Abstract Glutathione (GSH) is the master antioxidant in the body and mainly produced in hepatocytes. Constant efflux of hepatic glutathione into the blood stream allows the redox potential of the entire body to be precisely controlled. Thus, depletion of hepatic glutathione has found to strongly correlate with an increased susceptibility to oxidative stress and high risk of many diseases such as liver injuries, immunodeficiency, Parkinson’s disease and infectious diseases. However, since hepatic glutathione is diluted more than two orders in the blood plasma and consumed by different organs, unlike conventional liver serum biomarkers, this crucial pathophysiological event cannot be readily monitored through blood testing even through it could be used to predict disease progression much earlier than conventional serum markers. Until now, in the preclinical research, a large number of animals have to be sacrificed; so that fresh liver tissues can be collected for ex vivo quantification of the glutathione level. In clinical research, C13 magnetic resonance spectroscopy (MRS) and nuclear imaging are being developed to indirectly measure GSH level; however, such high-end instrumentation and special skill sets preclude the translation of the pathophysiological significance of hepatic glutathione depletion from laboratories into the clinics, in particular, those with limited resources, for early disease management. The objective of this proposal is to develop an innovative nanotechnology that empowers blood testing to serve as a simple and rapid tool for noninvasive and consecutive monitoring of hepatic glutathione depletion; so that hepatic glutathione depletion could be readily monitored in the clinics through blood test and be used as an earlier indicator for diagnosis of liver and other oxidative-stress related diseases, which are influencing hundreds of millions of people in the world.