[Biliary diffusion of tazocillin in man]. / Etude de la diffusion biliaire de la tazocilline chez l'homme.

The objective of this study was to determine the extent of biliary excretion of tazocillin, a combination of piperacillin and tazobactam administered as an intravenous infusion in a dose of 4 g of piperacillin and 0.5 g of tazobactam. In 10 patients, piperacillin and tazobactam levels were determined in serum, main bile duct bile, gallbladder bile, and gallbladder wall specimens harvested during a cholecystectomy procedure 1 h after completion of a tazocillin infusion. In five other patients, piperacillin and tazobactam levels were determined in bile collected from a main bile duct T-tube during 12 h following a tazocillin infusion given seven days after cholecystectomy. HPLC was used to assay both compounds. Piperacillin and tazobactam levels in the intraoperative specimens were as follows: 69.1 +/- 13.8 and 9.9 +/- 1.7 micrograms/ml, respectively, in the serum; 630 +/- 133 and 11.9 +/- 2.2 micrograms/ml, respectively, in the main bile duct bile; 342 +/- 114 and 7.7 +/- 2.3 micrograms/ml, respectively, in the gallbladder bile; and 49.3 +/- 20.2 and 2.9 +/- 0.6 micrograms/g, respectively, in the gallbladder wall. In the T-tube bile specimens, peak piperacillin and tazobactam levels were 358 +/- 281 and 9.9 +/- 3.3 micrograms/ml, respectively, after 1 h; total biliary excretion over 12 hours was 28.3 +/- 18.0 mg and 1.0 +/- 0.5 mg, i.e., 0.7 +/- 0.4% and 0.2 +/- 0.1% of the dose, respectively. The levels of piperacillin and tazobactam found in bile and gallbladder wall specimens in this study suggest that tazocillin may prove valuable for the prevention and treatment of biliary infections.

Biliary tract infections: a guide to drug treatment.

Initial therapy of acute cholecystitis and cholangitis is directed towards general support of the patient, including fluid and electrolyte replacement, correction of metabolic imbalances and antibacterial therapy. Factors affecting the efficacy of antibacterial therapy include the activity of the agent against the common biliary tract pathogens and pharmacokinetic properties such as tissue distribution and the ratio of concentration in both bile and serum to the minimum inhibitory concentration for the expected micro-organism. Antimicrobial therapy is usually empirical. Initial therapy should cover the Enterobacteriaceae, in particular Escherichia coli. Activity against enterococci is not required since their pathogenicity in biliary tract infections remains unclear. Coverage of anaerobes, in particular Bacteroides spp., is warranted in patients with previous bile duct-bowel anastomosis, in the elderly and in patients in serious clinical condition. In patients with acute cholecystitis or cholangitis of moderate clinical severity, monotherapy with a ureidopenicillin--mezlocillin or piperacillin--is at least as effective as the combination of ampicillin plus aminoglycoside. In severely ill patients with septicaemia, an antibacterial combination is preferable. Therapy with aminoglycosides, mostly for Pseudomonas aeruginosa-related infections, should not exceed a few days because the risk of nephrotoxicity seems to be increased during cholestasis. Relief of biliary obstruction is mandatory, even if there is clinical improvement with conservative therapy, because cholangitis is most likely to recur with continued obstruction. Emergency invasive therapy is reserved for patients who fail to show a clinical response to antibacterial therapy within the first 36 to 48 hours or for those who deteriorate after an initial clinical improvement. Immediate surgery is indicated for gangrenous cholecystitis and perforation with peritonitis. Long-term administration of antibacterials is required for recurrent cholangitis, as seen in bile duct-bowel anastomosis. Oral cotrimoxazole (trimethoprim/sulfamethoxazole) is the preferred agent. Wound infection rates after biliary tract surgery can be significantly reduced by preoperative administration of prophylactic antibacterials. Newer generation beta-lactams have not proven to be of greater benefit than older agents such as cefuroxime or cefazolin. Antibacterial prophylaxis before endoscopic retrograde cholangiopancreatography (ERCP) should be reserved for patients with obstructive jaundice, since the risk of infectious complications seems to be strongly associated with this clinical condition. Failure to achieve full biliary drainage is the most important factor in predicting septicaemia, and prophylaxis should be prolonged until the bile duct is unobstructed. Piperacillin, cefazolin, cefuroxime, cefotaxime and ciprofloxacin are effective for this indication.

Assessment of biliary excretion of piperacillin-tazobactam in humans.

Piperacillin-tazobactam concentrations in serum and bile were measured intraoperatively in 10 patients undergoing cholecystectomy (group 1) and 5 cholecystectomized patients provided with external bile duct drainage (group 2). Each patient received a single intravenous dose of piperacillin at 4 g plus tazobactam at 0.5 g over 30 min. Drug concentrations in both serum and bile were measured by high-performance liquid chromatography. In group 1 patients, serum and bile specimens and gallbladder wall fragments were collected at mean times of 70 and 83 min postinfusion, respectively. The mean concentrations of piperacillin and tazobactam were, respectively, 69.1 +/- 41.5 (standard deviation) and 9.9 +/- 5.1 microg/ml in serum, 630.4 microg/ml (range, 24.8 to 1,194 microg/ml) and 11.8 microg/ml (range, 3.6 to 22 microg/ml) in choledochal bile, 342.3 microg/ml (range, 1.1 to 1,149 microg/ml) and 7.7 microg/ml, (range, 0.2 to 23.1 microg/ml) in gallbladder bile, and 49.3 microg/g (range, 9.7 to 223 microg/g) and 2.9 microg/g (range, 0.1 to 5.9 microg/g) in the gallbladder wall. In group 2 patients, the amounts of drugs recovered in bile drainage obtained over 12 h were 28.4 +/- 18.0 and 1.0 +/- 0.5 mg for piperacillin and tazobactam, respectively. Peak piperacillin and tazobactam concentrations in bile reached 358 +/- 242 and 10.8 +/- 4.2 microg/ml, respectively. Comparison of drug levels in serum and bile suggests an underlying active secretion process for piperacillin elimination into the bile, unlike that of tazobactam. From a therapeutic viewpoint, given the concentrations of tazobactam recorded in bile fluid and tissue, the addition of this beta-lactamase inhibitor to piperacillin therapy might be of interest in the management of biliary tract infections, mostly in patients at risk of mixed aerobic-anaerobic infections due to beta-lactamase-producing organisms.

Drug administration in chronic liver disease.

Cirrhosis encompasses a range of pathophysiological changes that may alter drug disposition. Drugs that are dependent primarily on the liver for their systemic clearance are more likely to be subject to reduced elimination and subsequent accumulation. Drug accumulation may lead to excessive plasma drug concentrations and adverse effects, if the adverse effects of the drug are concentration-dependent. The effects of hepatic insufficiency on the pharmacokinetics of drugs are not consistent or predictable. Furthermore, the influence of hepatic disease on the disposition of various drugs can vary, even though those drugs may share the same apparent metabolic pathway. Problems in forecasting drug kinetic behaviour are further enhanced by the additional impairment of kidney function (frequently encountered in patients with advanced liver disease) and by the unpredictability of the glomerular filtration rate using customary methods in patients with cirrhosis. Accordingly, dosages are generally adapted empirically, with the help of serum drug concentrations, when applicable. However, drugs eliminated predominantly by hepatic metabolism are not among those most commonly inducing adverse drug reactions or causing severe complications in patients with cirrhosis. Electrolyte disturbances and the hepatorenal syndrome produced by furosemide (frusemide)-the disposition of which is not substantially modified in liver disease-appear to be the most frequent adverse drug reactions in patients with liver disease. Furthermore, clinically significant alterations in the action of medications at concentrations generally considered to be in the normal therapeutic range are not uncommon. Tissue responsiveness to the pharmacological action of some drugs may be modified, as evidenced by the increased susceptibility of the brain in patients with cirrhosis to the action of many psychoactive agents. Another example is the greater susceptibility of such patients to the nephrotoxic potential of aminogly-cosides, which should not be used in this patient group. Drugs may also interfere with adaptive physiological processes induced by liver disease. ACE inhibitors and nonsteroidal anti-inflammatory drugs counteract the enhanced activity of the renin-angiotensin system in advanced liver disease, thereby generating a high risk of excessive hypotension or acute renal failure, respectively. These drugs are best avoided in patients with cirrhosis. Finally, there may be pharmacological effects that overlap with some pathophysiological modifications related to the process of liver disease, such as increased portal pressure produced by some calcium antagonists, or hypoprothrombinaemia related to the inhibition of synthesis of vitamin K-dependent clotting factors by some beta-lactam antibacterials (especially moxalactam and cefamandole). Accordingly, the use of these drugs should be avoided in advanced liver disease. It is noteworthy that reduced drug metabolism in patients with liver disease does not seem to have a significant impact on the frequency of hepatotoxicity. Special caution should be exercised, however, in patients with alcoholic liver disease because excessive alcohol intake may potentiate the hepatotoxic effect of paracetamol (acetaminophen).

[Assessment of the role of enterocyte ion exchange in the intestinal absorption of amoxicillin, based on a study of the interaction with amiloride]. / Evaluation du rôle des échanges ioniques entérocytaires dans l'absorption intestinale de l'amoxicilline par l'étude de l'interaction avec l'amiloride.

Intestinal dipeptide carrier system has been shown in vitro to be involved in intestinal absorption of betalactam antibiotics. Given that efficiency of this transport system depends on a pH gradient (extracellular pH < intracellular pH) at the brush-border membrane of enterocytes, we assessed the effects of amiloride, a known inhibitor of the Na-H exchange, on the bioavilability of oral amoxicillin in eight normal volunteers. Following a single 10 mg oral dose of amiloride, the absolute bioavailability of oral amoxicillin turned out to decrease by 27% (p < 0.01). The extent of reduction of oral amoxicillin AUC appeared to significantly correlate (p = 0.005) with the extent of decrease in potassium renal excretion but not with variations in antibiotic renal clearance under amiloride effect. Such patterns seem to confirm in vivo the role of the Na-H exchange in betalactam absorption and to suggest the underlying regulatory function of intracellular Na concentration, the latter depending on the (NaK)-ATPase activity.

Amoxicillin intestinal absorption reduction by amiloride: possible role of the Na(+) -H+ exchanger.

Intestinal absorption of beta-lactam antibiotics has been shown to use the dipeptide carrier system. In vitro experiments have established that the efficiency of uptake by enterocytes depends on an inwardly directed proton gradient--dipeptides and beta-lactam antibiotics being cotransported along with hydrogen ion. This gradient is thought to result from the sodium-hydrogen (Na(+)-H+) exchanger located on the brush-border membrane. The aim of the present study was to assess the in vivo relevance of these data in humans by examining the effect of amiloride, a well-known inhibitor of the Na(+) -H+ exchanger, on the bioavailability of amoxicillin in eight healthy volunteers. The results show that amiloride reduces significantly amoxicillin absorption rate (mean time to maximum concentration increases from 1.0 to 1.6 hours, p < 0.05) and absolute bioavailability (by 27%, p < 0.01) and that amiloride-induced inhibition of the intestinal Na(+) -H+ exchange could be associated with an additional inhibitory effect on (Na/K)-ATPase activity. The present data seem to confirm the role of Na(+) -H+ exchange in the uptake of beta-lactams by the intestine and to support the indirect sodium dependence of this carrier system in vivo.

Pharmacological, toxicologic, and microbiological considerations in the choice of initial antibiotic therapy for serious infections in patients with cirrhosis of the liver.

Infection remains a leading cause of death among patients with cirrhosis of the liver. The high level of susceptibility of these patients to septicemic infection is accounted for by decreased reticuloendothelial function and impairment of several components of cell-mediated and humoral immunity. Escherichia coli and Streptococcus pneumoniae are the pathogens most frequently involved and must be covered by any empirical antibiotic regimen administered to seriously ill cirrhotic patients. In addition, antibiotic therapy in this situation must take into account cirrhosis-induced changes in the kinetic and dynamic behavior of antibacterial agents. Given the great toxic potential of aminoglycosides in liver cirrhosis, these agents should be used very cautiously. The third-generation cephalosporins are currently advocated for the treatment of severe infections in cirrhotic patients because of their high level of intrinsic activity against the most commonly encountered pathogens as well as their safe use at high doses for patients with liver insufficiency. The role of the quinolones deserves further clinical evaluation; the limited activity of these agents against S. pneumoniae is undoubtedly a drawback to their use as empirical monotherapy. Despite the potent antibacterial agents that have recently become available, the overall prognosis of these patients is difficult to improve because it remains closely related to the severity of their underlying liver disease.

Hepatic side-effects of antibiotics.

Although the liver is particularly exposed to drugs and their metabolites, hepatic side-effects of antibiotics are far less frequent than other adverse effects such as gastrointestinal disorders or cutaneous reactions. However, the potential severity of hepatic side-effects for some drugs is stressed. Antibiotic related liver injuries cover most of the clinical and pathological expressions of hepatic dysfunction, including cytotoxic hepatitis (isoniazid), intrahepatic cholestasis (macrolides, penicillins, clavulanic acid), mixed hepatitis (sulphonamides), chronic active hepatitis (nitrofurantoin), or microvesicular steatosis (tetracycline). In most cases, toxicity is idiosyncratic, reactions occurring only in some susceptible individuals. The mechanisms underlying toxicity may be primarily metabolite-dependent (isoniazid), hypersensitivity-mediated (beta-lactams), or result from both processes (sulphonamides, erythromycin derivatives). In some cases, the liver is not the primary target organ for toxicity but appears to mediate the clinical expression of some adverse effects induced by antibiotics. The most significant example of this is hypoprothrombinaemia due to the inhibition of hepatic gamma-carboxylation of vitamin K-dependent clotting factors by sulphydryl group-containing cephalosporins. Inhibition of bilirubin conjugation or transport by rifampicin or fusidic acid may also be viewed as hepatic side-effects of antibiotics. Ascertaining the casual relationship of a given drug to an hepatic adverse effect may prove particularly difficult, because of the potential contribution of host status and concurrent medications. Diagnosis is based mainly on circumstantial evidence, i.e. the temporal relationship between drug administration (or withdrawal) and the time-course of liver dysfunction. Improving morbidity related to drug hepatotoxicity relies on a free flow of information between manufacturers and practitioners in order to optimize detection of potentially serious liver damage, and advances in pharmacogenetics toward a better identification of those at particular risk for developing drug-related liver toxicity.

[Kinetics of cefixime biliary clearance in cholecystectomized patients]. / Cinétique de la clairance biliaire du céfixime chez des patients cholécystectomisés.

Cefixime is an orally administered cephalosporin with physicochemical properties able to account for a possibly significant biliary excretion. In addition, over 50% of total clearance of the drug has been shown to operate through extra renal pathways in healthy volunteers. The aim of the study was to quantify and to delineate the kinetics of cefixime biliary elimination in ten patients provided with external drainage. Following a single 200 mg oral dose of cefixime, biliary clearance of the drug appears to vary from 0.85 to 27.3 ml/min. Contribution of the latter to the apparent total clearance is relatively low since ranging from 0.8 to 18.6% (mean 5%). Additionally, biliary clearance kinetics of the drug proves non linear and well described according to a sigmoidal model. On account of these results, and given the dianionic charge of the molecule as well as the absence of any metabolite reported so far, an intrahepatic binding and accumulating process, mediated by ligandin, seems to underlie the hepatobiliary excretion of cefixime, as previously reported for other anionic beta-lactam antibiotics.

Biliary elimination and hepatic disposition of an association of piperacillin and tazobactam: experimental evaluation.

Biliary elimination and hepatic disposition of tazocillin, an association of a highly bile-excreted ureido-penicillin, piperacillin, with a beta-lactamase inhibitor, tazobactam, have been assessed applying an isolated perfused rabbit liver experimental model. Six investigations were performed, each during a 3 h period, using reconstituted blood circulating in a closed circuit. Piperacillin and tazobactam concentration in all specimens were determined by high performance liquid chromatography. Blood samples and cumulative bile secretion were collected every 30 min, and liver fragments were isolated at the end of each experiment for dosage purposes. Following the simultaneous administration of piperacillin 80 mg and tazobactam 10 mg (dose ratio 8/1) in the perfusion device, theoretical initial serum concentrations were respectively 414 micrograms/ml and 32.1 micrograms/ml. Maximal biliary concentrations of 4431 +/- 1541 (s.d.) of piperacillin and 21.3 +/- 7.8 micrograms/ml of tazobactam were reached between 0.5-1 h and 2.5-3 h, respectively. Cumulative biliary excretion (0-3 h) amounted to 37.6 +/- 17.7% of the administered dose for piperacillin and 1.5% for tazobactam. At the end of the perfusion, respectively 22.1% and 50.7% of piperacillin and tazobactam doses remained in the circulating blood, while 1.1% and 5.6% were found in the liver. On the basis of these data, the calculated percentages of piperacillin and tazobactam doses having undergone hepatic biotransformation, were 6.5% and 1.2%, respectively. Under such experimental conditions, concentrations and excretion of piperacillin in bile prove to be substantial. Of note, tazobactam concentrations turn out to be stable both in serum and in bile whereas they stay at a relatively constant level of 20 micrograms/ml during nearly all the perfusion time.(ABSTRACT TRUNCATED AT 250 WORDS)

Role of intrahepatic protein binding in the hepatobiliary extraction profile of cefixime in humans.

The hepatobiliary extraction profile of cefixime, a dianionic cephalosporin antibiotic, was studied in 10 patients, each of whom was provided with T-tube drainage of his or her common bile duct after cholecystectomy. After a single 200 mg oral dose, cefixime biliary clearance proved to be nonlinear, mostly in its initial phase, which is consistent with a concentrative uptake and intracellular protein binding for the drug. The latter process appears to be saturable and to operate at a rate that correlates with the total amount of cefixime recovered in the 24-hour bile drainage. Such findings seem to confirm the significant role played in vivo by hepatic ligandin in the hepatobiliary extraction of organic anions. The data also show that a single 200 mg oral dose of cefixime yields drug levels in bile substantially higher than the minimal inhibitory concentrations for the most frequent Enterobacteriaceae in biliary tract infections. Accordingly, this cephalosporin could be an interesting alternative in both prophylaxis and treatment of biliary tract infections.

Biliary excretion of cefixime: assessment in patients provided with T-tube drainage.

The biliary excretion profile of cefixime was studied in 10 patients provided with T-tube drainage of the common bile duct after cholecystectomy. Following a single 200-mg oral dose, the peak concentration of cefixime in bile reached 56.9 +/- 70 mg/liter, approximately 20 times as high as the peak concentration in serum, 2.3 +/- 0.85 mg/liter. Cefixime levels in bile proved relatively sustained, since a concentration of 4.3 +/- 3.7 mg/liter was still found 20 h after dosing. The cumulative amount of cefixime recovered in the 24-h bile drainage averaged 10.0 +/- 12.3 mg, which is 5% of the administered dose and positions this beta-lactam antibiotic among the most highly bile-excreted cephalosporins. The presented results show that a single 200-mg oral dose of cefixime provided drug levels in bile consistently higher than the MICs for the most frequently recovered members of the family Enterobacteriaceae in biliary tract infections and maintained these levels for over 20 h after dosing. Accordingly, this cephalosporin deserves further clinical trials to assess its usefulness in both prophylaxis and treatment of biliary tract infections.

Clinical pharmacokinetics of newer antibacterial agents in liver disease.

Liver disease may produce significant, albeit highly variable, effects on the pharmacokinetic behaviour of antibiotics in serum. Drug disposition may be altered through several pathophysiological mechanisms including reduced hepatobiliary clearance, and modifications in the volume of distribution induced by albumin synthesis deficiency or portal hypertension-related ascites. Antibacterial agents are not affected by potential alteration in hepatic first-pass effects. Only liver cirrhosis-induced effects on serum pharmacokinetics of antibiotics have been extensively studied, unlike those possibly produced by other forms of liver disease. In liver cirrhosis, pharmacokinetic alterations of nearly all beta-lactam or quinolone agents appear not to be marked enough to require dosage adjustment, provided that renal function stays normal. Adaptation in therapeutic schedule, however, is warranted for those drugs that are substantially cleared by the hepatobiliary system, namely mezlocillin, clindamycin, erythromycin, pefloxacin, enoxacin, antituberculous agents or nitroimidazole derivatives. Special caution should also be exercised when using aminoglycosides or vancomycin because of the wide interpatient variability of their pharmacokinetic disposition and their toxic potential. When renal function is impaired and there is an increased volume of distribution due to ascites, as frequently observed in severe liver insufficiency, the elimination half-life of most antibiotics is markedly prolonged, resulting in potential side effects due to drug accumulation. Accordingly, dosage adjustment applies to all drugs. In this regard, it should be remembered that delineating the dosage guidelines for a given antibiotic on the basis of reported pharmacokinetic parameters in patients with liver cirrhosis is awkward and probably of limited value. This pattern is ascribed to large interpatient variability in the active hepatic cell mass, the degree of portal hypertension and the alteration of serum binding capacity. Furthermore, there is no way of predicting accurately the extent of liver insufficiency in an individual patient. Dosage reduction is thus done empirically in most cases. Whenever possible, direct measurements of serum antibiotic concentrations should be the reasonable approach to manage antibiotic therapy in this kind of clinical condition.

Modification of cefixime bioavailability by nifedipine in humans: involvement of the dipeptide carrier system.

We studied the action of nifedipine on the bioavailability of cefixime, a molecule absorbed via the gut wall dipeptide carrier system in the rat, and on the bioavailability of D-xylose, which is absorbed via a pH (and Na(+)-)-dependent transporter. Each compound was administered alone or in combination with 20 mg of nifedipine to eight healthy male volunteers. Nifedipine significantly increased the absorption rate of cefixime (20.7 +/- 4.3 versus 16 +/- 3.5 mg/h in the absence of nifedipine). The absolute bioavailability of cefixime alone was 31% +/- 6% compared with 53% +/- 1% (P < 0.01) in the presence of nifedipine. The observed peak concentrations in serum were significantly different (2.5 +/- 0.3 mg/liter without nifedipine and 3.7 +/- 1.1 mg/liter with nifedipine; P < 0.02). In contrast, nifedipine induced no significant differences in the pharmacokinetic profile of xylose following oral administration. We conclude that (i) cefixime is absorbed in humans by an apparently active process which can be enhanced by a calcium channel blocker, in this case, nifedipine; and (ii) nifedipine does not modify the activity of the pentose transporter.

Adaptive computer program for determination of absorption profiles by numerical deconvolution: application to amoxicillin absorption.

We have developed a specific numerical deconvolution program for the Apple Macintosh microcomputer. After comparison with other methods, we used the program to evaluate the influence of nifedipine on the absorption and bioavailability of amoxicillin. The technique provided a model-independent approach. This study shows that the simultaneous administration of nifedipine with amoxicillin leads to a significant increase in both the total quantity of amoxicillin absorbed (+22%) and the rate of absorption. Parameters of clearance, volume of distribution, and elimination were unaffected. Numerical deconvolution analysis showed that nifedipine did not modify the absorption kinetics of amoxicillin, which are characterized by a lag time followed by a constant rate of absorption, suggesting zero-order kinetics with first-order kinetics at the end of the process. The results suggest the existence of a specialized, saturable transport molecule for this antibiotic.

[Biliary excretion and hepatic disposal of cefixime: experimental and clinical study]. / Elimination biliaire et disposition hépatique du céfixime: étude expérimentale et clinique.

Cefixime is a new oral cephalosporin with in vitro activity similar to that of third-generation cephalosporins. Renal excretion accounts for only 40% of systemic clearance of cefixime, suggesting that biliary excretion of the drug may be significant. This study was designed to determine to what extent nonrenal clearance of cefixime is due to biliary excretion of the parent compound. In an isolated perfused rabbit liver model, biliary excretion of cefixime was very low, with only 0.28 +/- 0.15% of a single 10 mg dose injected in the system being recovered in the bile after three hours perfusion. The liver biotransformation rate for cefixime was found to be 16.2%. These results are in striking contrast with those obtained in human studies. Cefixime levels in duodenal juice aspirates collected over four hours following an intravenous injection of 200 mg cefixime in six healthy volunteers were at least fivefold concomitant serum levels. Studies of bile collected by external biliary drainage during 24 hours following an oral dose of 200 mg cefixime in ten cholecystectomized patients showed that the Cmax was 56.9 +/- 70 mg/l, i.e., 25-fold the serum Cmax (2.3 +/- 0.85 mg/l). The bile AUC/serum AUC ratio was 20.4 +/- 20.3. Mean bile level of cefixime was still as high as 4.3 +/- 3.7 mg/l 20 hours after dosing. The amount of cefixime excreted in the bile over 24 hours was 10.0 +/- 12.3 mg i.e., 5% of the dose administered. Twenty-four hour renal excretion of cefixime was 53.3 +/- 26.2 mg.(ABSTRACT TRUNCATED AT 250 WORDS)

Evaluation of cefixime biliary disposition in the isolated perfused rabbit liver model and in humans.

Cefixime is a new orally effective third-generation cephalosporin. It inhibits a wide variety of Gram-positive and Gram-negative bacteria, especially most of the Enterobacteriaceae. Since extrarenal excretion processes have been reported to account for 60% of cefixime systemic clearance we have endeavoured to determine the place taken up by biliary excretion of unchanged cefixime in this pattern. We initially used the isolated perfused rabbit liver technique. Six perfusions were performed. Cefixime concentrations were measured by HPLC chromatography. After addition of a single 10-mg dose of cefixime to the circulating blood, biliary elimination of the drug proved to be very low, since only 0.28 +/- 0.15% of the dose was recovered during the 3-h perfusion period. The rate of cefixime biotransformation in the liver was found to be 16.2%. In contrast, the data obtained in humans highlight substantial biliary excretion of the drug. In six healthy volunteers submitted to duodenal aspiration and receiving a single 200-mg i.v. dose of cefixime, drug levels in duodenal fluid were at least fivefold greater than the simultaneous concentrations in serum. Biliary excretion of cefixime was further investigated in ten cholecystectomized patients provided with T-tube drainage: following a single 200 mg oral dose of cefixime, Cmax in bile reached 56.9 +/- 70 mg/l, that is about 25 times as high as Cmax in serum, 2.3 +/- 0.85 mg/l. Drug levels in choledochal bile proved to be sustained, since a concentration of 4.3 +/- 3.7 mg/ml was still observed 20 h after dosing.(ABSTRACT TRUNCATED AT 250 WORDS)