纳米材料在用于癌症诊断的呼出气挥发性有机物检测中的应用(英文)
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摘要
细胞新陈代谢的变化会导致挥发性有机化合物(VOCs)类型及含量发生变化,因此可通过分析某些标志性VOCs简立起多种疾病早期诊断的模型.人体呼出物中特征VOCs的检测作为一种非侵入性、无损的检测手段,近些年在疾病检测领域已成为世界范围内的研究热点.其中,纳米材料可用于增强传感器性能,并使传感器便携式小型化,推进检测传感器进入临床.在这篇综述中,作者将种类繁多的传感器中用到的纳米材料归纳总结为金属、金属氧化物、碳基、复合物和MOFs基纳米材料等几类,并讨论了不同类纳米材料在VOCs检测中的优劣势.本文所建立起的分析方法及讨论有助于进一步了解检测技术的优越性与局限性.最后,作者对利用VOCs的检测实现癌症早期筛选的研究及发展提出了个人观点.
Volatile organic compounds(VOCs) generated in human body can reflect one's health state, and numerous diseases are identified by some VOCs biomarkers. More recently, analyses of VOCs biomarkers from exhaled breath have turned into a research frontier worldwide because it offers a noninvasive way for diseases diagnosis. Various kinds of nanomaterials are used to enhance the performance of sensing techniques, and play an essential role in miniaturization detection. In this review, several kinds of nanomaterials(metallic, metal oxide, carbon-based, composites and MOFs-based materials) used in various VOCs detection methods, especially in VOCs sensors are summarized. Learning from the successful utilization of nanomaterials in these methods will help to further understand the superiority and limitation of detection techniques. A personal perspective of the research and development in exhaled breath VOCs detection for cancer diagnosis has been presented.
Volatile organic compounds(VOCs) generated in human body can reflect one's health state, and numerous diseases are identified by some VOCs biomarkers. More recently, analyses of VOCs biomarkers from exhaled breath have turned into a research frontier worldwide because it offers a noninvasive way for diseases diagnosis. Various kinds of nanomaterials are used to enhance the performance of sensing techniques, and play an essential role in miniaturization detection. In this review, several kinds of nanomaterials(metallic, metal oxide, carbon-based, composites and MOFs-based materials) used in various VOCs detection methods, especially in VOCs sensors are summarized. Learning from the successful utilization of nanomaterials in these methods will help to further understand the superiority and limitation of detection techniques. A personal perspective of the research and development in exhaled breath VOCs detection for cancer diagnosis has been presented.
引文
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[4]Li M X,Yang D K,Brock G,et al.Breath carbonyl compounds as biomarkers of lung cancer[J].Lung Cancer,2015,90(1):92-97.
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[6]Handa H,Usuba A,Maddula S,et al.Exhaled breath analysis for lung cancer detection using ion mobility spectrometry[J].Plo S One,2014,9(12):e114555.
[7]Sun X H,Shao K,Wang T.Detection of volatile organic compounds(VOCs)from exhaled breath as noninvasive methods for cancer diagnosis[J].Analytical and Bioanalytical Chemistry,2016,408(11):2759-2780.
[8]Buljubasic F,Buchbauer G.The scent of human diseases:a review on specific volatile organic compounds as diagnostic biomarkers[J].Flavour and Fragrance Journal,2015,30(1):5-25.
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[12]Boots A W,Bos L D,van der Schee M P,et al.Exhaled molecular fingerprinting in diagnosis and monitoring:validating volatile promises[J].Trends in Molecular Medicine,2015,21(10):633-644.
[13]Turner C.Techniques and issues in breath and clinical sample headspace analysis for disease diagnosis[J].Bioanalysis,2016,8(7):677-690.
[14]Zonta G,Anania G,Fabbri B,et al.Detection of colorectal cancer biomarkers in the presence of interfering gases[J].Sensors and Actuators B:Chemical,2015,218:289-295.
[15]de Lacy Costello B,Amann A,Al-Kateb H,et al.A review of the volatiles from the healthy human body[J].Journal of Breath Research,2014,8(1):014001.
[16]Wang Z,Wang C.Is breath acetone a biomarker of diabetes?A historical review on breath acetone measurements[J].Journal of Breath Research,2013,7(3):037109.
[17]Tangerman A,Meuwese-Arends M T,van Tongeren J HM.A new sensitive assay for measuring volatile sulphur compounds in human breath by Tenax trapping and gas chromatography and its application in liver cirrhosis[J].Clinica Chimica Acta,1983,130(1):103-110.
[18]Boots A W,Smolinska A,van Berkel J,et al.Identification of microorganisms based on headspace analysis of volatile organic compounds by gas chromatography-mass spectrometry[J].Journal of Breath Research,2014,8(2):027106.
[19]Mazzatenta A,Pokorski M,Sartucci F,et al.Volatile organic compounds(VOCs)fingerprint of Alzheimer’s disease[J].Respiratory Physiology&Neurobiology,2015,209:81-84.
[20]Mazzone P J.Analysis of volatile organic compounds in the exhaled breath for the diagnosis of lung cancer[J].Journal of Thoracic Oncology,2008,3(7):774-780.
[21]Vishinkin R,Haick H.Nanoscale sensor technologies for disease detection via volatolomics[J].Small,2015,11(46):6142-6164.
[22]Konvalina G,Haick H.Sensors for breath testing:from nanomaterials to comprehensive disease detection[J].Accounts of Chemical Research,2013,47(1):66-76.
[23]Kulkarni G S,Zhong Z.Detection beyond the Debye screening length in a high-frequency nanoelectronic biosensor[J].Nano Letters,2012,12(2):719-723.
[24]Garg N,Mohanty A,Lazarus N,et al.Robust gold nanoparticles stabilized by trithiol for application in chemiresistive sensors[J].Nanotechnology,2010,21(40):405501.
[25]Peng G,Hakim M,Broza Y Y,et al.Detection of lung,breast,colorectal,and prostate cancers from exhaled breath using a single array of nanosensors[J].British Journal of Cancer,2010,103(4):542-551.
[26]Dovgolevsky E,Konvalina G,Tisch U,et al.Monolayer-capped cubic platinum nanoparticles for sensing nonpolar analytes in highly humid atmospheres[J].The Journal of Physical Chemistry C,2010,114(33):14042-14049.
[27]Kahn N,Lavie O,Paz M,et al.Dynamic nanoparticlebased flexible sensors:Diagnosis of ovarian carcinoma from exhaled breath[J].Nano Letters,2015,15(10):7023-7028.
[28]Lentka L,Kotarski M,Smulko J,et al.Fluctuation-enhanced sensing with organically functionalized gold nanoparticle gas sensors targeting biomedical applications[J].Talanta,2016,160:9-14.
[29]Zhang Z,Yu W,Wang J,et al.Ultrasensitive surface-enhanced Raman scattering sensor of gaseous aldehydes as biomarkers of lung cancer on dendritic Ag nanocrystals[J].Analytical Chemistry,2017,89(3):1416-1420.
[30]Yamazoe N.New approaches for improving semiconductor gas sensors[J].Sensors and Actuators B:Chemical,1991,5(1/4):7-19.
[31]Barsan N,Schweizer-Berberich M,G?pel W.Fundamental and practical aspects in the design of nanoscaled SnO2gas sensors:a status report[J].Fresenius Journal of Analytical Chemistry,1999,365(4):287-304.
[32]Yamazoe N,Kurokawa Y,Seiyama T.Effects of additives on semiconductor gas sensors[J].Sensors and Actuators,1983,4:283-289.
[33]Korotcenkov G,Brinzari V,Boris Y,et al.Influence of surface Pd doping on gas sensing characteristics of SnO2thin films deposited by spray pirolysis[J].Thin Solid Films,2003,436(1):119-126.
[34]Korotcenkov G.Gas response control through structural and chemical modification of metal oxide films:state of the art and approaches[J].Sensors and Actuators B:Chemical,2005,107(1):209-232.
[35]Shin J,Choi S J,Lee I,et al.Thin-wall assembled SnO2fibers functionalized by catalytic Pt nanoparticles and their superior exhaled-breath-sensing properties for the diagnosis of diabetes[J].Advanced Functional Materials,2013,23(19):2357-2367.
[36]Righettoni M,Tricoli A,Gass S,et al.Breath acetone monitoring by portable Si:WO3gas sensors[J].Analytica Chimica Acta,2012,738:69-75.
[37]Katwal G,Paulose M,Rusakova I A,et al.Rapid growth of zinc oxide nanotube-nanowire hybrid architectures and their use in breast cancer-related volatile organics detection[J].Nano Letters,2016,16(5):3014-3021.
[38]Phillips M,Cataneo R N,Ditkoff B A,et al.Prediction of breast cancer using volatile biomarkers in the breath[J].Breast Cancer Research and Treatment,2006,99(1):19-21.
[39]Tomer V K,Duhan S.Ordered mesoporous Ag-doped TiO2/SnO2nanocomposite based highly sensitive and selective VOC sensors[J].Journal of Materials Chemistry A,2016,4(3):1033-1043.
[40]Zhang R,Zhou T T,Zhang T.Functionalization of hybrid1D Sn O2-Zn O nanofibers for formaldehyde detection[J].Advanced Materials Interfaces,2018,5(20):1800967.
[41]Wang C X,Yin L W,Zhang L Y,et al.Metal oxide gas sensors:sensitivity and influencing factors[J].Sensors,2010,10(3):2088-2106.
[42]Jalal A,Alam F,Roy Choudhury S,et al.Prospects and challenges of volatile organic compound(VOC)sensors in human healthcare[J].ACS Sensors,2018,3(7):1246-1263.
[43]Ellis J E,Star A.Carbon nanotube based gas sensors toward breath analysis[J].ChemPlusChem,2016,81(12):1248-1265.
[44]Zilberman Y,Tisch U,Shuster G,et al.Carbon nanotube/hexa-peri-hexabenzocoronene bilayers for discrimination between nonpolar volatile organic compounds of cancer and humid atmospheres[J].Advanced Materials,2010,22(38):4317-4320.
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