Accéder au contenu
MilliporeSigma
Home2D Materials in Biosensing

2D Materials in Biosensing

Chengye Dong1,3,5,**, Derrick Butler2,3,4,**, Rui Zhao, Yonghong Cheng5, Joshua A. Robinson1,3,4*, Aida Ebrahimi2,3,4*

1Department of Materials Science and Engineering, The Pennsylvania State University, University Park, PA 16802, USA, 2School of Electrical Engineering and Computer Science, The Pennsylvania State University, University Park, PA 16802, USA, 3Materials Research Institute, The Pennsylvania State University, University Park, PA 16802, USA, 4Center for Atomically Thin Multifunctional Coatings, The Pennsylvania State University, University Park, PA 16802, USA, 5State Key Lab of Electrical Insulation and Power Equipment, Xi’an Jiaotong University, Xi’an, Shaanxi 710049, People’s Republic of China

Material Matters, 2019, 14.1

* E-mail: sue66@engr.psu.edu and jrobinson@psu.edu
** These authors contributed equally.

Article Sections

Introduction
Synthesis of 2D Materials for Biosensing Applications
2D Materials for Biosensing Applications
Conclusions and Perspectives

Introduction

Since its isolation in 2004, graphene’s extraordinary electrical conductivity, large surface-to-volume ratio, unique optical/ vibrational modes, exceptional mechanical strength, and excellent biocompatibility have drawn increasing interestfor use in biochemical sensing applications.1-4 Furthermore, the surface of graphene, with specific defects and chemical functionalities  are excellent reaction sites for catalysis and electrochemical biosensing.5 Successful application of graphene in various biosensing technologies has sparked exploration of other graphene-like materials, including transition metal dichalcogenides (TMDs), transition metal oxides (TMOs), transition metal carbides/nitrides (MXenes), and hexagonal boron nitride (hBN) for biosensing applications.6,7 The diversity of composition, structure, and functionality offered by 2D materials makes them highly suitable for developing novel biochemical sensors. Additionally, the recent progress in the engineering of 2D materials via stacking, doping, functionalization, and alloying enables the construction of even more complex structures.

This mini-review highlights recent advances in synthesis and preparation of 2D materials, with emphasis on their relevance
for biosensing applications, followed by a summary of the electrochemical and optical biosensors which are the most
studied 2D materials-based biosensors (Figure 1). In addition, some of the less-explored biosensing technologies of 2D
materials will be discussed. The article concludes with a look into the future of 2D materials as biomedical analytical tools, and
where research is likely to go. 

An overview of various synthesis methods (i.e., exfoliation, chemical-vapor deposition (CVD), electrochemical deposition and liquidphase synthesis) of 2D materials for application in electrochemical biosensors (i.e., amperometric, potentiometric, and impedimetric methods) and optical biosensors (i.e. FRET: Forster resonance energy transfer, SERS: surface-enhanced Raman spectroscopy, and SPR: surface plasmon resonance)

Figure 1.An overview of various synthesis methods (i.e., exfoliation, chemical-vapor deposition (CVD), electrochemical deposition and liquidphase synthesis) of 2D materials for application in electrochemical biosensors (i.e., amperometric, potentiometric, and impedimetric methods) and optical biosensors (i.e. FRET: Forster resonance energy transfer, SERS: surface-enhanced Raman spectroscopy, and SPR: surface plasmon resonance)

Synthesis of 2D Materials for Biosensing Applications

Generally, preparation methods for 2D materials used in biosensors can be divided into mechanical and chemical exfoliation, electrodeposition, chemical-vapor deposition (CVD), and solution-phase synthesis. In this section, we focus on the synthesis of 2D layers (Figure 2) that produce to 2D flakes, powders, inks, and films.

Exfolation

Mechanical exfoliation (or micromechanical cleavage (MC), Figure 2A) is the most-reported method for the preparation of 2D materials from bulk layered structures.1 Although the quality of 2D flakes prepared by MC is superior to those prepared by other techniques, the high dependency on experimental skill and the poor yield limit its practical application for scalable device fabrication. On the other hand, chemical exfoliation (Figure 2B) methods are suitable for the large-scale synthesis of 2D flakes.8 The Li-intercalation and exfoliation method was developed to improve control over flake thickness and exfoliation yield when preparing MoS2 901187901867808652), TaS2, TiS2 (808717), WS2 (808806), ZrS2, NbSe2 (>808679), WSe2 (808822), Sb2Se3 (401196), Bi2Te3 (733482), and hBN (901349901410).8 While chemical exfoliation does exhibit high yields and efficient generation of 2D flakes, modifications of the 2D surface during exfoliation can introduce defects and impurities, and the co-existing single- and multilayered flakes are difficult to separate.

Chemical Vapor Deposition (CVD)

CVD (Figure 2C) is commonly used to synthesize 2D materials with high quality and large areas. For CVD, carbon-based  precursors are introduced into a furnace at high temperature, where they react and/or decompose to deposit carbon onto substrates such as Si/SiO2, transition metal catalysts (Cu, Ni), or sapphire, to form single- or multi-layer 2D materials. The quality, size, and thickness of the 2D materials can be tuned by experimental parameters including temperature, pressure, and substrate conditions. For example, graphene on conductive substrates with single or few layers and a centimeter-scale area has been prepared by this method, and transferred to insulator substrates for device fabrication.9 In addition, catalyst-free CVD graphene has been synthesized on sapphire (a dielectric substrate) eliminating the potential for damage by the transfer process and allowing fabrication of devices on directly-grown graphene.10

Methods for synthesizing of 2D materials.

Figure 2.Methods for synthesizing of 2D materials. A) Mechanical exfoliation of 2D materials using adhesive tape. B) Electrochemical lithiation process for the fabrication of 2D nanosheets from layered bulk material. Reprinted with permission from reference 8, copyright 2011 Wiley-VCH. C) Schematic of CVD process for the synthesis of 2D films. D) Electrodeposition process of reduced graphene oxide (rGO). Reprinted with permission from reference 12, copyright 2018 Beilstein-Institute. E) Solution phase synthesis of 2H- and 1T-WS2. Reprinted with permission from reference 15, copyright 2014 American Chemical Society.

Electrochemical Deposition

Electrochemical deposition (Figure 2D) is an alternative cost-effective technique for preparing thin films of nanomaterials at low temperatures. The morphology, thickness, and properties of the films can be tuned by adjusting the applied current, voltage, and deposition time. Graphene and rGO films have been electrochemically deposited on various working electrodes for biosensing applications, and some examples are discussed later in this article.11,12 Since such films are prepared from 2D nanosheet dispersions, films with abundant edges can be structured by other nanoparticles to enhance the signal and improve the sensitivity of the sensors.13 However, due to the aqueous surroundings and uncontrollable deposition process, obtaining high quality and reproducibility remains challenging.

Solution Phase Synthesis

Finally, solution phase synthesis (Figure 2E) enables production of gram-scale quantities of 2D materials with precise thickness under relatively mild conditions and low temperatures. It also allows for the functionalization of 2D materials in either aqueous or nonhydrolytic media. Recently, solution-based methods to synthesize graphene,14 TMDs (such as MoS2, MoSe2, WS2 and WSe2)15, and MXenes16 have been developed to prepare thickness- and morphology-controlled, 2D materials with high-yield and scalablility. Moreover, solution phase synthesis methods allow direct preparation of specific phases of 2D materials such as 1T′ MoTe2,17 which can be difficult to access via other methods.

2D Materials for Biosensing Applications

There are an exponentially growing number of reports on the use of 2D material-based biosensors for detection of neurotransmitters (dopamine, serotonin, etc.), metabolites (glucose, lactose, ascorbic acid, adenosine, etc.), inflammation markers (reactive oxygen and nitrogen species, such as hydrogen peroxide and nitric oxide), proteins, nucleic acids, bacterial cells, and heavy metals. The following sections summarize some of the recent biosensor reports using 2D materials for electrochemical (amperometric, impedimetric, and potentiometric—which includes field-effect transistors (FETs)),18-21 and optical (such as FRET,22 SPR,23 and SERS24) detection of various biological targets.

Electrochemical Sensors

Compared to other technologies, electrochemical sensors are often preferred for biochemical sensing applications, especially at the point-of-care, because of their high sensitivity, fast response time, cost efficiency, and simple readouts due to compatibility with integrated circuit (IC) technology. In developing electrochemical sensors, 2D materials can serve as the actual sensing element (i.e., the working electrode or channel material) or as a substrate for further modification with metal-, metaloxide, or carbon-nanostructures, biological enzymes, or other functional 2D materials. While many electrochemical sensors are based on amperometric detection (i.e., change of current at a particular potential applied to a working electrode), some electrochemical sensors rely on potentiometric detection (i.e., change of a surface potential) or impedance spectroscopy (i.e,. modulation of the impedance as a function of applied frequency).

Amperometric (or voltammetric) detection is based on a variety of techniques including cyclic voltammetry (CV), linear sweep voltammetry (LSV), differential pulse voltammetry (DPV), chronoamperometry, among others. Sun et al.18 used a nanocomposite electrode and DPV for the simultaneous detection of dopamine (DA), ascorbic acid (AA), and uric acid (UA) in phosphate buffered saline (PBS). Their sensor was based on a nanocomposite of MoS2 nanosheets (901187901867) synthesized by Li intercalation, combined with electrodeposited AuNPs (741949752568808628) and deposited on a glassy carbon electrode (GCE). The resulting sensor achieved detection limits of 50 µM, 50 nM, and 50 µM and linear ranges of 0.05–100 mM, 0.05–30 µM, and 0.05–40 mM for AA, DA, and UA, respectively. Our group showed that heterostructure of iron-sulfide with graphene enables highly sensitive and selective voltammetry detection of hydrogen peroxide down to ~0.1 nM, over a six orders of concentration range. It was shown that depending on “flavour” of graphene, the response varies significantly (with FeS/CVD graphene heterostructures outperforming FeS/n-type and /p-type epitaxial graphene layers). We specifically showed that oxidative stress induced by heat shock can be monitored in situ in E. coli cells.25 For amperometric glucose detection, Rakhi et al.19 combined MXene Ti3C2Tx nanosheets with AuNPs to form a nanocomposite, with immobilized glucose oxidase enzyme (GOx) and coated with Nafion (Cat. No. 70160). The sensor was able to detect at little as 5.9 µM of glucose in PBS (pH = 7) with a linear range of 0.1–18 mM (Figure 3A). The clinical values for blood glucose concentration (~5 mM) fall within this range, making it a viable sensor for real-world applications. The sensor maintained 93% of its response (at 3 mM) after 2 months of storage, demonstrating robustness and long-term stability.

Potentiometric biosensors are primarily FET-based sensors, which have attracted attention for detection of various analytes. A solution-gated potentiometric sensor for detection of glucose in PBS was developed by Zhang et al.,20 using CVDgrown graphene (900415900443900445773719> and 773700) for both the gate and channel. The gate electrode was modified with PtNPs ( 685453,771937) and GOx, which catalyzed glucose oxidation, resulting in the production of H2O2. The H2O2 was then oxidized, effectively altering the gate voltage. This was indirectly used to determine the glucose concentration (Figure 3B) with a glucose detection limit of 500 nM, which is low enough for noninvasive detection in samples like saliva and sweat. Impedimetric sensors rely on changes to either the Faradaic or non-Faradaic impedance in the presence or absence of a target analyte. For the Faradaic detection of Salmonella, Jia et al.21 developed a composite of rGO/MWCNTs, electrodeposited onto a GCE. Once the electrode was prepared, they drop-cast an amino-modified Salmonella aptamer onto the electrode. Based on the change in charge-transfer resistance, they were able to detect as few as 25 colony forming units (cfu) per ml, with a linear range of 75–7.5 105 cfu/ml, in 60 minutes without any pretreatment (Figure 3C). For typhoid fever-causing Salmonella, the infective dose can be as low as 1,000 cells, making this sensor potentially applicable in clinical settings.26

Examples of electrochemical sensors utilizing amperometric, potentiometric, and impedimetric transduction mechanisms.

Figure 3.Examples of electrochemical sensors utilizing amperometric, potentiometric, and impedimetric transduction mechanisms. A) The addition of glucose oxidase (GOx) enhances the peak current response to glucose for the MXene/AuNP/Nafion/GOx composite developed by Rakhi et al.19 The inset shows an SEM image of the MXene layers coated with AuNPs (scale bar = 2 µm). B) A potentiometric sensor utilizing graphene for both the gate and channel material for the indirect detection of glucose. GOx and PtNPs modify the gate electrode, resulting in generation of H2O2 upon reaction with glucose. H2O2 is oxidized resulting in an effective change in gate potential, which is used to determine glucose concentration.20 C) For the Faradaic impedimetric detection of Salmonella, Jia et al. used an aptamer-modified rGO/MWCNT composite on a GCE. The diameter of the semicircle of the Nyquist plot (-Zim vs Zre) qualitatively indicates the charge-transfer resistance, as seen in the equivalent circuit model. Reproduced with permission from references 19 and 20, copyright 2016 and 2015, respectively, Nature Publishing Group.

Optical Sensors

In addition to tunable electronic and electrochemical properties, 2D materials possess unique optical and vibrational properties, including photoluminescence, fluorescence quenching, second harmonic generation, and enhanced electron-photon interaction, which make them ideal for use in optical sensors.22-24 Common optical sensing techniques include Forster resonance energy transfer (FRET),22 surface plasmon resonance (SPR),23 and surface-enhanced Raman spectroscopy (SERS).24 Sensors based on fluorescence quenching or enhancement, such as FRET, detect changes in fluorescence in the presence/ absence of a target analyte. Kong et al. fabricated a sensor for the detection of prostate specific antigen (PSA), an important marker of prostate cancer.22 Their sensor utilized Li-intercalated MoS2 nanosheets with a fluorescent modified single-stranded (ss) DNA probe adsorbed onto the surface (Figure 4A). In the absence of PSA, the fluorescence was strongly quenched, but upon the addition of PSA, the fluorescence returned. They reported a dynamic response range of 0.5–300 ng/ml, with a linear range from 0.5–60 ng/ml. The limit of detection was 0.2 ng/ml, and the technique was selective in the presence of other common interfering proteins, including carcinoembryonic antigen (CEA). Since PSA values of 4 ng/ml or higher can be indicative of prostate cancer, this has obvious practical implications.

SPR sensors detect changes in the local refractive index in the presence or absence of a target analyte. Surface plasmons are highly sensitive to these changes. 2D materials are used to enhance the sensitivity of SPR sensors, because they integrate very well in these sensors due to their thin film nature.

Optical Sensors

Figure 4.A) The addition of more MoS2 nanosheets (0-40 µg/ml) for a given concentration of PSA aptamer (PA) (50 nM) quenches the fluorescence intensity. The fluorescence is restored upon increasing the concentration of PSA (0-300 ng/ml shown here). Reproduced with permission from reference 22, copyright 2015 Springer. B) The experimental setup of an SPR measurement used by Kamaruddin et al. Their chitosan-GO composite was used for the detection of Hg2+ and Pb2+ ions. Reprinted with permission from reference 23, under MDPI open access policy. C) AuNPs@WS2 nanosheets serve as the substrate for modification with an aptamer for the SERS-based detection of myoglobin (Mb). Changes in the Raman peak intensity can be used to determine the Mb concentration. Reproduced with permission from reference 24, copyright 2018 Springer.

Kamaruddin et al.23 combined chitosan with graphene oxide (763705763713 and 777676) and deposited it on an Au/Ag/Au layered substrate for the detection of the heavy metal ions Pb2+ and Hg2+. By using the Kretschmann configuration (Figure 4B), they were able to detect less than 1 ppm for both ions, showing a slightly higher sensitivity to Pb2+ ions than Hg2+ in both linear regimes (2.05 and 0.29 °ppm-1 versus 1.66 and 0.20 °ppm-1 for Pb2+ and Hg2+, respectively).

In addition to fluorescence-based and SPR methods, SERS detects minute changes in the Raman scattering due to adsorption of analytes to the surface. For the detection of myoglobin (Mb, M0630M5696), Shorie et al.24 fabricated a SERS-based sensor that combined liquid-exfoliated WS2 nanosheets with AuNPs (Figure 4C). Elevated Mb levels are indicative of muscle damage, and can be used for early detection of heart attacks. In this sensor, an anti-Mb aptamer was deposited onto the surface for selective detection of Mb, and was able to detect as little as 10-2 pg/ml, well below the blood level values (~85 ng/ml) that can indicate a heart attack or other muscle damage. The enhancement factor due to the WS2/AuNPs was 6.78 x 106 .

Conclusions and Perspectives

This article has summarized recent advances in synthesis of 2D materials, with a focus on their application in biosensing technologies. The advantages and disadvantages of various methods used to synthesize 2D materials as biosensing platforms have been discussed. Due to the unique properties of 2D materials, novel electrochemical and optical biosensors can detect neurotransmitters, metabolites, proteins, nucleic acids, bacterial cells, and heavy metals.

Considering the enhanced sensitivity offered by 2D materials, their atomically thin nature, and the advanced functionalization capabilities, this class of materials can open new avenues in healthcare, especially in point-of-care diagnostics and flexible and/or transient bioelectronics. However, in order to take advantage of their full capabilities, further technological development and better understanding of their properties are required. First, synthesis methods for developing environmentally stable 2D materials and heterostructures at lower cost and higher material/morphological control will make them more compatible with biosensing applications, especially for flexible platforms. Second, controlling of the layer number, defect chemistry, and material phase needs to be established, because the sensing performance of 2D materials is affected by these parameters. Third, control functionalization of the 2D material surface, which has a significant impact on the optical/ electronic/vibrational properties, has not been well-explored, and is an emerging research area for the community. Finally, biocompatibility and/or antibacterial properties of different 2D materials (beyond graphene, GO, rGO, and MoS2 ) and how synthesis process affect them need to be systematically investigated.

Materials
Loading

References

1.
Novoselov KS. 2004. Electric Field Effect in Atomically Thin Carbon Films. Science. 306(5696):666-669. https://doi.org/10.1126/science.1102896
2.
Lee C, Wei X, Kysar JW, Hone J. 2008. Measurement of the Elastic Properties and Intrinsic Strength of Monolayer Graphene. Science. 321(5887):385-388. https://doi.org/10.1126/science.1157996
3.
Liu K, Zhang J, Cheng F, Zheng T, Wang C, Zhu J. 2011. Green and facile synthesis of highly biocompatible graphene nanosheets and its application for cellular imaging and drug delivery. J. Mater. Chem.. 21(32):12034. https://doi.org/10.1039/c1jm10749f
4.
Hendry E, Hale PJ, Moger J, Savchenko AK, Mikhailov SA. Coherent Nonlinear Optical Response of Graphene. Phys. Rev. Lett.. 105(9): https://doi.org/10.1103/physrevlett.105.097401
5.
Wang Y, Li Z, Wang J, Li J, Lin Y. 2011. Graphene and graphene oxide: biofunctionalization and applications in biotechnology. Trends in Biotechnology. 29(5):205-212. https://doi.org/10.1016/j.tibtech.2011.01.008
6.
Li Z, Wong SL. 2017. Functionalization of 2D transition metal dichalcogenides for biomedical applications. Materials Science and Engineering: C. 701095-1106. https://doi.org/10.1016/j.msec.2016.03.039
7.
Luo Y, Li Z, Zhu C, Cai X, Qu L, Du D, Lin Y. 2018. Graphene-like Metal-Free 2D Nanosheets for Cancer Imaging and Theranostics. Trends in Biotechnology. 36(11):1145-1156. https://doi.org/10.1016/j.tibtech.2018.05.012
8.
Zeng Z, Yin Z, Huang X, Li H, He Q, Lu G, Boey F, Zhang H. 2011. Single-Layer Semiconducting Nanosheets: High-Yield Preparation and Device Fabrication. Angew. Chem. Int. Ed.. 50(47):11093-11097. https://doi.org/10.1002/anie.201106004
9.
Kim KS, Zhao Y, Jang H, Lee SY, Kim JM, Kim KS, Ahn J, Kim P, Choi J, Hong BH. 2009. Large-scale pattern growth of graphene films for stretchable transparent electrodes. Nature. 457(7230):706-710. https://doi.org/10.1038/nature07719
10.
Fanton MA, Robinson JA, Puls C, Liu Y, Hollander MJ, Weiland BE, LaBella M, Trumbull K, Kasarda R, Howsare C, et al. 2011. Characterization of Graphene Films and Transistors Grown on Sapphire by Metal-Free Chemical Vapor Deposition. ACS Nano. 5(10):8062-8069. https://doi.org/10.1021/nn202643t
11.
Chen L, Tang Y, Wang K, Liu C, Luo S. 2011. Direct electrodeposition of reduced graphene oxide on glassy carbon electrode and its electrochemical application. Electrochemistry Communications. 13(2):133-137. https://doi.org/10.1016/j.elecom.2010.11.033
12.
Liu M, Chen Y, Qin C, Zhang Z, Ma S, Cai X, Li X, Wang Y. Electrodeposition of reduced graphene oxide with chitosan based on the coordination deposition method. Beilstein J. Nanotechnol.. 91200-1210. https://doi.org/10.3762/bjnano.9.111
13.
Zhang Y, Zeng GM, Tang L, Chen J, Zhu Y, He XX, He Y. 2015. Electrochemical Sensor Based on Electrodeposited Graphene-Au Modified Electrode and NanoAu Carrier Amplified Signal Strategy for Attomolar Mercury Detection. Anal. Chem.. 87(2):989-996. https://doi.org/10.1021/ac503472p
14.
Yan X, Cui X, Li L. 2010. Synthesis of Large, Stable Colloidal Graphene Quantum Dots with Tunable Size. J. Am. Chem. Soc.. 132(17):5944-5945. https://doi.org/10.1021/ja1009376
15.
Mahler B, Hoepfner V, Liao K, Ozin GA. 2014. Colloidal Synthesis of 1T-WS2 and 2H-WS2 Nanosheets: Applications for Photocatalytic Hydrogen Evolution. J. Am. Chem. Soc.. 136(40):14121-14127. https://doi.org/10.1021/ja506261t
16.
Naguib M, Gogotsi Y. 2015. Synthesis of Two-Dimensional Materials by Selective Extraction. Acc. Chem. Res.. 48(1):128-135. https://doi.org/10.1021/ar500346b
17.
Sun Y, Wang Y, Sun D, Carvalho BR, Read CG, Lee C, Lin Z, Fujisawa K, Robinson JA, Crespi VH, et al. 2016. Low-Temperature Solution Synthesis of Few-Layer 1T??-MoTe2 Nanostructures Exhibiting Lattice Compression. Angew. Chem. Int. Ed.. 55(8):2830-2834. https://doi.org/10.1002/anie.201510029
18.
Sun H, Chao J, Zuo X, Su S, Liu X, Yuwen L, Fan C, Wang L. 2014. Gold nanoparticle-decorated MoS2 nanosheets for simultaneous detection of ascorbic acid, dopamine and uric acid. RSC Adv.. 4(52):27625. https://doi.org/10.1039/c4ra04046e
19.
Rakhi RB, Nayak P, Xia C, Alshareef HN. 2016. Erratum: Erratum: Novel amperometric glucose biosensor based on MXene nanocomposite. Sci Rep. 6(1): https://doi.org/10.1038/srep38465
20.
Zhang M, Liao C, Mak CH, You P, Mak CL, Yan F. 2015. Highly sensitive glucose sensors based on enzyme-modified whole-graphene solution-gated transistors. Sci Rep. 5(1): https://doi.org/10.1038/srep08311
21.
Jia F, Duan N, Wu S, Dai R, Wang Z, Li X. 2016. Impedimetric Salmonella aptasensor using a glassy carbon electrode modified with an electrodeposited composite consisting of reduced graphene oxide and carbon nanotubes. Microchim Acta. 183(1):337-344. https://doi.org/10.1007/s00604-015-1649-7
22.
Kong R, Ding L, Wang Z, You J, Qu F. 2015. A novel aptamer-functionalized MoS2 nanosheet fluorescent biosensor for sensitive detection of prostate specific antigen. Anal Bioanal Chem. 407(2):369-377. https://doi.org/10.1007/s00216-014-8267-9
23.
Kamaruddin N, Bakar AA, Mobarak N, Zan MS, Arsad N. Binding Affinity of a Highly Sensitive Au/Ag/Au/Chitosan-Graphene Oxide Sensor Based on Direct Detection of Pb2+ and Hg2+ Ions. Sensors. 17(10):2277. https://doi.org/10.3390/s17102277
24.
Shorie M, Kumar V, Kaur H, Singh K, Tomer VK, Sabherwal P. 2018. Plasmonic DNA hotspots made from tungsten disulfide nanosheets and gold nanoparticles for ultrasensitive aptamer-based SERS detection of myoglobin. Microchim Acta. 185(3): https://doi.org/10.1007/s00604-018-2705-x
25.
Ebrahimi A, Zhang K, Dong C, Subramanian S, Butler D, Bolotsky A, Goodnight L, Cheng Y, Robinson JA. 2019. FeSx-graphene heterostructures: Nanofabrication-compatible catalysts for ultra-sensitive electrochemical detection of hydrogen peroxide. Sensors and Actuators B: Chemical. 285631-638. https://doi.org/10.1016/j.snb.2018.12.033
26.
Food and Drug Administration. 2012. Bad Bug Book, Foodborne Pathogenic Microorganisms and Natural Toxins. 2nd ed.
Connectez-vous pour continuer

Pour continuer à lire, veuillez vous connecter à votre compte ou en créer un.

Vous n'avez pas de compte ?