How to Find an HNO Needle in a (Bio)-Chemical Haystack
Azanone (also called nitroxyl or simply HNO) is an intrinsic elusive molecule, with a proven history of chemically and biologically relevant reactivity. The chapter describes many HNO donors, potential HNO production reactions, and azanone potential biological effects. Azanone donors are based mainl...
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Acceso en línea: | http://hdl.handle.net/20.500.12110/paper_97811187_v58_n_p145_Doctorovich |
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todo:paper_97811187_v58_n_p145_Doctorovich2023-10-03T16:42:55Z How to Find an HNO Needle in a (Bio)-Chemical Haystack Doctorovich, F. Bikiel, D.E. Pellegrino, J. Suárez, S.A. Martí, M.A. Azanone Biochemical reactions Chemical reactions HNO releasing agents Real-time detection method Therapeutic compounds Trapping method Amines Chemical reactions Reaction kinetics Signal detection Azanone Biochemical reactions Real-time detection Releasing agent Therapeutic compounds Trapping methods Chemical detection Azanone (also called nitroxyl or simply HNO) is an intrinsic elusive molecule, with a proven history of chemically and biologically relevant reactivity. The chapter describes many HNO donors, potential HNO production reactions, and azanone potential biological effects. Azanone donors are based mainly on hydroxylamine and its derivatives, NONOates, and C-nitroso compounds. HNO releasing agents have interesting perspectives as potential therapeutic compounds. However, more work, where HNO detections methods are critical, is needed to understand the chemical mechanisms underlying the observed physiological effects. Quantification of HNO is challenging because it is a very reactive species with a high rate for dimerization. Two different methodologies, trapping and real-time detection methods, have been explored in order to quantify HNO. The chapter reviews the recent advances in both types of azanone detection methods. © 2014 by John Wiley & Sons, Inc. All rights reserved. CHAP info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_97811187_v58_n_p145_Doctorovich |
institution |
Universidad de Buenos Aires |
institution_str |
I-28 |
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R-134 |
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Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) |
topic |
Azanone Biochemical reactions Chemical reactions HNO releasing agents Real-time detection method Therapeutic compounds Trapping method Amines Chemical reactions Reaction kinetics Signal detection Azanone Biochemical reactions Real-time detection Releasing agent Therapeutic compounds Trapping methods Chemical detection |
spellingShingle |
Azanone Biochemical reactions Chemical reactions HNO releasing agents Real-time detection method Therapeutic compounds Trapping method Amines Chemical reactions Reaction kinetics Signal detection Azanone Biochemical reactions Real-time detection Releasing agent Therapeutic compounds Trapping methods Chemical detection Doctorovich, F. Bikiel, D.E. Pellegrino, J. Suárez, S.A. Martí, M.A. How to Find an HNO Needle in a (Bio)-Chemical Haystack |
topic_facet |
Azanone Biochemical reactions Chemical reactions HNO releasing agents Real-time detection method Therapeutic compounds Trapping method Amines Chemical reactions Reaction kinetics Signal detection Azanone Biochemical reactions Real-time detection Releasing agent Therapeutic compounds Trapping methods Chemical detection |
description |
Azanone (also called nitroxyl or simply HNO) is an intrinsic elusive molecule, with a proven history of chemically and biologically relevant reactivity. The chapter describes many HNO donors, potential HNO production reactions, and azanone potential biological effects. Azanone donors are based mainly on hydroxylamine and its derivatives, NONOates, and C-nitroso compounds. HNO releasing agents have interesting perspectives as potential therapeutic compounds. However, more work, where HNO detections methods are critical, is needed to understand the chemical mechanisms underlying the observed physiological effects. Quantification of HNO is challenging because it is a very reactive species with a high rate for dimerization. Two different methodologies, trapping and real-time detection methods, have been explored in order to quantify HNO. The chapter reviews the recent advances in both types of azanone detection methods. © 2014 by John Wiley & Sons, Inc. All rights reserved. |
format |
CHAP |
author |
Doctorovich, F. Bikiel, D.E. Pellegrino, J. Suárez, S.A. Martí, M.A. |
author_facet |
Doctorovich, F. Bikiel, D.E. Pellegrino, J. Suárez, S.A. Martí, M.A. |
author_sort |
Doctorovich, F. |
title |
How to Find an HNO Needle in a (Bio)-Chemical Haystack |
title_short |
How to Find an HNO Needle in a (Bio)-Chemical Haystack |
title_full |
How to Find an HNO Needle in a (Bio)-Chemical Haystack |
title_fullStr |
How to Find an HNO Needle in a (Bio)-Chemical Haystack |
title_full_unstemmed |
How to Find an HNO Needle in a (Bio)-Chemical Haystack |
title_sort |
how to find an hno needle in a (bio)-chemical haystack |
url |
http://hdl.handle.net/20.500.12110/paper_97811187_v58_n_p145_Doctorovich |
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