Letter: Severe metabolic acidosis associated with nalidixic acid overdose

Lactic acidosis: from sour milk to septic shock

Lactic acidosis is frequently encountered in the intensive care unit. It occurs when there is an imbalance between production and clearance of lactate. Although lactic acidosis is often associated with a high anion gap and is generally defined as a lactate level >5 mmol/L and a serum pH <7.35, the presence of hypoalbuminemia may mask the anion gap and concomitant alkalosis may raise the pH. The causes of lactic acidosis are traditionally divided into impaired tissue oxygenation (Type A) and disorders in which tissue oxygenation is maintained (Type B). Lactate level is often used as a prognostic indicator and may be predictive of a favorable outcome if it normalizes within 48 hours. The routine measurement of serum lactate, however, should not determine therapeutic interventions. Unfortunately, treatment options remain limited and should be aimed at discontinuation of any offending drugs, treatment of the underlying pathology, and maintenance of organ perfusion. The mainstay of therapy of lactic acidosis remains prevention.

Neurochemical studies on quinolone antibiotics: effects on glutamate, GABA and adenosine systems in mammalian CNS

Quinolone antibiotics, which can be proconvulsant in susceptible patients, were found to inhibit the specific binding of the adenosine receptor ligands L-3H-N6-phenylisopropyladenosine (L-3H-PIA) and 3H-N-ethylcarboxamidoadenosine (3H-NECA) to rat brain synaptic membranes. The inhibitions were concentration dependent, and for both ligands the order of potency was rosoxacin greater than nalidixic acid greater than oxolinic acid greater than or equal to ciprofloxacin greater than norfloxacin greater than enoxacin: IC20 values (concentrations causing a 20% inhibition of specific binding) ranged from 30-35 microM to 1-3 mM. Hill coefficients were approximately 0.5, suggesting that the compounds are probably antagonists at these sites. Most of the compounds did not alter 3H-diazepam binding directly, although rosoxacin showed relatively strong, and enoxacin weak, concentration-dependent inhibition. At 50 microM the compounds enhanced the maximal gamma-aminobutyric acid (GABA) activation of 3H-diazepam binding to varying degrees, without altering the EC50 of activation, whereas at 200 microM they tended to reduce GABA activation. Most noteworthy was the large increase in GABA-stimulated 3H-diazepam binding caused by 50 microM nalidixic acid. The compounds did not alter the Ca2+/Cl- -dependent binding of 3H-glutamate, nor of the binding of the glutamate site-selective ligands 3H-kainate and alpha-3H-amino-3-hydroxy-5-methylisoxazole-4-propionic acid (3H-AMPA); the uptake of the non-metabolized glutamate analogue D-3H-aspartate by cortical homogenates was also unaffected. The CNS side effects of these antibiotics may result, in part, from interaction with sites which mediate the inhibitory neurotransmission of adenosine and, possibly, GABA.

Lactic acidosis, hyperglycaemia and convulsions following nalidixic acid overdosage

A woman survived ingestion of 32 g nalidixic acid despite developing lactic acidosis, hyperglycaemia, convulsions and abnormal behaviour. The maximum recorded plasma concentration of nalidixic acid was 185 mg/l and the elimination half-life was 3.2 h. Carboxy-nalidixic acid was demonstrated in the plasma. Previously reported cases of nalidixic acid overdosage are reviewed.

Drug prescribing in renal failure: dosing guidelines for adults

The data base for rational guidelines to safe, efficacious drug prescribing in adults with renal insufficiency are presented in tabular form. Current medical literature was extensively surveyed to provide as much specific information as possible. When information is lacking, however, recommendations are based on pharmacokinetic variables in normal subjects. Nephrotoxicity, important adverse effects, and special considerations in renal patients are noted. Adjustments are suggested for hemodialysis and peritoneal dialysis when appropriate.

Clinical pharmacokinetics of probenecid

A review of the clinical applications and of the disposition of probenecid in man, including drug interactions, is presented. Probenecid is the classical competitive inhibitor of organic acid transport in the kidney and other organs. There are 2 primary clinical uses for probenecid: as a uricosuric agent in the treatment of chronic gout and as an adjunct to enhance blood levels of antibiotics (such as penicillins and cephalosporins). Adsorption of probenecid is essentially complete following oral administration. The drug is extensively metabolised by glucuronide conjugation and by oxidation of the alkyl side chains; oxidation of the aromatic ring does not occur. The half-life of probenecid in plasma (4 to 12 hours) is dose-dependent. Renal excretion is the major route of elimination of the metabolites; excretion of the parent drug is minimal and is dependent on urinary pH. Probenecid and its oxidised metabolites are extensively bound to plasma proteins, mainly to albumin. Tissue concentrations (based on animal studies) are generally lower than plasma concentrations. Most of the drug-drug interactions involving probenecid are due to an effect on the kidney-block of transport of acidic drugs. Similarly probenecid affects the tubular secretion of a number of acidic endogenous substances by the kidney. Probenecid is also involved in the block of transport of acidic metabolites of catecholamines, for example homovanillic and hydroxyindoleacetic acids, in the brain. There are a number of analytical procedures for the assay of probenecid. These are based on spectrophotometry, spectrofluorometry, gas and liquid chromatography and radioimmunoassay.

Nalidixic acid and lactic acidosis

Nalidixic acid may cause severe acidosis and we report a fatal case of lactic acidosis assocaited with nalidixic acid therapy. Studies in normal volunteers showed drug related impairment of lactate metabolism. We question whether the drug should be used in patients who may accumulate the drug or be predisposed to lactic acidosis.

Metabolic acidosis and coma due to an overdose of nalidixic acid

A case of severe metabolic acidosis and coma after taking 28 g of nalidixic acid is described. After administration of 600 mEq of sodium bicarbonate the patient developed a respiratory alkalosis with secondary tetany. She recovered her state of consciousness nine hours later and the acid-base disturbance resolved after sixty hours.