Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound

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Query: UMLS:C0020440 (hypercapnia)
7,939 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The knee of a boy with sickle-cell thalassemia became infected with Salmonella enteritidis, sensitive to ampicillin. Doses of ampicillin that achieved anti-bacterial titers of 32 in synovial fluid failed to eradicate the organism. The synovial fluid exhibited severe hypoxia, hypercapnia, and lactic acidosis. Methods were developed to estimate the oxygen saturation of blood in regional venous capillaries, the degree of periarticular sickling, changes in the viscosity of local blood, and the articular ratio of blood flow to oxygen utilization. The results suggest that local vascular insufficiency associated with sickling may affect host response to infection and efficacy of antibiotics. The Salmonella C1 readily transformed to an L form on hypertonic medium, thus acquiring resistance to ampicillin and other cell-wall inhibitors.
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PMID:Septic arthritis in sickle-cell thalassemia. Pathophysiology of impaired response to infection. 109 70

Disturbance in acid-base balance is commonly observed in patients with heart failure. The most common disturbance is metabolic alkalosis combined with hypokalemia, as a result of the excessive use of loop diuretics. Occasionary, hypoxia due to pulmonary edema stimulates ventilation, resulting in respiratory alkalosis. When pulmonary edema develops, carbon dioxide retention occurs, resulting in respiratory acidosis. Decreased tissue oxygen delivery may also produce lethal lactic acidosis. Compensatory mechanisms, coexistence of independent acid-base disorders and changes in electrolytes complicate acid-base balance in the individual patients. As acid-base disturbances have harmful effects on the cardiovascular system, precise diagnosis and proper treatment are highly important.
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PMID:[Acid-base disturbances in heart failure]. 143 8

The aim of physical exercise retraining in patients with chronic obstructive lung disease undergoing rehabilitation is to increase the anaerobic work capacity with a rise in VO2 max. Exercise programmes must take into account the duration, frequency and intensity of exercise. In these patients, numerous factors limit physical exercise, including (a) decreased ventilatory capacity and respiratory muscles fatigue; (b) decreased efficacy of the pulmonary gas exchanges; (c) altered pulmonary vascular bed with altered cardiovascular response. The most widely used training methods are walking (or running), practising on a conveyor belt and using an ergometric bicycle. The last named seems to be the best method to evaluate the physiological effects of exercise or for experimental studies. Patients who are fit to participate in a retraining programme must be in a stable period and have a stable pharmacological regimen; they must be subjected to a preliminary exercise test in order to evaluate the main physiological parameters and to obtain information on their tolerance to exercise, on the presence of lactic acidosis and on the degree of hypoxaemia and hypercapnia. In the absence of contra-indications, a training programme can be set up with 30 to 45 minutes of exercise per day at least 3 to 5 times a week during 5 to 8 weeks, with a load amounting to 50-60% of VO2 max. Two questions remain to be answered: (a) is oxygen therapy useful during retraining; (b) what effect has training on survival?
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PMID:[Indications and results of exercise rehabilitation in patients with chronic obstructive lung diseases]. 177 75

It is well known that brain pH changes rapidly in acute hypercapnia or hypocapnia. The effect of acute isocapnic metabolic acid-base change on brain pH is less certain. To study this problem, acute isocapnic metabolic acidosis was induced by HCl or lactic acid infusions in rats, and recovery from acidosis was accomplished by NaHCO3 infusion. Brain pH was measured by 31P-nuclear magnetic resonance. Despite decreases in blood pH of 0.34 and 0.36 units, respectively, in less than 1 h of acid infusion and rapid recovery during bicarbonate infusion, brain pH was unaffected (ranging between 7.08 and 7.11) and was uncorrelated with blood pH. The blood pH minus brain pH gradient was eliminated by the acidosis. By contrast, hypoxia-induced endogenous lactic acidosis lowered blood and brain pH equivalently, but the fall in brain pH preceded that in blood. During normoxic recovery, brain pH overshot and became alkaline when blood pH was still significantly reduced and blood lactate levels were markedly elevated. Presumably, this is due to stimulated active H+ transport. The results demonstrate that brain pH is affected differently in metabolic, respiratory, and endogenous acid-base disturbances. Thus brain pH cannot be predicted solely from blood pH values.
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PMID:Brain pH in acute isocapnic metabolic acidosis and hypoxia: a 31P-nuclear magnetic resonance study. 230 94

The influence of lactic acidosis and of extreme hypercapnia on free radical generation and lipid peroxidation in brain tissues was studied. Cortical homogenates were prepared from the rat brain in a bicarbonate buffer and incubated for 60 min. Lipid peroxidation was evaluated by measurements of thiobarbituric acid reactive (TBAR) material and alpha-tocopherol analysis. The pH during incubations were decreased to 6.10-6.20 by either lactic acid administration or equilibration with 60% CO2 gas in paired experiments. In homogenates treated with lactic acid there was a 20-fold increase in TBAR material and the alpha-tocopherol concentration decreased to approximately 60% of control. There was only a 10-fold increase in TBAR material and no change in alpha-tocopherol concentration if acidosis was induced by CO2. These differences between lactic acidosis and hypercapnic acidosis were statistically highly significant. The results indicate that lactic acidosis has a more pronounced effect in augmenting free radical generation in brain tissues than acidosis due to an increase in CO2 tension. It is suggested that this effect of lactic acid is mediated by increased dissociation of catalytic iron from proteins of the transferrin type.
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PMID:Enhancement of iron-catalyzed free radical formation by acidosis in brain homogenates: differences in effect by lactic acid and CO2. 249 27

In humans, arterial PCO2 (PaCO2) has been demonstrated to be regulated at or near resting levels in the steady state of moderate exercise (i.e., for work rates not associated with a sustained lactic acidosis). To determine how PaCO2 might be expected to behave under the nonsteady-state conditions of incremental exercise testing, the influence of the dynamic characteristics of the primary variables that determine PaCO2 was explored by means of computer modeling. We constructed a dynamic model that utilized previously reported experimental estimates for the kinetic response parameters of ventilation (VE) and CO2 output (VCO2). In response to incremental work rate forcings, the model yielded an increase in PaCO2, which reflected the disparity between the VE and VCO2 time constants; this hypercapnic condition was maintained despite VE and VCO2 both increasing linearly with respect to the input work rate profile. The degree of hypercapnia increased with the rate of the incremental forcing, reaching 9 Torr for a 50-W/min forcing. In conclusion, therefore, sustained increases in PaCO2 during nonsteady-state incremental exercise should be interpreted with caution, because this is the predicted response even in subjects with normal ventilatory control and lung function.
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PMID:Model implications of gas exchange dynamics on blood gases in incremental exercise. 249 67

The CO2 response of the phrenic neurogram before and during CO-induced isocapnic brain hypoxia was studied in peripherally chemodenervated, vagotomized, paralyzed, ventilated cats with blood pressure held constant. During inhalation of 0.5% CO in 40% O2, arterial O2 content (CaO2) was reduced to 40% and minute phrenic activity to 38.4 +/- 9.4% (SE; n = 9) of prehypoxic levels, primarily due to depression of peak phrenic amplitude (PP). CO2 response, defined as the slope of the plot of PP vs. end-tidal PCO2 during CO2 rebreathing, was unaffected by phrenic depression even to the point of total suppression of phrenic activity in two cats. The effect of the tissue metabolic acidosis associated with hypoxia on phrenic CO2 sensitivity was assessed in a separate group of cats by blocking lactate formation during hypoxia with dichloroacetate (DCA). Preventing lactic acidosis during hypoxia did not affect the CO2 response of the phrenic activity during hypoxia. We conclude that 1) hypoxic depression does not limit the ability of central respiratory neurons to respond to CO2, and 2) the failure of DCA to affect the CO2 response of the phrenic neurogram suggests that brain intracellular lactic acidosis does not modify the phrenic response to hypercapnia.
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PMID:CO2 sensitivity of cat phrenic neurogram during hypoxic respiratory depression. 313 17

The intrinsic processes involved in the initiation and arrest of seizures are not completely understood. Cortical and cerebellar inhibitory mechanisms, accumulation of metabolic products, and glial uptake of extracellular potassium (K+o), anions, and released neurotransmitters are all important processes that limit focal firing and terminate a seizure once it has been initiated. Of these, the intrinsic cortical inhibitory mechanisms--i.e., recurrent and surround inhibition--appear to be the most important. Active cation and anion transport processes are two metabolic events that have yet to be elucidated but clearly could be involved in terminating a seizure discharge. For example, without an active mechanism to transport chloride, opening of the chloride channel by the inhibitory transmitter GABA would not result in increased chloride permeability. The transient hypoxia and hypercapnia and lactic acidosis that follows a severe tonic-clonic seizure produces a mixed systemic metabolic and respiratory acidosis. In experimental animals, the hypercapnia that results is sufficient to block seizure discharges. Increasing the CO2 concentration significantly reduces the extension to flexion (E/F) ratio of mice given maximal electroshock seizures (MES) and increases the time required for 50% of the animals to recover sufficiently from a first MES to be able to have another MES. The decreased E/F ratio and the increased recovery time (RT50) are both indicative of a decrease in seizure activity. Since the extent to which CO2 is allowed to accumulate in the brain is regulated by the glial specific enzyme carbonic anhydrase (CA), it follows that the glial cell has an integral role in the mechanisms involved in arresting seizure activity. In contrast, hypoxia increased the E/F ratio and decreased the RT50, evidence that seizure activity was enhanced. Another metabolic factor affecting duration of seizure activity, susceptibility to seizures, and recovery from seizures is glucose. Recovery from seizures depends in part on an adequate supply of this energy source. An inverse correlation (R = 0.95) between RT50 and blood sugar was found when the blood sugar was altered experimentally by treatments that altered the endocrine status (pancreatectomy, treatment with alloxan, cortisol, insulin, glucagon, and dextrose). Since glial cells contain (as glycogen) the small amount of glucose present in the brain, they probably hasten the ability of the brain to recover normal function following a seizure.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Role of glial cation and anion transport mechanisms in etiology and arrest of seizures. 370 23

Brain tissue acidosis is a result of either an increase in tissue PCO2 or an accumulation of acids produced by metabolism. Severe hypercapnia (arterial PCO2 around 300 mm Hg) may cause a fall in tissue pH to around 6.6 without any deterioration of the cerebral energy state or morphologic evidence of irreversible cell damage. In severe ischemia and tissue hypoxia, anaerobic glycolysis leads to lactic acid accumulation. This is aggravated by hyperglycemia and by a (trickling) residual blood flow. Under such circumstances lactate concentration in the tissue may increase to levels above 20 to 25 mumol/g (tissue wet weight), causing a decrease in pH to around 6.0. If lactic acidosis during ischemia or hypoxia reaches these excessive levels, metabolic and functional restitution is severely hampered upon subsequent recirculation and reoxygenation. In these circumstances cell morphology shows signs of irreversible damage. Conversely there is less damage if severe tissue lactic acidosis can be hindered. The deleterious effect of excessive lactic acidosis may be related to an influence on the following: synthesis and degradation of cellular constituents; mitochondrial function; cell volume control; postischemic blood flow; and stimulation of pathologic free radical reactions. Possibilities for therapeutic interventions include the avoidance of hyperglycemia, inhibition of glycolysis, and measures for increasing the buffer capacity of the brain.
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PMID:Brain acidosis. 392 94

A critical review of the literature of retrolental fibroplasia indicates that the cause of this disease is not yet known. Oxygen is certainly a critical factor but it is still not possible to make precise recommendations as to the amount or the duration of therapy that is safe. We have overemphasized the role of oxygen in the past, and as a result of this the false impression has been created that RLF is a disease that can be prevented. This gross oversimplification of a complex disease with multiple causes has resulted in many unjustified malpractice claims. A study of the present epidemic indicates that excessive oxygen administration probably plays a minor role, in contrast to the first epidemic in which prolonged oxygen administration was clearly a major factor. A reasonable working hypothesis is that the developing retina is highly sensitive to any disturbance in its oxygen supply, either hyperoxemic or hypoxemic. The retinal circulation is subject to the same wide fluctuations as the cerebral circulation in newborn infants. The very low-birth-weight, sick premature infant suffers from a number of conditions, many of which can seriously disturb the retinal circulation, resulting in hypoperfusion and ischemia. These factors (immaturity, hyperoxia, hypoxia, blood transfusions, intraventricular hemorrhage, apnea, infection, hypercarbia, hypocarbia, patent ductus arteriosus, prostaglandin synthetase inhibitors, vitamin E deficiency, lactic acidosis, prenatal complications, genetic factors) may all be present in an infant. They may interact to produce various degrees of retinal damage. Nearly all of these factors cannot be prevented or controlled by our present methods of care. Unfortunately, this means that RLF is an extremely difficult disease to prevent, treat, or investigate. A disease of this complexity with multiple causes will require very large numbers of infants in any controlled study of a therapy. Retrolental fibroplasia should not be considered an avoidable iatrogenic disease in very low-birth-weight infants. Its cause in these infants is not known.
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PMID:A reexamination of the role of oxygen in retrolental fibroplasia. 641 99


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