Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Target Concepts:
Gene/Protein
Disease
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Drug
Enzyme
Compound
Query: UMLS:C0010200 (
cough
)
23,843
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Normally the daily volume of lower respiratory tract secretions, in man, is probably less than 100 ml. In hypersecretory disease the volume increases sufficiently to cause
cough
and expectoration of secretions as sputum. The proportions which are sol or gel vary in disease as does the way in which constituent molecules partition in each phase. The constituent molecules and the cells which produce them (indicated in parentheses) may be classified as follows: 1. Mucus-glycoproteins present as droplets, or sheets (produced by mucous cells), periciliary fluid (serous or ciliated cell or a transudate), surface muco-substance (all epithelial cells) or surfactant hypophase (Clara or type II alveolar cells). 2. Proteins and peptides such as lysozyme (serous cell and macrophage), lactoferrin (serous cell and neutrophil), secretory piece (surface epithelium and submucosal glands), regulatory neuropeptides (dense-core granulated cell and both motor and sensory nerves) and
fibronectin
(alveolar macrophages). 3. Glycosaminoglycans such as heparan sulphate (epithelial membranes), heparin (mast cell), chondroitin sulphates and hyaluronate (connective tissue constituents). 4. Lipids including triglycerides (stored in cells) glycolipids (cell membrane), phospholipids (type II alveolar cells), sphingolipids (cell membrane), steroids (? Clara cells) and terpenes (cell membrane). 5. Anti-proteases and anti-oxidants such as bronchial protease inhibitors (serous anc Clara cells), alpha-2-macroglobulin (macrophage), alpha-1-antitrypsin (transudate) and anti-oxidants (type II alveolar cell and macrophage). 6. Other 'secretions' including ions and water (surface epithelium and submucosal glands), mediators of inflammation (migratory cell granules and their membranes), and serum proteins (present in transudate/exudate).
...
PMID:The origins of secretions in the lower respiratory tract. 332 67
Classical radiation pneumonitis has been described after single dose whole lung irradiation in experimental animals where above a threshold dose of irradiation, there is a sigmoid dose response curve with increasing morbidity and mortality. After clinical fractionated irradiation, however, acute radiation pneumonitis consisting of
cough
shortness of breath and patchy radiological changes, occurs in <10% of patients, has dyspnoea out of proportion to the volume of lung irradiated and usually resolves completely without long-term effects. There is increasing evidence that this represents a bilateral lymphocytic alveolitis or hypersensitivity pneumonitis and has been termed sporadic pneumonitis. Late radiation toxicity results in pulmonary fibrosis. This is a consequence of repair, which is initiated by tissue injury within the radiation portal. It follows release of chemotactic factors for fibroblasts including transforming growth factor-beta,
fibronectin
and platelet derived growth factor. Radiation fibrosis is the clinically more significant syndrome for patients. It may result in progressive dyspnoea and mortality in patients. The most predictable change in laboratory lung function tests is a decrease in transfer factor due to damage at the capillary-alveolar level. It also results in decreased lung compliance, which will affect the total lung capacity and the forced vital capacity. The forced expiratory volume in 1 s is less affected, although this seems to depend on the volume of lung irradiated. There is also a decrease in perfusion in the irradiated lung. Radiation fibrosis seems to depend, amongst other factors, on the volume of lung, which is irradiated above a threshold of 20-30 Gy. The morbidity of radiation fibrosis may therefore be minimized by the use of dose volume histogram to minimize the volume of normal lung irradiated in patients at high risk, e.g., patients with who present with poor lung function. The importance of the baseline perfusion in the irradiated areas continues to be studied.
...
PMID:Lung toxicity following chest irradiation in patients with lung cancer. 1180 81
Work in swine confinement buildings leads to an inflammatory response and may be associated with increased levels of acute phase proteins. We compared the inflammatory response of a control group of young former farm workers with age-matched former farm workers who had previously developed the lower airway symptoms of wheeze,
cough
, tightness of the chest during work in swine confinement buildings, and because of these symptoms had stopped work. Both groups were subjected to an experimental exposure in a swine confinement building for 3 hours. Complement activation and acute phase proteins were measured in blood samples and broncho-alveolar lavage. Plasma C3d levels correlated with respirable dust, significantly so for individual cases and for the whole cohort. Plasma C3, fibrinogen and alpha (1) -acid glycoprotein peaked 1 and 6 h after exposure start, mannan-binding lectin, C-reactive protein and alpha(1)-antitrypsin peaked after 2 h. Surfactant protein D (SP-D) and alpha (2) -macroglobulin were downregulated. In lavage, only SP-D, alpha (2)-macroglobulin and
fibronectin
were detected. FEV(1), FVC, TLC and FEV(25-75) did not vary during exposure. There was complement activation in response to respiratory dust, more so amongst cases than in the control group. Acute exposure, with work related levels of organic dust containing endotoxin, leads to a weak systemic inflammatory response.
...
PMID:Plasma C3d levels of young farmers correlate with respirable dust exposure levels during normal work in swine confinement buildings. 1285 33
