Hypobaric impact on clinical tolerance and 24-h patterns in iron metabolism markers and plasma proteins in men

Long-distance flights can cause a number of clinical problems due to mild hypoxia resulting from cabin pressurization. Using a chronobiological approach, the aim of this work was to assess the clinical tolerance and biological impact of daytime exposure to hypobaric hypoxia on markers of iron metabolism and plasma proteins. Fourteen healthy, male volunteers, ages 23 to 39 yrs, spent 8.5 h in a hypobaric chamber (from 07:45 to 16:15 h) simulating an altitude of 8000 ft. This was followed by another 8.5-h session 4 wks later simulating conditions at an altitude of 12,000 ft. Biological variables were assayed every 2 h over two 24-h spans (control and hypoxia spans, respectively) per simulated altitude. Whereas most of the subjects tolerated the 8000 ft exposure well, eight subjects (57%) presented clear clinical signs of hypoxic intolerance at 12,000 ft. The 24-h blood iron profile showed a biphasic pattern at both altitude simulations, with a significant (～40%) increase during hypoxia, followed by a (～25%) decrease during the first hours of recovery. The iron circadian rhythm showed a significant phase delay during the hypoxic exposure at 8000 ft vs. reference. Mean 24-h ferritin levels decreased at both altitudes, but mainly during the nighttime after the 12,000 ft exposure in accordance with Cosinor analysis. The transferrin and total plasma proteins 24-h profiles did not show significant change. Moreover, significant differences, mainly in iron, ferritin, and transferrin, were found at 12,000 ft according to the clinical tolerance to hypoxia, and significant correlations were found between the mid-range crossing times, i.e., here half-descent times (d-T(50)), for ferritin and total plasma proteins and the reported level of clinical discomfort under hypoxia. This study shows that an 8.5-h exposure to mild hypoxia is able to alter very quickly the 24-h pattern of iron and ferritin. These alterations seem to depend, at least in part, on the clinical tolerance to hypoxia and may help explain the interindividual differences observed in the tolerance to hypoxia.     

Hypobaric Impact on Clinical Tolerance and 24-h Patterns in Iron Metabolism Markers and Plasma Proteins in Men

Long-distance flights can cause a number of clinical problems due to mild hypoxia resulting from cabin pressurization. Using a chronobiological approach, the aim of this work was to assess the clinical tolerance and biological impact of daytime exposure to hypobaric hypoxia on markers of iron metabolism and plasma proteins. Fourteen healthy, male volunteers, ages 23 to 39 yrs, spent 8.5 h in a hypobaric chamber (from 07:45 to 16:15?h) simulating an altitude of 8000 ft. This was followed by another 8.5-h session 4 wks later simulating conditions at an altitude of 12,000 ft. Biological variables were assayed every 2?h over two 24-h spans (control and hypoxia spans, respectively) per simulated altitude. Whereas most of the subjects tolerated the 8000 ft exposure well, eight subjects (57%) presented clear clinical signs of hypoxic intolerance at 12,000 ft. The 24-h blood iron profile showed a biphasic pattern at both altitude simulations, with a significant (～40%) increase during hypoxia, followed by a (～25%) decrease during the first hours of recovery. The iron circadian rhythm showed a significant phase delay during the hypoxic exposure at 8000 ft vs. reference. Mean 24-h ferritin levels decreased at both altitudes, but mainly during the nighttime after the 12,000 ft exposure in accordance with Cosinor analysis. The transferrin and total plasma proteins 24-h profiles did not show significant change. Moreover, significant differences, mainly in iron, ferritin, and transferrin, were found at 12,000 ft according to the clinical tolerance to hypoxia, and significant correlations were found between the mid-range crossing times, i.e., here half-descent times (d-T₅₀), for ferritin and total plasma proteins and the reported level of clinical discomfort under hypoxia. This study shows that an 8.5-h exposure to mild hypoxia is able to alter very quickly the 24-h pattern of iron and ferritin. These alterations seem to depend, at least in part, on the clinical tolerance to hypoxia and may help explain the interindividual differences observed in the tolerance to hypoxia. (Author correspondence: yvan.touitou@chronobiology.fr)     

Normoxic induction of the hypoxic-inducible factor-1 alpha by interleukin-1 beta involves the extracellular signal-regulated kinase 1/2 pathway in normal human cytotrophoblast cells

During early pregnancy, an environment of relative low oxygen tension is essential for normal embryonic and placental vasculature. In low-oxygen conditions, the hypoxic-inducible factor-1 (HIF-1), composed of alpha and beta subunits, controls the expression of a number of genes such as vascular endothelial growth factor (VEGF), a key angiogenic factor. The recent studies in some tumor cells have found that the labile component, HIF-1 alpha, is not only activated by hypoxia but also by peptides such as interleukin-1 (IL-1) in normoxia. In this article, we demonstrated that exposure of normal human cytotrophoblast cells to IL-1 beta stimulated the expression of HIF-1 alpha protein. Meanwhile, IL-1 beta also induced the secretion of VEGF in normal human cytotrophoblast cells. Our data indicated that IL-1 beta induced extracellular signal-regulated kinase (ERK) 1/2 phosphorylation. Moreover, treatment of cells with PD98059, an inhibitor of ERK1/2 signaling, inhibited the stimulation of HIF-1 alpha protein expression and VEGF secretion by IL-1 beta. These data indicate that, in normal human cytotrophoblast cells, IL-1 beta induces HIF- 1 alpha-mediated VEGF secretion and that IL-1 beta-stimulated ERK1/2 activation may be involved in this process.     

Cytokine network regulating terminal maturation of human bone marrow B cells capable of spontaneous and high rate Ig secretion in vitro.

Human bone marrow (BM) B cells capable of spontaneous and high rate Ig secretion for 14 days in vitro have been described previously. We have shown recently that Ig secretion by these BM cells depends on stromal adherent BM cell-derived factors identified as IL-6 and fibronectin. Our report shows that the endogenous generation of IL-1 beta and TNF-alpha in serum-containing cultures of BM mononuclear cells (BMMC) is also involved in the control of Ig-secreting cells, because their blockade with specific antibodies markedly reduced Ig production. Further experiments revealed that IL-1 beta and TNF-alpha acted by regulating IL-6 production, as can be deduced from the following findings: 1) the inhibition of Ig secretion caused by either anti-IL-1 beta or anti-TNF-alpha antibodies could be reversed by exogenous IL-6; 2) the addition of either of these antibodies inhibited endogenous IL-6 production in BMMC cultures; 3) IL-1 beta plus TNF-alpha, but neither one alone, restored complete IL-6 and Ig production by BMMC in serum-free cultures. Moreover, adherent, but not nonadherent, BM cells were responsible for endogenous IL-1 beta and TNF-alpha secretion. Finally, IL-1 beta plus TNF-alpha induced the production of IL-6, but not of Ig, by adherent BM cells. Neither IL-6 nor Ig production was induced by adding this cytokine combination to nonadherent BM cell cultures, despite the fact that this fraction contained all the Ig-secreting cells. However, the addition of IL-6 restored Ig secretion in this cell fraction. These results suggest that IL-1 beta and TNF-alpha produced by adherent BM cells synergistically induce early IL-6 generation, which, in turn, drives BM B cell producers into the high rate Ig-secreting state.     

Interleukin 1beta mediates the effect of high D-glucose on the secretion of TNF-alpha by mouse uterine epithelial cells.

Previous observations have shown that tumour necrosis factor alpha (TNF-alpha) synthesis is increased in the uterus of diabetic rats and that the epithelial layer lining the uterine lumen is the major site of TNF-alpha over-production. In the present study, TNF-alpha secretion was found to be stimulated by high D-glucose levels in primary cultures of mouse uterine luminal cells but not in cultures of the mouse uterine epithelial WEG-1 cell line. Experiments were performed to investigate the possibility that non-epithelial cells may mediate the influence of high D-glucose on TNF-alpha production by uterine epithelial cells. Immunocytochemical analysis revealed the reproducible presence of a small proportion of macrophages in primary cultures. Macrophages of the RAW 264.7 cell line were found to secrete more interleukin (IL)-1beta (but not TNF-alpha) when cultured in high D-glucose. TNF-alpha production in WEG-1 cells was increased upon exposure to IL-1beta and both protein kinase-C and tyrosine kinase pathways appeared to be involved in TNF-alpha stimulation. Addition of IL-1 receptor antagonist to primary cultures partially abrogated the effect of high D-glucose. Since WEG-1 cells do not produce IL-1beta, the data lend support to the hypothesis that uterine epithelial cells synthesize high levels of TNF-alpha in response to hyperglycaemia via an increase in IL-1beta secretion by stromal macrophages.     

Impact of hypobaric hypoxia in pressurized cabins of simulated long-distance flights on the 24 h patterns of biological variables, fatigue, and clinical status

Long-distance flights can cause a number of clinical problems in both passengers and crewmembers. Jet lag as well as mild hypoxia resulting from incomplete cabin pressurization could contribute to these problems. The objective of this study was to assess, using a chronobiological approach, the clinical impact of diurnal hypobaric, hypoxic exposure on fatigue and other common symptoms encountered during high-altitude exposure and to measure changes in blood chemistry (i.e., plasma creatinine, urea, uric acid, sodium, calcium, phosphorus, glycemia, and lipids). Fourteen healthy, diurnally active (from 07:00 to 23:00 h) male volunteers, aged 23 to 39 yrs, spent 8.5 h in a hypobaric chamber (08:00 to 16:30 h), at a simulated altitude of 8,000 ft (2,438 m). This was followed by an additional 8.5 h of study four weeks later at a simulated altitude of 12,000 ft (3,658 m). Clinical data were collected every 2 h between 08:00 and 18:00 h, and biological variables were assayed every 2 h over two (control and hypoxic-exposure) 24 h cycles. Clinical symptoms were more frequent with the 12,000 ft exposure. Wide interindividual variability was observed in the clinical tolerance to prolonged hypobaric hypoxia. The 24 h profiles of most biochemical variables were significantly altered at each altitude, with changes in mean plasma levels and a tendency toward phase delay, except for uric acid, which showed a phase advance. Changes in appetite mainly occurred with the simulated 12,000 ft exposure and may have been associated with changes in the postprandial glycemia profile. Finally, though the observed biochemical changes were significant, their clinical relevance must be clarified in studies involving actual long-distance flights.     

Relations between IL-3-induced proliferation and in vitro cytokine secretion of bone marrow cells from AML patients.

The influence of IL-3 on the bone marrow cells of 53 patients with acute myeloid leukaemia (AML) was investigated after 72 h suspension in cultures by analysing the proliferation of blasts and the secretion of cytokines. The titres of IL-1beta IL-6, TNF-alpha and IL-3 were measured in the supernatants of these cultures with ELISA tests. Comparing the percentage of cells in S-phases of control cultures and cultures with IL-3, the leukaemias were divided into two growth pattern groups: IL-3-insensitive (n=19) and IL-3-sensitive (n=34) leukaemias. The IL-3-insensitive AML cells show a greater ability for autonomous growth, first by the increase of S-phase in the control culture compared with the S-phase in vivo (P=0.0486) and second, by the higher constitutive secretion (control culture) of IL-1beta P =0.0004), IL-6 ( P =0.0395) and TNF-alpha P=0.0005). The IL-3-induced secondary cytokine secretion is also different in the two growth pattern groups. Whereas in the IL-3-insensitive AML cells a moderate increase of IL-1beta (1.48-fold increase) was present, in the IL-3-sensitive AML cells a 4.72-fold increase of IL-1beta 2.71-fold increase of IL-6 and 11.81-fold increase of the TNF-alpha titre could be detected. Overall, the data show an inverse correlation between the ability of AML cells to respond to IL-3 with increase of an S-phase and the constitutive secretion of IL-1beta, II-6 and TNF-alpha. A further effect of IL-3 is the induction of secondary cytokine secretion in the bone marrow of IL-3-sensitive growing AML cells.     

Nitric oxide synthase induction,cGMP elevation,and biopterin synthesis in vascular smooth muscle cells stimulated with interleukin-1beta in hypoxia

In cultured rat vascular smooth muscle cells (VSMC), inducible nitric oxide synthase (iNOS) expression evoked by interleukin-1beta (IL-1beta) or tumor necrosis factor-alpha was greatly enhanced in hypoxia (2% O(2)), compared to in normoxia. In contrast, iNOS induction by interferon-gamma, lipopolysaccharide or their combination was barely influenced by hypoxia. These results indicate that iNOS induction is regulated by hypoxia in different manners, depending on the stimuli in VSMC. Nitric oxide (NO) production in response to stimulation with interferon-gamma plus lipopolysaccharide was significantly decreased in hypoxia, due to a decrease in the concentration of O(2) as a substrate. In contrast, the level of NO production in hypoxia was almost the same as that in normoxia when the cells were stimulated by IL-1beta. In addition, cGMP increased in response to IL-1beta in hypoxia to a level comparable to that in normoxia. Thus, it seems that the IL-1beta-induced expression of iNOS is up-regulated in hypoxia to compensate for a decrease in the enzyme activity due to the lower availability of O(2) as a substrate, and consequently a sufficient amount of NO is produced to elevate cGMP to an adequate level. In addition, the IL-1beta-induced synthesis of tetrahydrobiopterin, a cofactor for iNOS, was also greatly stimulated by hypoxia in VSMC.     

Mechanism of salidroside relieving the acute hypoxia-induced myocardial injury through the PI3K/Akt pathway

ObjectiveThe objective was to investigate the anti-inflammatory effects of salidroside through the PI3K/Akt signaling pathway and its protective effects on acute hypoxia-induced myocardial injury in rats.MethodsA total of 24 healthy Sprague-Dawley male rats were selected as the experimental subjects. All rats were divided into 4 groups by using the random number table method, with 6 rats in each group. The groups included the normal control group, the salidroside group, the hypobaric hypoxia group, and the hypobaric hypoxia + salidroside group. Rats in the salidroside group were fed in the original animal laboratory and were intragastrically administered with salidroside every morning at a dosage of 35 mg/kg. Rats in the normal control group were intragastrically administered with an equal dosage of saline. Rats in the hypobaric hypoxia + salidroside group were intragastrically administered with salidroside every morning at a dosage of 35 mg/kg, who were fed in the hypoxic experiment module for animals. The altitude was increased to 4000 m, and the rats were kept in the module for 24 h. Rats in the hypobaric hypoxia group were intragastrically administered with an equal dosage of saline in the same environment, and the altitude was increased to 4000 m after administration. Parameters of blood gas analysis, histopathological changes in cardiac tissues, cardiac indexes, and inflammatory factors IL-6 and TNF-α levels of rats in groups were compared.Results1. The cardiac indexes of rats in groups were compared. The differences between the hypobaric hypoxia group and the hypobaric hypoxia + salidroside group were statistically significant (P < 0.05). 2. The results of blood gas analysis of rats in groups were compared. The differences between the hypobaric hypoxia group and the hypobaric hypoxia + salidroside group were significantly different (P < 0.05). 3. In the hypobaric hypoxia group, the myocardial cells of rats were arranged disorderly and shaped differently, with cases such as edema, degeneration, necrosis, nucleus pyknosis, and massive infiltration of inflammatory cells. In the hypobaric hypoxia + salidroside group, the above-mentioned pathological changes in myocardial cells were relieved. 4. Compared with the hypobaric hypoxia group, in the hypobaric hypoxia + salidroside group, the concentrations of IL-6 and TNF-α in rats decreased apparently, and the differences were statistically significant (P < 0.05).ConclusionSalidroside had the repairing and protective effects on the hypobaric hypoxia-induced myocardial injuries in rats. The application of salidroside could reduce the inflammatory responses of rats with hypobaric hypoxia-induced myocardial injuries through PI3K/Akt signaling pathway, thereby protecting the myocardial cells.     

模拟高原环境下高原肺水肿大鼠模型的建立

目的在人工实验舱模拟高原环境下,探讨建立高原肺水肿大鼠模型的条件。方法 Wistar大鼠,雌雄各半,随机分为5组:空白对照组、低氧24 h组、低氧48 h组、低氧72 h组、低氧7 d组,测定大鼠肺组织含水量,肺组织中TNF-α、IL-6含量及病理改变。结果与正常对照组相比,低氧24、48、72 h组大鼠肺组织含水量依次为(81.58±0.86)%、(82.13±0.57)%、(82.21±0.88)%,高于正常对照组(78.72±0.52)%,肺组织中IL-6依次为(329.30±133.58)、(323.92±127.42)、(506.29±197.19)pg/mL,TNF-α依次(221.08±20.26)、(208.05±20.33)、(244.63±51.53)pg/mL,高于正常对照组IL-6(187.26±69.49)pg/mL,TNF-α为(91.81±22.24)pg/mL。低氧7d组肺组织含水量(81.47±0.65)%、肺组织中IL-6(241.33±83.60)pg/mL、TNF-α(109.99±31.98)pg/mL,均显著低于低氧72h组,病理学结果显示72h组肺组织有炎性细胞浸润,肺泡壁有明显的充血和水肿。结论模拟海拔5000 m环境,建立大鼠肺水肿模型的较好的时间为72 h。     

Regulation of IL-1beta and IL-8 production by mu-, delta-opiate receptors agonists in vitro

The beta-endorphin 10(-7-)-10(-11) M in LPS (lypopolisaccharide) presence and in spontaneous cultures promoted the IL-1beta production in mixed leukocyte fraction. LPS-induced IL-8 production in leukocyte fraction was inhibited by beta-endorphin 10(-7), 10(-11) M. The enchasing effect of beta-endorphin on IL-1beta production was not blocked by naloxone and naltrindole. The inhibitory effect of beta-endorphin on IL-8 production was blocked by naloxone and naltrindole. In mononuclear and neutrophile fractions beta-endorphin and delta-agonist DADLE enchased IL-1beta production in spontaneous and LPS-stimulating cultures, when IL-8 production inhibited beta-endorphin and delta-agonist DADLE only in LPS presence. No effect of mu-agonist DAGO were observed on IL-1beta production, whereas LPS-induced IL-8 secretion in neutrophile fraction inhibited by DAGO.     

Hypoxia increases production of interleukin-1 and tumor necrosis factor by human mononuclear cells

Exposure to hypoxia (PO2 = 9 +/- 1 torr) increased human peripheral blood mononuclear cell production and secretion of interleukin-1 (IL-1)alpha, IL-1 beta, and tumor necrosis factor (TNF) percent of control = 190% for IL-1 alpha, p = 0.014; 219% for IL-1 beta, p = 0.014; and 243% for TNF, p = 0.037) following treatment with endotoxin (1 ng/ml). Hypoxia potentiated the increased production of these inflammatory cytokines at subthreshold levels of endotoxin with potentiation increasing at lower O2 concentrations. Hypoxia also increased cytokine production induced by the tumor promoter phorbol myristate acetate, suggesting a generalized biologic response. We conclude that hypoxia increases IL-1 and TNF production and speculate that this mechanism aggravates a variety of pathologic conditions involving endotoxin such as adult respiratory distress syndrome (ARDS), multiple organ failure, and septic shock.     

Differential modulation of interleukin-6 expression by interleukin-1beta in neuronal and glial cultures

We analysed the specific effects of IL-1beta immunoneutralization on the expression of IL-6 in different pure cultures of neurones and glia after both experimental subliminal hypoxia and recovery. Whereas the IL-1beta-deprivation signal induced a decrease in IL-6 expression and release of normoxic neurones, it provoked an increase in IL-6 protein in hypoxic neurones. Moreover, the direct correlation between IL-1beta and IL-6, observed in normal and recovering neuronal cultures, was reversed in hypoxic conditions. These reversals were not observed in glial cells, in which IL-1beta immunosuppression led to a decrease in IL-6 under all conditions considered. In conclusion, the IL-1beta modulates IL-6 in different ways according to the ambient physiological or pathological conditions, and also acts via different mechanisms, depending on the cellular phenotype.     

Transient hypobaric hypoxia improves spatial orientation in young rats

To achieve a better understanding of learning and declarative memory under mild transient stress, we investigated the effect of brief hypobaric hypoxia on spatial orientation in rats. Young male Wistar rats aged 30 days were exposed for 60 min to hypobaric hypoxia, simulating an altitude of 7,000 m (23,000 ft) either shortly prior to attempting or after mastering an allothetic navigation task in the Morris water maze with a submerged platform. The post-hypoxic group performed significantly better in the navigation task than the control animals (the mean difference in escape latencies was 11 seconds; P=0.0033, two-way ANOVA with repeated measures, group x session). The experimental group also achieved a remarkably higher search efficiency (calculated as a percentage of successful trials per session), especially during the first four days following hypoxic stress (P=0.0018). During the subsequent training, the post-hypoxic group performed better than the control animals, whilst the efficiency levels of both groups progressively converged. Spatial memory retention and recall of well-trained rats were not affected by the transient hypobaric hypoxia. These results indicate that brief hypobaric hypoxia enhances rats' spatial orientation. Our findings are consistent with several studies, which also suggested that mild transient stress improves learning.     

Simulation of long-haul flights in humans: prolonged mild hypoxia does not alter the circadian time structure of plasma testosterone and gonadotrophins

Mild hypobaric hypoxia caused by pressurisation may contribute to alter rhythmicity after long-haul flights, independently of the number of time zones crossed. In this controlled crossover study, we assessed the effects of two levels of hypoxia, equivalent to 8000 ft and 12,000 ft above sea level, on the rhythm of plasma concentrations of three hormones: testosterone, LH, and FSH. A hypoxia-induced decrease in LH and FSH has often been reported during mountaineering while testosterone is considered a marker of fatigue. Sixteen healthy male volunteers, aged 23-39 years, spent 8 h in a hypobaric chamber (08:00-16:30), simulating conditions at 8000 ft. This was followed by an additional 8 h four weeks later, simulating conditions at 12,000 ft. Plasma hormones were assayed every 2 h over two 24-h cycles (control and hypoxic-exposure cycles). We found no significant effects of hypoxia on the circadian profile of the gonadal axis hormones and, therefore, conclude that these hormones do not serve as valuable markers of post-flight alterations of the circadian system in human.