Physical, Chemical and Biological Structures based on ROS-sensitive Moieties that are able to respond to Oxidative Microenvironments

Abhay Shashikant Pandit

Physical, Chemical and Biological Structures based on ROS-sensitive Moieties that are able to respond to Oxidative Microenvironments

Biomedical Engineering

Research output: Contribution to a Journal (Peer & Non Peer) › Article › peer-review

Abstract

Reactive oxygen species (ROS) (H2O2, OCl #8722;, OH, O2 #8722;) are a family of reactive molecules that are generated intracellularly and are engaged in many biological processes. In physiological concentrations, ROS act as signaling molecules to a number of metabolic pathways; however, in excess they can be harmful to living organisms. Overproduction of ROS has been related to many pathophysiological conditions and a number of studies have been reported in elucidating their mechanism in these conditions. With the aim of harnessing this role, a number of imaging tools and therapeutic compounds have been developed. Here these imaging and therapeutic tools are reviewed and particularly those structures with ROS-sensitivity based on their biomedical applications and their functional groups. There is also a brief discussion about the method of preparation as well as the mechanism of action.

Original language	English (Ireland)
Journal	Advanced Materials
Volume	28
Issue number	27
Publication status	Published - 1 Jan 2016

Authors (Note for portal: view the doc link for the full list of authors)

Authors
Tapeinos, C. and Pandit, A.

Cite this

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title = "Physical, Chemical and Biological Structures based on ROS-sensitive Moieties that are able to respond to Oxidative Microenvironments",

abstract = "Reactive oxygen species (ROS) (H2O2, OCl \#8722;, OH, O2 \#8722;) are a family of reactive molecules that are generated intracellularly and are engaged in many biological processes. In physiological concentrations, ROS act as signaling molecules to a number of metabolic pathways; however, in excess they can be harmful to living organisms. Overproduction of ROS has been related to many pathophysiological conditions and a number of studies have been reported in elucidating their mechanism in these conditions. With the aim of harnessing this role, a number of imaging tools and therapeutic compounds have been developed. Here these imaging and therapeutic tools are reviewed and particularly those structures with ROS-sensitivity based on their biomedical applications and their functional groups. There is also a brief discussion about the method of preparation as well as the mechanism of action.",

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N2 - Reactive oxygen species (ROS) (H2O2, OCl #8722;, OH, O2 #8722;) are a family of reactive molecules that are generated intracellularly and are engaged in many biological processes. In physiological concentrations, ROS act as signaling molecules to a number of metabolic pathways; however, in excess they can be harmful to living organisms. Overproduction of ROS has been related to many pathophysiological conditions and a number of studies have been reported in elucidating their mechanism in these conditions. With the aim of harnessing this role, a number of imaging tools and therapeutic compounds have been developed. Here these imaging and therapeutic tools are reviewed and particularly those structures with ROS-sensitivity based on their biomedical applications and their functional groups. There is also a brief discussion about the method of preparation as well as the mechanism of action.

AB - Reactive oxygen species (ROS) (H2O2, OCl #8722;, OH, O2 #8722;) are a family of reactive molecules that are generated intracellularly and are engaged in many biological processes. In physiological concentrations, ROS act as signaling molecules to a number of metabolic pathways; however, in excess they can be harmful to living organisms. Overproduction of ROS has been related to many pathophysiological conditions and a number of studies have been reported in elucidating their mechanism in these conditions. With the aim of harnessing this role, a number of imaging tools and therapeutic compounds have been developed. Here these imaging and therapeutic tools are reviewed and particularly those structures with ROS-sensitivity based on their biomedical applications and their functional groups. There is also a brief discussion about the method of preparation as well as the mechanism of action.

M3 - Article

VL - 28

JO - Advanced Materials

JF - Advanced Materials

IS - 27

ER -

Physical, Chemical and Biological Structures based on ROS-sensitive Moieties that are able to respond to Oxidative Microenvironments

Abstract

Authors (Note for portal: view the doc link for the full list of authors)

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