103 research outputs found
Evaluation of multi-exponential curve fitting analysis of oxygen-quenched phosphorescence decay traces for recovering microvascular oxygen tension histograms
Although it is generally accepted that oxygen-quenched phosphorescence decay traces can be analyzed using the exponential series method (ESM), its application until now has been limited to a few (patho)physiological studies, probably because the reliability of the recovered oxygen tension (pO2) histograms has never been extensively evaluated and lacks documentation. The aim of this study was, therefore, to evaluate the use of the ESM to adequately determine pO2 histograms from phosphorescence decay traces. For this purpose we simulated decay traces corresponding to uni- and bimodal pO2 distributions and recovered the pO2 histograms at different signal-to-noise ratios (SNRs). Ultimately, we recovered microvascular pO2 histograms measured in the rat kidney in a model of endotoxemic shock and fluid resuscitation and showed that the mean microvascular oxygen tension, 〈pO2〉, decreased after induction of endotoxemia and that after 2 h of fluid resuscitation, 〈pO2〉 remained low, but the hypoxic peak that had arisen during endotoxemia was reduced. This finding illustrates the importance of recovering pO2 histograms under (patho)physiological conditions. In conclusion, this study has characterized how noise affects the recovery of pO2 histograms using the ESM and documented the reliability of the ESM for recovering both low- and high-pO2 distributions for SNRs typically found in experiments. This study might therefore serve as a frame of reference for investigations focused on oxygen (re)distribution during health and disease and encourage researchers to (re-)analyze data obtained in (earlier) studies possibly revealing new insights into complex disease states and treatment strategies
Changes in oxygen partial pressure of brain tissue in an animal model of obstructive apnea
Background: Cognitive impairment is one of the main consequences of obstructive sleep apnea (OSA) and is
usually attributed in part to the oxidative stress caused by intermittent hypoxia in cerebral tissues. The presence of
oxygen-reactive species in the brain tissue should be produced by the deoxygenation-reoxygenation cycles which
occur at tissue level during recurrent apneic events. However, how changes in arterial blood oxygen saturation
(SpO2) during repetitive apneas translate into oxygen partial pressure (PtO2) in brain tissue has not been studied.
The objective of this study was to assess whether brain tissue is partially protected from intermittently occurring
interruption of O2 supply during recurrent swings in arterial SpO2 in an animal model of OSA.
Methods: Twenty-four male Sprague-Dawley rats (300-350 g) were used. Sixteen rats were anesthetized and noninvasively
subjected to recurrent obstructive apneas: 60 apneas/h, 15 s each, for 1 h. A control group of 8 rats was
instrumented but not subjected to obstructive apneas. PtO2 in the cerebral cortex was measured using a fastresponse
oxygen microelectrode. SpO2 was measured by pulse oximetry. The time dependence of arterial SpO2
and brain tissue PtO2 was carried out by Friedman repeated measures ANOVA.
Results: Arterial SpO2 showed a stable periodic pattern (no significant changes in maximum [95.5 ± 0.5%; m ± SE]
and minimum values [83.9 ± 1.3%]). By contrast, brain tissue PtO2 exhibited a different pattern from that of arterial
SpO2. The minimum cerebral cortex PtO2 computed during the first apnea (29.6 ± 2.4 mmHg) was significantly
lower than baseline PtO2 (39.7 ± 2.9 mmHg; p = 0.011). In contrast to SpO2, the minimum and maximum values of
PtO2 gradually increased (p < 0.001) over the course of the 60 min studied. After 60 min, the maximum (51.9 ± 3.9
mmHg) and minimum (43.7 ± 3.8 mmHg) values of PtO2 were significantly greater relative to baseline and the first
apnea dip, respectively.
Conclusions: These data suggest that the cerebral cortex is partially protected from intermittently occurring
interruption of O2 supply induced by obstructive apneas mimicking OSA
Single molecule tracking fluorescence microscopy in mitochondria reveals highly dynamic but confined movement of Tom40
Tom40 is an integral protein of the mitochondrial outer membrane, which as the central component of the Translocase of the Outer Membrane (TOM) complex forms a channel for protein import. We characterize the diffusion properties of individual Tom40 molecules fused to the photoconvertable fluorescent protein Dendra2 with millisecond temporal resolution. By imaging individual Tom40 molecules in intact isolated yeast mitochondria using photoactivated localization microscopy with sub-diffraction limited spatial precision, we demonstrate that Tom40 movement in the outer mitochondrial membrane is highly dynamic but confined in nature, suggesting anchoring of the TOM complex as a whole
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