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1. |
Clinical Pharmacokinetics of the Third Generation Cephalosporins |
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Clinical Pharmacokinetics,
Volume 10,
Issue 2,
1985,
Page 101-143
L. Balant,
P. Dayer,
R. Auckenthaler,
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摘要:
At the present time, the third generation cephalosporins that are already on the market or close to this point include cefsulodin, cefotaxime, cefoperazone, latamoxef, ceftriaxone, ceftazidime, ceftizoxime and cefotetan. Other newer compounds are also under development but have not been included in this review.None of the third generation compounds is suitable for oral administration and, accordingly, their pharmacokinetics have been studied only after intravenous and intramuscular administration. Microbiological assays and HPLC methods have been used for the measurement of plasma/serum, urine, bile and cerebrospinal fluid (CSF) concentrations. As found with cefotaxime, microbiological assays should only be used when the full metabolite spectrum of a particular drug is known, as otherwise, the presence of microbiologically active metabolites may lead to erroneous conclusions.Under normal conditions, the major route of elimination is via the kidneys for cefsulodin, latamoxef, ceftazidime, ceftizoxime and cefotetan. In contrast, cefoperazone is mainly eliminated in the bile, whereas cefotaxime and ceftriaxone depend both on the liver and the kidneys for their elimination. With the exception of ceftriaxone, which has a longer elimination half-life (i.e. around 8 hours), all the other third generation cephalosporins have a t1/2ranging between 1.5 and 2.5 hours.Plasma protein binding is variable from one compound to another. However, the clinical relevance of this parameter is not clearly established since tissue penetration also depends on the relative affinity of the drug for tissue components. Third generation cephalosporins seem to penetrate adequately into the CSF and, thus pharmacokinetically appear to be appropriate agents for the treatment of meningitis.The degree of modification of pharmacokinetic parameters by renal insufficiency or hepatic diseases depends, as for other drugs, on the extent to which the compound is excreted via the kidneys or the liver. The third generation cephalosporins have been extensively studied under these conditions and recommendations for dosage modification in special circumstances are available for most of them. The pharmacokinetics of some third generation cephalosporins may be modified in neonates and elderly patients. Accordingly, their use at the extremes of age must be accompanied by a closer than usual clinical monitoring of the patient.From a clinical point of view, the third generation cephalosporins possess reliable pharmacokinetic properties. The only limitation to their use thus centres around their antibacterial activity which is clearly superior to that of the older compounds as far as Gram-negative micro-organisms are concerned, but somewhat inferior against Gram-positive micro-organisms.
ISSN:0312-5963
出版商:ADIS
年代:1985
数据来源: ADIS
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2. |
Clinical Pharmacokinetics of Prazosin - 1985 |
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Clinical Pharmacokinetics,
Volume 10,
Issue 2,
1985,
Page 144-154
John Vincent,
Peter A. Meredith,
John L. Reid,
Henry L. Elliott,
Peter C. Rubin,
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摘要:
Prazosin is a selective &agr;1-adrenoceptor antagonist which is useful alone or in combination for the treatment of hypertension and heart failure. Unlike many other antihypertensive drugs, the action of prazosin appears to be closely related to its concentration in plasma or whole blood. Prazosin is variably absorbed, is subject to first-pass metabolism, and is eliminated almost entirely as metabolites of much lower hypotensive activity than the parent drug. Prazosin is highly bound to plasma and tissue proteins.The influences of renal, hepatic and cardiac disease on the disposition of prazosin are reviewed, as are the effects of pregnancy and ageing. The optimum use of prazosin in clinical practice depends on an understanding of the pharmacokinetic properties of the drug.
ISSN:0312-5963
出版商:ADIS
年代:1985
数据来源: ADIS
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3. |
Concentration-Effect Relationships of Valproic Acid |
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Clinical Pharmacokinetics,
Volume 10,
Issue 2,
1985,
Page 155-163
D. W. Chadwick,
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摘要:
Valproic acid is an effective broad spectrum anticonvulsant drug. It has a relatively short half-life, and large diurnal fluctuations in serum concentrations occur, thus making it difficult to define clear relationships between individual serum concentrations and either therapeutic or adverse effects. The value of routine ‘one-off’ measurements of valproate in clinical practice are further reduced by the absence of a clearly defined dose-related neurotoxicity syndrome. The often quoted therapeutic range for valproate of 50 to 100 mg/L has therefore to be regarded with some circumspection, although available data does suggest an increased incidence of adverse reactions with serum concentrations above 100 mg/L.
ISSN:0312-5963
出版商:ADIS
年代:1985
数据来源: ADIS
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4. |
Clinical Pharmacokinetics of the Salicylates |
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Clinical Pharmacokinetics,
Volume 10,
Issue 2,
1985,
Page 164-177
Christopher J. Needs,
Peter M. Brooks,
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摘要:
The use of salicylates in rheumatic diseases has been established for over 100 years. The more recent recognition of their modification of platelet and endothelial cell function has lead to their use in other areas of medicine.Aspirin (acetylsalicylic acid) is still the most commonly used salicylate. After oral administration as an aqueous solution aspirin is rapidly absorbed at the low pH of the stomach millieu. Less rapid absorption is observed with other formulations due to the rate limiting step of tablet disintegration - this latter factor being maximal in alkaline pH. The rate of aspirin absorption is dependent not only on the formulation but also on the rate of gastric emptying.Aspirin absorption follows first-order kinetics with an absorption half-life ranging from 5 to 16 minutes. Hydrolysis of aspirin to salicylic acid by nonspecific esterases occurs in the liver and, to a lesser extent, the stomach so that only 68% of the dose reaches the systemic circulation as aspirin. Both aspirin and salicylic acid are bound to serum albumin (aspirin being capable of irreversibly acetylating many proteins), and both are distributed in the synovial cavity, central nervous system, and saliva.The serum half-life of aspirin is approximately 20 minutes. The fall in aspirin concentration is associated with a rapid rise in salicylic acid concentration. Salicylic acid is renally excreted in part unchanged and the rate of elimination is influenced by urinary pH, the presence of organic acids, and the urinary flow rate. Metabolism of salicylic acid occurs through glucuronide formation (to produce salicyl acyl glucuronide and salicyl phenolic glucuronide), conjugation with glycine (to produce salicyluric acid), and oxidation to gentisic acid. The rate of formation of salicyl phenolic glucuronide and salicyluric acid are easily saturated at low salicylic acid concentrations and their formation is described by Michaelis-Menten kinetics. The other metabolic products follow first-order kinetics. The serum half-life of salicylic acid is dose-dependent; thus, the larger the dose employed, the longer it will take to reach steady-state. There is also evidence that enzyme induction of salicyluric acid formation occurs.No significant differences exist between the pharmacokinetics of the salicylates in the elderly or in children when compared with young adults. Apart from differences in free versus albumin-bound salicylate in various disease states and physiological conditions associated with low serum albumin, pharmacokinetic parameters in patients with rheumatoid arthritis, osteoarthritis, chronic renal failure or liver disease are essentially the same. Pharmacokinetic interactions with various non-steroidal anti-inflammatory drugs do occur, but the clinical relevance of these is uncertain. Clinically important interactions may occur with heparin or oral anticoagulants, but these are due mainly to an effect on platelet function rather than on pharmacokinetic parameters.
ISSN:0312-5963
出版商:ADIS
年代:1985
数据来源: ADIS
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5. |
Pharmacokinetics of Oral Cibenzoline in Arrhythmia Patients |
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Clinical Pharmacokinetics,
Volume 10,
Issue 2,
1985,
Page 178-186
Romulus K. Brazzell,
Wayne A. Colburn,
Keiko Aogaichi,
Alice J. Szuna,
John C. Somberg,
Nathan Carliner,
James Heger,
Joel Morganroth,
Roger A. Winkle,
Paul Block,
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摘要:
The pharmacokinetics of oral cibenzoline were studied in 30 arrhythmia patients as part of an ascending multiple-dose efficacy study. The elimination half-life of the drug following repetitive dosing ranged from 7.6 to 22.3 hours, with a harmonic mean of 12.3 hours (n = 24), and increased with age and decreasing renal function. The drug exhibited apparent dose proportional and linear pharmacokinetics over the range of doses studied. Multivariate analysis revealed that the patients' age and serum creatinine concentration accounted for 71% of the variability in the range of &bgr; values (terminal elimination rate constant), and that 69.5% of the intersubject variability in the steady-state trough plasma concentrations could be accounted for by the patients' age, weight and serum creatinine concentration.These data suggest that, although there is some intersubject variability in the elimination and accumulation of cibenzoline, much of the variability can be explained by the patients' age, weight and renal function.
ISSN:0312-5963
出版商:ADIS
年代:1985
数据来源: ADIS
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