Your search keyword '"Caputa M"' showing total 10 results

1. Deferoxamine improves antioxidative protection in the brain of neonatal rats: The role of anoxia and body temperature.

Author

Kletkiewicz H, Nowakowska A, Siejka A, Mila-Kierzenkowska C, Woźniak A, Caputa M, and Rogalska J

Subjects

Animals, Animals, Newborn, Catalase metabolism, Female, Glutathione Peroxidase metabolism, Male, Malondialdehyde metabolism, Rats, Rats, Wistar, Superoxide Dismutase-1 metabolism, Antioxidants metabolism, Body Temperature, Brain enzymology, Deferoxamine administration & dosage, Hypoxia enzymology, Siderophores administration & dosage

Abstract

After hypoxic-ischemic insult iron deposited in the brain catalyzes formation of reactive oxygen species. Newborn rats, showing reduced physiological body temperature and their hyperthermic counterparts injected with deferoxamine (DF), a chelator of iron, are protected both against iron-mediated neurotoxicity and against depletion of low-molecular antioxidants after perinatal asphyxia. Therefore, we decided to study the effects of DF on activity of antioxidant enzymes (superoxide dismutase-SOD, glutathione peroxidase-GPx and catalase-CAT) in the brain of rats exposed neonatally to a critical anoxia at body temperatures elevated to 39°C. Perinatal anoxia under hyperthermic conditions intensified oxidative stress and depleted the pool of antioxidant enzymes. Both the depletion of antioxidants and lipid peroxidation were prevented by post-anoxic DF injection. The present paper evidenced that deferoxamine may act by recovering of SOD, GPx and CAT activity to reduce anoxia-induced oxidative stress., (Copyright © 2016 Elsevier Ireland Ltd. All rights reserved.)

Published

2016

2. Effects of body temperature on post-anoxic oxidative stress from the perspective of postnatal physiological adaptive processes in rats.

Author

Kletkiewicz H, Rogalska J, Nowakowska A, Wozniak A, Mila-Kierzenkowska C, and Caputa M

Subjects

Adaptation, Physiological, Animals, Animals, Newborn, Catalase metabolism, Female, Glutathione Peroxidase metabolism, Male, Malondialdehyde metabolism, Oxidative Stress, Rats, Wistar, Superoxide Dismutase metabolism, Body Temperature, Brain metabolism, Hypoxia metabolism

Abstract

It is well known that decrease in body temperature provides protection to newborns subjected to anoxia/ischemia. We hypothesized that the normal body temperature of 33°C in neonatal rats (4°C below normal body temperature in adults) is in fact a preadaptation to protect CNS from anoxia and further reductions as well as elevations in temperature may be counterproductive. Our experiments aimed to examine the effect of changes in body temperature on oxidative stress development in newborn rats exposed to anoxia. Two-day-old Wistar rats were divided into 4 temperature groups: i. hypothermic at body temperature of 31°C, ii. maintaining physiological neonatal body temperature of 33°C, iii. forced to maintain hyperthermic temperature of 37°C, and i.v. forced to maintain hyperthermic temperature of 39°C. The temperature was controlled starting 15 minutes before and afterword during 10 minutes of anoxia as well as for 2 hours post-anoxia. Cerebral concentrations of lipid peroxidation products malondialdehyde (MDA) and conjugated dienes (CD) and the activities of antioxidant enzymes had been determined post mortem: immediately after anoxia was finished and 3, 7, and 14 days later. There were no post-anoxic changes in the concentration of MDA, CD and in antioxidant enzymes activity in newborn rats kept at their physiological body temperature of 33°C. In contrast, perinatal anoxia at body temperature elevated to 37°C or 39°C as well as under hypothermic conditions (31°C) intensified post-anoxic oxidative stress and depleted the antioxidant pool. Overall, these findings suggest that elevated body temperature (hyperthermia or fever), as well as exceeding cooling beyond the physiological level of body temperature of newborn rats, may extend perinatal anoxia-induced brain lesions. Our findings provide new insights into the role of body temperature in anoxic insult in vivo.

Published

2016

3. Deferoxamine prevents cerebral glutathione and vitamin E depletions in asphyxiated neonatal rats: role of body temperature.

Author

Kletkiewicz H, Nowakowska A, Siejka A, Mila-Kierzenkowska C, Woźniak A, Caputa M, and Rogalska J

Subjects

Animals, Animals, Newborn, Brain drug effects, Deferoxamine pharmacology, Female, Hyperthermia, Induced, Male, Rats, Rats, Wistar, Body Temperature physiology, Brain metabolism, Glutathione metabolism, Hypoxia metabolism, Malondialdehyde metabolism, Vitamin E metabolism

Abstract

Hypoxic-ischaemic brain injury involves increased oxidative stress. In asphyxiated newborns iron deposited in the brain catalyses formation of reactive oxygen species. Glutathione (GSH) and vitamin E are key factors protecting cells against such agents. Our previous investigation has demonstrated that newborn rats, showing physiological low body temperature as well as their hyperthermic counterparts injected with deferoxamine (DF) are protected against iron-mediated, delayed neurotoxicity of perinatal asphyxia. Therefore, we decided to study the effects of body temperature and DF on the antioxidant status of the brain in rats exposed neonatally to critical anoxia. Two-day-old newborn rats were exposed to anoxia in 100% nitrogen atmosphere for 10 min. Rectal temperature was kept at 33 °C (physiological to rat neonates), or elevated to the level typical of healthy adult rats (37 °C), or of febrile adult rats (39 °C). Half of the rats exposed to anoxia under extremely hyperthermic conditions (39 °C) were injected with DF. Cerebral concentrations of malondialdehyde (MDA, lipid peroxidation marker) and the levels of GSH and vitamin E were determined post-mortem, (1) immediately after anoxia, (2) 3 days, (3) 7 days, and (4) 2 weeks after anoxia. There were no post-anoxic changes in MDA, GSH and vitamin E concentrations in newborn rats kept at body temperature of 33 °C. In contrast, perinatal anoxia at elevated body temperatures intensified oxidative stress and depleted the antioxidant pool in a temperature-dependent manner. Both the depletion of antioxidants and lipid peroxidation were prevented by post-anoxic DF injection. The data support the idea that hyperthermia may extend perinatal anoxia-induced brain lesions.

Published

2016

4. Comments on point:counterpoint: humans do/do not demonstrate selective brain cooling during hyperthermia.

Author

Crandall CG, Brothers RM, Zhang R, Brengelmann GL, Covaciu L, Jay O, Cramer MN, Fuller A, Maloney SK, Mitchell D, Romanovsky AA, Caputa M, Nordström CH, Reinstrup P, Nishiyasu T, Fujii N, Hayashi K, Tsuji B, Flouris AD, Cheung SS, Vagula MC, Nelatury CF, Choi JH, Shrivastava D, Gordon CJ, and Vaughan JT

Subjects

Animals, Cold Temperature, Humans, Body Temperature, Body Temperature Regulation, Brain physiopathology, Cerebrovascular Circulation, Fever physiopathology, Models, Neurological

Published

2011

5. Stress-induced behaviour in adult and old rats: effects of neonatal asphyxia, body temperature and chelation of iron.

Author

Rogalska J, Caputa M, Wentowska K, and Nowakowska A

Subjects

Age Factors, Animals, Animals, Newborn, Asphyxia metabolism, Brain metabolism, Female, Male, Maze Learning, Motor Activity physiology, Rats, Rats, Wistar, Stress, Physiological metabolism, Asphyxia physiopathology, Behavior, Animal physiology, Body Temperature physiology, Iron metabolism, Stress, Physiological physiopathology

Abstract

Perinatal asphyxia in mammals leads to iron accumulation in the brain, which results in delayed neurobehavioural disturbances, including impaired learning and abnormal alertness over their entire life span. The aim of this investigation was to verify our hypothesis that newborn rats, showing reduced normal body temperature, are protected against neurotoxicity of the asphyxia up to senescence. Alertness was studied in adult and old male Wistar rats after exposure to critical neonatal anoxia: (i) at physiological neonatal body temperature of 33 degrees C, (ii) at body temperature elevated to 37 degrees C, or (iii) at body temperature elevated to 39 degrees C (the thermal conditions remained unchanged both during anoxia and for 2 h postanoxia). To elucidate the effect of iron-dependent postanoxic oxidative damage to the brain, half of the group (iii) was injected with deferoxamine, a chelator of iron. Postanoxic behavioural disturbances were recorded in open-field, elevated plus-maze, and sudden silence tests when the rats reached the age of 12 and 24 months. Open-field stress-induced motor activity was reduced in rats subjected to neonatal anoxia under hyperthermic conditions. In contrast, these rats were hyperactive in the plus-maze test. Both the plus-maze and sudden silence tests show reduced alertness of these rats to external stimuli signalling potential dangers. The behavioural disturbances were prevented by body temperature of 33 degrees C and by administration of deferoxamine.

Published

2006

6. Effect of neonatal body temperature on postanoxic, potentially neurotoxic iron accumulation in the rat brain.

Author

Rogalska J, Danielisova V, and Caputa M

Subjects

3,3'-Diaminobenzidine, Analysis of Variance, Animals, Animals, Newborn, Brain drug effects, Brain pathology, Cell Count methods, Deferoxamine administration & dosage, Hypoxia therapy, Iron toxicity, Rats, Rats, Wistar, Siderophores administration & dosage, Body Temperature physiology, Brain metabolism, Hypoxia metabolism, Iron metabolism

Abstract

In asphyxiated newborns iron, released from heme and ferritin and deposited in the brain, contributes to neurodegeneration. Because hypothermia provides neuroprotection, newborn mammals, showing spontaneously reduced body temperature, might avoid the iron-mediated neurotoxicity. Therefore, we decided to study the effects of body temperature and chelation of iron with deferoxamine on iron accumulation in the brain of three weeks old rats exposed neonatally to a critical anoxia. At the age of two days, newborn rats were exposed to anoxia in 100% nitrogen atmosphere. Rectal temperature was kept at 33 degrees C (typical of the rat neonates), or elevated to a level typical of febrile (39 degrees C) adults. Control rats were exposed to atmospheric air in the respective thermal conditions. Half of the rats exposed to anoxia under hyperthermic conditions were injected with deferoxamine (DF), immediately after anoxia and 24 h later. Regional changes in cerebral iron deposition were examined in the frontal cortex, the hippocampus and the striatum, using iron histochemistry, when the rats reached the age of three weeks. Increased iron staining was found in neurons of each of the three cerebral regions in rats exposed to neonatal anoxia under hyperthermic conditions and the iron accumulation was prevented by postanoxic DF injection. In conclusion, febrile body temperature amplifies cerebral hyperferremia, which might induce neurodegenerative disturbances in the brain. On the other hand, a protection against the brain hyperferremia can be achieved by both the reduced physiological neonatal body temperature and by postasphyxic DF administration.

Published

2006

7. Stress-induced behaviour in juvenile rats: effects of neonatal asphyxia, body temperature and chelation of iron.

Author

Rogalska J, Caputa M, Wentowska K, and Nowakowska A

Subjects

Analysis of Variance, Animals, Animals, Newborn, Behavior, Animal, Deferoxamine pharmacology, Exploratory Behavior drug effects, Exploratory Behavior physiology, Iron Chelating Agents pharmacology, Motor Activity drug effects, Rats, Rats, Wistar, Stress, Physiological metabolism, Telemetry instrumentation, Time Factors, Asphyxia etiology, Body Temperature physiology, Iron metabolism, Motor Activity physiology, Stress, Physiological physiopathology

Abstract

Newborn mammals, showing reduced normal body temperature, might be protected against iron-mediated, delayed neurotoxicity of perinatal asphyxia. Therefore, we investigated the effects of (1) neonatal body temperature and neonatal critical anoxia as well as (2) postanoxic chelation of iron with deferoxamine, on open-field stress-induced behaviour in juvenile rats. The third aim of this study was to compare (after the above-mentioned treatments) circadian changes in spontaneous motor activity and body temperature in juvenile rats permanently protected from any stress. Neonatal anoxia at body temperature adjusted (both during anoxia and 2 h reoxygenation) to a level typical of healthy (37 degrees C) or febrile (39 degrees C) adults led to the stress-induced hyperactivity in juvenile (5-45 days old) rats. Both normal neonatal body temperature of 33 degrees C and chelation of iron prevented the hyperactivity in rats. Neither neonatal body temperature nor neonatal anoxia affected spontaneous motor activity or body temperature of juvenile rats, recorded in their home-cages with implantable transmitters. Circadian rhythmicity was also undisturbed. Presented data support the hypothesis that physiologically reduced neonatal body temperature can provide a protection against iron-mediated postanoxic disturbances of behavioural stress responses in juvenile rats.

Published

2004

8. Effect of temperature on postanoxic, potentially neurotoxic changes of plasma pH and free iron level in newborn rats.

Author

Caputa M, Rogalska J, and Nowakowska A

Subjects

Acidosis etiology, Acidosis metabolism, Acidosis physiopathology, Animals, Asphyxia Neonatorum physiopathology, Asphyxia Neonatorum therapy, Humans, Hydrogen-Ion Concentration, Hyperthermia, Induced, Hypothermia, Induced, Hypoxia, Brain pathology, Hypoxia, Brain physiopathology, Infant, Newborn, Nerve Degeneration physiopathology, Rats, Rats, Wistar, Animals, Newborn metabolism, Asphyxia Neonatorum metabolism, Blood metabolism, Body Temperature physiology, Hypoxia, Brain metabolism, Iron metabolism, Nerve Degeneration metabolism

Abstract

In asphyxiated newborns, iron, released from heme and ferritin and deposited in the brain, contributes to neurodegeneration. Because hypothermia provides neuroprotection, newborn mammals, showing reduced body temperature, might avoid iron-mediated neurotoxicity. However, hypothermia leads to acidosis, which induces hyperferremia. Therefore, we decided to study the effects of body temperature on plasma pH and iron levels in newborn rats exposed to a critical anoxia. Rectal temperature was kept at 33 degrees C (typical of neonates), reduced by 2 degrees C, or elevated to a level typical of healthy (37 degrees C) or febrile (39 degrees C) adults. Arterial blood samples were collected at 0, 10, 20, 30, and 120 min postanoxia. Control samples were obtained from normoxic, temperature-matched neonates. Anoxia tolerance time decreased progressively at rectal temperatures exceeding 33 degrees C. Neither pH nor plasma iron were significantly affected by anoxia at 33 degrees C. Although hypothermia (31 degrees C) resulted in acidosis in normoxic rats, both pH and iron levels were hardly influenced by anoxia. However, acidosis and hyperferremia, proportional to body temperature, developed at 37 and 39 degrees C. In conclusion, reduced body temperature is likely to protect asphyxiated newborns against iron-mediated brain injury.

Published

2001

9. Brain cooling in diving seals.

Author

Odden A, Folkow LP, Caputa M, Hotvedt R, and Blix AS

Subjects

Animals, Bradycardia, Cold Temperature, Female, Heart Rate physiology, Male, Body Temperature physiology, Brain physiology, Diving physiology, Seals, Earless physiology

Published

1999

10. Effects of brain and trunk temperatures on exercise performance in goats.

Author

Caputa M, Feistkorn G, and Jessen C

Subjects

Animals, Energy Metabolism, Female, Goats, Kinetics, Organ Specificity, Blood Pressure, Body Temperature, Brain physiology, Heart Rate, Physical Exertion

Abstract

In 40 experiments on seven goats head and trunk temperatures were altered independently of each other and the effects on exercise performance on a treadmill (speed: 3 km/h, slope: 16%-20%) were observed. Brain temperature between 38.5 degrees C and 42.0 degrees C and trunk temperature between 39 degrees C and 43.5 degrees C did not reduce exercise performance or running time. Blood lactate concentration increased with rising brain and trunk temperatures, but did not exceed 13.1 mmol/l-1. Blood pressure and heart rate did not show any dependence on brain or trunk temperatures. Brain temperature between 42.0 degrees C and 42.9 degrees C shortened running time in 3 out of 12 experiments and reduced performance during shortlasting upward deviations of temperature. This suggests that in this species, the thermal safety limit to exercise is very close to that range of temperature which is likely to induce heat stroke.

Published

1986