27 research outputs found
Ultrastructural changes of the intracellular surfactant pool in a rat model of lung transplantation-related events
<p>Abstract</p> <p>Background</p> <p>Ischemia/reperfusion (I/R) injury, involved in primary graft dysfunction following lung transplantation, leads to inactivation of intra-alveolar surfactant which facilitates injury of the blood-air barrier. The alveolar epithelial type II cells (AE2 cells) synthesize, store and secrete surfactant; thus, an intracellular surfactant pool stored in lamellar bodies (Lb) can be distinguished from the intra-alveolar surfactant pool. The aim of this study was to investigate ultrastructural alterations of the intracellular surfactant pool in a model, mimicking transplantation-related procedures including flush perfusion, cold ischemia and reperfusion combined with mechanical ventilation.</p> <p>Methods</p> <p>Using design-based stereology at the light and electron microscopic level, number, surface area and mean volume of AE2 cells as well as number, size and total volume of Lb were determined in a group subjected to transplantation-related procedures including both I/R injury and mechanical ventilation (I/R group) and a control group.</p> <p>Results</p> <p>After I/R injury, the mean number of Lb per AE2 cell was significantly reduced compared to the control group, accompanied by a significant increase in the luminal surface area per AE2 cell in the I/R group. This increase in the luminal surface area correlated with the decrease in surface area of Lb per AE2. The number-weighted mean volume of Lb in the I/R group showed a tendency to increase.</p> <p>Conclusion</p> <p>We suggest that in this animal model the reduction of the number of Lb per AE2 cell is most likely due to stimulated exocytosis of Lb into the alveolar space. The loss of Lb is partly compensated by an increased size of Lb thus maintaining total volume of Lb per AE2 cell and lung. This mechanism counteracts at least in part the inactivation of the intra-alveolar surfactant.</p
IGL-1 solution reduces endoplasmic reticulum stress and apoptosis in rat liver transplantation
Injury due to cold ischemia reperfusion (I/R) is a major cause of primary graft non-function following liver transplantation. We postulated that I/R-induced cellular damage during liver transplantation might affect the secretory pathway, particularly at the endoplasmic reticulum (ER). We examined the involvement of ER stress in organ preservation, and compared cold storage in University of Wisconsin (UW) solution and in Institute Georges Lopez-1 (IGL-1) solution. In one group of rats, livers were preserved in UW solution for 8 h at 4 °C, and then orthotopic liver transplantation was performed according to Kamada's cuff technique. In another group, livers were preserved in IGL-1 solution. The effect of each preservation solution on the induction of ER stress, hepatic injury, mitochondrial damage and cell death was evaluated. As expected, we found increased ER stress after liver transplantation. IGL-1 solution significantly attenuated ER damage by reducing the activation of three pathways of unfolded protein response and their effector molecules caspase-12, C/EBP homologous protein-10, X-box-binding protein 1, tumor necrosis factor-associated factor 2 and eukaryotic translation initiation factor 2. This attenuation of ER stress was associated with a reduction in hepatic injury and cell death. Our results show that IGL-1 solution may be a useful means to circumvent excessive ER stress reactions associated with liver transplantation, and may optimize graft quality
Towards a Mathematical Theory of Cortical Micro-circuits
The theoretical setting of hierarchical Bayesian inference is gaining acceptance as a framework for understanding cortical computation. In this paper, we describe how Bayesian belief propagation in a spatio-temporal hierarchical model, called Hierarchical Temporal Memory (HTM), can lead to a mathematical model for cortical circuits. An HTM node is abstracted using a coincidence detector and a mixture of Markov chains. Bayesian belief propagation equations for such an HTM node define a set of functional constraints for a neuronal implementation. Anatomical data provide a contrasting set of organizational constraints. The combination of these two constraints suggests a theoretically derived interpretation for many anatomical and physiological features and predicts several others. We describe the pattern recognition capabilities of HTM networks and demonstrate the application of the derived circuits for modeling the subjective contour effect. We also discuss how the theory and the circuit can be extended to explain cortical features that are not explained by the current model and describe testable predictions that can be derived from the model
Oxidative stress evaluation of ischemia and reperfusion in kidneys under various degrees of hypothermia in rats
PURPOSE: To design an animal model of ischemia-reperfusion (I/R) in kidneys and evaluate the role that predetermined ranges of local hypothermia plays on markers of stress-oxydative as well as on histologic sections. METHODS: Twenty eight male rats Wistar, under general anesthesia, undergone right nephrectomy (G0, control group) followed by left kidney ischemia during 40 min. Four temperatures groups were designed, with seven animals randomized for each group: normothermic (G1, ±37oC), mild hypothermia (G2, 26oC), moderate hypothermia (G3, 15oC) and deep hypothermia (G4, 4oC). Left kidney temperature was assessed with an intraparenchymal probe. Left nephrectomy was performed after 240 min of reperfusion. After I/R a blood sample was obtained for f2-IP. Half of each kidney was sent to pathological evaluation and half to analyze CAT, SOD, TBARS, NO3, NO2. RESULTS: Histopathology showed that all kidneys under I/R were significantly more injured than the G0 (p<0.001). TBARS had increased levels in all I/R groups compared with the G0 (p<0.001). CAT had a significant difference (p<0.03) between G1 and G4. Finally, no difference was found on SOD, NO3, NO2 nor on f2-IP. CONCLUSION: This model of I/R was efficient to produce oxidative-stress in the kidney, showing that 4ºC offered significant decrease in free radicals production, although tissue protection was not observed
Iron chelators do not reduce cold-induced cell injury in the isolated perfused rat kidney model.
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48607.pdf (publisher's version ) (Open Access)BACKGROUND: In vitro, cold-induced injury is an important contributor to renal tubular cell damage. It is mediated by iron-dependent formation of reactive oxygen species and can be prevented by iron chelation. We studied whether iron chelators can prevent cold-induced damage in the isolated perfused rat kidney (IPK) model both after cold perfusion (CP) and after cold storage (CS). We hypothesized that in the CP model iron-dependent cold-induced injury is more pronounced, since oxygen is constantly provided. METHODS: The IPK was either flushed with University of Wisconsin (UW) solution and stored for 4, 18 or 24 h at 4 degrees C or perfused during 4 h at 4 degrees C with UW for machine perfusion. The iron chelators 2,2'-dipyridyl or desferal, or the negative control 4,4'-dipyridyl were added during the cold perfusion. Kidney function was measured during 2 h reperfusion at 37.5 degrees C and compared to a control group (without cold preservation). RESULTS: Compared to control perfusion, kidney function was decreased in all experimental protocols. glomerular filtration rate and FR(H2O) were significantly decreased, while FE(gluc) and FE(Na) were higher after 4 h CS and CP. After 4 h CP, also renal vascular resistance was increased. Addition of 2,2'-dipyridyl did not improve kidney function after either CS or CP. Prolonged periods of CS worsened kidney function. The addition of 2,2'-dipyridyl or desferal did not improve kidney function after longer periods of CS. CONCLUSIONS: Addition of an iron chelator to the preservation solution UW did not improve kidney function after both CS and CP. Iron chelation is not able to prevent cold-induced damage in the isolated perfused rat kidney
Iron chelation or anti-oxidants prevent renal cell damage in the rewarming phase after normoxic, but not hypoxic cold incubation.
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34571.pdf (publisher's version ) (Closed access)It has now been firmly established that, not only ischemia/reperfusion, but also cold itself causes damage during kidney transplantation. Iron chelators or anti-oxidants applied during the cold plus rewarming phase are able to prevent this damage. At present, it is unknown if these measures act only during the cold, or whether application during the rewarming phase also prevents damage. We aimed to study this after cold normoxic and hypoxic conditions. LLC-PK1 cells were incubated at 4 degrees C in Krebs-Henseleit buffer for 6 or 24h, followed by 18 or 6h rewarming, respectively. Cold preservation was performed under both normoxic (95% air/5% CO2) and hypoxic (95% N2/5% CO2) conditions. The iron chelator 2,2'-DPD (100 microM), anti-oxidants BHT (20 microM) or sibilinin (200 microM), and xanthine oxidase inhibitor allopurinol (100 microM) were added during either cold preservation plus rewarming, or rewarming alone. Cell damage was assessed by LDH release (n=3-9). Addition of 2,2'-DPD and BHT during cold hypoxia plus rewarming did, but during rewarming alone did not prevent cell damage. When added during rewarming after 6h cold normoxic incubation, BHT and 2,2'-DPD inhibited rewarming injury compared to control (p<0.05). Allopurinol did not prevent cell damage in any experimental set-up. Our data show that application of iron chelators or anti-oxidants during the rewarming phase protects cells after normoxic but not hypoxic incubation. Allopurinol had no effect. Since kidneys are hypoxic during transplantation, measures aimed at preventing cold-induced and rewarming injury should be taken during the cold
Preserved vascular reactivity of rat renal arteries after cold storage.
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57371.pdf (publisher's version ) (Closed access)In cultured renal tubular cells hypothermia results in cell damage caused by iron-dependent formation of reactive oxygen species. It is unknown whether cold preservation affects function of renal vessels. Rat renal arcuate arteries were stored in a physiological salt solution at 4 degrees C for 24h and compared to control arteries (not stored). To some of the stored arteries the iron chelator 2,2'-dipyridyl was added. Endothelium-independent vasoconstriction was assessed by cumulative concentration-response curves for potassium and phenylephrine in a small vessel myograph. Endothelium-independent vasodilation was assessed with sodium nitroprusside and endothelium-dependent vasodilation with histamine. Cold storage for 24h did not affect vascular reactivity of renal small arteries and no influence of the iron chelator was seen. Since 24h of cold storage considerable damages renal tubular cells both in vitro and after kidney transplantation, these results suggest that renal arteries are less sensitive to cold-induced damage than tubular cells
Hypothermia causes a marked injury to rat proximal tubular cells that is aggravated by all currently used preservation solutions.
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178493.pdf (publisher's version ) (Closed access)Cold preservation results in cell death via iron-dependent formation of reactive oxygen species, leading to apoptosis during rewarming. We aimed to study cold-induced damage (i.e., injury as a consequence of hypothermia itself and not cold ischemia) in proximal tubular cells (PTC) in various preservation solutions presently applied and to clarify the role of mitochondria in this injury. Primary cultures of rat PTC were incubated at 4 degrees C for 24 h in culture medium, UW, Euro-Collins or HTK solution with and without the iron chelator desferal and rewarmed at 37 degrees C in culture medium. Cell damage, morphology, and apoptosis were studied and mitochondrial membrane potential was assessed by fluorescence microscopy. Cold incubation of PTC in culture medium followed by rewarming caused marked cell damage compared to warm incubation alone (LDH release 39+/-10% vs. 1.6+/-0.3%). Cold-induced damage was aggravated in all preservation solutions (LDH release 85+/-2% for UW; similar in Euro-Collins and HTK). After rewarming, cells showed features suggestive for apoptosis. Desferal prevented cell injury in all solutions (e.g., 8+/-2% for UW). Mitochondrial membrane potential was lost during rewarming and this loss could also be inhibited by desferal. Trifluoperazine, which is known to inhibit mitochondrial permeability transition (MPT), was able to prevent cold-induced injury (LDH 85+/-5% vs. 12+/-2%). We conclude that cold-induced injury occurs in PTC and is aggravated by UW, Euro-Collins, and HTK solution. Iron-dependent MPT is suggested to play a role in this damage. Strategies to prevent cold-induced injury should aim at reducing the availability of "free" iron
GWAS of lifetime cannabis use reveals new risk loci, genetic overlap with psychiatric traits, and a causal influence of schizophrenia
Cannabis use is a heritable trait that has been associated with adverse mental health outcomes. In the largest genome-wide association study (GWAS) for lifetime cannabis use to date (N = 184,765), we identified eight genome-wide significant independent single nucleotide polymorphisms in six regions. All measured genetic variants combined explained 11% of the variance. Gene-based tests revealed 35 significant genes in 16 regions, and S-PrediXcan analyses showed that 21 genes had different expression levels for cannabis users versus nonusers. The strongest finding across the different analyses was CADM2, which has been associated with substance use and risk-taking. Significant genetic correlations were found with 14 of 25 tested substance use and mental health-related traits, including smoking, alcohol use, schizophrenia and risk-taking. Mendelian randomization analysis showed evidence for a causal positive influence of schizophrenia risk on cannabis use. Overall, our study provides new insights into the etiology of cannabis use and its relation with mental health