Compartmental responses to acute osmotic stress in Leishmania major result in rapid loss of Na+ and Cl-.

The elemental composition of the cytoplasm, electron dense vacuoles, and heterochromatin and euchromatin regions of the nucleus of Leishmania major promastigotes was measured by electron probe X-ray microanalysis under iso-osmotic conditions (305 mOsM) and shortly after a sudden increase (to 615 mOsM) or decrease (to 153 mOsM) in the osmolality of the buffer in which they were suspended. In response to acute hypotonicity a complete loss of Na from the electron dense vacuoles and an approximately threefold decrease in the Na concentrations in the cytoplasm and the nuclear regions occurred, together with an approximately threefold decrease in Cl content in each compartment and a smaller (approx. 1.2-fold) decrease in K content. Thus, in addition to the rapid change in shape and release of amino acids known to occur in response to acute hypo-osmotic stress, a major efflux of Na and Cl, and, to a lesser extent, of K, also occurs. In response to acute hypertonicity Na in the acidocalcisomes did not change but Na content of the cytoplasm decreased by 33%. A small increase in the S content of the cytoplasm and the electron dense vacuolar compartments occurred. No changes were detectable in Ca or Zn content in any of the compartments examined in response to hypotonicity or hypertonicity.

Intermittent perfusion protects the brain during deep hypothermic circulatory arrest.

BACKGROUND: Deep hypothermic circulatory arrest (DHCA) has been shown to cause impairment in recovery of cerebral blood flow (CBF) and cerebral metabolism (CMRO2) proportional to the duration of the DHCA period. This effect on CMRO2 may be a marker for brain injury, because CMRO2 recovers normally after cardiopulmonary bypass (CPB) when DHCA is not used. The aim of this study was to investigate the effects of intermittent perfusion during DHCA on the recovery of CMRO2 after CPB and to correlate these findings with electron microscopy (EM) of the cerebral microcirculatory bed. METHODS: Fifteen neonatal piglets were placed on CPB and cooled to 18 degrees C. Each animal then underwent either: (1) 60 minute continuous CPB (control), (2) 60 minute uninterrupted DHCA (UI-DHCA), or (3) 60 minute DHCA with intermittent perfusion (1 minute every 15 minutes) (I-DHCA). All animals were then rewarmed and weaned from CPB. Measurements of CBF and CMRO2 were taken before and after CPB. A further 9 animals underwent CPB without DHCA (2 animals) or with DHCA (7 animals), under various conditions of arterial blood gas management, intermittent perfusion, and reperfusion time. RESULTS: UI-DHCA resulted in significant impairment to recovery of CMRO2 after CPB (p < 0.05). Regardless of the blood gas strategy used, the EM after UI-DHCA revealed extensive damage characterized by perivascular intracellular and organelle edema, and vascular collapse. I-DHCA, on the other hand, produced a pattern of normal CMRO2 recovery identical to controls, and the EM was normal for both these groups. CONCLUSIONS: Intermittent perfusion during DHCA is clinically practical and results in normal cerebral metabolic and ultrastructural recovery. Furthermore, the correlation between brain structure and CMRO2 suggests that monitoring CMRO2 during the operation may be an outstanding way to investigate new strategies for neuroprotection designed to reduce cerebral damage in children undergoing correction of congenital cardiac defects.

In vivo accumulation of iron on crocidolite is associated with decrements in oxidant generation by the fiber.

In vivo exposures to fibrous silicates are characterized by the formation of asbestos bodies. These structures consist of the original fiber with a coating of inexact composition, but it will include iron and protein. We tested the hypothesis that this iron, accumulated on asbestos bodies, participates in electron transport and oxidant generation. Thirty-day-old, male guinea pigs were intratracheally instilled with 1.0 mg crocidolite. Six months later, the animals were anesthetized, euthanized, and the fibers were isolated from the lungs. Energy-dispersive x-ray analysis and x-ray photoelectron spectroscopy confirmed an accumulation of metal onto the fiber after in vivo exposure. Stains for iron demonstrated a heterogeneous distribution of the metal on the silicate, while the uptake of a commercially available polyclonal antibody to ferritin localized to beaded enlargements along the coated fibers. Chelatable [Fe3+] associated with the fiber increased after in vivo exposure. However, oxidant generation by asbestos bodies was decreased relative to uncoated fibers despite the elevation in the concentration of metal associated with the crocidolite. We conclude that iron is accumulated onto fibers in the lungs of guinea pigs. Some portion of this accumulation of iron is in the form of ferritin, and this metal is not chemically reactive in oxidant production. Asbestos bodies may represent a successful attempt by the host to sequester the metal adsorbed to the surface of a fiber and diminish the oxidative challenge introduced by a fibrous silicate. Subsequently, the generation of free radicals by the fibrous silicate is diminished.

Elemental composition of Na pump inhibited rabbit aorta VSM cells by electron probe X-ray microanalysis.

The Na pump in vascular smooth muscle (VSM) is likely to influence not only intracellular Na content but also the content and distribution of other cations and anions measured by electron probe X-ray microanalysis (EPXMA). The hypothesis we tested was that EPXMA of pump-inhibited VSM would yield a characteristic cellular elemental profile, providing insight into the contribution of the Na pump to the intracellular milieu and an approach to identifying when VSM operates under the constraints of pump inhibition. We assessed the contractile state and elemental EPXMA profile of rabbit aorta that was either quiescent or contracted by serotonin (10(-6) M) or ouabain (10(-6) M). VSM cytoplasm showed the anticipated low Na (28 +/- 2 mM) and high K (182 +/- 5 mM) content. With ouabain, Na rose and K fell to reverse the Na-to-K ratio (0.15 +/- 0.01 vs. 6.6 +/- 0.3; P < 0.01). With serotonin, the ratio rose slightly (0.28 +/- 0.2; P < 0.05). Nuclei and mitochondria showed a similar pattern. CI showed a small increase (56 +/- 2 to 102 +/- 4 mM) with ouabain, a shift that could not be accounted for on the basis of charge redistribution to maintain neutrality because the change in Na and K were essentially offsetting. EPXMA measures total and not ionized Ca. If changes in cytoplasmic Ca occurred, they were too small to be measured by the imaging methods employed. The sustained, myogenic contractile response of VSM to Na pump inhibition shows a characteristic elemental profile that could prove useful in its identification. Direct measurement of membrane potential during the myogenic response to Na pump inhibition should have a high priority.

Calcium depletion and repletion in cultured chick heart muscle cells.

Calcium-free incubation followed by exposure to calcium damages naturally occurring cardiac muscle preparations irreversibly. Whether the observed calcium overload during calcium repletion is a primary cause for, or a secondary consequence of, sarcolemmal disruption and cell injury is controversial. We used cultured embryonic chicken heart muscle cells to correlate ionic, metabolic, and ultrastructural changes during calcium depletion (0Ca, 1 mM EGTA) and repletion. After 10 min of calcium depletion, intracellular Na increased four-fold above control levels, intracellular K decreased by 26%, total cell Ca decreased by 81%, and cytosolic ionized Ca concentration decreased by 87%. Within 10 min of subsequent calcium repletion, total cell Ca transiently increased to four-fold above control, cytosolic ionized Ca concentration transiently increased to twice control, and both Na and K returned toward control levels; by 3 h of calcium repletion, physiological cation (Na, K, Ca) contents were restored and adenine nucleotide contents were normal. Long-term (i.e. 120 min) calcium depletion did not significantly reduce cell ATP levels, but increased adenine nucleotide turnover as indicated by adenosine and lactate release; after 60 min of subsequent calcium repletion, ionic and metabolic parameters were returned to control levels. During calcium depletion (both short- and long-term) and subsequent repletion, no ultrastructural changes occurred. When Mg was also removed during calcium depletion, the ionic changes during depletion and subsequent repletion were enhanced. When 10 microM CCCP was present during calcium depletion and repletion, cytosolic ionized Ca concentration increased to six-fold above control with no increase in total cell Ca content, suggesting that the increased Ca is buffered, in part, by mitochondria. These results indicate that an increase in Ca per se, occurring when high energy phosphate levels and/or cellular Ca buffering capacity are maintained, does not seem to be associated with irreversible cell injury.

In situ cryofixation of kidney for electron probe X-ray microanalysis.

Cell physiological and pathophysiological studies often require information about the elemental composition of intracellular organelles in situ. Electron probe X-ray microanalysis (EPXMA) is one of the few methods by which intracellular elemental content and distribution can be measured simultaneously. While several cryofixation techniques for EPXMA have been utilized on isolated cells, few have been applied successfully to whole tissue in vivo or in situ. A recently developed, commercial, portable, metal-mirror device was used for preserving kidney in situ to determine the intracellular element distribution in proximal tubule cells. Kidneys of male rats were exposed, cryofixed, and analyzed for organelle elemental contents by EPXMA imaging. In addition, some portions of the frozen tissue were prepared for conventional transmission electron microscopy. Proximal tubules were preserved with intact brush borders and open lumens. The quality of preservation of tubule cell organelles varied inversely as a function of depth from the point of first contact with the mirror surface; the best preservation was within 15 microns, while the poorest preservation was deeper than 30 microns. Analysis of EPXMA images from the best-preserved regions revealed that proximal tubule cell cytoplasmic K/Na was approximately 6, cytoplasmic Cl was low relative to other subcellular compartments, and mitochondrial Ca levels were 1.8 nmole/mg dry weight; these observations indicate that the cells were physiologically viable at the time of cryofixation. The advantages of in situ cryofixation by this metal-mirror method include acquisition of organelle elemental content data in vivo, ease of use, reproducibility, portability, applicability to other tissues, and suitability for pathophysiological studies.

Mitochondrial localization and characterization of 99Tc-SESTAMIBI in heart cells by electron probe X-ray microanalysis and 99Tc-NMR spectroscopy.

As the development of targeted intracellular magnetic resonance contrast agents proceeds, techniques for the quantitative analysis of the subcellular compartmentation and characterization of metallopharmaceuticals must also advance. To this end, the subcellular distribution and chemical state of hexakis (2-methoxyisobutyl isonitrile) technetium-99 (99Tc-SESTAMIBI), the ground state of the organotechnetium radiopharmaceutical used for the noninvasive evaluation of myocardial perfusion and viability by scintigraphy, has been determined by a novel application of electron probe X-ray microanalysis (EPXMA) and 99Tc-NMR spectroscopy. In cryopreserved cultured chick heart cells equilibrated in 36 microM 99Tc-SESTAMIBI, EPXMA imaging of mitochondria yielded a respiratory uncoupler-sensitive characteristic 99Tc X-ray peak representing 32.0 +/- 2.9 nmoles Tc/mg dry weight, while EPXMA of cytoplasm or nucleus showed no peak significantly greater than the threshold detectability limit of approximately 1 nmole/mg dry weight. Technetium-99 NMR spectroscopy of heart cells equilibrated with 99Tc-SESTAMIBI showed a single peak at -45.5 ppm with no evidence of significant line broadening or chemical shift compared to aqueous chemical standards, indicating that the majority of the complex exists unbound within the mitochondrial matrix. These data quantitatively demonstrate the localization of this lipophilic cationic organometallic complex within mitochondria in situ, consistent with a sequestration mechanism dependent on membrane potentials. Furthermore, this study establishes the general feasibility of combined EPXMA and NMR spectroscopy for the direct subcellular localization and characterization of metallopharmaceuticals, techniques that are readily applicable to MR contrast agents.

Microprobe analysis of Tc-MIBI in heart cells: calculation of mitochondrial membrane potential.

Hexakis (2-methoxyisobutylisonitrile) technetium-99m (99mTc-MIBI) is a gamma-emitting radiopharmaceutical probe currently in clinical use to evaluate myocardial perfusion. Biochemical and cellular pharmacological studies have suggested that Tc-MIBI, a lipophilic cation, is sequestered in mitochondria in response to transmembrane potentials. To assess directly the subcellular distribution of the probe in heart tissue, cultured chick heart cells were analyzed by electron-probe X-ray microanalysis (EPXMA) following equilibration in micromolar concentrations of carrier-added 99Tc-MIBI, the ground-state radiopharmaceutical. Quantitation of the physiological elements Na, Ca, Mg, K, S, P, and Cl was correlated with exposure to increasing concentrations of 99Tc-MIBI. EPXMA signals indicated that 99Tc-MIBI was concentrated up to 1,000 times into mitochondria in a dose-dependent fashion based on measured Tc content in the mitochondria. Inner membrane potential (delta psi) of individual mitochondria was calculated as -117 mV using the Nernst equation. Concentrations of 99Tc-MIBI > 36 microM caused a significant efflux of K and Mg from the cell, as well as an increase in Cl in the mitochondria. Comparison of cell ultrastructure with conventional electron microscopy at extracellular 99Tc-MIBI concentrations of 36-72 microM showed no changes compared with control. 99Tc-MIBI allows valuable in situ investigation of cellular bioenergetics with EPXMA by quantitation of delta psi.

Quick-freezing of cultured cardiac cells in situ with special attention to the mitochondrial ultrastructure.

A new method has been developed which allows quick-freezing in situ of primary, cardiac cell cultures grown to confluence on gas-permeable membranes (Petriperm dishes). Small pieces of the growth substratum, with rhythmically beating myocardial cells, were slam-frozen, without cryoprotectants, against the surface of a helium-cooled copper block at approximately 16 K. The quality of the cellular cryopreservation, as judged by ultrastructural criteria, was studied in freeze-substituted specimens processed for transmission electron microscopy. The ultrastructure of cryofixed cardiac cells was compared with that of unfrozen, chemically fixed samples. The severity of cryodistortions increased progressively with increasing distance from the point of first impact. Of particular interest were the dramatic alterations of the mitochondrial ultrastructure. The concept that the reticular and the outer mitochondrial membranes are intimately and strongly associated was clearly demonstrated. Optimally frozen material revealed cryopreserved ultrastructure of high quality. The method described appears to offer an ideal model system for correlating the information gained by phase-contrast microscopy of living cell cultures with the ultrastructure of the same samples fixed in situ by chemical or physical techniques. Cryofixation would be particularly useful for studying dynamic cellular processes associated with physiological and pathophysiological conditions, e.g. metabolic inhibition, anoxia and substrate deprivation.

Real-time quantitative elemental analysis and mapping: microchemical imaging in cell physiology.

Recent advances in widely available microcomputers have made the acquisition and processing of digital quantitative X-ray maps of one to several cells readily feasible. Here we describe a system which uses a graphics-based microcomputer to acquire spectrally filtered X-ray elemental image maps that are fitted to standards, to display the image in real time, and to correct the post-acquisition image map with regard to specimen drift. Both high-resolution quantitative energy-dispersive X-ray images of freeze-dried cyrosections and low-dose quantitative bright-field images of frozen-hydrated sections can be acquired to obtain element and water content from the same intracellular regions. The software programs developed, together with the associated hardware, also allow static probe acquisition of data from selected cell regions with spectral processing and quantification performed on-line in real time. In addition, the unified design of the software program provides for off-line processing and analysing by several investigators at microcomputers remote from the microscope. The overall experimental strategy employs computer-aided imaging, combined with static probes, as an essential interactive tool of investigation for biological analysis. This type of microchemical microscopy facilitates studies in cell physiology and pathophysiology which focus on mechanisms of ionic (elemental) compartmentation, i.e. structure-function correlation at cellular and subcellular levels; it allows investigation of intracellular concentration gradients, of the heterogeneity of cell responses to stimuli, of certain fast physiological events in vivo at ultrastructural resolution, and of events occurring with low incidence or involving cell-to-cell interactions.

Elemental microanalysis of organelles in proximal tubules. I. Alterations in transport and metabolism.

Oxygen deprivation to the kidney causes a multifactorial series of morphological, physiological, and biochemical alterations that occur as a function of time. One of the earliest events involves significant changes in the cellular contents of the physiologically important elements (ions) Na and K. Controversy exists as to the nature of changes in the content of the regulatory ion Ca, in either its free or bound form, and much less is known regarding in situ distribution and amounts of other elements such as Mg, P, S, and Cl during physiological or pathophysiological states. The objective of these studies was to evaluate element compartmentation in proximal renal tubules by using quantitative electron probe x-ray microanalysis, during specific conditions which are at least partially manifested during oxygen deprivation. Cells from control proximal tubule suspensions were compared with those exposed to (1) ouabain, to inhibit (Na+, K+)-ATPase; (2) mitochondrial uncouplers, to rapidly deplete ATP content; or (3) calcium ionophores, to cause a rapid elevation in cytoplasmic free calcium. In parallel with electron probe x-ray microanalysis imaging of subcellular elemental content, total cell potassium and ATP contents, enzyme release, oxygen consumption, cytoplasmic free calcium levels, and ultrastructural alterations were assessed. Results indicated that ATP depletion was, in the short term, more deleterious to renal proximal tubules than any of the tested ionic alterations. Intracellular organelles including mitochondria and nuclei appeared to be readily permeable to Na, K, and Cl, altering their concentrations of these ions in parallel with cytoplasmic concentrations. Lysosomes exhibited evidence of Cl accumulation, consistent with an inwardly directed proton ATPase with accompanying Cl transport. Whereas in the cytoplasm Na, K and Cl appeared to be mostly free, a large fraction of these ions within intracellular organelles seemed bound.

Elemental microanalysis of organelles in proximal tubules. II. Effects of oxygen deprivation.

This communication describes the effects of anoxia on rabbit proximal renal tubule element (ion) content by using high-resolution electron probe x-ray microanalytical imaging to obtain quantitative elemental data from subcellular compartments not previously resolvable with low-resolution imaging. These organelles and regions include the heterochromatin and euchromatin of the nucleus and the microvilli of the apical brush border, in addition to mitochondria, lysosomes, and cytoplasm. Anoxia of 40-min duration caused the expected decrease in K and increase in Na and Cl concentrations in the tubules with the cytoplasmic K:Na ratio declining to 0.13:1. These changes were accompanied by decreases in ATP and total K contents, and an increase in lactate dehydrogenase release. Swelling occurred in some cells as evidenced by ultrastructural changes. No alterations were evident after oxygen deprivation in Ca content of cytoplasm (control, 6.7 +/- 0.6 versus anoxia, 7.6 +/- 0.7 nmol/mg dry wt) or mitochondria (control, 4.0 +/- 0.4 versus anoxia, 4.9 +/- 0.6 nmol/mg dry wt) or in S content of recognizable lysosomes (control, 314 +/- 11 versus anoxia, 325 +/- 12 nmol/mg dry wt). Brush border (microvillus) Ca content was higher than cytoplasmic Ca content during normoxia (10.7 +/- 0.9 nmol/mg dry wt) and increased further during anoxia (17.0 +/- 1.0 nmol of Ca/mg dry wt). The finding of higher Ca content within the brush border region during normoxia is unexpected and novel, because such results suggest that Ca homeostasis in the apical elaboration of the proximal cell may be different from that in the cytoplasm. The results also raise the possibility that an increase in Ca content in the brush border membrane region may be involved in the pathogenesis of renal cell injury.

Structural and elemental characterization of heart cells grown in a collagen matrix.

A novel preparation of spontaneously contracting heart cells embedded in a collagen strand provides an ideal experimental system for correlative structure-function experiments that utilize the techniques of electron microscopy, quantitative electron probe x-ray microanalysis (EPXMA) and imaging. Heart cells grown within the strand for 1 day possess the subcellular content and distribution of physiologically relevant elements--Na, Mg, P, S, Cl, K, and Ca--found in intact heart cell preparations. The presence of junctional specializations between, and organized myofibrils within, the majority of cells after 1 day in culture also establishes that the collagen matrix promotes vigorous cell development as well as maintains physiological integrity. EPXMA, combined with ultrastructural analyses, provides elemental content data on a cell-by-cell basis. In studies presented here, viable cells, comprising over 80% of the strand cell population, could be distinguished easily from those which had been functionally compromised, not only by aberrant structure but also by altered subcellular compartmentation of Na, K, Cl, and Ca. Within individual viable cells, compartmental differences in element content were notable especially between mitochondria and cytoplasm. However, nuclear euchromatin, but not heterochromatin, appeared approximately identical to cytoplasm in elemental and water content. In such cells, the cytoplasmic K:Na ratio was maintained at a high level (approximately 15:1). The results with respect to K, Na, and other elements demonstrated the integrity of membrane transport mechanisms regulating the movement and distribution of ions and the maintenance of ionic homeostasis in cells of the strand preparation.

Elemental composition of polyphosphate-containing vacuoles and cytoplasm of Leishmania major.

Leishmania major promastigotes contain electron-dense vacuoles. The elemental composition of these vacuoles and of the cytoplasm was measured by electron probe X-ray microanalysis, using rapid cryopreservation techniques to prevent alterations in composition due to diffusion. The electron-dense vacuoles are rich in P, presumably present as polyphosphate (poly P). Mg is present at about 9 times its cytoplasmic level. There is sufficient Mg to largely neutralize most of the negative charge of the Poly P. The electron-dense vacuoles also contain appreciable amounts of Ca and Zn, which are not detectable in the cytoplasm, as well as Na, K, and Cl, the latter two at concentrations below that of the cytoplasm. These results suggest that the vacuolar membranes have at least one cation transport system. Incubation of the promastigotes for 1 h in the absence of phosphate in the presence or absence of glucose did not cause significant changes in the vacuolar contents of P, Mg, or Zn, but changes in K and Cl content were observed in both the electron-dense vacuoles and in the cytoplasm.

Calcium measurements with electron probe X-ray and electron energy loss analysis.

This paper presents a broad survey of the rationale for electron probe X-ray microanalysis (EPXMA) and the various methods for obtaining qualitative and quantitative information on the distribution and amount of elements, particularly calcium, in cryopreserved cells and tissues. Essential in an introductory consideration of microanalysis in biological cryosections is the physical basis for the instrumentation, fundamentals of X-ray spectrometry, and various analytical modes such as static probing and X-ray imaging. Some common artifacts are beam damage and contamination. Inherent pitfalls of energy dispersive X-ray systems include Si escape peaks, doublets, background, and detector calibration shifts. Quantitative calcium analysis of thin cryosections is carried out in real time using a multiple least squares fitting program on filtered X-ray spectra and normalizing the calcium peak to a portion of the continuum. Recent work includes the development of an X-ray imaging system where quantitative data can be retrieved off-line. The minimum detectable concentration of calcium in biological cryosections is approximately 300 mumole kg dry weight with a spatial resolution of approximately 100 A. The application of electron energy loss (EELS) techniques to the detection of calcium offers the potential for greater sensitivity and spatial resolution in measurement and imaging. Determination of mass thickness with EELS can facilitate accurate calculation of wet weight concentrations from frozen hydrated and freeze-dried specimens. Calcium has multiple effects on cell metabolism, membrane transport and permeability and, thus, on overall cell physiology or pathophysiology. Cells can be rapidly frozen for EPXMA during basal or altered functional conditions to delineate the location and amount of calcium within cells and the changes in location and concentration of cations or anions accompanying calcium redistribution. Recent experiments in our laboratory document that EPXMA in combination with other biochemical and electrophysiological techniques can be used to study, for example, sodium and calcium compartmentation in cultured cardiac cells. Such analyses can also be used to clarify the role of calcium in anoxic renal cell injury and to evaluate proposed ionic defects in cells of individuals with cystic fibrosis.

Correction for specimen movement after acquisition of element-specific electron microprobe images.

Because a long time is generally required to generate X-ray maps of specific elements by electron beam methods, images are subject to a loss of resolution due to stage movement. Methods have been previously described for correcting stage drift during exposure by sensing the drift and deflecting the beam to follow the stage; but these methods require modifications of the equipment. When the drift is not excessive, it is possible to correct a series of images after the exposure series is finished. Here we demonstrate two methods for correcting the drift, one based on manual assignment of specimen position and one on the use of cross-correlation functions to determine objectively the misalignment of images in the series. The success of the methods is illustrated in calcium-specific images of a bone section that show the collagen periodicity after drift correction.

Quantitative microchemical imaging of calcium in Na-K pump inhibited heart cells.

Quantitative electron probe X-ray imaging techniques have been utilized to determine simultaneously the element content within a single cultured embryonic chick heart cell and its intracellular compartments as well as the average elemental content of several heart cells within a population. These features of microchemical imaging have permitted establishment of data regarding: (1) the heterogeneity of calcium accumulation in mitochondrial, cytoplasmic and nuclear compartments under conditions which elevate total cell calcium without producing irreversible cell injury; and (2) the variability of calcium accumulation from cell to cell within the population sampled. The results indicate that during Na-K pump inhibition (K-free HT-BSS, 10(-4) M ouabain, 60 min) elevation of mitochondrial calcium, measured in situ by electron probe X-ray microanalysis, to levels more than 100 times greater than in the basal state, may not cause irreversible mitochondrial uncoupling and cell death.

Real-time graphics display of mass variation or elemental concentration during electron beam microanalysis using a general purpose computer.

A method is described for using a general purpose multi-process minicomputer for the real-time display of graphic summaries of a variety of spectroscopic results while the spectrum acquisition is simultaneously underway.

Frontiers in electron probe microanalysis: application to cell physiology.

The application of electron probe microanalysis techniques, using X-ray and electron energy loss instruments, to problems in cell physiology is reviewed. The details of the special methodological requirements for the analysis of cryosections at high spatial resolution in an analytical electron microscope are discussed together with a comprehensive review of data obtained on major organ systems and cell types.