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
Query: EC:3.1.4.1 (
phosphodiesterase
)
18,767
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Theophylline and its derivatives, such as aminophylline, have an established role as bronchodilators, although their mode of action in man is not clear. There is circumstantial evidence that therapeutic doses of theophylline may have a
phosphodiesterase
inhibiting effect, thus potentiating the effects of cyclic AMP. However, it remains to be established whether this is the primary mode of action of theophylline at the biochemical level. The pathways of theophylline metabolism have been clarified, although most of the enzymes involved have not been characterized. Hepatic microsomal enzyme induction by polycyclic hydrocarbons will increase the rate of theophylline elimination. There are a number of factors which influence theophylline clearance in adults, which is known to be highly variable. These factors include obesity, smoking habit, diet and the presence of such diseases as hepatic cirrhosis, acute pulmonary oedema, cor pulmonale and viral
respiratory infection
. There is a good correlation between plasma theophylline level and bronchodilator effect. This can be demonstrated at plasma levels as low as 5 microgram/ml, although optimal levels are usually greater than 10 microgram/ml. Unacceptable toxicity usually occurs in association with plasma levels greater than 20 microgram/ml. The maintenance of adequate plasma theophylline levels by the use of a sustained-release aminophylline tablet is discussed.
...
PMID:Theophylline: biochemical pharmacology and pharmacokinetics. 22 Jan 19
The common underlying heart diseases were ischemic heart disease (39%), valvular heart disease (27%), hypertensive heart disease (10%) in 104 patients (mean age 79 yrs) with congestive heart failure (CHF). Cardiomyopathy (5%) and congenital heart disease (2%) such as atrial septal defect were less common. In addition, many extracardiac diseases including anemia, hypothyroidism, renal failure and pulmonary disease contributed to the etiology of CHF in the elderly. Cardiac amyloidosis should be considered as an uncommon cause of refractory CHF. While the precipitating factor was not found in half of the 104 patients with CHF, the most common factors were
respiratory infection
, myocardial ischemia and arrhythmia. In addition, inappropriate drug usage including poor drug compliance, the use of beta-blockers and excessive intake of sodium and fluid precipitated or exacerbated heart failure. Renal failure was a most important complication and predisposed to refractory CHF. Aged patients with mild CHF (NYHA class II) showed an insufficient production of cyclic AMP and GMP in proportion to the increases of norepinephrine and atrial natriuretic peptide in comparison with health aged subjects after the submaximal treadmill exercise test. This finding may suggest that an inadequate compensation of neurohumoral factors is prone to cause CHF in the elderly. Appropriate management of acute CHF in the elderly begins with recognition of the underlying heart disease, complications and the severity of cardiac function. In addition to medical management including loop diuretics, vasodilator, beta-receptor agonist and
phosphodiesterase
inhibitor, cases associated with respiratory and renal failure require mechanical ventilation and continuous hemofiltration.
...
PMID:[The etiology and management of congestive heart failure in the elderly]. 820 67
We experienced a Duchenne muscular dystrophy (DMD) patient with severe congestive heart failure (CHF) successfully treated with milrinone. He had been diagnosed as having CHF since 24 years of age when he began to have mechanical ventilation with a nasal mask at home. Although angiotensin converting enzyme (ACE) inhibitor was effective for his CHF, cardiac function worsened year by year.
Respiratory infection
triggered the exacerbation of CHF at the end of 1997 (27 years old). On admission to our hospital on January 7, 1998, PaO2 was 48 mmHg and cardiothoracic ratio (CTR) was 62%. Both ventricles were dilated and ventricular wall motility was markedly reduced on ultrasonocardiography. Ejection fraction of the left ventricle (LVEF) was 5%. Serum brain natriuretic peptide (BNP) was 760 pg/ml. Continuous intravenous infusion of milrinone was started on January 8 at the rate of 0.25-0.35 microgram/kg/min. His general condition improved and LVEF increased up to 15% on January 27. No serious side effects were observed. Even after milrinone withdrawal, his cardiac condition remained stable until the end of February 1998. Temporary deteriorated CHF due to urinary tract infection was successfully treated by chemotherapy and milrinone. Subsequently he was discharged on March 13 and could stay in his home for 7 weeks uneventfully with milrinone infusion therapy. When he was readmitted to the hospital for evaluation of CHF on April 30, CTR was 44%, LVEF was 20% and BNP was 44 pg/ml. CHF is one of the life threatening complications for DMD. Although catecholamine is a well utilized agent for advanced CHF, it has limited effect in DMD, because beta receptors are down-regulated due to long-lasting cardiac dysfunction. Increased heart rate and arrhytmia are also serious problems during catecholamine therapy. Milrinone is a type III
phosphodiesterase
inhibitor having inotropic and vasodilatic actions with modest increase of heart rate and little torelance. Milrinone is probably effective in improving CHF of DMD and has less side effects as compared to catecholamine. We concluded that milrinone might improve quality of lives of DMD patients with advanced CHF, although further cumultative studies are necessary to confirm its effectiveness and safety.
...
PMID:[Effective milrinone therapy to a Duchenne muscular dystrophy patient with advanced congestive heart failure]. 1050 90
Pharmacological treatment of patients with chronic obstructive pulmonary disease (COPD) aims to reduce disease burden and prevent future risk, especially exacerbations, hospitalizations, decline of lung function and quality of life, and mortality. This review will describe the basic pharmacology of the different classes of agents, followed by the effects they exert in patients with COPD, and the side effects. Targets for pharmacological treatments include airway smooth muscle contraction, inflammation, mucus production, alpha-1-antitrypsin deficiency and
respiratory infection
. Inhaled bronchodilators are the mainstay, with methylxanthines as secondary choice agents. Anti-inflammatory therapy can be administered as corticosteroids,
phosphodiesterase
inhibitor, and long-term macrolides such as azithromycin. Mucus production is addressed by use of mucolytics. In some countries, alpha-1-antitrypsin augmentation therapy is available for severe alpha-1-antitrypsin deficiency. The treatment of bacterial infection and/or colonization can be attempted with antibiotics; there is a dire need for effective anti-viral agents for the common viruses causing exacerbations of COPD. Since clinicians need to choose medications for their individual patients, algorithms for how to choose and change medication are increasingly being presented with more elements of treatable traits and personalized medicine.
...
PMID:Airway pharmacology: treatment options and algorithms to treat patients with chronic obstructive pulmonary disease. 3173 47
