methane and uric acid

methane has been researched along with uric acid in 111 studies

Research

Studies (111)

TimeframeStudies, this research(%)All Research%
pre-19903 (2.70)18.7374
1990's0 (0.00)18.2507
2000's15 (13.51)29.6817
2010's73 (65.77)24.3611
2020's20 (18.02)2.80

Authors

AuthorsStudies
Bergmann, F; Levene, L1
Langenbeck, U; Seegmiller, JE1
D'Mello, JP1
Luo, G; Wang, aY; Wang, Z1
Fei, J; Hu, S; Wu, K1
Jiang, X; Lin, X1
Jin, LT; Li, CX; Li, XH; Wan, Q; Wang, XL; Xian, YZ; Yamamoto, K; Zhang, FF1
De Zhang, W; Loh, KP; Poh, WC; Sheu, FS; Triparthy, S; Ye, JS1
Choi, YK; Huang, XJ; Im, HS; Kim, HS; Kim, JH; Lee, DH; Yarimaga, O1
Li, Y; Lin, X; Wang, L; Wang, P1
Chen, SM; Thiagarajan, S; Umasankar, Y; Yogeswaran, U1
Honma, I; Liu, A; Zhou, H1
Davis, J; Forsythe, S; Sharp, D1
Affum, AO; Brajter-Toth, A; Kathiwala, M; Perry, J1
Ardakani, MM; Beitollahi, H; Ganjipour, B; Naeimi, H1
Hou, H; Huang, J; Liu, Y; You, T1
Beitollahi, H; Ganjipour, B; Mazloum-Ardakani, M; Naeimi, H; Nejati, M1
Alwarappan, S; Li, CZ; Liu, G1
Chen, L; Chen, Q; Fang, Y; Miao, Z; Qin, X; Shan, M; Wang, H; Wang, X; Zhao, W; Zhao, Z1
Andrews, R; Gairola, CG; Han, SG1
Cai, C; Chen, D; Jin, J; Wang, H; Wang, Q; Wu, P; Yu, S; Zhang, H1
Bhambi, M; Malhotra, BD; Pundir, CS; Sumana, G1
Chen, DH; Huang, SH; Liao, HH1
Akbari, R; Khorasani-Motlagh, M; Noroozifar, M; Taheri, A1
Bishnoi, S; Goyal, RN; Rana, AR1
Bishnoi, S; Goyal, RN1
Ensafi, AA; Karimi-Maleh, H; Khoddami, E; Rezaei, B1
Dadkhah, M; Ensafi, AA; Karimi-Maleh, H1
Chauhan, N; Pundir, CS1
He, Y; Li, X; Wu, Z; Xue, Y; Yuan, Z; Zhao, H1
Amiri, M; Bezaatpour, A; Pakdel, Z; Shahrokhian, S1
Ensafi, AA; Karimi-Maleh, H1
Akbari, R; Bemanadi Parizi, M; Khorasani-Motlagh, M; Noroozifar, M1
Wang, Y1
Binh, NH; Lam, TD; Quan, do P; Tram, PT; Tuyen, do P; Viet, PH1
Chang, CT; Lee, HH; Pong, WF; Sham, TK; Sun, CL; Wang, J; Zhou, J1
Beitollahi, H; Hosseinzadeh, R; Raoof, JB1
Chauhan, N; Chawla, S; Dahiya, T; Pundir, CS; Rawal, R1
Dalmasso, PR; Pedano, ML; Rivas, GA1
Hallaj, R; Salimi, A; Teymourian, H1
Du, J; Li, Y; Liu, D; Lu, X; Yang, J1
Chai, Y; Yuan, R; Zhang, Y; Zhong, H; Zhong, X1
Chang, JK; Ger, MD; Lee, MT; Sun, CL; Wang, CH; Wu, CH; Wu, JW1
Feng, X; Shi, H; Song, W; Xue, K; Zhou, S1
Andrews, RJ; Chen, B; Koehne, JE; Lee, KH; Marsh, MP; Meyyappan, M; Periyakaruppan, A; Rand, E; Tanaka, Z; Zhang, DA1
Chen, X; Fei, S; Huang, H; Liang, C; Lin, M; Liu, Y; Ni, C1
Ab Ghani, S; Ali, AS; Ghadimi, H; Mohamed, N; Tehrani, RM1
Chih, YK; Yang, MC1
Martis, P; Mascarenhas, RJ; Mekhalif, Z; Swamy, BE; Thomas, T1
Makarem, S; Nasirizadeh, N; Shekari, Z; Zare, HR1
Benvenutti, EV; Canevari, TC; Landers, R; Machado, SA; Raymundo-Pereira, PA1
Mohamadi, M; Mostafavi, A; Torkzadeh-Mahani, M1
Arvand, M; Hassannezhad, M1
Li, W; Yang, YJ1
Kanatharana, P; Numnuam, A; Thavarungkul, P1
Li, H; Pan, Y; Si, P; Wang, M; Xiao, X1
Chen, S; Liu, X; Wei, S; Yuan, D; Zhang, W1
Chen, H; Dang, X; Hu, C; Hu, S; Huang, J; Wang, S; Wang, Y1
Cesarino, I; Galesco, HV; Machado, SA1
Allafchian, AR; Arashpour, B; Ensafi, AA; Rezaei, B1
Kong, J; Li, H; Luo, J; Su, B; Wang, Y; Ye, D; Zhang, S1
Arora, K; Choudhary, M; Malhotra, BD1
Brett, CM; Ghica, ME1
Su, CH; Sun, CL; Wu, JJ1
Afraz, A; Najafi, M; Rafati, AA1
Erden, PE; Kaçar, C; Kılıç, E; Öztürk, F1
Correa, DS; Iwaki, LE; Mattoso, LH; Mercante, LA; Oliveira, ON; Pavinatto, A; Scagion, VP; Zucolotto, V1
Ergul, B; Zhao, EH; Zhao, W1
Das, AK; Raj, CR1
Chen, Y; Li, Y; Ma, Y; Meng, Q; Shi, J; Yan, Y1
Bhakta, AK; D'Souza, OJ; Dalhalle, J; Detriche, S; Mascarenhas, RJ; Mekhalif, Z; Satpati, AK1
Hensley, D; Jacobs, CB; Venton, BJ; Yang, C; Zestos, AG1
Kemp, KC; Kim, KS; Tiwari, JN; Vij, V1
Heo, J; Kim, H; Kim, TH; Oh, JW; Yoon, YW; Yu, J1
Bao, SJ; Wang, MQ; Xu, MW; Ye, C; Yu, YN; Zhang, Y1
Arivanandhan, M; Hayakawa, Y; Kanchana, P; Navaneethan, M; Radhakrishnan, S; Sekar, C1
Jacobs, CB; Trikantzopoulos, E; Venton, BJ; Yang, C1
Noroozifar, M; Rajabi, H1
Al-Graiti, W; Baughman, R; Chen, J; Foroughi, J; Huang, XF; Wallace, G; Yue, Z1
Cai, W; Liu, W; Liu, Y; Tang, L; Wang, J; Wu, J; Xie, Y; Xu, W; Zhang, S; Zhao, G1
Abellán-Llobregat, A; Canals, A; González-Gaitán, C; Morallón, E; Vidal, L1
Kordas, K; Koskinen, J; Laurila, T; Palomäki, T; Peltola, E; Pitkänen, O; Sainio, S; Wester, N1
Goh, E; Hwang, GS; Jung, S; Lee, HJ; Park, JW; Si, Y1
Cui, G; Han, D; Niu, L; Qiu, M; Sun, P; Yang, H; Zhao, J1
Goyal, RN; Moon, JM; Park, DS; Raj, M; Shim, YB1
Alma, MH; Asiri, AM; Calimli, MH; Demirkan, B; Nas, MS; Özdil, B; Savk, A; Şen, F1
Deng, H; Ding, J; Li, Y; Lü, X; Yao, Y1
Li, M; Yang, Y; Zhu, Z1
Guo, C; Li, CM; Li, X; Shi, Z; Wu, J; Wu, X; Yu, L1
Haram, SK; Kumar, S; Poudyal, DC; Satpati, AK1
Cheng, H; Guo, X; Huang, X; Jin, W; Liu, X; Wang, F; Wen, Y; Wu, Y; Yang, H; Ying, Y1
Duan, X; Li, Y; Lu, X; Sheng, Y; Wen, Y; Xu, J; Xue, T; Zhu, Y1
Zhang, X; Zheng, J1
Foroughi, MM; Hassani Nadiki, H; Iranmanesh, T; Jahani, S; Shahidi Zandi, M1
Fukuda, T; Hiratsuka, A; Iwasa, H; Kishimoto, T; Muguruma, H; Shimizu, T; Tanaka, T; Tsuji, K1
Clauss, M; Frei, S; Hatt, JM; Kreuzer, M1
Lee, HJ; Lee, JE; Park, YE; Si, Y1
Sarkar, P; Sen, S1
Guan, JF; Jiang, XY; Liu, YP; Yu, JG; Zou, J1
Bao, N; Chen, C; Gu, H; Li, J; Shi, W; Wei, Q; Wu, J; Yu, C1
Lai, M; Li, R; Liang, H; Wang, S; Ye, H; Zhang, H; Zhang, W; Zhu, M; Zhu, R1
Cheng, J; Liu, P; Wang, H; Yang, M1
Cheng, YS; Ren, MJ; Sun, WB; Wang, M; Wu, FH; Wu, KL; Yan, Z1
Finšgar, M; Majer, D1
Bukharinova, MA; Khamzina, EI; Novakovskaya, EA; Sokolkov, SV; Stozhko, NY; Tarasov, AV1
Chen, J; Jiang, XY; Li, WJ; You, Y; Yu, JG; Zou, J1
Bellucci, S; Cancelliere, R; Cataldo, A; Micheli, L; Tinno, AD1
Chen, Y; Hou, C; Huo, D; Liu, Y; Qi, N; Wang, Y; Yang, M; Zhao, P; Zhao, S1
Gavrović-Jankulović, M; Knežević, S; Nešić, A; Ognjanović, M; Stanković, D; Stanković, V; Zlatanova, M1
Basumatary, M; Deffo, G; Deussi Ngaha, MC; Hazarika, R; Hussain, N; Kalita, S; Ngameni, E; Njanja, E; Puzari, P1
Jiang, XY; Li, SN; Liu, B; You, Y; Yu, JG1

Reviews

1 review(s) available for methane and uric acid

ArticleYear
Engineered Carbon-Nanomaterial-Based Electrochemical Sensors for Biomolecules.
    ACS nano, 2016, Jan-26, Volume: 10, Issue:1

    Topics: Ascorbic Acid; Biosensing Techniques; DNA; Dopamine; Electrochemical Techniques; Electrodes; Glucose; Graphite; Humans; Hydrogen Peroxide; Limit of Detection; MicroRNAs; Nanotubes, Carbon; Uric Acid

2016

Other Studies

110 other study(ies) available for methane and uric acid

ArticleYear
Oxidation of N-methyl substituted hypoxanthines, xanthines, purine-6,8-diones and the corresponding 6-thioxo derivatives by bovine milk xanthine oxidase.
    Biochimica et biophysica acta, 1976, May-13, Volume: 429, Issue:3

    Topics: Animals; Binding Sites; Cattle; Hydrogen-Ion Concentration; Hypoxanthines; Kinetics; Methane; Milk; Protein Binding; Purines; Purinones; Structure-Activity Relationship; Uric Acid; Xanthine Oxidase; Xanthines

1976
Gas chromatography--mass spectrometry studies of tetramethyl uric acids.
    Analytical biochemistry, 1973, Volume: 56, Issue:1

    Topics: Chemical Phenomena; Chemistry; Chromatography, Gas; Diazomethane; Mass Spectrometry; Methane; Methods; Quaternary Ammonium Compounds; Stereoisomerism; Uric Acid

1973
The use of methane-utilising bacteria as a source of protein for young chicks.
    British poultry science, 1973, Volume: 14, Issue:3

    Topics: Alanine Transaminase; Amino Acids; Animal Feed; Animals; Aspartate Aminotransferases; Bacteria; Bacterial Proteins; Body Weight; Chickens; Eggs; Housing, Animal; Male; Methane; Nitrogen; Uric Acid; Zea mays

1973
A selective voltammetric method for uric acid detection at beta-cyclodextrin modified electrode incorporating carbon nanotubes.
    The Analyst, 2002, Volume: 127, Issue:10

    Topics: Ascorbic Acid; beta-Cyclodextrins; Cyclodextrins; Electrochemistry; Electrodes; Humans; Microscopy, Electron, Scanning; Nanotubes, Carbon; Uric Acid

2002
Simultaneous determination of dopamine and serotonin on a glassy carbon electrode coated with a film of carbon nanotubes.
    Analytical biochemistry, 2003, Jul-01, Volume: 318, Issue:1

    Topics: Adsorption; Ascorbic Acid; Carbon; Dopamine; Electrochemistry; Electrodes; Humans; Hydrogen-Ion Concentration; Nanotechnology; Nanotubes, Carbon; Organophosphates; Oxidation-Reduction; Reproducibility of Results; Serotonin; Uric Acid

2003
Immobilization of DNA on carbon fiber microelectrodes by using overoxidized polypyrrole template for selective detection of dopamine and epinephrine in the presence of high concentrations of ascorbic acid and uric acid.
    The Analyst, 2005, Volume: 130, Issue:3

    Topics: Ascorbic Acid; Biosensing Techniques; Carbon; Carbon Fiber; DNA; Dopamine; Epinephrine; Humans; Microelectrodes; Polymers; Pyrroles; Uric Acid

2005
Assay for uric acid level in rat striatum by a reagentless biosensor based on functionalized multi-wall carbon nanotubes with tin oxide.
    Analytical and bioanalytical chemistry, 2005, Volume: 382, Issue:6

    Topics: Animals; Biosensing Techniques; Corpus Striatum; Electrochemistry; Male; Microscopy, Electron, Transmission; Nanotubes, Carbon; Rats; Rats, Sprague-Dawley; Spectroscopy, Fourier Transform Infrared; Tin Compounds; Urate Oxidase; Uric Acid

2005
Biosensing properties of diamond and carbon nanotubes.
    Langmuir : the ACS journal of surfaces and colloids, 2004, Jun-22, Volume: 20, Issue:13

    Topics: Ascorbic Acid; Biosensing Techniques; Boron; Chemical Phenomena; Chemistry, Physical; Diamond; Dopamine; Electrodes; Hydrophobic and Hydrophilic Interactions; Microscopy, Electron, Scanning; Microscopy, Electron, Transmission; Nanotubes, Carbon; Spectrum Analysis, Raman; Uric Acid

2004
Direct electrochemistry of uric acid at chemically assembled carboxylated single-walled carbon nanotubes netlike electrode.
    The journal of physical chemistry. B, 2006, Nov-02, Volume: 110, Issue:43

    Topics: Ascorbic Acid; Electrochemistry; Electrodes; Nanotubes, Carbon; Uric Acid

2006
Overoxidized polypyrrole film directed single-walled carbon nanotubes immobilization on glassy carbon electrode and its sensing applications.
    Biosensors & bioelectronics, 2007, Jun-15, Volume: 22, Issue:12

    Topics: Ascorbic Acid; Biosensing Techniques; Catalysis; Dopamine; Electrochemistry; Electrodes; Nanotubes, Carbon; Oxidation-Reduction; Polymers; Pyrroles; Reproducibility of Results; Sensitivity and Specificity; Uric Acid

2007
Nanocomposite of functionalized multiwall carbon nanotubes with nafion, nano platinum, and nano gold biosensing film for simultaneous determination of ascorbic acid, epinephrine, and uric acid.
    Analytical biochemistry, 2007, Jun-01, Volume: 365, Issue:1

    Topics: Ascorbic Acid; Biosensing Techniques; Coated Materials, Biocompatible; Electrochemistry; Epinephrine; Fluorocarbon Polymers; Gold Colloid; Microscopy, Atomic Force; Microscopy, Electron, Scanning; Nanocomposites; Nanotubes, Carbon; Platinum; Reproducibility of Results; Sensitivity and Specificity; Uric Acid

2007
Simultaneous voltammetric detection of dopamine and uric acid at their physiological level in the presence of ascorbic acid using poly(acrylic acid)-multiwalled carbon-nanotube composite-covered glassy-carbon electrode.
    Biosensors & bioelectronics, 2007, Aug-30, Volume: 23, Issue:1

    Topics: Acrylic Resins; Ascorbic Acid; Biosensing Techniques; Body Fluids; Coated Materials, Biocompatible; Complex Mixtures; Dopamine; Electrochemistry; Equipment Design; Equipment Failure Analysis; Nanotubes, Carbon; Reproducibility of Results; Sensitivity and Specificity; Uric Acid

2007
Carbon fibre composites: integrated electrochemical sensors for wound management.
    Journal of biochemistry, 2008, Volume: 144, Issue:1

    Topics: Biosensing Techniques; Carbon; Carbon Fiber; Electrochemistry; Humans; Uric Acid; Wound Infection

2008
Direct measurements of xanthine in 2000-fold diluted xanthinuric urine with a nanoporous carbon fiber sensor.
    The Analyst, 2008, Volume: 133, Issue:6

    Topics: Carbon; Carbon Fiber; Chromatography, High Pressure Liquid; Electrochemistry; Humans; Microscopy, Electron, Scanning; Nanotechnology; Rheumatic Diseases; Uric Acid; Xanthine

2008
Novel 2,2'-[1,2-ethanediylbis(nitriloethylidyne)]-bis-hydroquinone double-wall carbon nanotube paste electrode for simultaneous determination of epinephrine, uric acid and folic acid.
    Biosensors & bioelectronics, 2008, Nov-15, Volume: 24, Issue:3

    Topics: Catalysis; Electrochemistry; Electrodes; Epinephrine; Folic Acid; Humans; Hydroquinones; Nanotubes, Carbon; Uric Acid

2008
Simultaneous electrochemical determination of dopamine, uric acid and ascorbic acid using palladium nanoparticle-loaded carbon nanofibers modified electrode.
    Biosensors & bioelectronics, 2008, Dec-01, Volume: 24, Issue:4

    Topics: Ascorbic Acid; Biosensing Techniques; Complex Mixtures; Dopamine; Electrochemistry; Equipment Design; Equipment Failure Analysis; Microelectrodes; Nanotechnology; Nanotubes, Carbon; Palladium; Reproducibility of Results; Sensitivity and Specificity; Uric Acid

2008
Electrochemical and catalytic investigations of dopamine and uric acid by modified carbon nanotube paste electrode.
    Bioelectrochemistry (Amsterdam, Netherlands), 2009, Volume: 75, Issue:1

    Topics: Catalysis; Dopamine; Electrochemical Techniques; Electrodes; Humans; Hydrogen-Ion Concentration; Nanotubes, Carbon; Oxidation-Reduction; Uric Acid

2009
Simultaneous detection of dopamine, ascorbic acid, and uric acid at electrochemically pretreated carbon nanotube biosensors.
    Nanomedicine : nanotechnology, biology, and medicine, 2010, Volume: 6, Issue:1

    Topics: Ascorbic Acid; Biosensing Techniques; Carbon; Dopamine; Electrochemical Techniques; Electrodes; Glass; Nanotubes, Carbon; Spectrum Analysis, Raman; Uric Acid

2010
A novel nonenzymatic hydrogen peroxide sensor based on multi-wall carbon nanotube/silver nanoparticle nanohybrids modified gold electrode.
    Talanta, 2009, Dec-15, Volume: 80, Issue:2

    Topics: Acetaminophen; Ascorbic Acid; Biosensing Techniques; Electrochemical Techniques; Electrodes; Gold; Hydrogen Peroxide; Microscopy, Electron, Transmission; Models, Chemical; Nanoparticles; Nanotubes, Carbon; Oxidation-Reduction; Reproducibility of Results; Silver; Uric Acid

2009
Acute pulmonary response of mice to multi-wall carbon nanotubes.
    Inhalation toxicology, 2010, Volume: 22, Issue:4

    Topics: 8-Hydroxy-2'-Deoxyguanosine; Animals; Blotting, Western; Bronchoalveolar Lavage Fluid; Cell Count; Deoxyguanosine; Female; Inhalation Exposure; Interleukin-1beta; L-Lactate Dehydrogenase; Lung; Mice; Mice, Inbred C57BL; Mucins; Nanotubes, Carbon; Pulmonary Surfactant-Associated Protein A; Pulmonary Surfactant-Associated Protein D; Superoxide Dismutase; Tumor Necrosis Factor-alpha; Uric Acid

2010
Low-potential detection of endogenous and physiological uric acid at uricase-thionine-single-walled carbon nanotube modified electrodes.
    Analytical chemistry, 2010, Mar-15, Volume: 82, Issue:6

    Topics: Bacillus; Biosensing Techniques; Cell Line; Electrodes; Enzymes, Immobilized; Humans; Limit of Detection; Nanotubes, Carbon; Time Factors; Urate Oxidase; Uric Acid

2010
An amperomertic uric acid biosensor based on immobilization of uricase onto polyaniline-multiwalled carbon nanotube composite film.
    Artificial cells, blood substitutes, and immobilization biotechnology, 2010, Volume: 38, Issue:4

    Topics: Aniline Compounds; Bacillus; Biosensing Techniques; Electrochemistry; Electrodes; Enzymes, Immobilized; Equipment Reuse; Hydrogen-Ion Concentration; Microscopy, Electron, Scanning; Nanocomposites; Nanotubes, Carbon; Reproducibility of Results; Time Factors; Tin Compounds; Urate Oxidase; Uric Acid

2010
Simultaneous determination of norepinephrine, uric acid, and ascorbic acid at a screen printed carbon electrode modified with polyacrylic acid-coated multi-wall carbon nanotubes.
    Biosensors & bioelectronics, 2010, Jun-15, Volume: 25, Issue:10

    Topics: Acrylic Resins; Ascorbic Acid; Biosensing Techniques; Coated Materials, Biocompatible; Complex Mixtures; Conductometry; Electrodes; Equipment Design; Equipment Failure Analysis; Nanotubes, Carbon; Norepinephrine; Reproducibility of Results; Sensitivity and Specificity; Uric Acid

2010
Simultaneous determination of ascorbic acid and uric acid by a new modified carbon nanotube-paste electrode using chloromercuriferrocene.
    Analytical sciences : the international journal of the Japan Society for Analytical Chemistry, 2010, Volume: 26, Issue:4

    Topics: Ascorbic Acid; Catalysis; Electrochemistry; Electrodes; Humans; Limit of Detection; Nanotubes, Carbon; Ointments; Organomercury Compounds; Time Factors; Uric Acid

2010
A sensitive voltammetric sensor for detecting betamethasone in biological fluids.
    Combinatorial chemistry & high throughput screening, 2010, Volume: 13, Issue:7

    Topics: Adult; Albumins; Ascorbic Acid; Betamethasone; Body Fluids; Chromatography, High Pressure Liquid; Electrochemistry; Electrodes; Female; Graphite; High-Throughput Screening Assays; Humans; Hydrogen-Ion Concentration; Hypoxanthine; Male; Molecular Conformation; Nanotubes, Carbon; Particle Size; Sensitivity and Specificity; Surface Properties; Uric Acid

2010
Voltammetric determination of amlodipine besylate in human urine and pharmaceuticals.
    Bioelectrochemistry (Amsterdam, Netherlands), 2010, Volume: 79, Issue:2

    Topics: Amlodipine; Angina Pectoris; Antihypertensive Agents; Ascorbic Acid; Body Fluids; Carbon; Electrodes; Humans; Hydrogen-Ion Concentration; Limit of Detection; Microscopy, Electron, Scanning; Nanotechnology; Nanotubes, Carbon; Pharmaceutical Preparations; Potentiometry; Reproducibility of Results; Uric Acid; Xanthine

2010
p-Aminophenol-multiwall carbon nanotubes-TiO2 electrode as a sensor for simultaneous determination of penicillamine and uric acid.
    Colloids and surfaces. B, Biointerfaces, 2010, Nov-01, Volume: 81, Issue:1

    Topics: Aminophenols; Biosensing Techniques; Dielectric Spectroscopy; Electrochemical Techniques; Electrodes; Hydrogen-Ion Concentration; Microscopy, Electron, Scanning; Molecular Structure; Nanotubes, Carbon; Oxidation-Reduction; Penicillamine; Reproducibility of Results; Titanium; Uric Acid

2010
Determination of isoproterenol and uric acid by voltammetric method using carbon nanotubes paste electrode and p-chloranil.
    Colloids and surfaces. B, Biointerfaces, 2011, May-01, Volume: 84, Issue:1

    Topics: Chloranil; Electrodes; Humans; Isoproterenol; Male; Molecular Structure; Nanotubes, Carbon; Potentiometry; Uric Acid

2011
An amperometric uric acid biosensor based on multiwalled carbon nanotube-gold nanoparticle composite.
    Analytical biochemistry, 2011, Jun-15, Volume: 413, Issue:2

    Topics: Biosensing Techniques; Electrodes; Enzymes, Immobilized; Gold; Humans; Metal Nanoparticles; Nanotubes, Carbon; Sensitivity and Specificity; Urate Oxidase; Uric Acid

2011
Simultaneous determination of 3,4-dihydroxyphenylacetic acid, uric acid and ascorbic acid by poly(L-arginine)/multi-walled carbon nanotubes composite film.
    Journal of nanoscience and nanotechnology, 2011, Volume: 11, Issue:2

    Topics: 3,4-Dihydroxyphenylacetic Acid; Ascorbic Acid; Nanocomposites; Nanotechnology; Nanotubes, Carbon; Oxidation-Reduction; Peptides; Uric Acid

2011
Electrocatalytic determination of sumatriptan on the surface of carbon-paste electrode modified with a composite of cobalt/Schiff-base complex and carbon nanotube.
    Bioelectrochemistry (Amsterdam, Netherlands), 2011, Volume: 81, Issue:2

    Topics: Ascorbic Acid; Cobalt; Electrochemistry; Electrodes; Hydrogen-Ion Concentration; Limit of Detection; Nanotubes, Carbon; Oxidation-Reduction; Polarography; Potentiometry; Schiff Bases; Sumatriptan; Tablets; Uric Acid

2011
Determination of 6-mercaptopurine in the presence of uric acid using modified multiwall carbon nanotubes-TiO2 as a voltammetric sensor.
    Drug testing and analysis, 2012, Volume: 4, Issue:12

    Topics: Catalysis; Dielectric Spectroscopy; Drug Monitoring; Electrodes; Equipment Design; Humans; Hydrogen-Ion Concentration; Kinetics; Limit of Detection; Linear Models; Mercaptopurine; Microscopy, Electron, Scanning; Nanotubes, Carbon; Oxidation-Reduction; Potentiometry; Surface Properties; Titanium; Uric Acid

2012
Simultaneous and sensitive determination of a quaternary mixture of AA, DA, UA and Trp using a modified GCE by iron ion-doped natrolite zeolite-multiwall carbon nanotube.
    Biosensors & bioelectronics, 2011, Oct-15, Volume: 28, Issue:1

    Topics: Ascorbic Acid; Biosensing Techniques; Calibration; Dopamine; Electrochemistry; Electrodes; Hydrogen-Ion Concentration; Microscopy, Electron, Scanning; Microscopy, Electron, Transmission; Nanotubes, Carbon; Oxidation-Reduction; Tryptophan; Uric Acid; Zeolites

2011
Simultaneous determination of uric acid, xanthine and hypoxanthine at poly(pyrocatechol violet)/functionalized multi-walled carbon nanotubes composite film modified electrode.
    Colloids and surfaces. B, Biointerfaces, 2011, Dec-01, Volume: 88, Issue:2

    Topics: Benzenesulfonates; Electrodes; Humans; Hypoxanthine; Nanotechnology; Nanotubes, Carbon; Polymers; Uric Acid; Xanthine

2011
Electrochemically selective determination of dopamine in the presence of ascorbic and uric acids on the surface of the modified Nafion/single wall carbon nanotube/poly(3-methylthiophene) glassy carbon electrodes.
    Colloids and surfaces. B, Biointerfaces, 2011, Dec-01, Volume: 88, Issue:2

    Topics: Ascorbic Acid; Dopamine; Electrochemistry; Electrodes; Nanotechnology; Nanotubes, Carbon; Polymers; Thiophenes; Uric Acid

2011
Microwave-assisted synthesis of a core-shell MWCNT/GONR heterostructure for the electrochemical detection of ascorbic acid, dopamine, and uric acid.
    ACS nano, 2011, Oct-25, Volume: 5, Issue:10

    Topics: Ascorbic Acid; Chemistry Techniques, Synthetic; Dopamine; Electrochemistry; Electrodes; Glass; Graphite; Microwaves; Nanostructures; Nanotubes, Carbon; Uric Acid

2011
Electroanalysis and simultaneous determination of 6-thioguanine in the presence of uric acid and folic acid using a modified carbon nanotube paste electrode.
    Analytical sciences : the international journal of the Japan Society for Analytical Chemistry, 2011, Volume: 27, Issue:10

    Topics: Electrochemical Techniques; Electrodes; Folic Acid; Nanotubes, Carbon; Particle Size; Surface Properties; Thioguanine; Uric Acid

2011
Construction of amperometric uric acid biosensor based on uricase immobilized on PBNPs/cMWCNT/PANI/Au composite.
    International journal of biological macromolecules, 2012, Jan-01, Volume: 50, Issue:1

    Topics: Aniline Compounds; Biosensing Techniques; Electrochemistry; Enzymes, Immobilized; Ferrocyanides; Gold; Humans; Hydrogen-Ion Concentration; Metal Nanoparticles; Microscopy, Electron, Scanning; Nanocomposites; Nanotubes, Carbon; Reproducibility of Results; Spectroscopy, Fourier Transform Infrared; Urate Oxidase; Uric Acid

2012
Dispersion of multi-wall carbon nanotubes in polyhistidine: characterization and analytical applications.
    Analytica chimica acta, 2012, Jan-13, Volume: 710

    Topics: Ascorbic Acid; Dopamine; Electrochemical Techniques; Electrodes; Histidine; Humans; Hydrogen-Ion Concentration; Nanotubes, Carbon; Oxidation-Reduction; Sonication; Temperature; Uric Acid

2012
Electrocatalytic oxidation of NADH at electrogenerated NAD+ oxidation product immobilized onto multiwalled carbon nanotubes/ionic liquid nanocomposite: application to ethanol biosensing.
    Talanta, 2012, Feb-15, Volume: 90

    Topics: Acetaminophen; Alcohol Dehydrogenase; Ascorbic Acid; Biosensing Techniques; Catalysis; Electrochemistry; Electrodes; Ethanol; Glucose; Ionic Liquids; NAD; Nanocomposites; Nanotubes, Carbon; Oxidation-Reduction; Uric Acid

2012
Electrocatalytic detection of dopamine in the presence of ascorbic acid and uric acid using single-walled carbon nanotubes modified electrode.
    Colloids and surfaces. B, Biointerfaces, 2012, Sep-01, Volume: 97

    Topics: Ascorbic Acid; Catalysis; Dopamine; Electrodes; Nanotechnology; Nanotubes, Carbon; Uric Acid

2012
Carbon nanotubes incorporated with sol-gel derived La(OH)3 nanorods as platform to simultaneously determine ascorbic acid, dopamine, uric acid and nitrite.
    Colloids and surfaces. B, Biointerfaces, 2012, Dec-01, Volume: 100

    Topics: Ascorbic Acid; Dopamine; Electrochemical Techniques; Electrodes; Humans; Lanthanum; Limit of Detection; Microscopy, Electron, Transmission; Nanotubes; Nanotubes, Carbon; Nitrites; Phase Transition; Reproducibility of Results; Uric Acid; X-Ray Diffraction

2012
The effects of ionic liquid on the electrochemical sensing performance of graphene- and carbon nanotube-based electrodes.
    The Analyst, 2013, Jan-21, Volume: 138, Issue:2

    Topics: Ascorbic Acid; Biosensing Techniques; Catalysis; Dopamine; Electrochemical Techniques; Electrodes; Graphite; Ionic Liquids; Nanotubes, Carbon; Palladium; Uric Acid

2013
Design of templated nanoporous carbon electrode materials with substantial high specific surface area for simultaneous determination of biomolecules.
    Biosensors & bioelectronics, 2013, Apr-15, Volume: 42

    Topics: Ascorbic Acid; Biosensing Techniques; Catalysis; Dopamine; Electrodes; Hydrogen-Ion Concentration; Nanopores; Nanotubes, Carbon; Surface Properties; Uric Acid

2013
A carbon nanofiber based biosensor for simultaneous detection of dopamine and serotonin in the presence of ascorbic acid.
    Biosensors & bioelectronics, 2013, Apr-15, Volume: 42

    Topics: Ascorbic Acid; Biosensing Techniques; Carbon; Dopamine; Hydrogen-Ion Concentration; Nanofibers; Nanotubes, Carbon; Serotonin; Uric Acid

2013
High loading of uniformly dispersed Pt nanoparticles on polydopamine coated carbon nanotubes and its application in simultaneous determination of dopamine and uric acid.
    Nanotechnology, 2013, Feb-15, Volume: 24, Issue:6

    Topics: Dopamine; Electrochemical Techniques; Electrodes; Indoles; Limit of Detection; Metal Nanoparticles; Nanotubes, Carbon; Platinum; Polymers; Uric Acid

2013
Sensitive voltammetric determination of paracetamol by poly (4-vinylpyridine)/multiwalled carbon nanotubes modified glassy carbon electrode.
    Analytica chimica acta, 2013, Feb-26, Volume: 765

    Topics: Acetaminophen; Ascorbic Acid; Carbon; Electrochemical Techniques; Electrodes; Humans; Hydrogen-Ion Concentration; Nanotubes, Carbon; Oxidation-Reduction; Polyvinyls; Uric Acid

2013
An 2,2'-azino-bis(3-ethylbenzthiazoline-6-sulfonic acid)-immobilized electrode for the simultaneous detection of dopamine and uric acid in the presence of ascorbic acid.
    Bioelectrochemistry (Amsterdam, Netherlands), 2013, Volume: 91

    Topics: Ascorbic Acid; Benzothiazoles; Dielectric Spectroscopy; Dopamine; Dopamine Agents; Electrochemical Techniques; Electrodes; Humans; Nanotubes, Carbon; Sensitivity and Specificity; Sulfonic Acids; Uric Acid

2013
Multi-walled carbon nanotube modified carbon paste electrode as an electrochemical sensor for the determination of epinephrine in the presence of ascorbic acid and uric acid.
    Materials science & engineering. C, Materials for biological applications, 2013, Aug-01, Volume: 33, Issue:6

    Topics: Ascorbic Acid; Biosensing Techniques; Carbon; Catalysis; Electrochemical Techniques; Electrodes; Epinephrine; Hydrogen-Ion Concentration; Nanotubes, Carbon; Oxidation-Reduction; Uric Acid

2013
Electrocatalytic determination of dopamine in the presence of uric acid using an indenedione derivative and multiwall carbon nanotubes spiked in carbon paste electrode.
    Materials science & engineering. C, Materials for biological applications, 2013, Apr-01, Volume: 33, Issue:3

    Topics: Carbon; Catalysis; Dopamine; Electrochemical Techniques; Electrodes; Humans; Hydrogen-Ion Concentration; Indenes; Injections; Nanotubes, Carbon; Oxidation-Reduction; Solutions; Uric Acid

2013
Sol-gel thin-film based mesoporous silica and carbon nanotubes for the determination of dopamine, uric acid and paracetamol in urine.
    Talanta, 2013, Nov-15, Volume: 116

    Topics: Acetaminophen; Dopamine; Electrochemical Techniques; Electrodes; Humans; Hydrofluoric Acid; Hydrogen-Ion Concentration; Limit of Detection; Microscopy, Electron, Scanning; Nanotubes, Carbon; Oxidation-Reduction; Phase Transition; Porosity; Silicon Dioxide; Uric Acid

2013
Voltammetric behavior of uric acid on carbon paste electrode modified with salmon sperm dsDNA and its application as label-free electrochemical sensor.
    Biosensors & bioelectronics, 2014, Apr-15, Volume: 54

    Topics: Animals; Biosensing Techniques; DNA; Electrochemical Techniques; Electrodes; Humans; Limit of Detection; Male; Nanotubes, Carbon; Salmon; Spermatozoa; Uric Acid

2014
Magnetic core-shell Fe₃O₄@SiO₂/MWCNT nanocomposite modified carbon paste electrode for amplified electrochemical sensing of uric acid.
    Materials science & engineering. C, Materials for biological applications, 2014, Mar-01, Volume: 36

    Topics: Calibration; Electrochemical Techniques; Electrodes; Ferrosoferric Oxide; Hydrogen-Ion Concentration; Nanocomposites; Nanotubes, Carbon; Reproducibility of Results; Silicon Dioxide; Solutions; Spectroscopy, Fourier Transform Infrared; Time Factors; Uric Acid

2014
CTAB functionalized graphene oxide/multiwalled carbon nanotube composite modified electrode for the simultaneous determination of ascorbic acid, dopamine, uric acid and nitrite.
    Biosensors & bioelectronics, 2014, Jun-15, Volume: 56

    Topics: Ascorbic Acid; Biosensing Techniques; Cetrimonium; Cetrimonium Compounds; Dopamine; Electrochemical Techniques; Graphite; Humans; Limit of Detection; Nanotubes, Carbon; Nitrites; Oxides; Uric Acid

2014
An amperometric uric acid biosensor based on chitosan-carbon nanotubes electrospun nanofiber on silver nanoparticles.
    Analytical and bioanalytical chemistry, 2014, Volume: 406, Issue:15

    Topics: Ascorbic Acid; Biosensing Techniques; Buffers; Catalysis; Chitosan; Electrochemistry; Electrodes; Enzymes, Immobilized; Glucose; Hydrogen-Ion Concentration; Lactic Acid; Limit of Detection; Metal Nanoparticles; Nanofibers; Nanotubes, Carbon; Oxygen; Silver; Urate Oxidase; Uric Acid; Urine

2014
Non-enzymatic glucose sensors based on controllable nanoporous gold/copper oxide nanohybrids.
    Talanta, 2014, Volume: 125

    Topics: Ascorbic Acid; Biosensing Techniques; Copper; Electrochemical Techniques; Electrochemistry; Electroplating; Glucose; Gold; Humans; Limit of Detection; Microscopy, Electron, Scanning; Microscopy, Electron, Transmission; Nanocomposites; Nanostructures; Nanotechnology; Nanotubes, Carbon; Porosity; Uric Acid

2014
Graphene-multiwall carbon nanotube-gold nanocluster composites modified electrode for the simultaneous determination of ascorbic acid, dopamine, and uric acid.
    Applied biochemistry and biotechnology, 2014, Volume: 173, Issue:7

    Topics: Ascorbic Acid; Dopamine; Electrochemistry; Electrodes; Gold; Graphite; Models, Molecular; Molecular Conformation; Nanotubes, Carbon; Time Factors; Uric Acid

2014
Preparation and application of a novel electrochemical sensing material based on surface chemistry of polyhydroquinone.
    Materials science & engineering. C, Materials for biological applications, 2014, Jul-01, Volume: 40

    Topics: Adsorption; Dopamine; Electrochemical Techniques; Graphite; Hydrophobic and Hydrophilic Interactions; Indoles; Nanotubes, Carbon; Polymers; Solubility; Surface Properties; Uric Acid; Water

2014
Determination of serotonin on platinum electrode modified with carbon nanotubes/polypyrrole/silver nanoparticles nanohybrid.
    Materials science & engineering. C, Materials for biological applications, 2014, Jul-01, Volume: 40

    Topics: Ascorbic Acid; Electrochemical Techniques; Electrodes; Humans; Hydrogen-Ion Concentration; Metal Nanoparticles; Nanostructures; Nanotubes, Carbon; Oxidation-Reduction; Polymers; Pyrroles; Serotonin; Silver; Uric Acid

2014
Voltammetric behavior of dopamine at a glassy carbon electrode modified with NiFe(2)O(4) magnetic nanoparticles decorated with multiwall carbon nanotubes.
    Materials science & engineering. C, Materials for biological applications, 2014, Jun-01, Volume: 39

    Topics: Ascorbic Acid; Biomarkers; Carbon; Cysteine; Dielectric Spectroscopy; Dopamine; Electrodes; Humans; Hydrogen-Ion Concentration; Limit of Detection; Magnetite Nanoparticles; Nanotubes, Carbon; Uric Acid

2014
An electrochemical sensor for simultaneous determination of ascorbic acid, dopamine, uric acid and tryptophan based on MWNTs bridged mesocellular graphene foam nanocomposite.
    Talanta, 2014, Volume: 127

    Topics: Ascorbic Acid; Dopamine; Electric Conductivity; Electrochemical Techniques; Electrodes; Graphite; Hydrogen-Ion Concentration; Nanocomposites; Nanotubes, Carbon; Reproducibility of Results; Surface Properties; Tryptophan; Uric Acid

2014
Enhancing performance of uricase using multiwalled carbon nanotube doped polyaniline.
    Applied biochemistry and biotechnology, 2014, Volume: 174, Issue:3

    Topics: Aniline Compounds; Biosensing Techniques; Dielectric Spectroscopy; Electrodes; Enzymes, Immobilized; Microscopy, Electron, Scanning; Nanotubes, Carbon; Spectroscopy, Fourier Transform Infrared; Tin Compounds; Urate Oxidase; Uric Acid

2014
Poly(brilliant green) and poly(thionine) modified carbon nanotube coated carbon film electrodes for glucose and uric acid biosensors.
    Talanta, 2014, Volume: 130

    Topics: Biosensing Techniques; Coloring Agents; Electrochemistry; Electrodes; Enzymes, Immobilized; Glucose; Glucose Oxidase; Nanotubes, Carbon; Phenothiazines; Quaternary Ammonium Compounds; Uric Acid

2014
Synthesis of short graphene oxide nanoribbons for improved biomarker detection of Parkinson's disease.
    Biosensors & bioelectronics, 2015, May-15, Volume: 67

    Topics: Ascorbic Acid; Biomarkers; Biosensing Techniques; Dopamine; Graphite; Humans; Nanotubes, Carbon; Oxides; Parkinson Disease; Uric Acid

2015
Optimization of modified carbon paste electrode with multiwalled carbon nanotube/ionic liquid/cauliflower-like gold nanostructures for simultaneous determination of ascorbic acid, dopamine and uric acid.
    Materials science & engineering. C, Materials for biological applications, 2014, Volume: 44

    Topics: Ascorbic Acid; Biosensing Techniques; Dielectric Spectroscopy; Dopamine; Electrochemical Techniques; Electrodes; Gold; Humans; Ionic Liquids; Metal Nanoparticles; Microscopy, Electron, Scanning; Nanotubes, Carbon; Oxidation-Reduction; Spectrometry, X-Ray Emission; Uric Acid; X-Ray Diffraction

2014
Amperometric uric acid biosensor based on poly(vinylferrocene)-gelatin-carboxylated multiwalled carbon nanotube modified glassy carbon electrode.
    Talanta, 2015, Volume: 134

    Topics: Biosensing Techniques; Carbon; Electrochemistry; Electrodes; Ferrous Compounds; Gelatin; Humans; Nanotubes, Carbon; Polyvinyls; Serum; Urate Oxidase; Uric Acid

2015
Electrospun polyamide 6/poly(allylamine hydrochloride) nanofibers functionalized with carbon nanotubes for electrochemical detection of dopamine.
    ACS applied materials & interfaces, 2015, Mar-04, Volume: 7, Issue:8

    Topics: Ascorbic Acid; Biosensing Techniques; Calorimetry, Differential Scanning; Caprolactam; Dopamine; Electrochemical Techniques; Electrodes; Nanofibers; Nanotubes, Carbon; Polyamines; Polymers; Thermogravimetry; Tin Compounds; Uric Acid

2015
Caffeine's antioxidant potency optically sensed with double-stranded DNA-encased single-walled carbon nanotubes.
    The journal of physical chemistry. B, 2015, Mar-12, Volume: 119, Issue:10

    Topics: Antioxidants; Ascorbic Acid; Caffeine; DNA; Electron Spin Resonance Spectroscopy; Hydrogen Peroxide; Hydroxyl Radical; Nanotubes, Carbon; Reactive Oxygen Species; Uric Acid

2015
Electrochemical Decoration of Carbon Nanotubes with Au Nanostructure for the Electroanalysis of Biomolecules.
    Analytical sciences : the international journal of the Japan Society for Analytical Chemistry, 2015, Volume: 31, Issue:7

    Topics: Ascorbic Acid; Electrochemistry; Electrodes; Epinephrine; Gold; Metal Nanoparticles; Nanotubes, Carbon; Time Factors; Uric Acid

2015
A Nicotinamide Adenine Dinucleotide Dispersed Multi-walled Carbon Nanotubes Electrode for Direct and Selective Electrochemical Detection of Uric Acid.
    Analytical sciences : the international journal of the Japan Society for Analytical Chemistry, 2015, Volume: 31, Issue:8

    Topics: Ascorbic Acid; Biosensing Techniques; Dopamine; Electrochemistry; Electrodes; Humans; Limit of Detection; NAD; Nanocomposites; Nanotubes, Carbon; Oxidation-Reduction; Time Factors; Uric Acid

2015
Iron nanoparticles decorated multi-wall carbon nanotubes modified carbon paste electrode as an electrochemical sensor for the simultaneous determination of uric acid in the presence of ascorbic acid, dopamine and L-tyrosine.
    Materials science & engineering. C, Materials for biological applications, 2015, Dec-01, Volume: 57

    Topics: Ascorbic Acid; Biosensing Techniques; Carbon; Complex Mixtures; Conductometry; Dopamine; Equipment Design; Equipment Failure Analysis; Iron; Metal Nanoparticles; Microelectrodes; Nanotubes, Carbon; Ointments; Reproducibility of Results; Sensitivity and Specificity; Tyrosine; Uric Acid

2015
Carbon nanospikes grown on metal wires as microelectrode sensors for dopamine.
    The Analyst, 2015, Nov-07, Volume: 140, Issue:21

    Topics: Adsorption; Ascorbic Acid; Carbon; Carbon Fiber; Dopamine; Electrodes; Limit of Detection; Metals; Microelectrodes; Microscopy, Electron, Scanning; Nanotubes, Carbon; Neurotransmitter Agents; Oxidation-Reduction; Oxygen; Reproducibility of Results; Surface Properties; Uric Acid

2015
Electrochemical detection of nanomolar dopamine in the presence of neurophysiological concentration of ascorbic acid and uric acid using charge-coated carbon nanotubes via facile and green preparation.
    Talanta, 2016, Jan-15, Volume: 147

    Topics: Ascorbic Acid; Carbon; Citric Acid; Dopamine; Electrochemical Techniques; Electrodes; Green Chemistry Technology; Microscopy, Electron, Scanning; Nanotubes, Carbon; Polyethyleneimine; Spectroscopy, Fourier Transform Infrared; Uric Acid

2016
Carbon nanotubes implanted manganese-based MOFs for simultaneous detection of biomolecules in body fluids.
    The Analyst, 2016, Feb-21, Volume: 141, Issue:4

    Topics: Ascorbic Acid; Dopamine; Electrochemistry; Electrodes; Humans; Hydrogen-Ion Concentration; Limit of Detection; Manganese; Nanocomposites; Nanotubes, Carbon; Organometallic Compounds; Temperature; Time Factors; Uric Acid; Urinalysis

2016
Electrochemical Sensor Based on Fe Doped Hydroxyapatite-Carbon Nanotubes Composite for L-Dopa Detection in the Presence of Uric Acid.
    Journal of nanoscience and nanotechnology, 2016, Volume: 16, Issue:6

    Topics: Catalysis; Durapatite; Electrochemistry; Electrodes; Glass; Iron; Levodopa; Limit of Detection; Mucuna; Nanotubes, Carbon; Oxidation-Reduction; Uric Acid

2016
Evaluation of carbon nanotube fiber microelectrodes for neurotransmitter detection: Correlation of electrochemical performance and surface properties.
    Analytica chimica acta, 2017, 05-01, Volume: 965

    Topics: Ascorbic Acid; Biosensing Techniques; Dopamine; Electric Conductivity; Electrochemical Techniques; Electrons; Microelectrodes; Nanotubes, Carbon; Neurotransmitter Agents; Oxygen; Polyethyleneimine; Serotonin; Sulfonic Acids; Surface Properties; Uric Acid

2017
New synthesis of poly ortho-methoxyaniline nanostructures and its application to construct modified multi-wall carbon nanotube/graphite paste electrode for simultaneous determination of uric acid and folic acid.
    Materials science & engineering. C, Materials for biological applications, 2017, Jun-01, Volume: 75

    Topics: Biosensing Techniques; Catalysis; Electrochemical Techniques; Electrodes; Folic Acid; Nanotubes, Carbon; Uric Acid

2017
Probe Sensor Using Nanostructured Multi-Walled Carbon Nanotube Yarn for Selective and Sensitive Detection of Dopamine.
    Sensors (Basel, Switzerland), 2017, Apr-18, Volume: 17, Issue:4

    Topics: Ascorbic Acid; Dopamine; Nanotubes, Carbon; Uric Acid

2017
Systematic Structure-Activity Relationship (SAR) Exploration of Diarylmethane Backbone and Discovery of A Highly Potent Novel Uric Acid Transporter 1 (URAT1) Inhibitor.
    Molecules (Basel, Switzerland), 2018, Jan-27, Volume: 23, Issue:2

    Topics: Benzbromarone; Biological Transport, Active; Carbon Radioisotopes; Drug Design; Gene Expression; HEK293 Cells; Humans; Methane; Organic Anion Transporters; Organic Cation Transport Proteins; Structure-Activity Relationship; Thioglycolates; Triazoles; Uric Acid; Uricosuric Agents

2018
Portable electrochemical sensor based on 4-aminobenzoic acid-functionalized herringbone carbon nanotubes for the determination of ascorbic acid and uric acid in human fluids.
    Biosensors & bioelectronics, 2018, Jun-30, Volume: 109

    Topics: 4-Aminobenzoic Acid; Ascorbic Acid; Biosensing Techniques; Dopamine; Electrochemistry; Humans; Limit of Detection; Nanotubes, Carbon; Polymers; Uric Acid

2018
Unmodified and multi-walled carbon nanotube modified tetrahedral amorphous carbon (ta-C) films as in vivo sensor materials for sensitive and selective detection of dopamine.
    Biosensors & bioelectronics, 2018, Oct-30, Volume: 118

    Topics: Animals; Ascorbic Acid; Biosensing Techniques; Carbon; Dopamine; Electrodes; Mice; Nanotubes, Carbon; Uric Acid

2018
Layer-by-layer electrochemical biosensors configuring xanthine oxidase and carbon nanotubes/graphene complexes for hypoxanthine and uric acid in human serum solutions.
    Biosensors & bioelectronics, 2018, Dec-15, Volume: 121

    Topics: Biosensing Techniques; Blood Chemical Analysis; Electrodes; Graphite; Humans; Hypoxanthine; Nanotubes, Carbon; Uric Acid; Xanthine Oxidase

2018
Hierarchical bi-continuous Pt decorated nanoporous Au-Sn alloy on carbon fiber paper for ascorbic acid, dopamine and uric acid simultaneous sensing.
    Biosensors & bioelectronics, 2019, Jan-15, Volume: 124-125

    Topics: Ascorbic Acid; Biosensing Techniques; Carbon Fiber; Dopamine; Metal Nanoparticles; Nanopores; Platinum; Tin; Uric Acid

2019
Simultaneous detection of ATP metabolites in human plasma and urine based on palladium nanoparticle and poly(bromocresol green) composite sensor.
    Biosensors & bioelectronics, 2019, Feb-01, Volume: 126

    Topics: Adenosine Triphosphate; Biosensing Techniques; Humans; Hypoxanthine; Inosine; Metabolome; Metal Nanoparticles; Nanotubes, Carbon; Palladium; Uric Acid; Xanthine

2019
Multiwalled carbon nanotube-based nanosensor for ultrasensitive detection of uric acid, dopamine, and ascorbic acid.
    Materials science & engineering. C, Materials for biological applications, 2019, Volume: 99

    Topics: Alloys; Ascorbic Acid; Biosensing Techniques; Dopamine; Electrochemical Techniques; Nanoparticles; Nanotubes, Carbon; Nickel; Uric Acid; Zinc

2019
[Prevalence and influencing factors of hyperuricemia among natural gas drilling workers in Northwest Sichuan gas field in 2016].
    Wei sheng yan jiu = Journal of hygiene research, 2019, Volume: 48, Issue:1

    Topics: China; Humans; Hyperuricemia; Natural Gas; Occupational Exposure; Oil and Gas Fields; Prevalence; Risk Factors; Uric Acid

2019
A novel electrochemical sensor based on carbon nanotubes array for selective detection of dopamine or uric acid.
    Talanta, 2019, Aug-15, Volume: 201

    Topics: Ascorbic Acid; Dopamine; Electrochemical Techniques; Electrodes; Humans; Indoles; Limit of Detection; Nanotubes, Carbon; Oxidation-Reduction; Uric Acid

2019
Atomic matching catalysis to realize a highly selective and sensitive biomimetic uric acid sensor.
    Biosensors & bioelectronics, 2019, Sep-15, Volume: 141

    Topics: Biomimetics; Biosensing Techniques; Ferrocyanides; Humans; Limit of Detection; Models, Molecular; Nanoparticles; Nanotubes, Carbon; Nitrogen; Oxidation-Reduction; Uric Acid

2019
High sensitive determination of dopamine through catalytic oxidation and preconcentration over gold-multiwall carbon nanotubes composite modified electrode.
    Materials science & engineering. C, Materials for biological applications, 2019, Volume: 103

    Topics: Ascorbic Acid; Catalysis; Dopamine; Electrochemical Techniques; Electrodes; Gold; Humans; Limit of Detection; Metal Nanoparticles; Nanotubes, Carbon; Oxidation-Reduction; Uric Acid

2019
A flexible carbon nanotube-modified poly(styrene-butadiene)-based dopamine sensor.
    Nanotechnology, 2020, Jan-03, Volume: 31, Issue:1

    Topics: Ascorbic Acid; Biosensing Techniques; Butadienes; Dopamine; Electrochemical Techniques; Humans; Hydrogen-Ion Concentration; Nanotubes, Carbon; Polystyrenes; Uric Acid

2020
In-situ reduction of Ag
    Biosensors & bioelectronics, 2019, Dec-01, Volume: 145

    Topics: Biosensing Techniques; Carboxymethylcellulose Sodium; Electrochemical Techniques; Humans; Hypoxanthine; Limit of Detection; Metal Nanoparticles; Nanocomposites; Nanotubes, Carbon; Oxygen; Silver; Uric Acid; Water; Xanthine

2019
High-index {hk0} facets platinum concave nanocubes loaded on multiwall carbon nanotubes and graphene oxide nanocomposite for highly sensitive simultaneous detection of dopamine and uric acid.
    Talanta, 2020, Jan-15, Volume: 207

    Topics: Dopamine; Electrochemistry; Electrodes; Graphite; Limit of Detection; Models, Molecular; Molecular Conformation; Nanocomposites; Nanotubes, Carbon; Platinum; Time Factors; Uric Acid

2020
Green and facile microwave solvent-free synthesis of CeO
    Talanta, 2020, Jan-15, Volume: 207

    Topics: Acetaminophen; Ascorbic Acid; Cerium; Dopamine; Electrochemistry; Electrodes; Green Chemistry Technology; Hydrogen-Ion Concentration; Limit of Detection; Microwaves; Nanoparticles; Nanotechnology; Nanotubes, Carbon; Surface Properties; Time Factors; Uric Acid

2020
Electrochemical determination of uric acid in urine and serum with uricase/carbon nanotube /carboxymethylcellulose electrode.
    Analytical biochemistry, 2020, 02-01, Volume: 590

    Topics: Adult; Biosensing Techniques; Carboxymethylcellulose Sodium; Electrochemistry; Electrodes; Enzymes, Immobilized; Humans; Male; Nanotubes, Carbon; Urate Oxidase; Uric Acid

2020
Methane emissions of geese (Anser anser) and turkeys (Meleagris gallopavo) fed pelleted lucerne.
    Comparative biochemistry and physiology. Part A, Molecular & integrative physiology, 2020, Volume: 242

    Topics: Animal Feed; Animal Nutritional Physiological Phenomena; Animals; Diet; Digestion; Female; Fermentation; Geese; Herbivory; Male; Medicago sativa; Methane; Turkeys; Uric Acid

2020
Nanocomposites of poly(l-methionine), carbon nanotube-graphene complexes and Au nanoparticles on screen printed carbon electrodes for electrochemical analyses of dopamine and uric acid in human urine solutions.
    The Analyst, 2020, May-18, Volume: 145, Issue:10

    Topics: Dopamine; Electrochemistry; Electrodes; Gold; Graphite; Humans; Metal Nanoparticles; Nanocomposites; Nanotubes, Carbon; Peptides; Printing; Uric Acid; Urinalysis

2020
A simple electrochemical approach to fabricate functionalized MWCNT-nanogold decorated PEDOT nanohybrid for simultaneous quantification of uric acid, xanthine and hypoxanthine.
    Analytica chimica acta, 2020, Jun-01, Volume: 1114

    Topics: Bridged Bicyclo Compounds, Heterocyclic; Electrochemical Techniques; Gold; Hypoxanthine; Metal Nanoparticles; Molecular Structure; Nanotubes, Carbon; Particle Size; Polymers; Surface Properties; Uric Acid; Xanthine

2020
Hybrid carbon nanotubes modified glassy carbon electrode for selective, sensitive and simultaneous detection of dopamine and uric acid.
    Ecotoxicology and environmental safety, 2020, Sep-15, Volume: 201

    Topics: Animals; Carbon; Cattle; Dopamine; Electrochemical Techniques; Electrodes; Limit of Detection; Nanotubes, Carbon; Reproducibility of Results; Uric Acid

2020
An electrochemical biosensor based on multi-wall carbon nanotube-modified screen-printed electrode immobilized by uricase for the detection of salivary uric acid.
    Analytical and bioanalytical chemistry, 2020, Volume: 412, Issue:26

    Topics: Biosensing Techniques; Electrochemical Techniques; Electrodes; Enzymes, Immobilized; Humans; Nanotubes, Carbon; Saliva; Urate Oxidase; Uric Acid

2020
Electrochemical dual signal sensing platform for the simultaneous determination of dopamine, uric acid and glucose based on copper and cerium bimetallic carbon nanocomposites.
    Bioelectrochemistry (Amsterdam, Netherlands), 2021, Volume: 139

    Topics: Biomarkers; Biosensing Techniques; Blood Glucose; Cerium; Copper; Dopamine; Electrochemical Techniques; Electrodes; Graphite; Humans; Limit of Detection; Metabolic Syndrome; Metal Nanoparticles; Nanocomposites; Nanotubes, Carbon; Uric Acid

2021
A 3D electrochemical biosensor based on Super-Aligned Carbon NanoTube array for point-of-care uric acid monitoring.
    Biosensors & bioelectronics, 2021, May-01, Volume: 179

    Topics: Biosensing Techniques; Electrochemical Techniques; Electrodes; Nanotubes, Carbon; Point-of-Care Systems; Urate Oxidase; Uric Acid

2021
One-dimensional nitrogen doped porous carbon nano-array arranged by carbon nanotubes for electrochemical sensing ascorbic acid, dopamine and uric acid simultaneously.
    Nanotechnology, 2021, Mar-31, Volume: 32, Issue:25

    Topics: Ascorbic Acid; Dopamine; Electrochemical Techniques; Limit of Detection; Nanotubes, Carbon; Nitrogen; Porosity; Uric Acid

2021
Single-Drop Analysis of Epinephrine and Uric Acid on a Screen-Printed Carbon Electrode.
    Biosensors, 2021, Aug-19, Volume: 11, Issue:8

    Topics: Ascorbic Acid; Biosensing Techniques; Catalysis; Electrochemical Techniques; Electrochemistry; Electrodes; Epinephrine; Humans; Nanotubes, Carbon; Uric Acid

2021
Developing Activated Carbon Veil Electrode for Sensing Salivary Uric Acid.
    Biosensors, 2021, Aug-20, Volume: 11, Issue:8

    Topics: Biosensing Techniques; Charcoal; Dielectric Spectroscopy; Electrochemical Techniques; Electrodes; Humans; Limit of Detection; Metal Nanoparticles; Nanotubes, Carbon; Oxidation-Reduction; Saliva; Uric Acid

2021
Novel lanthanum vanadate-based nanocomposite for simultaneously electrochemical detection of dopamine and uric acid in fetal bovine serum.
    International journal of biological macromolecules, 2022, Jan-15, Volume: 195

    Topics: Ascorbic Acid; Dopamine; Electrochemical Techniques; Electrodes; Graphite; Lanthanum; Limit of Detection; Nanocomposites; Nanotubes, Carbon; Serum Albumin, Bovine; Spectroscopy, Fourier Transform Infrared; Uric Acid; Vanadates

2022
Powerful Electron-Transfer Screen-Printed Platforms as Biosensing Tools: The Case of Uric Acid Biosensor.
    Biosensors, 2021, Dec-21, Volume: 12, Issue:1

    Topics: Biosensing Techniques; Electrochemical Techniques; Electrodes; Electrons; Nanotubes, Carbon; Reproducibility of Results; Uric Acid

2021
Hemin-Functionalized Microfluidic Chip with Dual-Electric Signal Outputs for Accurate Determination of Uric Acid.
    ACS applied materials & interfaces, 2022, Sep-14, Volume: 14, Issue:36

    Topics: Biosensing Techniques; Electrochemical Techniques; Hemin; Microfluidics; Nanotubes, Carbon; Receptor Protein-Tyrosine Kinases; Uric Acid

2022
La(OH)
    Biosensors, 2022, Sep-01, Volume: 12, Issue:9

    Topics: Allergens; Electrochemical Techniques; Electrodes; HEK293 Cells; Humans; Irritants; Nanotubes, Carbon; Peptide Hydrolases; Reproducibility of Results; Uric Acid

2022
An ultra-sensitive uric acid second generation biosensor based on chemical immobilization of uricase on functionalized multiwall carbon nanotube grafted palm oil fiber in the presence of a ferrocene mediator.
    Analytical methods : advancing methods and applications, 2023, 05-25, Volume: 15, Issue:20

    Topics: Biosensing Techniques; Humans; Metallocenes; Nanotubes, Carbon; Palm Oil; Reproducibility of Results; Urate Oxidase; Uric Acid

2023
Ingenious fabrication of bamboo leaf-like ferric vanadate intertwined multi-walled carbon nanotubes nanocomposite as a sensitive sensor for determination of uric acid in fetal bovine serum.
    Mikrochimica acta, 2023, 10-16, Volume: 190, Issue:11

    Topics: Electrochemical Techniques; Humans; Iron; Limit of Detection; Nanocomposites; Nanotubes, Carbon; Serum Albumin, Bovine; Uric Acid; Vanadates

2023