The effects of 1-methyl-5-thiotetrazole in a rat liver vitamin K-dependent carboxylase assay

Hypoprothrombinemia associated with cefmetazole

OBJECTIVE

To report a case of hypoprothrombinemia associated with the use of cefmetazole sodium, define patients at risk for this adverse effect, and identify options to prevent this problem.

CASE SUMMARY

A malnourished patient with endstage renal disease received cefmetazole following a below-the-knee amputation of the right leg. Three days later, a prothrombin time (PT) and an international normalized ratio (INR) were obtained and were markedly elevated from baseline; however, the patient had no clinical symptoms of bleeding. Cefmetazole was discontinued. Vitamin K and fresh frozen plasma were administered. The PT and INR normalized within 24 hours and remained normal throughout the remainder of hospitalization.

DISCUSSION

The incidence of hypoprothrombinemia associated with cefmetazole reported in the literature is conflicting and not consistent. There are three proposed mechanisms of cephalosporin-associated hypoprothrombinemia, two of which involve the N-methylthiotetrazole (NMTT) chain. The most plausible mechanism is NMTT inhibition of vitamin K epoxide reductase in the liver. Patients at an increased risk for this adverse event include those with low vitamin K stores, specifically patients who are malnourished, with low albumin concentrations and poor food intake. The elderly and patients with liver or renal dysfunction are examples of populations at risk.

CONCLUSIONS

Hypoprothrombinemia may occur with cephalosporins and is especially problematic with those containing an NMTT side chain. Clinicians need to identify patients at risk for developing antibiotic-associated hypoprothrombinemia, monitor them closely, and give vitamin K as prophylaxis accordingly.

Comparative evaluation of the pharmacokinetics of N-methylthiotetrazole following administration of cefoperazone, cefotetan, and cefmetazole

The comparative pharmacokinetics and in vivo production of N-methylthiotetrazole (NMTT) were evaluated following administration of cefoperazone, cefotetan, and cefmetazole. In a randomized-crossover manner, 11 healthy male volunteers received single 2-g intravenous doses of each agent and serial blood and urine samples were collected. Concentrations of NMTT and the parent compound in plasma, urine, and the reconstituted antibiotic solution were determined by high-pressure liquid chromatography. The amounts of NMTT administered were 6.06 +/- 0.46, 14.4 +/- 0.87, and 17.4 +/- 1.06 mg for cefoperazone, cefotetan, and cefmetazole, respectively (P less than 0.05). The mean NMTT plasma concentration-time profiles following administration of each cephalosporin were markedly different. Six hours after dosing, NMTT concentrations in plasma following cefoperazone administration were higher than those following administration of cefmetazole and cefotetan. Urinary recoveries of NMTT averaged 137.0 +/- 37.1, 38.3 +/- 6.98, and 25.2 +/- 5.95 mg following administration of cefoperazone, cefotetan, and cefmetazole, respectively (P less than 0.01). The apparent amount of NMTT produced in vivo, calculated by subtracting the amount of NMTT administered from the amount of NMTT excreted in urine, was significantly lower following cefmetazole administration than after administration of cefoperazone and cefotetan (P less than 0.01). The discrepancy between in vitro NMTT production (cefmetazole greater than cefotetan greater than cefoperazone) and the amount of NMTT formed in vivo and excreted unchanged (cefoperazone greater than cefotetan greater than cefmetazole) suggests that in vivo production of NMTT is dependent on the disposition of the parent cephalosporin. These results further suggest that cephalosporins which undergo extensive biliary excretion, such as cefoperazone, are associated with the greatest amount of in vivo NMTT release, whereas cephalosporins which are primarily renally excreted, such as cefmetazole, are associated with the lowest in vivo production of NMTT.

Fast-LC determination of 1-methyl-1H-tetrazole-5-thiol in human plasma with column-switching sample clean-up

A simple, fast and sensitive method for the quantitative determination of 1-methyl-1H-tetrazole-5-thiol using HPLC is reported. Samples are deproteinated by plasma water filtration and injected into a HPLC system capable of column switching and backflushing the analytical column. The limit of quantitation was determined to be 70 ng ml-1 and the limit of detection 22 ng ml-1. Between-day precision (expressed as percent coefficient of variation) of standard curve slopes was +/- 3.5% with a range of within-day percent coefficient of variations from 0.28 to 1.4%. Recovery and precision of spiked control samples was 96 +/- 7% over a concentration range of 630-6300 ng ml-1.

Depression of liver microsomal vitamin K epoxide reductase activity associated with antibiotic-induced coagulopathy

Hypoprothrombinemic changes in blood coagulation parameters, such as prolongation of prothrombin time, increase in the level of plasma protein induced by vitamin K absence, and decrease in plasma prothrombin level, were detected in rats fed a vitamin K-deficient diet. These changes were enhanced by the administration of beta-lactam antibiotics containing N-methyltetrazolethiol, thiadiazolethiol or methyl-thiadiazolethiol. Microsomal vitamin K epoxide reductase activity was suppressed with the maximum effect at 1-2 days after the treatment and with recovery, thereafter, gradually to the normal level after 5-7 days. Hypoprothrombinemic alterations in blood coagulation parameters following a single administration of antibiotic to vitamin K-deficient rats were somewhat delayed compared with the change in the epoxide reductase activity, but the effects of the antibiotic on both blood coagulation parameters and the enzyme activity disappeared completely 7 days after the antibiotic treatment. Antibiotic-induced depression of the epoxide reductase activity was observed even in the vitamin K sufficient rats, although the hypoprothrombinemic changes in the blood coagulation parameters did not develop. Vitamin K administration could normalize the blood coagulation parameters in the hypoprothrombinemic rats caused by treatment with the antibiotics but without recovery of the decreased epoxide reductase activity. These results suggest that some antibiotics inhibit liver microsomal vitamin K epoxide reductase, which causes hypoprothrombinemia to develop under vitamin K-deficient conditions.

Comparison of N-methylthiotetrazole dispositions in healthy volunteers following single intravenous doses of moxalactam, cefoperazone, and cefotetan

The N-methylthiotetrazole side chain (NMTT) that is present on several cephalosporins has been implicated in the development of antibiotic-associated hypoprothrombinemia. A randomized three-way crossover trial was conducted to compare the release of the NMTT side chain from three NMTT-containing antibiotics. Single 2-g doses of moxalactam, cefoperazone, and cefotetan were given, followed by serial blood and urine sampling. The concentrations of the parent compound and the NMTT side chain in plasma, urine, and the reconstituted antibiotic solution were determined by high-pressure liquid chromatography. Peak NMTT concentrations ranged from 0.42 to 16.50 micrograms/ml and were significantly higher after moxalactam administration than after cefoperazone or cefotetan administration (P less than 0.01). The NMTT trough concentrations (12.5 h) ranged from nondetectable to 2.47 micrograms/ml and tended to be greater following cefoperazone administration. The amounts of NMTT administered (e.g., the amount in the reconstituted antibiotic solution) were 25.8 +/- 1.4, 15.2 +/- 0.9, and 22.1 +/- 3.0 mg following moxalactam, cefoperazone, and cefotetan administration, respectively (P less than 0.01). In contrast, urinary recoveries of NMTT were 57.4 +/- 26.2, 73.6 +/- 44.3, and 29.7 +/- 22.9 mg following moxalactam, cefoperazone, and cefotetan, respectively. The amount of NMTT formed in vivo and excreted unchanged, as assessed by subtracting in vitro NMTT formation from NMTT urinary recovery, was significantly higher after cefoperazone than after moxalactam or cefotetan administration (P less than 0.05). The discrepancy between in vitro NMTT production (moxalactam > cefotetan > cefoperazone) and the amount of NMTT formed in vivo and excreted unchanged (cefoperazone > moxalactam > cefotetan) demonstrated that the in vivo production of NMTT is dependent on the disposition of the parent cephalosporin.

Impaired hemostasis caused by beta-lactam antibiotics

Beta-lactam antibiotics can directly impair hemostasis by two separate nonimmune mechanisms. First, the NMTT-substituted cephalosporin drugs may cause hypoprothrombinemia by interfering with the hepatic activation of clotting factors II, VII, IX, and X. Second, the antipseudomonal penicillins may cause the bleeding time to be prolonged by interfering with platelet aggregation to physiologic agonists. In surgical patients who are malnourished, have impaired gastrointestinal function, or have renal failure, the potential for these adverse effects is increased. Serious bleeding requires treatment with fresh frozen plasma when hypoprothrombinemia is caused by NMTT-containing cephalosporins, since the prothrombin time returns to baseline relatively slowly after therapy with vitamin K. Hemorrhage caused by beta-lactam-induced platelet dysfunction must be treated with platelet concentrates, since new platelets sufficient to correct the defect do not enter the circulation for several days after treatment with the offending drug is discontinued. The more desirable approach is to prevent hypoprothrombinemia by giving vitamin K prophylaxis and to avoid beta-lactams that impair platelet function in seriously ill patients at increased risk for bleeding.

In vivo effects of beta-lactam antibiotics and heterocyclic thiol compounds on vitamin K-dependent carboxylation activity and blood coagulation factors in vitamin K-deficient rats

The in vivo effects of heterocyclic thiol compounds, corresponding to the 3'-position substituents of several beta-lactam antibiotics, on blood coagulation factors and on liver microsomal gamma-glutamylcarboxylation (gamma-carboxylation) activity were evaluated in rats maintained on a vitamin K-deficient diet. These rats, when compared to normal control animals, exhibited hypoprothrombinemic changes: prolongation of both prothrombin time and activated partial thromboplastin time, decreases in factor VII and plasma prothrombin, and increases in PIVKA II (descarboxyprothrombin) both in plasma and liver. They also displayed a marked increase in liver microsomal gamma-carboxylation activity. These blood coagulation variables could be altered markedly by administering various heterocyclic thiol compounds to the vitamin K-deficient rats, although these compounds did not inhibit gamma-carboxylation activity in an assay system using phylloquinone. A similar pattern of alteration was observed when some beta-lactam antibiotics were administered. Increased microsomal gamma-carboxylation activity in antibiotic-treated vitamin K-deficient rats was normalized by the administration of vitamin K, concomitant with the recovery of blood coagulation variables to the normal range. The results indicate that antibiotic-induced hypoprothrombinemia in vivo is not caused by inhibition of enzymes of the gamma-carboxylation system, such as vitamin K reductase and gamma-glutamylcarboxylase, but is related to the endogenous vitamin K level.

The development of hypoprothrombinaemia following antibiotic therapy in malnourished patients with low serum vitamin K1 levels

A group of nine well-nourished patients, with normal serum vitamin K1 levels (mean 546, range 310-1350 pg/ml), maintained normal prothrombin times (PTs) and factor VII clotting activities throughout a 7 d course of i.v. cefotetan disodium, an N-methyl-thiotetrazole (NMTT) containing cephalosporin antibiotic. However, 11 of 20 patients, with acute intra-abdominal sepsis and initially normal PTs who underwent emergency surgery, developed prolonged PTs (INR 1.4-3.1) associated with reduction in factor VII activities (0.74-0.38 u/ml) after 3-7 d of antibiotic therapy. Nine of these 11 patients had clinical evidence of malnutrition and nine had subnormal serum vitamin K1 levels (mean 119, range 43-354 pg/ml) on admission. Seven received cefotetan but four were treated with a non-NMTT-containing cephalosporin or antibiotics belonging to other groups. The nine patients who maintained normal PTs all had normal nutritional status and normal serum vitamin K1 levels (mean 279, range 103-915 pg/ml) at presentation. The PT is a relatively insensitive indicator of vitamin K stores, and malnourished patients with low serum vitamin K1 levels are at risk of developing hypoprothrombinaemia following intravenous antibiotic therapy.

Mechanism of cephalosporin-induced hypoprothrombinemia: relation to cephalosporin side chain, vitamin K metabolism, and vitamin K status

The mechanism of cephalosporin-induced hypoprothrombinemia has been investigated in hospitalized patients, with respect to cephalosporin structure, vitamin K metabolism, and vitamin K status. Cephalosporins containing side chains of N-methylthiotetrazole (latamoxef, cefmenoxime, cefoperazone, cefotetan, cefamandole) or methyl-thiadiazole (cefazolin) all caused the transient plasma appearance of vitamin K1 2,3-epoxide in response to a 10-mg intravenous dose of vitamin K1, whereas two cephalosporins without a heterocyclic side chain (cefotaxime and cefoxitin) did not. The plasma accumulation of vitamin K1 2,3-epoxide was qualitatively similar to, but quantitatively less than, that produced by the oral anticoagulant phenprocoumon. Patients eating normally had plasma vitamin K1 concentrations (176 to 1184 pg/mL) that were within the normal range (150 to 1550 pg/mL) and their clotting tests remained consistently normal for all antibiotics tested. Patients on total parenteral nutrition had lower plasma vitamin K1 concentrations (50 to 790 pg/mL) but normal clotting before starting antibiotic therapy. Of 19 parenterally fed patients, all seven treated with latamoxef developed hypoprothrombinemia, PIVKA-II and a decrease of protein C within four days whereas 12 patients treated with cefotaxime or cefoxitin showed no clotting changes. Latamoxef-associated hypoprothrombinemia was readily reversible by 1 mg of vitamin K1 given intravenously, but hypoprothrombinemia and sub-normal plasma vitamin K1 could recur within two to three days. The data suggest that NMTT-cephalosporins are inhibitors of hepatic vitamin K epoxide reductase and that a lower nutritional-vitamin K status predisposes to hypoprothrombinemia.

Disposition of moxalactam and N-methyltetrazolethiol in rats and monkeys

The disposition of moxalactam (MOX) and N-methyltetrazolethiol (NMTT) in rats and monkeys after intravenous injection was investigated, focusing on the in vivo liberation of NMTT, by using [NMTT-14C]MOX and [14C]NMTT. After [NMTT-14C]MOX injection, MOX levels in plasma quickly became high in both rats and monkeys and then declined, with half-lives at the beta phase of 18.8 and 67.1 min, respectively. The levels of NMTT liberated from MOX were much lower than those of MOX, but the apparent elimination was significantly slow. The levels of MOX and NMTT in rat liver were almost comparable but lower than those in plasma. With [14C]NMTT administration, the level of NMTT in plasma declined, with half-lives at the beta phase of 21.5 min in rats and 54.0 min in monkeys. After [NMTT-14C]MOX injection, most of the radioactivity was excreted in urine as MOX, with 11% of the dose in rats and 8% of the dose in monkeys eliminated as NMTT until 24 h. Total biliary excretion was 26% of the injected radioactivity in rats, and most of it was due to MOX. In one monkey, the total biliary excretion was only 0.2% of the injected radioactivity. With [14C]NMTT administration, most radioactivity was excreted in the urine as unchanged NMTT in both animals. Oral administration in rats showed that part of the biliary-excreted MOX was degraded to NMTT in the intestine and then absorbed. Repeated administration of [NMTT-14C]MOX to rats did not change the levels of MOX and NMTT in plasma or liver nor did it change the excretion profiles. Thus, accumulation of MOX and NMTT did not occur.

Effect of N-methyl-thiotetrazole on vitamin K epoxide reductase

Clinical use of antibiotics containing a N-methyl-thiotetrazole (NMTT) side chain has been reported to be associated with an increased incidence of a vitamin K-responsive hypoprothrombinemia. Administration of NMTT to rats decreased the activity of the liver microsomal vitamin K epoxide reductase, increased the liver ratio of vitamin K epoxide to vitamin K, and decreased the rate of metabolism of injected vitamin K epoxide. These responses are the same as those observed following the administration of coumarin anticoagulants. In contrast to the effect of coumarin anticoagulants, NMTT did not inhibit the vitamin K epoxide reductase in vitro. These data suggest that the hypoprothrombinemia which has been observed following use of these antibiotics results from the inactivation of the liver vitamin K epoxide reductase by NMTT or a NMTT metabolite.

Effect of N-methyl-thiotetrazole on rat liver microsomal vitamin K-dependent carboxylation

The use of a number of antibiotics which contain an N-methyl-thiotetrazole (NMTT) side chain has been reported to be associated with an increased incidence of hypoprothrombinemia. The suggested role of NMTT as an inhibitor of the liver microsomal vitamin K-dependent carboxylase has been investigated. In standard incubations, NMTT had no effect on carboxylation when vitamin KH2 was a substrate but was a weak inhibitor when [vitamin K + NADH] was a substrate. Microsomal vitamin K reductases, however, were not inhibited by NMTT. Preincubation of the incubation mixture with NADH and NMTT resulted in inhibition of carboxylase activity when either vitamin KH2 or [vitamin K + NADH] was the substrate. A fraction of the microsomal membrane which was not readily solubilized by dilute detergent protected the enzyme from this inhibition. The data suggest that NMTT is metabolized to an active inhibitor or is able to covalently inactivate the enzyme in the presence of NMTT. The vitamin K responsiveness of the clinically observed hypoprothrombinemia suggests that it is not related to this in vitro inhibition of the vitamin K-dependent carboxylase.

Comparative toxicities of third-generation cephalosporins

Data on the adverse effects experienced by 2,539 patients who received ceftazidime were compared with adverse effects reported with cefoperazone, cefotaxime, ceftizoxime, and moxalactam. There were 216 such reactions among the ceftazidime-treated patients; 158 patients (6.2 percent) had reactions that were possibly or probably drug-related. The clinical and laboratory safety profile of ceftazidime in regard to renal, hepatic, hematopoietic, and hemostatic parameters compared favorably with that of other third-generation cephalosporins. An increased serum creatinine level was observed in 0.8 percent of ceftazidime-treated patients, an increased blood urea nitrogen level in 1.6 percent, hepatic abnormalities in approximately 6 percent, diarrhea in 1.3 percent, pseudomembranous colitis in 0.12 percent, increased prothrombin time in 0.5 percent, and clinical bleeding in none. The incidence of colonization (3.8 percent) and superinfections (3 percent) associated with ceftazidime therapy was comparable to rates with other agents in this class.