piperidines and Hyperoxia

The cholinergic anti-inflammatory pathway is a neural mechanism that suppresses the innate inflammatory response and controls inflammation employing acetylcholine as the key endogenous mediator. In this study, we investigated the effects of the cholinergic agonists, physostigmine and donepezil, on neurodegeneration, inflammation and oxidative stress during oxygen toxicity in the developing rat brain. The aim of this study was to investigate the level of neurodegeneration, expression of proinflammatory cytokines, glutathione and lipid peroxidation after hyperoxia and treatment with the acetylcholinesterase (AChE) inhibitors, physostigmine and donepezil in the brain of neonatal rats. Six-day-old Wistar rats were exposed to 80% oxygen for 12-24 h and received 100 μg/kg physostigmine or 200 μg/kg donepezil intraperitoneally. Sex-matched littermates kept in room air and injected with normal saline, physostigmine or donepezil served as controls. Treatment with both inhibitors significantly reduced hyperoxia-triggered activity of AChE, neural cell death and the upregulation of the proinflammatory cytokines IL-1β and TNF-α in the immature rat brain on the mRNA and protein level. In parallel, hyperoxia-induced oxidative stress was reduced by concomitant physostigmine and donepezil administration, as shown by an increased reduced/oxidized glutathione ratio and attenuated malondialdehyde levels, as a sign of lipid peroxidation. Our results suggest that a single treatment with AChE inhibitors at the beginning of hyperoxia attenuated the detrimental effects of oxygen toxicity in the developing brain and may pave the way for AChE inhibitors, which are currently used for the treatment of Alzheimer's disease, as potential candidates for adjunctive neuroprotective therapies to the immature brain.

Topics: Animals; Animals, Newborn; Blotting, Western; Brain; Cholinesterase Inhibitors; Disease Models, Animal; Donepezil; Female; Hyperoxia; Immunohistochemistry; Indans; Male; Nerve Degeneration; Oxidative Stress; Oxygen; Physostigmine; Piperidines; Rats; Rats, Wistar; Real-Time Polymerase Chain Reaction

Hyperoxaemia depresses the output of peripheral and central chemoreceptors. Patients treated with opioids often receive supplemental oxygen to avert possible decreases in oxygen saturation (Sp(O2)).We examined the effect of a single dose of remifentanil in healthy volunteers inhaling room air vs air enriched with 50% oxygen.. Twenty healthy volunteers received i.v. 50 mg remifentanil (infused over 60 s) at anormoxic (N) or hyperoxic (FI(O2) 0.5, H) background on separate occasions. Minute ventilation (Vi), respiratory rate (RR), end-tidal PC(O2), and Sp(O2) were collected on a breath to-breath basis. The occurrence of apnoea was recorded.. During normoxia, remifentanil decreased Vi from 7.4 (1.3) [mean (SD)] to 2.2 (1.2) litre min 21 (P,0.01), and during hyperoxia from 7.9 (1.0) to 1.2 (1.2) litre min 21 (P,0.01; H vs N: P,0.001). RR decreased from 13.1 (2.9) to 6.1 (2.8) bpm during N (P,0.01) and from 13.2 (3.0) to 3.6 (4.0) bpm during H (P,0.01; H vs N: P,0.01). During normoxia, Sp(O2) decreased from 98.4 (1.5) to 88.6 (6.7)% (P,0.01), while during hyperoxia, Sp(O2) changed from 99.7 (0.7) to 98.7 (1.0)% (P,0.001). Apnoea developed in two subjects during normoxia and 10 during hyperoxia.. Respiratory depression from remifentanil is more pronounced in hyperoxia than normoxia as determined from minute ventilation, end-tidal PC(O2), and RR. During hyperoxia, respiratory depression may be masked when measuring Sp(O2) as pulse oximetry remains in normal values during the first minutes of respiratory depression.

Topics: Adolescent; Adult; Analgesics, Opioid; False Negative Reactions; Female; Humans; Hyperoxia; Male; Monitoring, Physiologic; Oximetry; Oxygen; Oxygen Inhalation Therapy; Piperidines; Remifentanil; Respiratory Insufficiency; Respiratory Rate; Young Adult

Oxygen is a pulmonary vasodilator, but data suggest high O(2) concentrations impede that response. We previously reported 24 h of 100% O(2) increased phosphodiesterase 5 (PDE5) activity in fetal pulmonary artery smooth muscle cells (FPASMC) and in ventilated neonatal lambs. PDE5 degrades cyclic GMP (cGMP) and inhibits nitric oxide (NO)-mediated cGMP-dependent vasorelaxation. We sought to determine the mechanism by which hyperoxia initiates reactive oxygen species (ROS) production and regulates PDE5.. Thirty minutes of hyperoxia increased mitochondrial ROS versus normoxia (30.3±1.7% vs. 21.1±2.8%), but had no effect on cytosolic ROS, measured by roGFP, a ratiometric protein thiol redox sensor. Hyperoxia increased PDE5 activity (220±39%) and decreased cGMP responsiveness to NO (37±17%). Mitochondrial catalase overexpression attenuated hyperoxia-induced mitochondrial roGFP oxidation, compared to FPASMC infected with empty adenoviral vector (50±3% of control) or mitochondrial superoxide dismutase. MitoTEMPO, mitochondrial catalase, and DT-3, a cGMP-dependent protein kinase I alpha inhibitor, decreased PDE5 activity (32±13%, 26±21%, and 63±10% of control, respectively), and restored cGMP responsiveness to NO (147±16%,172±29%, and 189±43% of control, respectively). C57Bl6 mice exposed to 90%-100% O(2) for 45 min±mechanical ventilation had increased PA PDE5 activity (206±39% and 235±75%, respectively).. This is the first description that hyperoxia induces ROS in the mitochondrial matrix prior to the cytosol. Our results indicate that short hyperoxia exposures can produce significant changes in critical cellular signaling pathways.. These results indicate that mitochondrial matrix oxidant signals generated during hyperoxia, specifically H(2)O(2), activate PDE5 in a cGMP-dependent protein kinase-dependent manner in pulmonary vascular smooth muscle cells.

Topics: Animals; Antioxidants; Catalase; Cell Hypoxia; Cells, Cultured; Cyclic GMP; Cyclic GMP-Dependent Protein Kinase Type I; Cyclic GMP-Dependent Protein Kinases; Cyclic Nucleotide Phosphodiesterases, Type 5; Enzyme Activation; Fetus; Hydrogen Peroxide; Hyperoxia; Male; Mice; Mice, Inbred C57BL; Mitochondria, Muscle; Muscle, Smooth, Vascular; Myocytes, Smooth Muscle; Nitric Oxide; Organophosphorus Compounds; Oxidation-Reduction; Phosphodiesterase 5 Inhibitors; Piperazines; Piperidines; Pulmonary Artery; Purines; Sheep, Domestic; Sildenafil Citrate; Sulfones; Superoxide Dismutase

Life-threatening side effects such as profound bradypnea or apnea and variable upper airway obstruction limit the use of opioids for analgesia. It is yet unclear which sites containing μ-opioid receptors (μORs) within the intact in vivo mammalian respiratory control network are responsible. The purpose of this study was 1) to define the pontine region in which μOR agonists produce bradypnea and 2) to determine whether antagonism of those μORs reverses bradypnea produced by intravenous remifentanil (remi; 0.1-1.0 μg·kg(-1)·min(-1)). The effects of microinjections of agonist [D-Ala(2),N-Me-Phe(4),Gly-ol(5)]-enkephalin (DAMGO; 100 μM) and antagonist naloxone (NAL; 100 μM) into the dorsal rostral pons on the phrenic neurogram were studied in a decerebrate, vagotomized, ventilated, paralyzed canine preparation during hyperoxia. A 1-mm grid pattern of microinjections was used. The DAMGO-sensitive region extended from 5 to 7 mm lateral of midline and from 0 to 2 mm caudal of the inferior colliculus at a depth of 3-4 mm. During remi-induced bradypnea (~72% reduction in fictive breathing rate) NAL microinjections (~500 nl each) within the region defined by the DAMGO protocol were able to reverse bradypnea by 47% (SD 48.0%) per microinjection, with 13 of 84 microinjections producing complete reversal. Histological examination of fluorescent microsphere injections shows that the sensitive region corresponds to the parabrachial/Kölliker-Fuse complex.

Topics: Analgesics, Opioid; Anesthetics, Intravenous; Animals; Brain Mapping; Diaphragm; Dogs; Enkephalin, Ala(2)-MePhe(4)-Gly(5)-; Hyperoxia; Infusions, Intravenous; Naloxone; Narcotic Antagonists; Phrenic Nerve; Piperidines; Pons; Receptors, Opioid, mu; Remifentanil; Respiratory Rate

To investigate whether nitric oxide (NO) regulates retinal circulation during and after induction of hyperoxia in cats.. Hyperoxia was induced for 10 minutes with 100% oxygen. The vessel diameter and blood velocity were measured simultaneously in second-order retinal arterioles by laser Doppler velocimetry; the retinal blood flow (RBF) and wall shear rate (WSR) were calculated during and after hyperoxia. PBS, L-NAME, D-NAME, BQ-123, BQ-788, and 7-nitroindazole (7-NI) were administered before induction of hyperoxia.. In the PBS group, vessel diameter, blood velocity, and RBF decreased during hyperoxia and returned to baseline within 10 minutes after hyperoxia ended. WSR decreased transiently and then returned to baseline by the delayed constriction of retinal arterioles during hyperoxia. In the l-NAME and BQ-788 groups, the decreases in RBF during hyperoxia did not differ from those in the PBS group. However, the recovery of RBF after hyperoxia ended was attenuated significantly until 20 minutes after hyperoxia ended in both groups compared with the PBS group (P < 0.05). In the BQ-123 group, the intravitreous injection of BQ-123 caused less reduction of blood velocity and RBF during hyperoxia compared with that in the PBS group, whereas the RBF immediately returned to baseline after hyperoxia. D-NAME and 7-NI did not affect RBF in response to hyperoxia.. The current results indicate that NO contributes to RBF recovery after hyperoxia, probably through the action of endothelial NOS via the ETB receptor in the vascular endothelium of the retinal arterioles, suggesting that the RBF response to hyperoxia may be used to evaluate the endothelial function of the retinal arterioles.

Topics: Animals; Antihypertensive Agents; Blood Flow Velocity; Blood Pressure; Cats; Enzyme Inhibitors; Female; Heart Rate; Hydrogen-Ion Concentration; Hyperoxia; Indazoles; Injections; Laser-Doppler Flowmetry; Male; NG-Nitroarginine Methyl Ester; Nitric Oxide; Oligopeptides; Oxygen; Partial Pressure; Peptides, Cyclic; Piperidines; Regional Blood Flow; Retinal Vessels; Vitreous Body

Topics: Animals; Bemegride; Carbachol; Epinephrine; Glutethimide; Hyperoxia; Inert Gas Narcosis; Methamphetamine; Nitrogen; Oxygen; Pentylenetetrazole; Phenacetin; Physostigmine; Piperidines; Rats; Scopolamine