Cellular metabolism of water-soluble nitroxides: Effect on rate of reduction of cell/nitroxide ratio,oxygen concentrations and permeability of nitroxides

In order to interpret more accurately studies that have used nitroxides and to improve the efficacy of the use of nitroxides in both basic studies of cells and as contrast agents for in vivo NMR, we have initiated a systematic study of the distribution and metabolism of nitroxides in biological systems. Overall, the results provide a reasonably coherent picture of some aspects of the interactions between nitroxides and cells. Reduction of the nitroxides appears to be an intracellular process, so that one of the principal variables that affects the rate of reduction is the ability of a nitroxide to enter cells. The entrance of nitroxides into cells shows considerable variability and ranges from essentially no penetration (e.g., 2,2,6,6-tetramethylpiperidine-N-oxyl-4-trimethylamine) through rates that are comparable to rates of reduction (e.g., 2,2,5,5-tetramethylpyrrolidine-N-oxyl-3-carboxylic acid), to rates that are so fast that there is complete equilibrium between intracellular and extracellular compartments (e.g., Tempone). The presence of a charged group on the nitroxide appears to be the important variable that affects their ability to enter cells. Once a nitroxides enters the cell, the structure of the nitroxide, e.g., piperidine vs. pyrrolidine ring, is major factor that affects the rate of reduction. The rates of reduction increase with increasing concentrations of nitroxides. This indicates that the principal mechanism(s) of reduction do not saturate in the concentration range we studied. We observed no abrupt changes in the rates of reduction over the entire concentration range of cells and nitroxides that we studied, which suggests that the mechanism(s) of nitroxide reduction did not change. The presence of oxygen decreased the observed rate of reduction of many of the nitroxides and this effect was independent of the concentration of nitroxide.     

Cellular uptake of electron paramagnetic resonance imaging probes through endocytosis of liposomes

Electron paramagnetic resonance imaging (EPRI) allows detection and localization of paramagnetic spin probes in vivo and in real time. We have shown that nitroxide spin probes entrapped in the intracellular milieu can be imaged by EPRI. Therefore, with the development of a tumor-targetable vehicle that can efficiently deliver nitroxides into cells, it should be possible to use nitroxide spin probes to label and image cells in a tumor. In this study, we assess the potential of liposomes as a delivery vehicle for imaging probes. We demonstrate that liposomes can stably encapsulate nitroxides at very high concentrations (> 100 mM), at which nitroxides exhibit concentration-dependent quenching of their EPR signal—a process analogous to the quenching of fluorescent molecules. The encapsulating liposomes thus appear spectroscopically “dark”. When the liposomes are endocytosed and degraded by cells, the encapsulated nitroxides are liberated and diluted into the much larger intracellular volume. The consequent relief of quenching generates a robust intracellular nitroxide signal that can be imaged. We show that through endocytosis of nitroxide-loaded liposomes, CV1 cells can achieve intracellular nitroxide concentrations of ∼ 1 mM. By using tissue phantom models, we verify that this concentration is more than sufficient for in vivo EPR imaging.     

The cellular-induced decay of DMPO spin adducts of .OH and .O2

In a recent report, it was concluded that DMPO, often considered the spin trap of choice for detection of superoxide and hydroxyl radical adducts in biological systems, may be unsuitable for many biological uses because of its instability in cellular systems. It was demonstrated in red blood cells and in hamster V79 cells that the DMPO spin adducts of .O2- and .OH are metabolized very rapidly so that even if formed, they may not be detected in many experiments with cells. Because of the potential importance of these findings to experiments already reported on the occurrence of oxygen radicals in cellular systems, and the implications of these findings for future experiments, we have extended the studies on DMPO to other cellular, systems. We have also investigated the role of oxygen in this system because it has been shown recently that very hypoxic cells reduce some nitroxides much more rapidly than oxic cells and therefore it seemed possible that the rapid loss of radical adducts of DMPO was due to the hypoxic conditions under which the previous experiments were carried out. The results of the present experiments indicate that the loss of the DMPO spin adducts occurs in other cell systems as well, that the decomposition rate is independent of the concentration of oxygen, and that the final products of cellular metabolism of DMPO adducts are different from those of most nitroxides. There is no evidence that intracellular DMPO-spin adducts of oxygen radicals can be observed under conditions similar to those used in this study. We conclude that DMPO is not likely to be a suitable agent for studying intracellular oxygen radicals.     

Effects of oxygen on the metabolism of nitroxide spin labels in cells

The products of the reduction of nitroxides in cells are the corresponding hydroxylamines, which cells can oxidize back to the nitroxides in the presence of oxygen. Both the reduction of nitroxides and the oxidation of hydroxylamines are enzyme-mediated processes. For lipid-soluble nitroxides, the rates of reduction are strongly dependent on the intracellular concentration of oxygen; severely hypoxic cells reduce nitroxides more rapidly than cells supplied with oxygen. In contrast, the rates of oxidation of hydroxylamines increase smoothly with increasing intracellular oxygen concentration up to 150 microM. In order to separate the effects on the rates of metabolism of nitroxides due directly to oxygen from effects due to the redox state of enzymes, we studied the cells under conditions in which each of these variables could be changed independently. Oxygen affects the metabolism of these nitroxides primarily by interacting with cytochrome c oxidase to change the redox state of the enzymes in the respiratory chain. Our results are consistent with the conclusions that in these cells reduction of lipophilic nitroxides occurs at the level of ubiquinone in the respiratory chain in mitochondria, and oxidation of the corresponding hydroxylamines occurs at the level of cytochrome c oxidase.     

Oximetry in cells and tissues using a nitroxide-liposome system

In order to avoid the complication of reduction of nitroxides in biological media during oxygen measurements, liposomes containing a water-soluble nitroxide, 2,2,6,6-tetramethyl-piperidine-N-oxyl-4-trimethylammonium (Cat1), were used in studies of oxygen consumption by thymus-bone-marrow cells. The superhyperfine structure of Cat1 contained in liposomes was found to be sensitive to oxygen concentration in a fashion similar to that of free Cat1. Measurements of cellular respiration using Cat1 contained in liposomes agreed well with the results obtained using free Cat1. Using this nitroxide-liposome system, the respiration of liver slices was measured successfully, whereas such measurements using free cat1 were complicated by rapid reduction of the nitroxide. This nitroxide-liposome system also could be used in conjunction with a membrane permeable nitroxide and an extracellular broadening agent to measure intracellular and extracellular oxygen concentrations simultaneously.     

Cellular metabolism of proxyl nitroxides and hydroxylamines

Previous data from model systems indicated that the proxyl nitroxides should be especially resistant to bioreduction and therefore could be an effective solution to this often problematic characteristic of nitroxides. Therefore, we investigated the rate of reduction by cells and by the usual model system, ascorbate, of four proxyl nitroxides and three reference nitroxides. We found that, while the rate of reduction by ascorbate of the proxyl nitroxides was slower than the rate of a prototypic pyrrolidine nitroxide (PCA), the reverse was true for reduction by cells. We also studied the rate of oxidation of the corresponding hydroxylamines. The rate of oxidation by cells of the proxyl hydroxylamines was relatively fast, especially for the most lipophilic derivative. These results indicate that: (i) proxyl nitroxides may not be unusually resistant to bioreduction by functional biological systems; (ii) accurate knowledge of relative rates of metabolism of nitroxides and hydroxylamines in cells and tissues will require direct studies in these systems because the rates may not closely parallel those observed in model (chemical) systems; and (iii) proxyl nitroxides show potential value as agents to measure oxygen concentrations by the rates of oxidation of their corresponding hydroxylamines.     

Kinetics of superoxide-induced exchange among nitroxide antioxidants and their oxidized and reduced forms.

Nitroxide stable radicals generally serve for probing molecular motion in membranes and whole cells, transmembrane potential, intracellular oxygen and pH, and are tested as contrast agents for magnetic resonance imaging. Recently nitroxides were found to protect against oxidative stress. Unlike most low molecular weight antioxidants (LMWA) which are depleted while attenuating oxidative damage, nitroxides can be recycled. In many cases the antioxidative activity of nitroxides is associated with switching between their oxidized and reduced forms. In the present work, superoxide radicals were generated either radiolytically or enzymatically using hypoxanthine/xanthine oxidase. Electron paramagnetic resonance (EPR) spectrometry was used to follow the exchange between the nitroxide radical and its reduced form; whereas, pulse radiolysis was employed to study the kinetics of hydroxylamine oxidation. The results indicate that: a) The rate constant of superoxide reaction with cyclic hydroxylamines is pH-independent and is lower by several orders of magnitude than the rate constant of superoxide reaction with nitroxides; b) The oxidation of hydroxylamine by superoxide is primarily responsible for the non-enzymatic recycling of nitroxides; c) The rate of nitroxides restoration decreases as the pH decreases because nitroxides remove superoxide more efficiently than is hydroxylamine oxidation; d) The hydroxylamine reaction with oxidized nitroxide (comproportionation) might participate in the exchange among the three oxidation states of nitroxide. However, simulation of the time-dependence and pH-dependence of the exchange suggests that such a comproportionation is too slow to affect the rate of non-enzymatic nitroxide restoration. We conclude that the protective activity of nitroxides in vitro can be distinguished from that of common LMWA due to hydroxylamine oxidation by superoxide, which allows nitroxide recycling and enables its catalytic activity.     

Nitroxides inhibit peroxyl radical-mediated DNA scission and enzyme inactivation

Nitroxides are cell-permeable stable radicals that protect biomolecules from oxidative damage in several ways. The mechanisms of protection studied to date include removal of superoxide radicals as SOD-mimics, oxidation of transition metal ions to preempt the Fenton reaction, and scavenging carbon-centered radicals. However, there is no agreement regarding the reaction of piperidine nitroxides with peroxyl radicals. The question of whether they can protect by scavenging peroxyl radicals is important because these radicals are formed in the presence of oxygen abundant in biological tissues. To further our understanding of the antioxidative behavior of piperidine nitroxides, we studied their effect on biochemical systems exposed to the water soluble radical initiator 2,2'-azobis (2-amidinopropane) hydrochloride (AAPH). AAPH thermally decomposes to yield tert-amidinopropane radicals (t-AP(*)) that readily react with oxygen to form peroxyl radicals (t-APOO(*)). It has recently been reported that piperidine nitroxides protect plasmid DNA from t-AP(*) though not from t-APOO(*). The present study was directed at the question of whether these nitroxides can protect biological systems from damage inflicted by peroxyl radicals. The reaction of nitroxides with AAPH-derived radicals was followed by cyclic voltammetry and electron paramagnetic resonance spectroscopy, whereas the accumulation of peroxide was iodometrically assayed. Assaying DNA damage in vitro, we demonstrate that piperidine nitroxides protect from both t-AP(*) and t-APOO(*). Similarly, nitroxides inhibit AAPH-induced enzyme inactivation. The results indicate that piperidine nitroxides protect the target molecule by reacting with and detoxifying peroxyl radicals.     

Pro-oxidative activity of nitroxides in their reactions with glutathione

Nitroxides are unreactive towards glutathione in vitro. Interaction of nitroxides with peroxynitrite does not lead to a significant loss of their electron paramagnetic resonance (EPR) signal. However, addition of peroxynitrite to a solution containing glutathione and nitroxides induces an irreversible disappearance of EPR signal of nitroxides and augmentation of glutathione oxidation which is a pro-oxidant effect of these compounds. Nitroxide loss leading to the formation of amine derivatives is initiated by products of glutathione oxidation by peroxynitrite. The pro-oxidant action of nitroxides at micromolar concentrations may be important in view of the proposed use of these compounds as antioxidants.     

Simultaneous measurements of the intra- and extra-cellular oxygen concentration in viable cells.

An EPR method that can measure the intra- and extra-cellular oxygen concentration [O2] simultaneously in vitro has been developed using specially designed nitroxides. In the presence of Fe(CN)6(3-) in the medium, intracellular [O2] is measured by a neutral 15N-nitroxide and extracellular [O2] is measured by a negatively charged 14N-nitroxide, since charged species do not enter cells and the EPR spectrum of a 15N-nitroxide does not overlap with that of a 14N-nitroxide. The method is based in part on the minimal broadening of negatively charged nitroxides by Fe(CN)6(3-) and the very effective broadening of neutral nitroxides by the same paramagnetic ions. Results with this method confirm the existence of gradients in [O2] between the extracellular and intracellular compartments in CHO cells and M5076 tumor cells, even without stimulation of cellular respiration by CCCP. The nature of the barrier that needs to be involved to account for the experimental results raises some significant questions.     

Nitroxide metabolism in the human keratinocyte cell line HaCaT

Metabolism of different nitroxides with piperidine structure used as spin labels in electron spin resonance (ESR) studies in vitro and in vivo was investigated in human keratinocytes of the cell line HaCaT by GC and GC-MS technique combined with S-band ESR. Besides the well known reduction of the nitroxyl radicals to the ESR silent hydroxylamines as primary products our results indicate the formation of the corresponding secondary amines. These reductions are inhibited by the thiol blocking agent N-ethylmaleimide and by the strong inhibitors of the thioredoxin reductase (TR) 2-chloro-2,4-nitrobenzene and 2,6-dichloroindophenol. The competitive inhibitor TR inhibitor azelaic acid and the cytochrome P-450 inhibitor metyrapone lack any effects. The rates of reduction to the hydroxylamines and secondary amines were dependent on the lipid solubility of the nitroxides. Therefore, it can be assumed that the nitroxides must enter the cells for their bioreduction. The mostly discussed intracellular nitroxide reducing substances ascorbic acid and glutathione were unable to form the secondary amines. In conclusion, our results suggest that the secondary amine represents one of the major metabolites of nitroxides besides the hydroxylamine inside keratinocytes formed via the flavoenzyme thioredoxin reductase most probably. Further metabolic conversions were detected with 4-oxo-2,2,6,6-tetramethylpiperidine-1-oxyl and the benzoate of 4-hydroxy-2,2,6,6-tetramethylpiperidine-1-oxyl as substrates.     

Metabolism of nitroxide spin labels in subcellular fraction of rat liver. I. Reduction by microsomes

As part of an ongoing study of the role of subcellular fractions on the metabolism of nitroxides, we studied the metabolism of a set of seven nitroxides in microsomes obtained from rat liver. The nitroxides were chosen to provide information on the effects of the type of charge, lipophilicity and the ring on which the nitroxide group is located. Important variables that were studied included adding NADH, adding NADPH, induction of enzymes by intake of phenobarbital and the effects of oxygen. Reduction to nonparamagnetic derivatives and oxidation back to paramagnetic derivatives were measured by electron-spin resonance spectroscopy. In general, the relative rates of reduction of nitroxides were similar to those observed with intact cells, but the effects of the various variables that were studied often differed from those observed in intact cells. The rates of reduction were very slow in the absence of added NADH or NADPH. The relative effect of these two nucleotides changed when animals were fed phenobarbital, and paralleled the levels of NADPH cytochrome c reductase, cytochrome P-450, cytochrome b5 and NADH cytochrome c reductase; results with purified NADPH-cytochrome c reductase were consistent with these results. In microsomes from uninduced animals the rate of reduction was about 10-fold higher in the absence of oxygen. The products of reduction of nitroxides by microsomes were the corresponding hydroxylamines. We conclude that there are significant NADH- and NADPH-dependent paths for reduction of nitroxides by hepatic microsomes, probably involving cytochrome c reductases and not directly involving cytochrome P-450. From this, and from parallel studies now in progress in our laboratory, it seems likely that metabolism by microsomes is an important site of reduction of nitroxides. However, mitochondrial metabolism seems to play an even more important role in intact cells.     

Metabolism of aqueous soluble nitroxides in hepatocytes: effects of cell integrity, oxygen, and structure of nitroxides

The optimum use of nitroxides in viable biological systems, including live animals, requires knowledge of the metabolism of nitroxides by major organ systems, especially the liver. We report here details of the metabolism of several prototypic aqueous soluble nitroxides in suspensions of freshly isolated hepatocytes. The general patterns of metabolism were similar to those observed in other types of cells (previous studies have been done principally in cells from tissue culture, such as CHO cells) including the primary initial reaction being reduction to the hydroxylamine, an increased rate of metabolism of some nitroxides in hypoxic cells, faster rates of reduction of nitroxides on six-membered piperidine rings compared to five-membered pyrrolidine rings, and most metabolism being intracellular. Metabolism in hepatocytes differed from other cell lines in having (1) significant reduction in the extracellular medium due to ascorbate that was released from damaged hepatocytes; (2) decreased rates of metabolism in freeze-thawed cells due to damage to subcellular organelles. These results provide much of the data needed to understand the role of the liver in the metabolism of nitroxides by intact animals and explain some previously puzzling results which indicated an apparent unusually high rate of metabolism of a charged nitroxide (Cat1) by hepatocytes. Our results also indicate that the use of freshly isolated cells or tissue homogenates may introduce experimental artifacts in the study of the metabolism of nitroxides.     

Cyto- and genotoxic effects of novel aromatic nitroxide radicals in vitro

Because of the increasing interest in the use of nitroxide radicals as antioxidants and probes for various applications in biological systems, the question of their toxicity is of paramount importance. Cytotoxicity and mutagenicity studies have been extensively performed with the commercially available aliphatic nitroxides, and the general outcome is that these compounds are nonmutagenic and relatively noncytotoxic. In this study, the cytotoxicity and genotoxicity of a new class of aromatic nitroxides that we have synthesized (i.e., indolinonic and quinolinic nitroxides), whose antioxidant activity has been established in both chemical and biological systems, were evaluated and compared with those of two commercial nitroxides and with that of butylated hydroxytoluene (BHT). The mutagenicity assay was performed using Salmonella typhimurium tester strains TA98, TA100, and TA102, chosen on the basis of their ability to detect various types of mutations and their sensitivity to oxidative damage. None of the compounds tested were found to be mutagenic. The colony-forming assay (CFA) using Chinese hamster ovary (CHO) AS52 cells was employed for determining the cytotoxicity of the test compounds. On comparing the effective dose that inhibits the CFA by 50% (IC(50)), most of the compounds tested on an equal molar concentration basis were less toxic than BHT. Therefore, the overall results obtained correlate well with the data reported in the literature on the toxicity of aliphatic nitroxides and lend support to the possible use of these compounds as therapeutic antioxidants.     

Measurements in vivo of parameters pertinent to ROS/RNS using EPR spectroscopy

The technique of in vivo EPR spectroscopy can provide useful and even unique information pertinent to the study of oxygen/ nitrogen radicals and related processes. The parameters that can be measured include: (a) Oxygen centered radicals (by spin trapping); (b) carbon centered radicals (by spin trapping and sometimes by direct observation); (c) sulfur centered radicals (by spin trapping and sometimes by direct observation); (d) nitric oxide (by spin trapping); (e) oxygen (using oxygen sensitive paramagnetic materials); (f) redox state (using metabolism of nitroxides); (g) thiol groups (using special nitroxides); (h) pH (using special nitroxides); (h) perfusion (using washout of paramagnetic tracers); (i) some redox active metal ions (chromium, manganese). The current state of the art for these and other measurements is discussed, especially in relationship to experiments that are likely to be useful for studies of reactive oxygen species (ROS) and/or reactive nitrogen species (RNS).     

Differential protection by nitroxides and hydroxylamines to radiation-induced and metal ion-catalyzed oxidative damage

Modulation of radiation- and metal ion-catalyzed oxidative-induced damage using plasmid DNA, genomic DNA, and cell survival, by three nitroxides and their corresponding hydroxylamines, were examined. The antioxidant property of each compound was independently determined by reacting supercoiled DNA with copper II/1,10-phenanthroline complex fueled by the products of hypoxanthine/xanthine oxidase (HX/XO) and noting the protective effect as assessed by agarose gel electrophoresis. The nitroxides and their corresponding hydroxylamines protected approximately to the same degree (33-47% relaxed form) when compared to 76.7% relaxed form in the absence of protectors. Likewise, protection by both the nitroxide and corresponding hydroxylamine were observed for Chinese hamster V79 cells exposed to hydrogen peroxide. In contrast, when plasmid DNA damage was induced by ionizing radiation (100 Gy), only nitroxides (10 mM) provide protection (32.4-38.5% relaxed form) when compared to radiation alone or in the presence of hydroxylamines (10 mM) (79.8% relaxed form). Nitroxide protection was concentration dependent. Radiation cell survival studies and DNA double-strand break (DBS) assessment (pulse field electrophoresis) showed that only the nitroxide protected or prevented damage, respectively. Collectively, the results show that nitroxides and hydroxylamines protect equally against the damage mediated by oxidants generated by the metal ion-catalyzed Haber-Weiss reaction, but only nitroxides protect against radiation damage, suggesting that nitroxides may more readily react with intermediate radical species produced by radiation than hydroxylamines.     

Metabolism of nitroxide spin labels in subcellular fraction of rat liver: I. Reduction by microsomes

As part of an ongoing study of the role of subcellular fractions on the metabolism of nitroxides, we studied the metabolism of a set of seven nitroxides in microsomes obtained from rat liver. The nitroxides were chosen to provide information on the effects of the type of charge, lipophilicity and the ring on which the nitroxide group is locted Important variables that were studied included adding NADH, adding, induction of enzymed by intake of phenobarbital and the effects of oxygen. Reduction of nonparamagnetic derivatives and oxidation to paramagnetic derivatives were measured by electron-spin resonance spectroscopy. In general, the relative rates of reduction of nitroxides were similar to those observed with intact cells, but the effects of the various variables that were studied often differed from those observed in intact cells. The rates of reduction were very slow in the absence of added NADh or NADPH. The relative effect of these two nucleotides changed when animals were fed phenobarbital and paralleled the levels of NADPH cytochrome c reductase, cytochrome P-450, cytochrome b₅ and NADH cytochrome c reductase; results with purified NADPH-cytochrome c reductase were consistent with these results. In microsomes from uninduced animals the rate of reduction was about 10-fold higher in the absence of oxygen. The products of reduction of nitroxides by microsomes were the corresponding hydroxylmines. We conclude that there are significant NADH- and NADPH-dependent paths for reduction of nitroxides by hepatic microsomes, probably involving cytochrome c reductases and not directly involving cytochrome P-450. From this, and from parallel studies now in progress in our laboratory, it seems likely that metabolism by microsomes is an important site of reduction of nitroxides. However, mitochondrial metabolism seems to play an even more important role in intact cells.     

In vivo measurement of oxygen concentration using sonochemically synthesized microspheres.

Proteinaceous microspheres filled with nitroxides dissolved in an organic liquid have been synthesized for the first time using high intensity ultrasound; these were used to measure oxygen concentrations in living biological systems. The microspheres have an average size of 2.5 microns, and the proteinaceous shell is permeable to oxygen. Encapsulation of the nitroxides into the microsphere greatly increased the sensitivity of the electron paramagnetic resonance signal line width to oxygen because of the higher solubility of oxygen in organic solvents. The encapsulation also protected the nitroxide from bioreduction. No decrease in intensity of the electron paramagnetic resonance signal was observed during 70 min after intravenous injection of the microspheres into a mouse. Measurement of the changes in oxygen concentration in vivo by means of restriction of blood flow, anesthesia, and change of oxygen content in the respired gas were made using these microspheres.     

Ascorbate- and dehydroascorbic acid-mediated reduction of free radicals in the human erythrocyte

Nitroxides were used as models of persistent free radicals to study the antioxidant function of ascorbic acid in the human erythrocyte. It was concluded that: 1) ascorbate and other reductant(s) derived from dehydroascorbic acid (DHA) in the presence of thiols are the only significant reducing agents for nitroxides, 2) glutathione and DHA reduce nitroxides by a process that cannot be inhibited by ascorbic acid oxidase, 3) erythrocytes can be depleted of ascorbic acid by exhaustive washing in the presence of membrane-permeable cationic nitroxides such as N,N-dimethylamino-Tempo, 4) ascorbate-depleted cells do not reduce nitroxides; however, nitroxide reduction is restored when the cells are incubated with DHA, 5) reduction of nitroxides in ascorbate-depleted, DHA-treated cells is significantly faster than in buffered solutions of DHA and glutathione, 6) several equivalents of nitroxide are reduced relative to the intracellular ascorbate pool, 7) sustained nitroxide reduction is observed even when most of the intracellular ascorbate is oxidized, 8) spin trapping of oxyradicals in tert-butyl hydroperoxide-treated cells is accelerated with ascorbate depletion and inhibited with ascorbate loading, 9) ascorbate can be quantified within intact cells by analyzing the initial reduction rates of membrane-permeable cationic nitroxides, and 10) DHA-stimulated reduction of cationic nitroxides is slower and less extensive in erythrocytes deficient in glucose-6-phosphate dehydrogenase than in normal erythrocytes.     

Measurements in vivo of parameters pertinent to ROS/RNS using EPR spectroscopy

The technique of in vivo EPR spectroscopy can provide useful and even unique information pertinent to the study of oxygen/nitrogen radicals and related processes. The parameters that can be measured include: (a) Oxygen centered radicals (by spin trapping); (b) carbon centered radicals (by spin trapping and sometimes by direct observation); (c) sulfur centered radicals (by spin trapping and sometimes by direct observation); (d) nitric oxide (by spin trapping); (e) oxygen (using oxygen sensitive paramagnetic materials); (f) redox state (using metabolism of nitroxides); (g) thiol groups (using special nitroxides); (h) pH (using special nitroxides); (h) perfusion (using washout of paramagnetic tracers); (i) some redox active metal ions (chromium, manganese). The current state of the art for these and other measurements is discussed, especially in relationship to experiments that are likely to be useful for studies of reactive oxygen species (ROS) and/or reactive nitrogen species (RNS).