistry,2021,39(12):3369.

[11] LYU M Z,CHEN M X,ZHANG R,et al.Manganese is critical for antitumor immune responses via cGAS-STING and improves the efficacy of clinical immunotherapy[J].Cell Research,2020,30(11):966.

[12] WALDRON K J,RUTHERFORD J C,FORD D,et al.Metalloproteins and metal sensing[J].Nature,2009,460(7257):823.

[13] SIGNORELLA S,PALOPOLI C,LEDESMA G.Rationally designed mimics of antioxidant manganoenzymes:role of structural features in the quest for catalysts with catalase and superoxide dismutase activity[J].Coordination Chemistry Reviews,2018,365:75.

[14] HUGHEY C C,CRAWFORD P A.Pyruvate carboxylase wields a double-edged metabolic sword[J].Cell Metabolism,2019,29(6):1236.

[15] MALALASEKERA A P,WANG H W,SAMARAKOON T N,et al.A nanobiosensor for the detection of arginase activity[J].Nanomedicine:Nanotechnology,Biology and Medicine,2017,13(2):383.

[16] LIU Y F,CHENG Y,ZHANG H,et al.Integrated cascade nanozyme catalyzes in vivo ROS scavenging for anti-inflammatory therapy[J].Science Advances,2020,6(29):eabb2695.

[17] CHEN F,BAI M,CAO K,et al.Fabricating MnO2 nanozymes as intracellular catalytic DNA circuit generators for versatile imaging of base-excision repair in living cells[J].Advanced Functional Materials,2017,27(45):1702748.

[18] ZHU Y,WANG W Y,CHENG J J,et al.Stimuli-responsive manganese single-atom nanozyme for tumor therapy via integrated cascade reactions[J].Angewandte Chemie International Edition,2021,60(17):9480.

[19] CHEN Y F,JIAO L,YAN H Y,et al.Hierarchically porous S/N codoped carbon nanozymes with enhanced peroxidase-like activity for total antioxidant capacity biosensing[J].Analytical Chemistry,2020,92(19):13518.

[20] LIU W X,HUANG J J,YANG Q,et al.Multi-shelled hollow metal-organic frameworks[J].Angewandte Chemie International Edition,2017,56(20):5512.

[21] HU M,JU Y,LIANG K,et al.Void engineering in metal-organic frameworks via synergistic etching and surface functionalization[J].Advanced Functional Materials,2016,26(32):5827.

[22] DI CASTRO V,POLZONETTI G.XPS study of MnO oxidation[J].Journal of Electron Spectroscopy and Related Phenomena,1989,48(1):117.

[23] CHEN Z J,HUANG Z C,SUN Y M,et al.The most active oxidase-mimicking Mn2O3 nanozyme for biosensor signal generation[J].Chemistry:A European Journal,2021,27(37):9597.

[24] ZHANG C H,CHEN C X,ZHAO D,et al.Multienzyme cascades based on highly efficient metal-nitrogen-carbon nanozymes for construction of versatile bioassays[J].Analytical Chemistry,2022,94(8):3485.