UMLS:C0011570 - FACTA Search

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Query: UMLS:C0011570 (depression)
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Mechanisms causing gradual recruitment of damaged cells in the penumbra zone around the core of a focal ischaemic lesion may encompass irregularly occurring depolarization waves of the spreading depression (SD) type, each leading to transient loading of cells with calcium. It has been speculated that, when elicited in an underperfused or otherwise energy-compromised tissue, such depolarization waves lead to cell damage. We assessed under what conditions the calcium transients during KCl-induced SDs are prolonged, and explored if marked prolongation of the transients leads to brain damage. Cerebral blood flow (CBF) was reduced by marked hypocapnia. Tissue oxygenation was reduced by arterial hypoxia, without or with unilateral carotid artery occlusion, or by occlusion of the carotid arteries in normoxic, anaesthetized rats. In all animals the DC potential and extracellular calcium concentration (Ca2+e) were measured before and during a series of SDs. The animals were recovered for histopathological assessment. Hypoxia alone (Pao2, 32.5 +/- 3.8 mmHg) increased mean and total depolarization times, but repeated SDs elicited over 1.7 (+/-0.4) h failed to induce cell damage. Unilateral carotid artery occlusion further prolonged the SD waves but, in spite of total depolarization times of up to 40 min during 2 h, only two out of seven animals showed damage, localized to caudoputamen and parietal cortex, as well as to the subiculum, CA1 and CA3 sectors of the hippocampus. Bilateral carotid artery occlusion was associated with the most pronounced prolongation of the DC potential shifts and Ca2+ transients, with total depolarization times of up to 70 min. In spite of this, only four out of 13 animals showed brain damage and in two of these the damage was contralateral. The results justify modification of the hypothesis stating that SD-like depolarizations in the perifocal penumbra zone per se is what leads to gradual recruitment of such tissues in the infarction process. It is suggested that additional factors are required, such as a larger reduction in CBF, or the proximity of cells at risk to necrotic tissue.
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PMID:Induced spreading depressions in energy-compromised neocortical tissue: calcium transients and histopathological correlates. 921 84

Forty-six patients who were exposed to sarin consulted our hospital because of darkness of vision, and ocular pain, vomiting, dyspnea and headaches on June 27 and 28, 1994. Eighteen patients were admitted and 4 of them were in the critical state. There were 6 features: 1) depression of plasma cholinesterase activity (17 of 18 patients, 94%), 2) hypokalemia (4/18, 22%), 3) depression of triglyceride (12/18, 67%), 4) hypocapnia (5/17, 29%), 5) partial pressure of oxygen (PaO2) <80 mmHg, or requirement of O2 inhalation (15/18, 83%), 6) white blood cells (WBC) >9,000 per mm3 (13/18, 72%). Seventeen patients were discharged from hospital, but one patient is still suffering from akinetic mutism after two years.
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PMID:Eighteen cases exposed to sarin in Matsumoto, Japan. 924 Apr 89

To elucidate the various actions of volatile anesthetics on respiratory activity and chemosensitivity, we have studied the activities of the respiration-related structures in the medulla of the in vitro brainstem-spinal cord preparation of the newborn rat. Halothane decreased respiratory burst frequency (fR), inspiratory duration (Ti), integrated ventral C4 root activity (integral of C4) and respiratory minute activity (RMA) in a concentration-dependent fashion. Bicuculline counteracted the depressive effect of halothane on fR, integral of C4, and RMA. Inspiratory neuronal activity recorded at the rostral ventrolateral medulla (RVL) corresponded to these changes. Activities of Pre-Inspiratory (Pre-I) neurons and expiratory neurons in the RVL were also inhibited by halothane. The C4 activity did not always correspond to Pre-I neurons' discharge. In this comparative study of three volatile anesthetics, the inhibitory effect on fR appeared to be greater with enflurane than with halothane or isoflurane. The reversal effects of bicuculline on decreases in fR, integral of C4, and RMA also seemed to be greater with enflurane than with halothane or isoflurane. Hypercapnia (pH 7.0) induced a significant increase in fR and RMA, and a significant decrease in Ti. Although halothane inhibited overall activities, chemo-responsiveness to hypercapnia changed similarly even during halothane application. Hypocapnia (pH 7.8) significantly decreased fR, and increased integral of C4 and Ti. Hypocapnia during halothane application also induced a significant decrease in fR and RMA. These results suggest that the modification of GABAA receptor-mediated neurotransmission is in part responsible for the respiratory depression by volatile anesthetics, affecting especially fR, integral of C4, and RMA. Low respiratory rate by enflurane is associated with GABAergic modification. Prolongation of Ti by enflurane, seen clinically, does not seem to be either central or GABAergic. These findings demonstrate the responsiveness to CO2 and the respiratory compensation mechanism via respiratory frequency in the isolated preparation. It is, furthermore, indicated that halothane preserves the central chemosensitivity while its concentration is high enough to reduce the respiratory activities.
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PMID:Effects of volatile anesthetics on respiratory activity and chemosensitivity in the isolated brainstem-spinal cord of the newborn rat. 961 6

Microinjections of carbachol into the pontine tegmentum of decerebrate cats have been used to study the mechanisms underlying the suppression of postural and respiratory motoneuronal activity during the resulting rapid eye movement (REM) sleep-like atonia. During REM sleep, distinct respiratory muscles are differentially affected; e.g., the activity of the diaphragm shows little suppression, whereas the activity of some upper airway muscles is quite strong. To determine the pattern of the carbachol-induced changes in the activity of different groups of upper airway motoneurons, we simultaneously recorded the efferent activity of the recurrent laryngeal nerve (RL), pharyngeal branch of the vagus nerve (Phar), and genioglossal branch of the hypoglossal (XII) and phrenic (Phr) nerves in 12 decerebrate, paralyzed, vagotomized, and artificially ventilated cats. Pontine carbachol caused a stereotyped suppression of the spontaneous activity that was significantly larger in Phar expiratory (to 8.3% of control) and XII inspiratory motoneurons (to 15%) than in Phr inspiratory (to 87%), RL inspiratory (to 79%), or RL expiratory motoneurons (to 72%). The suppression in upper airway motor output was significantly greater than the depression caused by a level of hypocapnia that reduced Phr activity as much as carbachol. We conclude that pontine carbachol evokes a stereotyped pattern of suppression of upper airway motor activity. Because carbachol evokes a state having many neurophysiological characteristics similar to those of REM sleep, it is likely that pontine cholinoceptive neurons have similar effects on the activity of upper airway motoneurons during both states.
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PMID:Differential suppression of upper airway motor activity during carbachol-induced, REM sleep-like atonia. 975 29

Listeria monocytogenes septicemia was diagnosed in a 6-day-old Thoroughbred foal. Primary clinical signs included fever, depression, diarrhea, and respiratory distress. Hematologic abnormalities included leukopenia, neutropenia, degenerative left shift, and hyperfibrinogenemia. Clinical chemistry and blood gas abnormalities included metabolic acidosis, hypoxemia, hypocapnia, hypoglycemia, and hyponatremia. Despite aggressive therapeutic intervention and intensive care, the foal died within 12 hours of admission. A postmortem examination was performed, and the primary gross lesion was bilaterally severe, focally extensive bronchopneumonia. Histopathology revealed severe subacute multifocal suppurative bronchopneumonia with necrotizing vasculitis and intralesional coccobacilli. Cultures of blood collected at admission and immediately prior to death were positive for L. monocytogenes, as were cultures obtained from lung and liver at necropsy. Immunohistochemical examination of formalin-fixed tissues revealed abundant intra- and extracellular L. monocytogenes antigen within the lung and intravascularly in multiple organs.
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PMID:Listeria monocytogenes septicemia in a Thoroughbred foal. 1073 Sep 52

We have developed a mathematical model of the regulation of ventilation that successfully simulates breathing in the awake as well as in sleeping states. In previous models, which were used to simulate Cheyne-Stokes breathing and respiration during sleep, the controller was only responsive to chemical stimuli, and allowed no ventilation at sub-normal carbon dioxide levels. The current model includes several new features. The chemical controller responds continuously to changes in P(CO(2)) with a lower sensitivity during hypocapnia than in the hypercapnic ranges. Hypoxia interacts multiplicatively with P(CO(2)) over the entire range of activity. The controller in the current model, besides the chemical drive, includes also a neural component. This neural drive increases and decreases as the level of alertness changes, and adds or subtracts from ventilation levels demanded by the chemical controller. The model also includes the effects of post-stimulus potentiation (PSP) and hypoxic ventilatory depression (HVD). While PSP eliminates apneas after a disturbance and also dampens the subsequent dynamics of the respiration, it is not a major factor in the damping of the response. Another finding is that HVD is destabilizing. The model is the first to reproduce results reported in conscious humans after hyperventilation and after acute and longer-term hypoxia. It also reproduces the effects of NREM sleep.
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PMID:Effects of neural drives on breathing in the awake state in humans. 1178 35

Although cardiorespiratory complications contribute to the high morbidity/mortality of familial dysautonomia (FD), the mechanisms remain unclear. We evaluated respiratory, cardiovascular, and cerebrovascular control by monitoring ventilation, end-tidal carbon dioxide (CO2-et), oxygen saturation, RR interval, blood pressure (BP), and midcerebral artery flow velocity (MCFV) during progressive isocapnic hypoxia, progressive hyperoxic hypercapnia, and during recovery from moderate hyperventilation (to simulate changes leading to respiratory arrest) in 22 subjects with FD and 23 matched control subjects. Subjects with FD had normal ventilation, higher CO2-et, lower oxygen saturation, lower RR interval, and higher BP. MCFV was also higher but depended on the higher baseline CO2-et. In the FD group, whereas hyperoxic hypercapnia induced normal cardiovascular and ventilatory responses, progressive hypoxia resulted in blunted increases in ventilation, paradoxical decreases in RR interval and BP, and lack of MCFV increase. Hyperventilation induced a longer hypocapnia-induced apneic period (51.5 +/- 9.9 versus 11.2 +/- 5.5 seconds, p < 0.008) with profound desaturation (to 75.8 +/- 3.5%), marked BP decrease, and RR interval increase. Subjects with FD develop central depression in response to even moderate hypoxia with lack of expected change in cerebral circulation, leading to hypotension, bradycardia, hypoventilation, and potentially respiratory arrest. Higher resting BP delays occurrence of syncope during hypoxia. Therapeutic measures preventing hypoxia/hypocapnia may correct cardiovascular accidents in patients with FD.
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PMID:Respiratory and cerebrovascular responses to hypoxia and hypercapnia in familial dysautonomia. 1240 29

The ventilatory response to several minutes of hypoxia consists of various time-dependent phenomena, some of which occur during hypoxia (e.g., short-term depression), whereas others appear on return to normoxia (e.g., posthypoxic frequency decline). Additional phenomena can be elicited by acute, intermittent hypoxia (e.g., progressive augmentation, long-term facilitation). Current data suggest that these phenomena originate centrally. We tested the hypothesis that carotid body afferent activity undergoes time-dependent modulation, consistent with a direct role in these ventilatory phenomena. Using an in vitro rat carotid body preparation, we found that 1) afferent activity declined during the first 5 min of severe (40 Torr Po(2)), moderate (60 Torr Po(2)), or mild (80 Torr Po(2)) hypoxia; 2) after return to normoxia (100 Torr Po(2)) and after several minutes of moderate or severe hypoxia, afferent activity was transiently reduced compared with prehypoxic levels; and 3) with successive 5-min bouts of mild, moderate, or severe hypoxia, afferent activity during bouts increased progressively. We call these phenomena sensory hypoxic decline, sensory posthypoxic decline, and sensory progressive augmentation, respectively. These phenomena were stimulus specific: similar phenomena were not seen with 5-min bouts of normoxic hypercapnia (100 Torr Po(2) and 50-60 Torr Pco(2)) or hypoxic hypocapnia (60 Torr Po(2) and 30 Torr Pco(2)). However, bouts of either normoxic hypercapnia or hypocapnic hypoxia resulted in sensory long-term facilitation. We suggest time-dependent carotid body activity acts in parallel with central mechanisms to shape the dynamics of ventilatory responses to respiratory chemostimuli.
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PMID:Time-dependent modulation of carotid body afferent activity during and after intermittent hypoxia. 1567 24

Rett syndrome (RTT) is a neurodevelopmental disorder caused by mutations in the X-linked gene methyl-CpG-binding protein 2 (MECP2) that encodes a DNA binding protein involved in gene silencing. Selective deletion of Mecp2 in post-mitotic neurons in mice results in a Rett-like phenotype characterized by disturbances in motor activity and body weight, suggesting that these symptoms are exclusively caused by neuronal deficiency. Included in the RTT phenotype are episodes of respiratory depression that follow hyperventilation. Here we show that the respiratory phenotype depends on the organ distribution of Mecp2 deficiency. Both female mice heterozygous for a null mutation in Mecp2 (Mecp2+/-) and those with selective deletion of the protein in neurons (Mecp2+/nestin-Cre lox), showed an initial response to hypoxia that exceeded that in wild type (WT). However, marked respiratory depression following hypoxic hyperventilation was only seen in Mecp2+/- animals. Addition of carbon dioxide to the hypoxic exposure eliminated the respiratory depression. Tidal volume and lung volume were larger in Mecp2+/- and respiratory depression was directly related to tidal volume. Taken together these results indicate that the depression is due to hypocapnia. Respiratory depression in this mouse model of Rett Syndrome is seen in with ubiquitous deficiency in Mecp2 but not when it is confined to neurons.
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PMID:Separate respiratory phenotypes in methyl-CpG-binding protein 2 (Mecp2) deficient mice. 1654 21

The ventilatory responses to immersion and changes in temperature are reviewed. A fall in skin temperature elicits a powerful cardiorespiratory response, termed "cold shock," comprising an initial gasp, hypertension, and hyperventilation despite a profound hypocapnia. The physiology and neural pathways of this are examined with data from original studies. The respiratory responses to skin cooling override both conscious and other autonomic respiratory controls and may act as a precursor to drowning. There is emerging evidence that the combination of the reestablishment of respiratory rhythm following apnea, hypoxemia, and coincident sympathetic nervous and cyclic vagal stimulation appears to be an arrhythmogenic trigger. The potential clinical implications of this during wakefulness and sleep are discussed in relation to sudden death during immersion, underwater birth, and sleep apnea. A drop in deep body temperature leads to a slowing of respiration, which is more profound than the reduced metabolic demand seen with hypothermia, leading to hypercapnia and hypoxia. The control of respiration is abnormal during hypothermia, and correction of the hypoxia by inhalation of oxygen may lead to a further depression of ventilation and even respiratory arrest. The immediate care of patients with hypothermia needs to take these factors into account to maximize the chances of a favorable outcome for the rescued casualty.
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PMID:Respiratory responses to cold water immersion: neural pathways, interactions, and clinical consequences awake and asleep. 1671 16

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