Improved quantitative electron probe X-ray microanalysis of biological cryosections using an EDS germanium detector and a super-atmosphere thin window (SuperATW).

A new Link energy-dispersive GEM detector with SuperATW window was tested for quantitative electron probe microanalysis of low calcium and sodium concentrations ([Ca], [Na]) in intracellular compartments of cardiac myocytes. We compare Ca profiles with high count statistics and similar peak area collected under the same conditions with either a Be-windowed Si and a Ge SuperATW detector. The height of the Ca peak was increased by 7%, the full width at half-maximum height was reduced by 9% with the Ge detector. The counts statistics of the Ca K alpha peak improved by 9% and the partial overlap with the K K beta peak was better deconvoluted. We calculate [Ca] and errors of the single measurement in mitochondria of guinea-pig cardiac myocytes from spectra acquired with a Si or Ge detector. For identical analysis conditions, the [Ca] were identical; however, with the Ge SuperATW detector, the calculated error of the single measurement was only 1/2.7 of that calculated from measurements with the Si detector. We compare the peak area of identical [Na] in spectra collected with the Be-windowed Si detector and Ge SuperATW detector. The peak area was significantly higher with the SuperATW Ge than with the Si detector and Be window, whereas the continuum in the range 4-10 keV was comparable, demonstrating the improved sensitivity for low atomic elements such as Na of the Ge SuperATW detector. [Na] and errors of the single measurement in mitochondria of quiescent guinea-pig cardiac myocytes were calculated from spectra acquired with the Si or the Ge detector. The use of the Ge SuperATW detector improved the detectability limit for sodium by more than 80% and reduced the error of the single measurement by a factor of 7-8.

Demonstration of mercury in the human brain and other organs 17 years after metallic mercury exposure.

A male subject became exposed to metallic mercury vapor at work in 1973. He excreted 1,850 mg Hg/l urine initially. Controls of urine mercury excretion after D-penicillamine administration led to the assumption of a total body clearance of mercury latest since 1976. Subsequently he developed an organic psychosyndrome without detectable signs of classical mercurialism. He never returned to work again and died of lung cancer in 1990. In different organs (brain, kidney, and lung) which were sampled at autopsy elevated levels of mercury were documented by atomic absorption analysis. Histological examination of the tissue by the Danscher and Schroder method, which is specific for mercury, showed a highly positive staining in the majority of nerve cells and cells of other organs. Ultrastructurally mercury could be demonstrated by elemental x-ray analysis within lipofuscin deposits. The lipofuscin content was increased in the mercury positive nerve cells as demonstrated by a strong positive autofluorescence.

Intrasarcomere [Ca2+] gradients in ventricular myocytes revealed by high speed digital imaging microscopy.

Cardiac muscle contraction is triggered by a small and brief Ca2+ entry across the t-tubular membranes, which is believed to be locally amplified by release of Ca2+ from the adjacent junctional sarcoplasmic reticulum (SR). As Ca2+ diffusion is thought to be markedly attenuated in cells, it has been predicted that significant intrasarcomeric [Ca2+] gradients should exist during activation. To directly test for this, we measured [Ca2+] distribution in single cardiac myocytes using fluorescent [Ca2+] indicators and high speed, three-dimensional digital imaging microscopy and image deconvolution techniques. Steep cytosolic [Ca2+] gradients from the t-tubule region to the center of the sarcomere developed during the first 15 ms of systole. The steepness of these [Ca2+] gradients varied with treatments that altered Ca2+ release from internal stores. Electron probe microanalysis revealed a loss of Ca2+ from the junctional SR and an accumulation, principally in the A-band during activation. We propose that the prolonged existence of [Ca2+] gradients within the sarcomere reflects the relatively long period of Ca2+ release from the SR, the localization of Ca2+ binding sites and Ca2+ sinks remote from sites of release, and diffusion limitations within the sarcomere. The large [Ca2+] transient near the t-tubular/ junctional SR membranes is postulated to explain numerous features of excitation-contraction coupling in cardiac muscle.

Microheterogeneity of subsarcolemmal sodium gradients. Electron probe microanalysis in guinea-pig ventricular myocytes.

1. The effect of stimulation on possible subsarcolemmal sodium accumulation was studied in ventricular myocytes (2 mM [Ca2+]o, 36 degrees C). By trains of eighteen paired voltage-clamp pulses (180 ms to 0 mV, 20 ms to -45 mV, 180 ms to +50 mV, 620 ms to -45 mV) unloaded contractions were potentiated to an optimum. 2. Potentiation reversibly enlarged and prolonged the diastolic tail currents due to Na(+)-Ca2+ exchange. Eighteen pulse pairs were estimated to provide a sodium influx that could increment the total intracellular sodium concentration (sigma Na(i)) by no more than 0.5 mM. 3. Potentiation reversibly increased the current at +50 mV and made it more noisy. Cell-attached recordings with a second electrode attributed this noise to the activation of K+ (Na) channels. In inside-out patches, a comparable channel activity was obtained with 40 mM sodium. Hence, the cell-attached recordings suggest that potentiation can increase intracellular sodium concentration to 40 mM. 4. Electron probe microanalysis (EPMA) measured sigma Na in a volume within 20 nm of the inner side of the sarcolemma. Potentiation reversibly increased sigma Na20nm to 40 +/- 7 mM. When stimulation was terminated, sigma Na20nm fell within 8 s to 37 +/- 8 mM and within 3 min to 19 +/- 6 mM. In unstimulated cells sigma Na20nm was 17 +/- 5 mM. 5. In potentiated cells, shock-frozen at early systole, sigma Na fell with a space constant of 28 nm from the sarcolemma to the centre; at 1 microns distance sigma Na was 12 +/- 3 mM. The steep gradient suggests that sodium does not freely diffuse and sigma Na20nm is controlled by transmembrane fluxes rather than by cell dialysis. 6. sigma Na20nm data were distributed with peaks at 5, 30 and 60 mM. Quantitative elemental digital imaging demonstrated patches with 60-80 mM sigma Na20nm alternating with others of 0-15 mM sigma Na20nm. This 'sodium microheterogeneity' suggests that Ca2+ efflux at low sigma Na20nm and K+(Na) channel activation at high sigma Na20nm can operate simultaneously.

Changes in mitochondrial calcium concentration during the cardiac contraction cycle.

OBJECTIVE: The aim was to examine whether mitochondrial Ca2+ fluxes are high enough to change mitochondrial and cytosolic calcium concentration during the contraction cycle. METHODS: Isolated guinea pig ventricular myocytes were stimulated with paired voltage clamp pulses until contractions were maximal (2 mM [Ca2+]o, 36 degrees C). At defined times of diastole or systole, the cells were shock frozen. Electron-probe microanalysis measured the concentration of total calcium in mitochondria (sigma Ca(mito)) and surrounding cytosol (sigma Cac). Other experiments were performed to evaluate DNP sensitive mitochondrial Ca2+ uptake from depolarisation induced [Ca2+]c transients (K5indo-1 fluorescence). RESULTS: At end of diastole, sigma Ca(mito) was 446 mumol.litre-1. During systole, sigma Ca(mito) increased with a 20 ms delay. A peak sigma Ca(mito) of 1050 mumol.litre-1 was measured 40 ms after start of systole, while 95 ms after start of systole sigma Ca(mito) had fallen to 530 mumol.litre-1. From the changes in sigma Ca(mito) the rates of net mitochondrial Ca2+ flux were estimated at 100 nmol.s-1 x mg-1 protein for Ca2+ influx and 36 nmol.s-1 x mg-1 protein for Ca2+ egress. Decay of sigma Ca(mito) was coupled to a rise in sigma Na(mito). sigma Cl(mito) and sigma K(mito) rose and fell in parallel with sigma Ca(mito), suggesting Ca2+ activation of mitochondrial anion and cation channels. Activation of the non-specific permeability can be excluded. Block of mitochondrial Ca2+ uptake with DNP (100 microM) or FCCP (10 microM) increased the amplitude of the [Ca2+]c transients for 1-3 min by about 50%; evaluation of mitochondrial Ca2+ uptake from DNP sensitive difference signals, however, was hampered by sequestration of mitochondrial Ca2+ into the sarcoplasmic reticulum. CONCLUSIONS: Mitochondrial calcium content changes during each individual contraction cycle; a substantial amount of calcium is taken up during the systole and released during later systole and diastole.

Binding of calcium to myoplasmic buffers contributes to the frequency-dependent inotropy in heart ventricular cells.

In guinea-pig ventricular cells, the Ca2+ buffer capacity of the myoplasm was estimated from the ratio of ionized calcium (from Indo-1 fluorescence) through total calcium (ionized plus bound calcium, from x-ray microprobe analysis). During post-rest potentiation (1 Hz paired-pulses in voltage-clamp), where diastolic sarcomere length remained nearly constant, Ca2+ buffer capacity slowly fell from 5500:1 to 700:1 suggesting that slow Ca2+ binding sites became saturated. We discuss that frequency-inotropy depends not only on the replenishment of intracellular stores with Ca2+, but also on binding of Ca2+ to these slow sites; the slow Ca2+ sites could complete with the fast activator sites on troponin C for systolic Ca2+, or they could enhance the Ca2+ affinity of the fast Ca2+ sites on troponin C by cooperative interaction.

Potentiation of contraction as related to changes in free and total intracellular calcium.

In voltage-clamped guinea-pig ventricular myocytes, we studied the potentiation of contraction in dependence on the concentration of intracellular calcium; ionized calcium [Ca2+]c was measured by Indo-1 microfluospectroscopy and total calcium (sigma Ca) by electronprobe microanalysis (EPMA). After a 15 min rest period, [Ca2+]c was approx. 90 nM and sigma Ca was below the detection limit (80 microM) in myoplasm (sigma Ca(myo)), junctional sarcoplasmic reticulum (sigma CaSR) and mitochondria (sigma Ca(Mito)). Post rest, repetitive clamp steps (1 Hz) potentiated extent and rate of shortening by 300%. In the literature, post-rest potentiation is attributed to the replenishment of SR with releasable calcium; by EPMA the postulated increase in sigma CaSR was measured directly. Post-rest, the peaks of systolic [Ca2+]c transients increased, however only by 40%. In addition, a moderate increase of end-diastolic [Ca2+]c was measured. In an other series of experiments, contraction was potentiated by 800% increase by means of paired voltage-clamp pulses (1 Hz, 36 degrees C, 2 mM [Ca2+]o). In the potentiated state, end-diastolic [Ca2+]c was 180 nM and sigma Ca(myo) was 0.65 mM. During systole, [Ca2+]c peaked within 20 ms to 950 nM. sigma Ca(myo) rose within 20 ms to 1.4 mM and fell within 40 ms to 1.1 and within 90 ms to 0.8 mM. In contrast, the time course of contraction was slow and peaked at a time (130 ms) when the [Ca2+]c and sigma Ca(myo) transients were finished. We suggest that Ca2+ bound to troponin C (TnC) controls only the onset but not the time course of myofilament interaction. From [Ca2+]c and sigma Ca(myo) we estimated a Ca2+ buffering capacitance of 1.5 mmol sigma Ca(myo) per pCa change, only a fraction of which can be attributed to Ca2+ binding sites on TnC. A model explaining the results requires the assumption of 0.6 mM additional slow, high affinity Ca2+ sites and 2 mM fast, low affinity Ca2+ sites. We discuss that end-diastolic Ca2+ binding to these sites contributes to the potentiation of contraction. Junctional SR. At the end of diastole sigma CaSR was 2.4 mM which is 4 times larger than sigma Ca(myo). This difference disappeared 20 ms after depolarization (sigma CaSR 1.1 mM), within another 20 ms it largely recovered (sigma CaSR 2.0 mM). These properties suggest that the junctional SR is a compartment suitable not only for Ca2+ release but also for rapid Ca2+ reuptake. Mitochondria. Paired-pulse potentiation increased end-diastolic sigma Ca(Mito) significantly (0.4 mM).(ABSTRACT TRUNCATED AT 400 WORDS)

Total and free myoplasmic calcium during a contraction cycle: x-ray microanalysis in guinea-pig ventricular myocytes.

1. At 36 degrees C and 2 mM [Ca2+]o single guinea-pig ventricular myocytes were voltage clamped with patch electrodes. With a paired-pulse protocol applied at 1 Hz, a first pulse to +5 mV was followed by a second pulse to +50 mV. When paired pulsing had potentiated the contraction to the maximum, the cells were shock-frozen for electron-probe microanalysis (EPMA). Shock-freezing was timed at the end of diastole (-80 mV) or at different times during systole (+5 mV). 2. The same paired-pulse protocol was applied to another group of myocytes from which contraction and [Ca2+]i was estimated by microfluospectroscopy (50 microM-Na5-Indo-1). Potentiation moderately reduced diastolic sarcomere length from 1.85 to 1.82 microns and increased diastolic [Ca2+]i from about 95 to 180 nM. In potentiated cells, during the first pulse, contraction peaked within 128 +/- 25 ms after start of depolarization. [Ca2+]i peaked within 25 ms to 890 +/- 220 nM (mean +/- S.E.M.) and fell within 100 ms to about 450 nM. 3. Sigma Camyo, the total calcium concentration in the overlapping myofilaments (A-band), was measured by EPMA in seventeen potentiated myocytes. During diastole, sigma Camyo was 2.6 +/- 0.4 mmol (kg dry weight (DW]-1 which can be converted to 0.65 mM (mmoles per litre myofibrillar space). Since [Ca2+]i was 180 nM, we estimate that 99.97% of total calcium is bound. 4. A time course for systolic sigma Camyo was determined by shock-freezing thirteen cells at different times after start of depolarization to +5 mV. Sigma Camyo was 5.5 +/- 0.3 mmol (kg DW)-1 (1.4 mM) after 15-25 ms, 4.6 +/- 0.5 mmol (kg DW)-1 (1.1 mM) after 30-45 ms, and 3.1 mmol (kg DW)-1 (0.8 mM) after 60-120 ms. The fast time course of sigma Camyo suggests that calcium binds to and unbinds from troponin C at a fast rate. Hence, it is the slow kinetics of the cross-bridges that determines the 130 ms time-to-peak shortening. 5. Mitochondria of potentiated cells contained during diastole a total calcium concentration, sigma Camito, of 1.3 +/- 0.2 mmol (kg DW)-1 (0.4 mM). During the initial 15-25 ms of systole, sigma Camito did not change, however, during 30-45 ms sigma Camito rose to 3.7 +/- 0.5 mmol (kg DW)-1 (1.2 mM). The data suggest that sigma Camito can follow sigma Camyo with some delay, thereby participating in both slow diastolic and fast systolic changes in total calcium (sigma Ca), at least under the given conditions.(ABSTRACT TRUNCATED AT 400 WORDS)

Large and rapid changes of myofibrillar total calcium during the cardiac cycle. Electron probe microanalysis of voltage-clamped guinea-pig ventricular myocytes.

At 36 degrees C and 2 mM [Ca2+]o, single guinea-pig ventricular myocytes were voltage clamped with patch electrodes. When paired pulsing had potentiated the contraction to the maximum, the cells were shock-frozen for electron probe microanalysis (EPMA). Shock-freezing was timed at the end of diastole (-80 mV) or at different times during systole (+5 mV). The same paired-pulse protocol was applied to another group of myocytes from which contraction was recorded and [Ca2+]i was estimated by microfluospectroscopy (50 microMNa-Indo-1). In potentiated cells, during the first pulse, contraction peaked within 128 +/- 25 ms after start of depolarization. [Ca2+]i peaked within 25 ms to 890 /+- 220 nM (mean +/- SEM) and fell within 100 ms to about 450 nM. sigma Camyo, the total calcium concentration in the overlapping myofilaments (A-band), was measured by EPMA in 17 potentiated myocytes. During diastole, sigma Camyo was 2.6 +/- 0.4 mmol/kg dry weight (dw), which can be converted to 0.65 mM (mmoles per liter myofibrillar space). Since [Ca2+]i was 180 nM, we estimate that 99.97% of total calcium is bound. A time-course for systolic sigma Camyo was determined by shock-freezing 13 cells at different times after start of depolarization to +5 mV. sigma Camyo was 5.5 +/- 0.3 mmol/kg dw (1.4 mM) after 15-25 ms, 4.6 +/- 0.5 mmol/kg dw (1.1 mM) after 30-45 ms, and 3.1 mmol/kg dw (0.8 mM) after 60-120 ms. The fast time-course of sigma Camyo suggests that calcium binds to and unbinds from troponin C at a fast rate.(ABSTRACT TRUNCATED AT 250 WORDS)

X-ray microanalysis of single cardiac myocytes frozen under voltage-clamp conditions.

By means of a patch pipette, an isolated ventricular myocyte was transferred into the taper of a silver holder covered by pioloform film. Once the cell was on the film, the cell was voltage clamped (pulses from -45 to +5 mV at 0.5 Hz). The amount of Ca entry was estimated from the Ca current. When contractility (cell shortening) was potentiated with either five pulses of 0.2 s or four pulses of 1 s, shock freezing was timed 116 or 816 ms after start of the clamp pulse. Electron micrographs from freeze-substituted cells revealed the good preservation of the intracellular compartments. The myocytes were cut at -150 degrees C, and the cryosections were freeze dried. In representative examples, the amount of Ca entry is compared with the subcellular Ca distribution as it is analyzed with energy dispersive X-ray microprobe analysis in cytoplasm, junctional sarcoplasmic reticulum (SR), mitochondria, and the subsarcolemmal space (sarcolemma, peripheral SR, fringe of cytosol).

Ca-pools involved in the regulation of cardiac contraction under positive inotropy. X-ray microanalysis on rapidly-frozen ventricular muscles of guinea-pig.

Electron probe microanalysis of rapidly-frozen small ventricular trabeculae of guinea-pig demonstrates that the distribution of total intracellular calcium varies under positive inotropy depending on the type of inotropic intervention. The sarcoplasmic reticulum (SR) (or part of it) localized at the level of the z-lines reveals high calcium accumulation at the end of diastole whenever a stimulus is followed by a contraction with a short time to peak of force. After paired pulse stimulation, only this cell compartment accumulates calcium at the end of diastole. Since this cell compartment is "Ca-empty" in muscles frozen during contraction, SR is considered to be the source of activator Ca. In several cases of inotropy (after application of ARL, caffeine or after lowering the extracellular Na+ concentration), calcium is also detectable on the mitochondria, suggesting that these organelles participate in slow regulation of cytosolic calcium. In some cases, total calcium located on the sarcomeres is increased. The interpretation of this finding is intriguing and requires the assumption of supplementary cytosolic Ca-sinks as yet unknown.

Extra- and intracellular lanthanum: modified calcium distribution, inward currents and contractility in guinea pig ventricular preparations.

In guinea pig ventricular strips and isolated cells, 0.1 mM LaCl3 blocks contractility and shortens the action potential (AP) in less than 2 min ("early La-effect"). After 30 min, it prolongs the APs which trigger slow contractions ("late La-effect"). These results confirm earlier reports. X-ray microprobe analysis shows that La initially displaces only a small fraction of that Ca which is superficially bound to the sarcolemma. But, since this Ca is completely removed by Ca-free solutions within 2 min, we suggest that La blocks contractility not by displacing superficial Ca but by blocking the Ca inward current iCa. Blocking of iCa is analyzed with voltage clamp experiments. It is not La-specific, and can also be observed with other calcium channel blockers as well. When iCa has been blocked, the membrane can still generate 100-200 ms long plateaus via the sodium inward current iNa. During the late La-effect, the cells internalize La. Intracellular La is detected by x-ray microprobe analysis in cryosections of frozen muscles and as La-precipitates in EM images from freeze substituted preparations. Simultaneously, the cytosol gains Na and Ca, but the plasmalemmal and sarcoplasmic reticulum (SR) membranes are no longer occupied by Ca but by La. The late La-effect on the prolongation of the AP is La-specific. In the absence of extracellular La, it can be induced by pressure injection of La into the cytosol. The long APs are based on an additional La, it can be induced by pressure injection of La into the cytosol. The long APs are based on an additional inward current which is insensitive to Ca-removal, is inactivated by holding potentials of -40 mV, and is TTX-sensitive. We suggest that the current flows through a fraction of original Na-channels that is modified by i.c. La with respect to inactivation and selectivity. We attribute the late re-occurrence of contractility to activator Ca entering from the bath. Ca-entry might be mediated via enhanced Na/Ca-exchange whose rate is increased by the i.c. Na-load. In addition, Ca may enter through the La-modified Na-channels due to their impaired selectivity. Since i.c. La is known to interfere with the Ca-sequestration by the SR, it is expected to impair relaxation.

Presystolic calcium-loading of the sarcoplasmic reticulum influences time to peak force of contraction. X-ray microanalysis on rapidly frozen guinea-pig ventricular muscle preparations.

Guinea-pig ventricular small papillary muscles and trabeculae were rapidly frozen presystolically after prolonged rest following positive inotropic interventions which strongly influenced peak of force and time to peak force. The possible sources of activator calcium for the different types of contraction were investigated. After rest in the presence of noradrenaline (10(-5)mol/l) the first post-rest contraction showed a retarded activation and a "late" peak of force. Muscle strips frozen after a rest period of 5 min in a bath solution containing noradrenaline were cryosectioned and analyzed with X-ray microanalysis for elemental distribution: although at this time an applied stimulus would induce a potentiated contraction, intracellular membrane systems such as sarcoplasmic reticulum and mitochondria failed to reveal any accumulation of calcium. After rest in a low sodium Tyrode the first post-rest contraction showed an "early" peak of force. Muscles frozen after rest in a low sodium solution revealed intracellular Ca accumulation on the sarcoplasmic reticulum, in the network at the level of the Z-lines. The results support the hypothesis that 1. the sarcoplasmic reticulum (SR) accumulates calcium presystolically when "early" contractions follow stimulation; 2. the network of sarcoplasmic reticulum at the level of the Z-lines is a crucial source of activator calcium; 3. the activator calcium for late contractions is probably of extracellular origin.

Effects of non-toxic doses of ouabain on sodium, potassium, calcium distribution in guinea pig papillary muscle. Electronprobe microanalysis.

The mechanisms and the cellular structures which are definitely involved in the accumulation and release of calcium in heart muscle treated with cardiac glycosides are not yet known. The distribution of sodium, potassium and calcium in small papillary muscles of the guinea pig right ventricle was examined with the aid of energy dispersive x-ray microanalysis and cryotechniques. The primary aim of the present study was twofold: firstly, to determine whether an increase in intracellular sodium concentration is detectable in muscles showing positive inotropy resulting from treatment with non-toxic doses of ouabain; and secondly, whether at the end of diastole cellular stores are detectable accumulating Ca which could be responsible for the pronounced contraction which normally would follow. Analyses on interstitium, cell membrane, sarcomeres, Z-lines and mitochondria of 7 muscles strips treated with non-toxic doses of ouabain and frozen at the end of diastole showed the following: sodium concentration in the sarcoplasm was significantly higher than over the mitochondria; it was also higher than over the sarcoplasm of non-treated muscles frozen at the end of diastole. High calcium concentrations were also measured over the cell membrane. These calcium concentrations were higher than that detected in sarcomeres, Z-lines and mitochondria. Over the sarcomeres, the calcium concentration was higher than in experiments on non-treated muscles which were also frozen at the end of diastole. Mitochondria did not accumulate any detectable concentration of calcium.(ABSTRACT TRUNCATED AT 250 WORDS)

Intracellular membranes as boundaries for ionic distribution. In situ elemental distribution in guinea pig heart muscle in different defined electro-mechanical coupling states.

Using x-ray microanalysis and cryoultramicrotomy, calcium and other diffusible elements were localized in heart muscle strips which had been shock frozen under different, defined conditions of electromechanical coupling. Guniea pig papillary muscles were shock frozen: 1) 1/2 seconds after paired stimulation, 2) 5 minutes after rest in normal bath medium and 3) 5 minutes after rest in bath medium to which noradrenaline was added. In 1) high calcium concentrations of 11.5 mmol/kg d.w. were regularly detected in sites at the level of Z-lines, which probably correspond to the Z rete of SR. In 2) in which the mechanogram of the fist contraction after rest normally showed a small and retarded peak, the cell stores seemed to be nearly empty, with exception of a few regions between the mitochondria which revealed calcium accumulations of 77 mmol/kg d.w. These regions included JSR and/or T-tubuli. In 3) in which the mechanogram of the first contraction after rest normally showed a retarded peak with high tension, calcium was found in several cell structures. The highest amount, 25 mmol/kg d.w., was detected over the cell membrane. Measurable amounts were also detected over Z-lines and sarcomeres. In the present experiments, the respective rate of rise of tension, and time to peak tension, were extremely different. Possible correlations between different contraction patterns and different calcium stores involved in the various experiments have been discussed.

Ionic shifts in myelinated nerve fibers during early stages of Wallerian degeneration.

The distribution and relative mass fraction of the diffusible ions Na, K, Cl and Ca were determined by X-ray microanalysis in the axons of rat sciatic nerve 18 h and 36 h after crush and in control nerves. The investigations were performed in freeze-dried ultrathin cryosections after shock freezing of the nerves in liquified propane. 18 h after crush, no definite alteration of the ions were found compared to the control nerves. In electron micrographs of routinely processed nerves, no ultrastructural changes were seen. 36 h after crush, two types of ionic imbalance were found, the first characterized by decreased K and slightly increased Na in the axon, the second by concurrently increasing axonal Na and Cl, accompanied, in some fibers, by accumulating Ca. These types of ionic imbalance presumably represent two stages of axolemmal permeability alteration corresponding to early structural changes of axoplasm in electron micrographs of routinely processed nerves at that time.

Cryoultramicrotomy, electron probe microanalysis and STEM of myocardial tissue.

Heart muscle preparations (papillary muscles and trabeculae) were frozen at 4.2 K on metal plate under vaccum after their length-tension relationships showed that no damage had occurred during dissecting and mounting the strips on the holder. Freeze substitution of some preparations directly after freezing demonstrated that no important cell damage due to ice crystals occurred in superficial cell layers during freezing. Ultrathin cryosections obtained at -130 degrees C were freeze dried and analyzed, in the STEM mode. The better the freezing procedure, the poorer was the contrast of the sections under electron microscopy. Preliminary approaches to increasing contrast after sublimation of tissue water show that a small increase in contrast is generally obtained at the cost of the peak/background ratio due to pronounced mass loss. The results of our analyses show that C1 content in heart muscle cells is high and distributed throughout the cytoplasm. Ca is detectable and quantitable in resting muscle in SR cisternae. The Ca amount in cytoplasm is low and just at the limit of detectability under our current analysis conditions. Preliminary experiments on papillary muscles subjected to caffeine contracture showed that calcium is not detectable in the cisternae as is the case in control experiments. Only a moderate amount of Ca is detectable in mitochondria, whereas the concentrations in cytoplasm, as in resting cardiac muscle, is too low to be quantitated.