In vivo and in vitro EPR oximetry with fusinite: a new coal-derived, particulate EPR probe

Quantitative measurement of superoxide generation and oxygen consumption from leukocytes using electron paramagnetic resonance spectroscopy

In view of the important role of superoxide in cellular injury, there has been a great need for methods suitable for quantitation of superoxide production from cells. Previous methods have had limited sensitivity or specificity as well as problems with side reactions in cellular systems. Recently, we have shown that the new spin trap 5-(diethoxyphosphoryl)-5-methyl-1-pyrroline-N-oxide has ideal properties for quantitative superoxide measurement in chemical/biochemical systems; however, its suitability and potential for measurements in cellular systems has not been determined. Therefore, we evaluated the use of DEPMPO for quantitative measurement of superoxide formed by polymorphonuclear leukocytes. After activation of these cells with the phorbol ester (PMA, 200 ng/ml) or opsonized zymosan (1 mg/ml) at 24 degrees C a strong signal of the superoxide adduct, DEPMPO-OOH, was observed. This technique was highly sensitive and enabled measurement of superoxide generation from as few as 2 x 10(3) cells. The kinetics of adduct formation and decay were measured which enabled quantitation of superoxide formation. Spin label electron paramagnetic resonance (EPR) oximetry was used to measure the oxygen consumption from these cells. With PMA activation rapid onset of superoxide generation occurred with a rate of 0.78 nmol/min/10(6) cells while with zymosan a slower gradual onset of activation was seen to a peak rate of 0.061 nmol/min/10(6) cells. With both stimulators the ratios of superoxide production to oxygen consumption were similar with values of approximately 50% obtained. Thus, EPR spin trapping with DEPMPO together with EPR oximetry methods can be used to provide sensitive and specific quantitation of cellular superoxide generation and oxygen consumption. These methods provide a promising new approach for the measurement of oxygen reduction and superoxide generation in cellular systems.

Gloxy: an oxygen-sensitive coal for accurate measurement of low oxygen tensions in biological systems

This paper describes the characteristics of a new oxygen sensitive, paramagnetic material that has some significant advantages for measurements of tissue pO2 by in vivo EPR. This paramagnetic component of Welsh coal, termed "gloxy" was found to have valuable EPR features that allow accurate measurement of low oxygen tensions in vivo; these include large oxygen-dependent changes in linewidth, a high number of paramagnetic spin centers (resulting in high signal amplitude), and stability in tissue allowing repeated pO2 measurements to be made in vivo with high precision. Renal pO2 was measured deep in the medulla region of isolated perfused kidneys and found to be lower than that in the cortex (1.7 +/- 0.05 and 7.1 +/- 0.3 mm Hg, respectively). The quality of the EPR signal obtained from the renal outer medulla and also from tumors in mice was such that the pO2 measurements were obtained with a precision of +/-3% of the measured pO2 (Kidney: 1.7 +/- 0.05 mmHg; Tumor: 1.37 +/- 0.04 mmHg). In vitro tests on the viability of cells and in vivo studies using Gloxy demonstrate the stability and inertness of this oxygen-sensitive material.

Quantitative measurement of superoxide generation using the spin trap 5-(diethoxyphosphoryl)-5-methyl-1-pyrroline-N-oxide

Measurement and quantitation of superoxide by electron paramagnetic resonance (EPR) using the spin trap 5,5-dimethyl-1-pyrroline-N-oxide (DMPO) have been limited by the short half-life of the superoxide adduct DMPO-OOH (approximately 50 s at pH 7). Recently a beta-phosphorylated nitrone, 5-(diethoxyphosphoryl)-5-methyl-1-pyrroline-N-oxide (DEPMPO), was developed and reported to form a more stable superoxide adduct with a half-life of approximately 15 min. We evaluated the use of DEPMPO for quantitative measurement of superoxide in chemical and biochemical systems. To estimate the efficiency of trapping, EPR oximetry was used to measure oxygen consumption and the intensity of the DEPMPO-OOH signal to measure superoxide generation and adduct decay. With the superoxide-generating systems, riboflavin/light and xanthine/xanthine oxidase, DEPMPO trapped approximately 65% of the superoxide produced. The efficiency of superoxide trapping by DEPMPO was compared to the commonly used cytochrome c reduction method. When superoxide production was > 20 microM, cytochrome c detected approximately 100% of the superoxide produced, while DEPMPO trapped 60 to 70%. However, EPR detection with DEPMPO was 40-fold more sensitive than cytochrome c. Thus, DEPMPO is an efficient spin trap which enables specific and sensitive detection and quantitation of superoxide generation.

Histological assessment of rodent CNS tissues to EPR oximetry probe material

The effects of the paramagnetic oxygen sensing material, lithium phthalocyanine (LiPc) and fusinite were assessed in the brain of Mongolian gerbils and the spinal columns of rats respectively, to determine if there are histologically discernible changes in the tissue surrounding the probe material. This information is essential for the evaluation of the role of EPR oximetry in the measurements of pO2 in the CNS; the technique has great potential value for such measurements because it reports on the pO2 accurately and sensitively and, after the initial placement, measurements can be made repeatedly without invasive procedures or anesthesia. Histologic assessments demonstrated the inert nature of both the fusinite and LiPc EPR probes in rodent CNS tissue over relatively long (2 month) time periods. The fusinite suspensions and LiPc crystals (size range of approximately 100-200 microns) remained well localized to the point of injection and created mild acute tissue reaction on implantation (which appeared to resolve quickly) and virtually no tissue reaction at later times. The majority of the implanted fusinite and LiPc material was present extracellularly in the brain and spinal cord. MRI provided an accurate, noninvasive assessment of probe placement and was able to investigate pathologic effects (hemorrhage, edema, necrosis) associated with the probe placement and treatment effects.

In vivo EPR: an effective new tool for studying pathophysiology, physiology and pharmacology

The development of spectrometers working at lower frequencies with improved resonators now permits the routine use of non-invasive EPR spectroscopy in vivo. The capabilities of EPR spectra to reflect environmental conditions, combined with the use of paramagnetic materials as selective non-toxic labels, has led to increasingly widespread and productive applications of the technique to complex problems involving physiology, pharmacology and pathophysiology. Some of the especially promising applications in which EPR techniques uniquely appear to provide valuable information are illustrated, including the measurement of oxygen and oxygen gradients, monitoring of the metabolism of xenobiotics, monitoring pharmacokinetics of drugs, measurement of perfusion, measurement of pH, recognition and labeling of receptors, and characterization of drug releasing systems.

Development of biocompatible implants of fusinite for in vivo EPR oximetry

The development of oxygen-sensitive paramagnetic materials is being actively pursued because of their potential applications for in vivo electron paramagnetic resonance (EPR) oximetry. Among these materials, fusinite is of particular interest because of the high sensitivity of the EPR linewidth to the partial pressure pO2. Although this material has led to a number of very useful results in experimental systems, its potential use in humans is limited by the need to prove that it will not cause deleterious effects. The strategy used in this study to optimize the biocompatibility of the oxygen-sensitive materials was to prepare small silicon implants containing the fusinite. The use of silicon permits the diffusion of oxygen inside the implant while the material does not have contact with the biological environment. Radiosterilization did not affect the pO2 sensitivity of the material. The feasibility of performing pO2 measurement was verified in vivo by periodically inducing ischemia in the gastrocnemius muscle of mice over a period of 6 weeks.

The oxidizing agent menadione induces an increase in the intracellular molecular oxygen concentration in K562 and A431 cells: direct measurement using the new paramagnetic EPR probe fusinite

The intracellular molecular oxygen concentration in control and menadione-treated K562 (an erythroleukemic cell line that grows in suspension) and A431 (an epidermal carcinoma that grows in monolayer) cells was measured directly by using the new electron paramagnetic resonance (EPR) probe fusinite. Because the oxidizing agent menadione is known to damage mitochondria and the cytoplasmic membrane in other cell systems, before conducting measurements of oxygen concentration in K562 and A431 cells, it was necessary to establish injury in these systems as well. Consequently, morphological and flow cytometric analyses were conducted after menadione treatment. The data presented here show that the two cell lines are heavily damaged by menadione. Once this menadione-induced injury was demonstrated, measurements of oxygen concentration were carried out in both K562 and A431 cells. Treatment with this quinone induces a sharp increase in intracytoplasmic molecular oxygen in both cell lines (from about 1% to about 10 and 15% in K562 and A431 cells, respectively). In addition, to gain a more complete understanding of the effects of menadione on cells, the extracellular molecular oxygen concentration and the oxygen consumption rate were also measured in control and menadione-treated K562 cells. These measurements demonstrate that menadione treatment results in an increase in the extracellular oxygen concentration (from about 5% in controls to 15% in treated cells) as well as a decrease in the oxygen consumption rate (from about 10 ng O/min/10(6) cells in controls to 3 ng O/min/10(6) cells after menadione exposure). The importance of the new EPR probe fusinite in monitoring directly cellular functions in which oxygen is involved and the effects of menadione on cellular oxygen balance are discussed.

The apparent diffusion constant measured by MRI correlates with pO2 in a RIF-1 tumor

As tissue oxygen tension (pO2) is an important variable in cancer therapy, it would be of major clinical benefit to be able to measure pO2 noninvasively. Current methods for determining pO2 in clinical settings are limited to superficial tumors. The authors measured the apparent diffusion constant (ADC) in an implanted murine fibrosarcoma (RIF-1) using magnetic resonance imaging and correlated the ADC with tissue pO2 measured by electron paramagnetic resonance oximetry. The ADC correlates significantly with tissue pO2 in this tumor (r = 0.89; n = 14) and so may provide a noninvasive index of pO2 in tumors.

Assessment of cerebral pO2 by EPR oximetry in rodents: effects of anesthesia, ischemia, and breathing gas

This report describes experiments designed to assess and illustrate the effectiveness of a new method for the measurement of cerebral interstitial pO2 in conscious rodents. It is based on the use of low frequency electron paramagnetic resonance (EPR) spectroscopy with lithium phthalocyanine as the oxygen sensitive probe. Magnetic resonance imaging was used to document placement of the probe in the brain, and to assess potential cerebral changes associated with the placement. The technique provided accurate and reproducible measurements of localized pO2 in the brains of conscious rodents under a variety of physiological conditions and for time periods of at least 2 weeks. Using this approach we quantitated the depressing effects on cerebral pO2 of three representative anesthetics, isoflurane, ketamine/xylazine, and sodium pentobarbital. The effects of changing the content of oxygen in the breathing gas was investigated and found to change the cerebral pO2. In experiments with gerbils, crystals of lithium phthalocyanine were implanted in each side of the brain and using a one-dimensional magnetic field gradient, simultaneous measurement of pO2 values from normal and ischemic (ischemia induced by unilateral ligation of a carotid artery) hemispheres of the brain were obtained. These results demonstrate that EPR oximetry with lithium phthalocyanine is a versatile and useful method in the measurement of cerebral pO2 under various physiological and pathophysiological conditions.

Accuracy of oxygen measurements in T2 (line width) EPR oximetry

EPR oximetry is used for in vivo and in vitro measurements of oxygen in biological systems, including experimental animals. The accuracy of oxygen measurements in T2 (line width) EPR oximetry is significantly improved if least-squares simulation is used to extract the line width parameters. The oxygen effect on the EPR spectra of nitroxide solutions and aqueous suspensions of fusinite can be described as an additional homogeneous broadening that modifies the EPR spectrum of the oxygen-free probe. This allows one to use a one-parameter line width model in most cases. The simulations were carried out with the use of a fast-convolution algorithm followed by Levenberg-Marquardt optimization. The validity of error estimates provided by this method was tested on sets of experimental spectra taken under common conditions. It is shown that the accuracy of oxygen measurements in line width (T2) oximetry is determined not only by the probe sensitivity (rate of line width change versus oxygen concentration), but also by the signal-to-noise ratio, inhomogeneous contribution to the line shape (e.g., unresolved proton superhyperfine structure), and the spectral window. The accuracy of oxygen measurements is compared for aqueous solutions of two nitroxide radicals with different superhyperfine structure and for aqueous suspensions of fusinite.

Direct measurement of the accumulation and mitochondrial conversion of nitric oxide within Chinese hamster ovary cells using an intracellular electron paramagnetic resonance technique

We have developed an electron paramagnetic resonance (EPR) method for the nondestructive detection and quantification of intracellular NO in real time. Based upon this technique, we have obtained evidence for the metabolism of this bioregulatory molecule by mitochondria. Line-broadening of the EPR signal of a coal derivative, fusinite, was calibrated as a function of NO concentration in aqueous solution. The methodology was validated using two compounds which release NO in a controlled and predictable manner with first-order rate constants k1 = 5.0 x 0.10(-3) s-1 and k'1 = 3.4 x 10(-4) s-1 (35 degrees C). Fusinite was internalized in Chinese hamster ovary cells (CHO) by phagocytosis, after which the cells were allowed to consume the available O2, producing an hypoxic environment. The NO released from one of the NO donors, added to the culture fluid at an initial concentration of 50 microM, was directly measured in the intracellular environment as line-broadening of the fusinite EPR signal. The linewidth diminished with time, indicating that NO was being converted to a non-paramagnetic species by the cells with an apparent zero-order rate constant of 5 x 10(8) NO molecules cell-1 min-1 (20 degrees C). Addition of cyanide to the culture medium (5 mM final concentration) inhibited this disappearance of NO. NO also was converted in the presence of isolated mitochondria in the absence of oxygen. These observations suggest that under hypoxic conditions, there exists in CHO cells a metabolic pathway for the conversion of NO to diamagnetic species, which involves interactions with mitochondria.

In vivo oximetry using EPR and India ink

Recent advances in electron paramagnetic resonance (EPR) oximetry have established the use of the particulate materials fusinite and lithium phthalocyanine (LiPc) as probes for measurement of oxygen tensions in tissues in vivo with a sensitivity and accuracy that is relevant for studying pathophysiological processes. India ink, another potentially very useful new probe for EPR oximetry, shares the critical properties of fusinite and LiPc and has the additional advantage of already having been widely used clinically with no apparent toxicity. The line width is particularly sensitive to changes in oxygen tension of less than 30 mmHg; in this range the line broadening/unit of pO2 is much greater than that of fusinite and LiPc. Over the range of biological conditions that can occur in vivo, the response of the EPR spectrum of India ink to pO2 is independent of pH, oxidants, reductants, and the nature of the medium. In this paper we describe the relevant properties of India ink and its use to measure pO2 in vivo in experimental animals and a human subject.

Fusinite as a specific probe for the determination of molecular oxygen concentration in cells

The feasibility of using EPR and the paramagnetic derivative of coal 'fusinite' to measure intracellular oxygen concentration in cultured cells in which this substance was internalized in the cytoplasm was examined. First, the possible cytotoxic effects of fusinite on cultured cells were ruled out by both morphological as well as by growth characteristics analyses. After construction of a calibration curve in which the EPR spectral linewidth of this substance was measured in response to known oxygen concentrations, the efficacy of using fusinite in the determination of intracellular oxygen concentration in cells was also tested by flowing different known oxygen gas mixtures outside cultured cells. The results indicate that fusinite is able of measuring the variations in cytoplasmic oxygen concentration that exist in response to the different gas mixtures. In addition, as an example of a possible use of fusinite, data are also presented demonstrating a decrease in cytoplasmic oxygen concentration during respiration in cells with a limited supply of oxygen. In fact, as the oxygen is consumed by the cells, the linewidth of fusinite narrows giving an intracellular oxygen concentration corresponding to zero. From the results obtained, fusinite appears to represent a new extremely precise biophysical cellular oxygen probe which may prove useful in the understanding of the complex interrelationships between oxygen and normal cell physiology and/or pathology.