Publications

Here are the publications by professors and research partners related to urease inhibitors at NIST. These articles and book chapters represent significant contributions to the advancement of scientific knowledge in the field, sharing innovative findings and technological approaches.

Articles

81. Guimarães et al. (2024). Flavone-rich Passiflora edulis fruit shells as urease inhibitors for sustainable agricultural solutions. Theoretical and Experimental Plant Physiology, v. 36, p. 313-324. DOI

80. Marciéli et al. (2024). Exploring Urease Inhibition by Coumarin Derivatives through in silico and in vitro Methods. JOURNAL OF THE BRAZILIAN CHEMICAL SOCIETY, v. 35, p. 1-15, 2024.DOI

79. Viana et al. (2024). Synergizing structure and function: Cinnamoyl hydroxamic acids as potent urease inhibitors. BIOORGANIC CHEMISTRY, v. 146, p. 107247.DOI

78. Lopes et al. (2023). Methods to quantify the nitrogen derived from the fertilizer in maize applying blends of controlled-release and NBPT-treated urea. JOURNAL OF PLANT NUTRITION, v. 46, p. 1066-1076.DOI

77. Tavares et al. (2023). The influence of N-alkyl chains in benzoyl-thiourea derivatives on urease inhibition: Soil studies and biophysical and theoretical investigations on the mechanism of interaction. BIOPHYSICAL CHEMISTRY, v. 299, p. 107042. DOI

76. Vareijao et al. (2023). Rubrolide Analogues as Urease Inhibitors. MONATSHEFTE FUR CHEMIE (INTERNET), v. 1, p. 1-11.DOI

75. Soares et al. (2023). Dynamics of ammonia volatilization from NBPT-treated urea in tropical acid soils. SCIENTIA AGRICOLA, v. 80, p. e20220076. DOI

74. Rosetto et al. (2023). Controlled-release urea for use in sugarcane ratoons. Sugar Industry-Zuckerindustrie, v. 148, p. 638-641. DOI

73. Ribeiro et al. (2023). An overview on the anticancer activity of Ru(II)/acylthiourea complexes. COORDINATION CHEMISTRY REVIEWS, v. 488, p. 215161.DOI

72. Fabris et al. (2023). Computational Strategies Targeting Inhibition of and Ureases. CURRENT PHARMACEUTICAL DESIGN, v. 29, p. 777-792.DOI

71. Cândido et al. (2023). EXTRATOS PIROLENHOSOS DE CASCA DE COCO, ACÁCIA NEGRA E EUCALIPTO: CARACTERIZAÇÃO FÍSICO-QUÍMICA E AVALIAÇÃO IN VITRO COMO POTENCIAIS INIBIDORES DA UREASE. QUIMICA NOVA, v. 46, p. 961-971,.DOI

70. Biasi'Garbin et al. (2022). In Vitro Antimicrobial Screening of Benzoylthioureas: Synthesis, Antibacterial Activity toward Streptococcus agalactiae and Molecular Docking Study. ChemistrySelect, v. 7, p. e202202117.DOI

69. Camargo et al. (2022). Thiohydantoins and hydantoins derived from amino acids as potent urease inhibitors: Inhibitory activity and ligand-target interactions. CHEMICO-BIOLOGICAL INTERACTIONS, v. 365, p. 110045. DOI

68. Oliveira et al. (2022). Soil pH does not interfere with nitrification inhibitor efficiency for reducing N2O emissions from soils treated with concentrated vinasse and urea. GEODERMA, v. 426, p. 116087.DOI

67. Tavares et al. (2022). Interaction and inhibition mechanism of urease in vitro and soil system by a natural benzylisothiocyanate isolated from Moringa oleifera. INDUSTRIAL CROPS AND PRODUCTS, v. 178, p. 114580. DOI

66. Pereira et al. (2022). 2-(Pyridin-4yl)benzothiazole and Its Benzimidazole-Analogue: Biophysical and in silico Studies on Their Interaction with Urease and in vitro Anti-Helicobacter pylori Activities. JOURNAL OF THE BRAZILIAN CHEMICAL SOCIETY, v. 33, p. 1041-1057. DOI

65. Eden et al. (2021). Eficiência da adubação nitrogenada associada ao inibidor de urease no cultivo de girassol-mexicano irrigado. RESEARCH, SOCIETY AND DEVELOPMENT, v. 10, p. e372101220621.DOI

64. Moreira et al. (2021). Urea- Versus Ammonium Nitrate-Based Fertilizers for Green Sugarcane Cultivation. JOURNAL OF SOIL SCIENCE AND PLANT NUTRITION, v. 21, p. 1329-1338. DOI

63. Tavares et al. (2021). Paper-based analytical device with colorimetric detection for urease activity determination in soils and evaluation of potential inhibitors. TALANTA, v. 230, p. 122301. DOI

62. Werneck et al. (2021). Ammonia volatilization and agronomical efficiency of a mixture of urea with natural zeolite for rose fertilization. PESQUISA AGROPECUÁRIA BRASILEIRA (ONLINE), v. 56, p. 1-9. DOI

61. Chaves-Silva et al. (2020). Do schiff bases-based urease inhibitors improve plant growth and affect the activity of soil arginase?. INDUSTRIAL CROPS AND PRODUCTS, v. 145, p. 111995.DOI

60. Brito et al. (2020). Benzoylthioureas: Design, Synthesis and Antimycobacterial Evaluation. Medicinal Chemistry, v. 16, p. 93-103.DOI

59. Leite et al. (2020). Co-addition of humic substances and humic acids with urea enhances foliar nitrogen use efficiency in sugarcane (Saccharum officinarum L.). HELIYON, v. 6, p. e05100.DOI

58. Lopes et al. (2020). Nitrogen Fertilization Management with Blends of Controlled-Release and Conventional Urea Affects Common Bean Growth and Yield during Mild Winters in Brazil. Agronomy-Basel, v. 10, p. 1935-1952. DOI

57. Lopes et al. (2020). 15N-Fertilizer Recovery in Maize as an Additional Strategy for Understanding Nitrogen Fertilization Management with Blends of Controlled-Release and Conventional Urea. Agronomy-Basel, v. 10, p. 1932-1953.DOI

56. Almeida et al. (2019). Trivelin, Paulo César Ocheuze . Polymer-Coated Urea in Broadcast or Furrow Application in the Corn-Palisadegrass Intercropping System. Journal of Agricultural Science, v. 11, p. 226-241.DOI

55. Braga et al. (2019). Ionic Liquid-assisted Synthesis of Dihydropyrimidin(thi)ones Biginelli Adducts and Investigation of their Mechanism of Urease Inhibition. New Journal of Chemistry, v. 43, p. 15187-15200.DOI

54. De Oliveira et al. (2019). The molecular structure of an epoxide hydrolase from Trichoderma reesei in complex with urea or amide-based inhibitors. INTERNATIONAL JOURNAL OF BIOLOGICAL MACROMOLECULES, v. 129, p. 653-658. DOI

53. Fiori-Duarte et al. (2019). Insights into the design of inhibitors of the urease enzyme - a major target for the treatment of Helicobacter pylori infections. CURRENT MEDICINAL CHEMISTRY, v. 26, p. 1-15. DOI

52. Lopes et al. (2019). Effect of nitrogen rates applying controlled-release and conventional urea blend in maize. JOURNAL OF PLANT NUTRITION. v. 42, p. 2199-2208.DOI

51. Lopes et al. (2019). Placement Effect of Controlled-release and Conventional Urea Blend in Maize. COMMUNICATIONS IN SOIL SCIENCE AND PLANT ANALYSIS, v. 50, p. 1-9. DOI

50. Mariano et al. (2019). Ammonia losses following surface application of enhanced-efficiency nitrogen fertilizers and urea. ATMOSPHERIC ENVIRONMENT, v. 203, p. 242-251. DOI

49. Muniz et al. (2019). Pre-emergence Application of (Thio)urea Analogues Compromises the Development of the Weed Species Bidens pilosa, Urochloa brizantha and Urochloa decumbens. JOURNAL OF ADVANCED RESEARCH, v. 17, p. 95-102. DOI

48. Sá et al. (2019). Risk assessment of the antifungal and insecticidal peptide Jaburetox and its parental protein the Jack bean (Canavalia ensiformis) urease. FOOD AND CHEMICAL TOXICOLOGY, v. 135, p. 110977. DOI

47. Rinaldi et al. (2019). N-Urea efficiency in maize as influenced by humic substances and urease inhibitors treatments. COMMUNICATIONS IN SOIL SCIENCE AND PLANT ANALYSIS, v. 50, p. 198-208.DOI

46. Nain-Perez et al. (2019). Anti-ureolytic activity of substituted 2,5-diaminobenzoquinones. CHEMISTRY & BIODIVERSITY, v. 16, p. e1900503. DOI

45. Cantarella et al. (2018). Agronomic Efficiency of NBPT as a Urease Inhibitor: A review. JOURNAL OF ADVANCED RESEARCH, v. 13, p. 19-27. DOI

44. De Fátima et al. (2018). Schiff bases and their metal complexes as urease inhibitors - a brief review. JOURNAL OF ADVANCED RESEARCH, v. 13, p. 113-126, 2018. DOI

43. Garcia et al. (2018). Nitrogen use efficiency and nutrient partitioning in maize as affected by blends of controlled-release and conventional urea. Archives of Agronomy and Soil Science, v. 64, p. 1-19. DOI

42. Gava et al. (2018). Nitrogen source contribution in sugarcane-inoculated plants with diazotrophic bacterias under urea-N fertigation management. Sugar Tech, v. 21, p. 462-470. DOI

41. Lage et al. (2018). In vitro inhibition of Helicobacter pylori and interaction studies of lichen natural products with jack bean urease. NEW JOURNAL OF CHEMISTRY, v. 42, p. 5356-5366.DOI

40. Modolo et al. (2018). A minireview on what we have learned about urease inhibitors of agricultural interest since mid-2000s. JOURNAL OF ADVANCED RESEARCH, v. 13, p. 29-37. DOI

39. Rego et al. (2018). A Review on the Development of Urease Inhibitors as Antimicrobial Agents against Pathogenic Bacteria. JOURNAL OF ADVANCED RESEARCH, v. 13, p. 69-100.DOI

38. REIS, SAYRON ; APARECIDO LIBERTO, NATÁLIA ; ANTÔNIO FERNANDES, SERGIO ; de FÁTIMA, A. ; DE ALMEIDA, WAGNER B. ; GUIMARÃES, LUCIANA ; NASCIMENTO, CLEBIO S. . Theoretical Investigation on the Molecular Inclusion Process of Urease Inhibitors into p -sulfonic acid calix[4,6]arenes. CHEMICAL PHYSICS LETTERS, v. 692, p. 117-123, 2018.

37. Schoninger et al. (2018). Corn grain yield and 15N-fertilizer recovery as a function of urea sidedress timing. ANAIS DA ACADEMIA BRASILEIRA DE CIÊNCIAS (ONLINE), v. 2018, p. 1-14.DOI

36. Campos et al. (2017). Nitrogen release from urea with different coatings or urease inhibitor. JOURNAL OF THE SCIENCE OF FOOD AND AGRICULTURE, v. 000, p. 000-00, 2017.DOI

35. Silva et al. (2017). Volatilização de amônia do solo após doses de ureia com inibidores de urease e nitrificação na cultura do abacaxi. REVISTA CERES, v. 64, p. 327-335.DOI

34. Rech et al. (2017). Additives incorporated into urea to reduce nitrogen losses after application to the soil. PESQUISA AGROPECUARIA BRASILEIRA, v. 52, p. 194-204.DOI

33. Reis et al. (2017). Molecular Inclusion Process of Urease Inhibitors into Cyclodextrins: A Theoretical Study. Chemical Physics Letters (Print), v. 675, p. 69-74. DOI

32. Martins et al. (2017). Impact of plant growth-promoting bacteria on grain yield, protein content, and urea-15 N recovery by maize in a Cerrado Oxisol. PLANT AND SOIL, v. 422, p. 239-250, 2017. DOI

31. Mesquita et al. (2017). A practical approach for assessing the efficiency of coated urea on controlling nitrogen availability. BRAGANTIA, v. 76, p. 311-317.DOI

30. Mira ets al. (2017). Optimizing urease inhibitor usage to reduce ammonia emission following urea application over crop residues. AGRICULTURE ECOSYSTEMS & ENVIRONMENT, v. 248, p. 105-112.DOI

29. Espinal et al. (2016). Utilization of nitrogen (15N) from urea and green manures by rice as affected by nitrogen fertilizer rate. African Journal of Agricultural Research, v. 11, p. 1171-1180. DOI

28. Guimarães et al. (2016). Comparison of urease inhibitor N-(n-butyl) thiophosphoric triamide and oxidized charcoal for conserving urea-N in soil. JOURNAL OF PLANT NUTRITION AND SOIL SCIENCE, v. 179, p. 520-528.DOI

27. Guimarães et al. (2016). Value of copper, zinc, and oxidized charcoal for increasing forage efficiency of urea N uptake. AGRICULTURE ECOSYSTEMS & ENVIRONMENT, v. 224, p. 157-165.DOI

26. Horta et al. (2016). Urease Inhibitors of Agricultural Interest Inspired by Structures of Plant Phenolic Aldehydes. Journal of the Brazilian Chemical Society (Impresso), v. 27, p. 1512-1519.DOI

25. Mendonça et al. (2016). Theoretical and NMR experimental insights on urea, thiourea and diindolyurea as fluoride carriers. Journal of Molecular Structure (Print), v. 1114, p. 13-20.DOI

24. Milagres et al. (2016). Soil N Losses by Denitrification Evaluated Using the N Tracer Method. Communications in Soil Science and Plant Analysis, v. 47, p. 1709-1719. DOI

23. Esteves et al. (2015). A simple one-pot methodology for the synthesis of substituted benzoylguanidines from benzoylthioureas using tert-butyl hydroperoxide. TETRAHEDRON LETTER, v. 56, p. 6872-6874. DOI

22. Brito et al. (2015). Design, syntheses and evaluation of benzoylthioureas as urease inhibitors of agricultural interest. RSC Advances: an international journal to further the chemical sciences, v. 5, p. 44507-44515.DOI

21. Bueno et al. (2015). Cuban zeolite as ammonium carrier in urea-based fertilizer pellets: Photoacoustic-based sensor for monitoring N-ammonia losses by volatilization in aqueous solutions. Sensors and Actuators. B, Chemical, v. 212, p. 35-40, 2015.DOI

20. De Araujo et al. (2015). Efficient sodium bisulfite-catalyzed synthesis of benzothiazoles and their potential as ureases inhibitors. RSC Advances: an international journal to further the chemical sciences, v. 5, p. 28814-28821. DOI

19. Guimarães et al. (2015). Volatilization of Ammonia Originating from Urea Treated with Oxidized Charcoal. JOURNAL OF THE BRAZILIAN CHEMICAL SOCIETY, v. 26, p. 1928-1935.DOI

18. Mariano et al. (2015). Ammonia losses estimated by an open collector from urea applied to sugarcane straw. Revista Brasileira de Ciência do Solo (Impresso), v. 36, p. 411-419. DOI

17. Modolo et al. (2015). An overview on the potential of natural products as ureases inhibitors: A review. Journal of Advanced Research, v. 6, p. 35-44.DOI

16. Soares et al. (2015). Enhanced-Efficiency Fertilizers in Nitrous Oxide Emissions from Urea Applied to Sugarcane. Journal of Environmental Quality, v. 44, p. 423-430.DOI

15. Oliveira et al. (2014). Synthesis, molecular properties and DFT studies of new phosphoramidates as potential urease inhibitors. Medicinal Chemistry Research (Print), v. 23, p. 5174-5187.DOI

14. Boaretto et all. (2013). Absorption of 15NH3 volatilized from urea by Citrus trees. Plant and Soil (Dordrecht. Online), v. 365, p. 283-290. DOI

13. Fortes et al. (2013). Contribution of nitrogen from sugarcane harvest residues and urea for crop nutrition. Scientia Agrícola (USP. Impresso), v. 70, p. 313-320.DOI

12. Oliveira et al. (2012). Structure?activity relationship of pyridin-2(1H)-ones derivatives as urease inhibitors. Journal of Pharmacy Research, v. 5, p. 5326.

11. Paiva et al. (2012). Urea coated with oxidized charcoal reduces ammonia volatilization. REVISTA BRASILEIRA DE CIENCIA DO SOLO, v. 36, p. 1221-1230. DOI

10. Cantarella et al. (2012). Ammonia volatilization losses from surface-applied urea with urease and nitrification inhibitors. Soil Biology & Biochemistry, v. 52, p. 82-89. DOI

9. Franco et al. (2012). Synthesis and Antimalarial Activity of Dihydroperoxides and Tetraoxanes Conjugated with Bis(benzyl)acetone Derivatives. Chemical Biology & Drug Design, v. 79, p. 790-797.DOI

8. Bernardi et al. (2011). Yield, Quality Components, and Nitrogen Levels of Silage Corn Fertilized with Urea and Zeolite. Communications in Soil Science and Plant Analysis, v. 42, p. 1-10, 2011. DOI

7. Fortes et al. (2011). Recovery of Nitrogen (15N) by Sugarcane from Previous Crop Residues and Urea Fertilisation Under a Minimum Tillage System. Sugar Tech, v. 13, p. 42-46, 2011. DOI

6. Rosa et al. (2010). Flavonoides e atividade antioxidante em Palicourea rigida Kunth. Revista Brasileira de Farmacognosia (Impresso), v. 20, p. 484-488. DOI

5. Cantarella et al. (2008) Ammonia volatilization from urease inhibitor-treated urea applied to sugarcane trash blankets. Scientia Agricola, v. 65, p. 397-401. DOI

4. Cunha et al. (2007). Antimicrobial Activity and Structural Study of Disubstituted Thiourea Derivatives. Monatshefte fur Chemie, v. 138, p. 511-516.DOI

3. Gava et al. (2005). Urea and sugarcane straw nitrogen balance in a soil-sugarcane crop system. Pesquisa Agropecuária Brasileira, Brasília, v. 40, n.7, p. 689-695. DOI

2. Boaretto et al. (2004). Fate of 15N-urea applied to wheat-soybean succession crop. Bragantia, v. 63, n. 2, p. 265-274 DOI

1. Muraoka et al(2002). Eficiencia de abonos verdes (Crotalaria y Mucuna) y urea, aplicados solos o juntamente, como fuentes de N para el cultivo de arroz. Terra (México), Chapingo, v. 20, p. 17-23, 2002.

Book Chapters

2. Lopes, Thamirys Andrade ; Lopes, Nayara Franzini ; Portilho, Gabriel Reis ; Andrade, Frances Alves ; Silva, Luana Bertolini de Jesus ; CASTRO, RENATO VINÍCIUS OLIVEIRA ; TONOLI, GUSTAVO HENRIQUE DENZIN ; Carneiro, Angélica de Cássia Oliveira . NANOPARTÍCULAS DE LIGNINA E SEUS EFEITOS NAS PROPRIEDADES DO ADESIVO UREIA-FORMALDEÍDO PARA COLAGEM DE MADEIRA. Engenharia Industrial Madeireira:Tecnologia, pesquisa e tendências. 1ed.: , 2021, v. , p. 219-242.

1. Ferreira, Andréia C.S. ; Cruz, Rosana C. ; Rosa, Clara Q. ; DE FÁTIMA, ÂNGELO ; MODOLO, LUZIA V. . Reaching food security: harnessing urease inhibitors to meet the challenges of growing global population. Ureases. 1aed.: Elsevier, 2024, v. , p. 359-373.