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)

Mouth occlusion pressure 0.1 s after onset of inspiration (P0.1) reflects central respiratory drive (CRD), but its dependence on respiratory muscle strength is unknown. To clarify this relationship, we produced progressive levels of respiratory muscle weakness by infusion of d-tubocurarine in eight supine spontaneously breathing normal subjects. Hypercapnic ventilatory response (HCVR) was measured before curarization and at mild (mean inspiratory effort 62 +/- 3% of control), moderate (42 +/- 3%), and severe (23 +/- 1%) weakness. At the severe level of weakness 1) supine functional residual capacity was not significantly changed from base line, 2) the percent of base-line slope of delta P0.1/delta PCO2 (122 +/- 27%) was significantly greater (P less than 0.01) than that for change in expired minute ventilation (delta VE)/delta PCO2 (39 +/- 10%), 3) the percent of base-line delta P0.1/delta VE (381 +/- 46%) during HCVR was significantly increased (P less than 0.01), 4) the P0.1 response was significantly increased from base line at two out of three specific levels of PCO2 while the VE was unchanged or significantly decreased, and 5) peak inspiratory resistance did not significantly change. Thus P0.1, unlike VE, did not decrease with even severe respiratory muscle weakness. Indeed, P0.1 increased at two out of three levels of PCO2 under circumstances when higher CRD is expected. One potential explanation for the results is that P0.1 may at least qualitatively reflect CRD up to the level of severe respiratory muscle weakness attained in this study.
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PMID:Effect of respiratory muscle weakness on P0.1 induced by partial curarization. 643 29

An unusual patient with hypoxemia, hypercapnia, and right ventricular failure is presented. Minimal skeletal muscle weakness, although present, cannot explain hypercapnia. Muscle biopsy revealed diabetic microangiopathy. Carbon dioxide stimulation demonstrated a diminished hypercapnic ventilatory response. The patient benefited from progesterone therapy. In this unusual patient, mild muscular weakness, caused by diabetes, and central alveolar hypoventilation have acted in synergism to cause abnormal ventilation and right ventricular failure.
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PMID:Right ventricular failure in a patient with diabetic neuropathy (myopathy) and central alveolar hypoventilation. 664 56

Ventilatory responses of 10 control and 10 dystrophic male hamsters to air, hypercapnia, and hypoxia were evaluated at four ages (40, 70, 100, and 140 days). Tidal volume (VT), frequency (f), minute ventilation (VE) as well as inspiratory and expiratory time of awake animals were measured with a plethysmograph. There was a small increase of VT in both groups with age. Although there was no change of f in the control group with age, there was a progressive decrease in f (means +/- SE: 92 +/- 8, 97 +/- 9, 74.5 +/- 10, and 68 +/- 8 breaths/min) in the dystrophic group. Consequently VE on air decreased in the dystrophic group. Both groups showed similar responses to hypoxia (13 and 10% O2) and hypercapnia (3, 5, and 8% CO2) at 40 days. By 70 days the hypercapnic, but not hypoxic, response of the dystrophic animals was significantly decreased compared with that of the control group (at 8% CO2, VE = 47.4 +/- 4.1 vs. 75.7 +/- 7.6 ml/min, P less than 0.01). At both 100 and 140 days the response of the dystrophic group to CO2 was flat; i.e., the slope VE vs. fractional concentration of inspired CO2 was close to zero, and the hypoxic responses were greatly diminished. Because hamsters increase VE in response to CO2 primarily by increasing VT, the data suggest that dystrophic hamsters are unable to increase VT at a very early age, presumably due to muscle weakness. The normal response of hamsters to hypoxia, which is primarily to increase f, appears to be maintained for a longer time.
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PMID:An evaluation of ventilation in dystrophic Syrian hamsters. 672 69

The ability to maintain alveolar ventilation is compromised by respiratory muscle weakness. To examine the independent role of reflexly mediated neural mechanisms to decreases in the strength of contraction of respiratory muscles, we studied the effects of partial paralysis on the level and pattern of phrenic motor activity in 22 anesthetized spontaneously breathing dogs. Graded weakness induced with succinylcholine decreased tidal volume and prolonged both inspiratory and expiratory time causing hypoventilation and hypercapnia. Phrenic peak activity as well as the rate of rise of the integrated phrenic neurogram increased. However, when studied under isocapnic conditions, increases in the severity of paralysis, as assessed from the ratio of peak diaphragm electromyogram to peak phrenic activity, produced progressive increases in inspiratory time and phrenic peak activity but did not affect its rate of rise. After vagotomy, partial paralysis induced in 11 dogs with succinylcholine also prolonged the inspiratory burst of phrenic activity, indicating that vagal reflexes were not solely responsible for the alterations in respiratory timing. Muscle paresis was also induced with gallamine or dantrolene, causing similar responses of phrenic activity and respiratory timing. Thus, at constant levels of arterial CO2 in anesthetized dogs, respiratory muscle partial paralysis results in a decrease in breathing rate without changing the rate of rise of respiratory motor activity. This is not dependent solely on vagally mediated reflexes and occurs regardless of the pharmacological agent used. These observations in the anesthetized state are qualitatively different from the response to respiratory muscle paralysis or weakness observed in awake subjects.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Respiratory response to partial paralysis in anesthetized dogs. 673 17

Hypokalemia has been previously reported as a cause for respiratory impairment complicating therapy for diabetic ketoacidosis. A case is presented with a short interval of hypoventilation documented by hypercapnia. A reversal from hypercapnia to hypocapnia occurred when the serum potassium level became normal after potassium replacement. Causes of muscular weakness other than hypokalemia were considered unlikely on the basis of clinical and laboratory data. The present report records the occurrence of hypoventilation associated with hypokalemia in diabetic ketoacidosis and serves to underscore the need for adequate potassium replacement during the treatment of this disorder.
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PMID:Hypokalemic hypoventilation complicating severe diabetic ketoacidosis. 676 71

We have previously shown that the chemosensitivity of the respiratory centers is well preserved in myotonic dystrophy but that the ventilatory output is reduced. The present study was designed to determine at which degree of ventilatory performance weakness and fatigability of the respiratory muscles are interfering with ventilation and which mechanical factors contribute to the tachypnea of patients with myotonic dystrophy at rest and during low ventilatory output. We studied 10 patients with the disease and 10 normal control subjects. The strength of respiratory muscles was assessed by measurements of maximal pressure-volume diagrams generated against airway occlusion. Performance was evaluated during 1-min maximal voluntary ventilation (1-min MVV) test, during 7-min 7% CO2 breathing and during quiet breathing. Occlusion pressure (P0.1) in patients at rest was slightly higher than in control subjects, and during CO2 breathing, it was similar to that of control subjects. Maximal static pressure was reduced in patients to an average of 35% of that of control subjects. During the 1-min MVV test, there was a 50% reduction in esophageal and transdiaphragmatic pressure output (Pes, Pdi) in patients, resulting in similar reduction in ventilation (VE) and patients had rapid cycles of alternating dominant thoracic and abdominal volume displacements (Vrc/Vabd) suggesting respiratory muscle fatigue. During the 3- to 4-fold increase in breathing drive induced by hypercapnia, pressure output and the Vrc/Vabd were identical in both groups. However, ventilation was reduced in patients who had tachypneic respiration. In patients, tachypnea was also observed during quiet breathing. This tachypnea was associated with higher impedance of the respiratory system (Zrs) in patients and identical impedance of the lung (ZL) in both groups. In addition, Pdi during tidal volume was significantly higher in patients. These data demonstrate that the ventilatory output in out patients was altered predominantly by weakness and fatigability of the respiratory muscles during high ventilatory performance and by increased impedance of the respiratory system at lower degrees of ventilation.
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PMID:Pathogenesis of respiratory insufficiency in myotonic dystrophy: the mechanical factors. 680 50

Respiratory impairment in patients with Steinert's muscular dystrophy is known to lead to respiratory failure. Both the blunted chemical drive of breathing and the respiratory muscle weakness have been cited in the pathophysiology of premature death in these patients. To further assess the chemical control of breathing in these patients, we measured their respiratory responses to hypoxia (Weil's method), hyperoxia (Dejours' method), and hypercapnia (Read's method). In response to the stimuli from these respiratory centers, minute ventilation (VE), tidal volume (VT), respiratory frequency (F), mean inspiratory flow rate (VT/Ti), and occlusion pressure (P0.1) were measured in 12 patients and in 12 normal persons matched to the patients on the basis of age, sex, and arm span. The patients were similar to the control subjects in occlusion pressure results. However, they differed significantly (P less than 0.01) in ventilatory responses by a lower VE, lower VT, higher F, and lower VT/Ti in response to the hypercapnia and hypoxia tests. The responses of patients and control subjects were similar during the hyperoxia tests. Our study, therefore, established that the chemosensitivity of the respiratory centers, as measured by P0.1, is well preserved in Steinert's myotonic dystrophy, but the output to breathing (VE, VT, F, VT/Ti) is modulated by the impaired respiratory mechanics causing a tachypneic breathing pattern, even in the absence of restricted lung volume.
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PMID:Control and modulation of respiration in Steinert's myotonic dystrophy. 736 35

Respiratory disorders during sleep were studied in 42 patients with Duchenne muscular dystrophy (DMD) (mean age 18.4 years). Chest and abdominal movement, nasal airflow, snoring sounds, eye movement, and oxygen saturation were monitored during sleep. Three patterns of disorders were found: obstructive apnea, central apnea, and paradoxical respiration without upper airway obstruction (non-obstructive paradoxical respiration). Of these three patterns, obstructive apnea was the most common. Hypertrophy of the tongue and collapsibility of the upper airway seemed to be responsible for the obstructive apnea in these patients. The relationships between PaCO2 while breathing room air and the various indices of respiratory disorders were studied. The index of central apnea differed significantly between patients in whom PaCO2 was less than 50 Torr (early disease, n = 22) and those in whom PaCO2 was greater than or equal to 50 Torr (advanced disease, n = 20), but the indices of obstructive apnea and non-obstructive paradoxical respiration did not differ between those two groups. In conclusion, sleep disorders were common in patients with DMD, and the most common was obstructive apnea. In the patients with advanced DMD, blood gas analysis showed hypercapnia, and the index of central sleep apnea was high, probably because of respiratory muscle weakness or abnormalities in the respiratory center.
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PMID:[Respiratory disorders during sleep in Duchenne muscular dystrophy]. 747 61

In early phases of neuromuscular disease, patients are either free of respiratory symptoms or have exertional dyspnea not explained by obvious obstructive or restrictive lung disease. Physical examination may be negative because generalized muscle weakness does not correlate with the degree of respiratory muscle involvement. When the diaphragm is involved, one may detect the absence of outward excursion during inspiration or even paradoxic inward inspiratory movement of the abdomen on one side. A substantial loss of respiratory muscle strength is typically accompanied by little or no change in spirometry or arterial blood gas composition. Other characteristics are moderate loss of maximal voluntary ventilation and an increase in residual volume, yet PImax and PEmax may be as low as 50% of the predicted value. In more advanced neuromuscular disease, patients may have severe symptoms if the onset is acute or subacute; however, patients with chronic advanced generalized muscle weakness do not exercise and, therefore, may not be breathless. Many patients with advanced neuromuscular disease present with daytime somnolence as a manifestation of a sleep-related breathing disorder. Physical examination may reveal generalized muscle weakness and difficulty with speech or swallowing. Signs specific to respiratory involvement include tachypnea, use of neck inspiratory muscles and abdominal expiratory muscles, and loss of chest-abdomen synchrony. Sometimes paradoxic bilateral inward movement of the abdomen with inspiration is overt. Patients may be unable to cough effectively, have scoliosis, and lack a gag reflex. At this advanced stage, PImax and PEmax are lower than 50% of the predicted value, and the vital capacity is reduced. Maximal voluntary ventilation increases, and residual volume increases further. Patients may not yet exhibit CO2 retention during the day and may even have a low PaCO3. A sleep study may reveal significant hypopneas with severe desaturation and hypercapnia, especially during REM sleep. It is important to be aware that overt ventilatory failure can occur abruptly and that measurement of arterial blood gas composition is not a reliable indicator of this danger. Therefore, it is critically important to heed clinical phenomena, such as increasing dyspnea and tachypnea, and symptoms of sleep disturbance, such as morning headache and daytime somnolence. Physicians should make serial measurements of VC and respiratory muscle strength in patients considered to be at risk for further deterioration.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Assessment of ventilatory function in patients with neuromuscular disease. 786 89

Pregnancy often poses a risk to patients with neuromuscular and skeletal disorders when these affect the respiratory muscles or the rib cage. The outlook is determined both by the severity of the underlying condition and the physiological changes during pregnancy. Patients with a vital capacity of less than 1 to 1.5 litres, hypercapnia, severe scoliosis, diaphragm weakness or pulmonary hypertension before pregnancy are particularly at risk. Pregnancy may adversely affect the conducting airways, respiratory pump and gas exchange in the lungs. Close monitoring of high risk patients during pregnancy is required and either a termination of pregnancy or mechanical respiratory support may be indicated if ventilatory or cardiac failure develops.
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PMID:Pregnancy in neuromuscular and skeletal disorders. 808 20


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