Imipenem versus moxalactam in the treatment of serious infections

Derivation of a Precise and Consistent Timeline for Antibiotic Development

Antibiotic resistance is a global health crisis. New classes of antibiotics that can treat drug-resistant infections are urgently needed. To communicate this message, researchers have used antibiotic development timelines, but these are often contradictory or imprecise. We conducted a systematic literature review to produce an antibiotic timeline that incorporates the dates of discovery, first use, and initial reports of the emergence of resistance for the 38 classes of clinically used antibiotics. From our timeline, we derive lessons for identifying new antibiotics that are less prone to resistance. These include a required focus on molecules that exhibit multiple modes of action, possess unusually long 'resistance windows', or those that engage cellular targets whose molecular architectures are at least in part decoupled from evolutionary pressures. Our analysis also further highlights the importance of safeguarding antibiotics as a mechanism for mitigating the development of resistance. We have made our data and sources freely available so that the research community can adapt them to their own needs.

Imipenem/Cilastatin: The First Carbapenem Antibiotic

Imipenem/cilastatin is the first of a new class of β-lactam antibiotics called carbapenems. The antibacterial spectrum of imipenem exceeds any antibiotic investigated to date and includes gram-positive, gram-negative, and anaerobic organisms. Only methicillin-resistant organisms, Strep. faecium, Pseudomonas cepacia, and Pseudomonas maltophilia have been shown to be resistant. Imipenem is administered in a 1:1 ratio with cilastatin, which inhibits a renal enzyme (dehydropeptidase) and improves urinary recovery of imipenem. The elimination half-life of both compounds is 1.0 hours and recommended doses are 0.25–0.5 g iv q6h. Adverse events are similar in nature and incidence to β-lactam antibiotics, with phlebitis/thrombophlebitis, diarrhea, nausea, skin rash, and elevations of hepatic enzymes most common.

Clinical studies in phase II and III trials have shown imipenem/cilastatin to be effective in soft tissue infections, endocarditis, obstetrics and gynecology, complicated urinary tract infections, mixed anaerobic-aerobic infections, osteomyelitis, bacteremias, and pneumonias. Several comparative clinical trials have shown imipenem/cilastatin to be equal in efficacy to combination therapy. Imipenem/cilastatin may prove to be an alternative to combination antibiotic therapy because of its extremely broad spectrum of activity.

Carbapenems and monobactams: imipenem, meropenem, and aztreonam

Imipenem and meropenem, members of the carbapenem class of beta-lactam antibiotics, are among the most broadly active antibiotics available for systemic use in humans. They are active against streptococci, methicillin-sensitive staphylococci, Neisseria, Haemophilus, anaerobes, and the common aerobic gram-negative nosocomial pathogens including Pseudomonas. Resistance to imipenem and meropenem may emerge during treatment of P. aeruginosa infections, as has occurred with other beta-lactam agents; Stenotrophomonas maltophilia is typically resistant to both imipenem and meropenem. Like the penicillins, the carbapenems have inhibitory activity against enterococci. In general, the in vitro activity of imipenem against aerobic gram-positive cocci is somewhat greater than that of meropenem, whereas the in vitro activity of meropenem against aerobic gram-negative bacilli is somewhat greater than that of imipenem. Daily dosages may range from 0.5 to 1 g every 6 to 8 hours in patients with normal renal function; the daily dose of meropenem, however, can be safely increased to 6 g. Infusion-related nausea and vomiting, as well as seizures, which have been the main toxic effects of imipenem, occur no more frequently during treatment with meropenem than during treatment with other beta-lactam antibiotics. The carbapenems should be considered for treatment of mixed bacterial infections and aerobic gram-negative bacteria that are not susceptible to other beta-lactam agents. Indiscriminate use of these drugs will promote resistance to them. Aztreonam, the first marketed monobactam, has activity against most aerobic gram-negative bacilli including P. aeruginosa. The drug is not nephrotoxic, is weakly immunogenic, and has not been associated with disorders of coagulation. Aztreonam may be administered intramuscularly or intravenously; the primary route of elimination is urinary excretion. In patients with normal renal function, the recommended dosing interval is every 8 hours. Patients with renal impairment require dosage adjustment. Aztreonam is used primarily as an alternative to aminoglycosides and for the treatment of aerobic gram-negative infections. It is often used in combination therapy for mixed aerobic and anaerobic infections. Approved indications for its use include infections of the urinary tract or lower respiratory tract, intra-abdominal and gynecologic infections, septicemia, and cutaneous infections caused by susceptible organisms. Concurrent initial therapy with other antimicrobial agents is recommended before the causative organism has been determined in patients who are seriously ill or at risk for gram-positive or anaerobic infection.

In vitro effect of cefodizime, imipenem/cilastatin and co-trimoxazole on dexamethasone and cyclosporin A depressed phagocytosis

Phagocytosis is an important part of the host defense against infection. Antibiotics can influence phagocytic function. In the present study, leukocyte metabolic response to phagocytic challenge by latex was assessed in relation to in vitro addition of cotrimoxazole, imipenem/cilastatin, cefodizime, dexamethasone (DXM), and/or cyclosporin A (CsA). Using latex particles as phagocytic challenge, glucose-1-14C utilization and 14CO2 production were measured by liquid scintillation counting. The phagocytic response was impaired by in vitro addition of DXM or CsA and this setup was used as an experimental model of immunodepression. The addition of co-trimoxazole to control samples (without DXM or CsA) depressed the response to latex challenge, whereas imipenem and cefodizime had a neutral effect. In the presence of DXM, co-trimoxazole induced a further decrease. The depressive effect of DXM was partially neutralized in the presence of cefodizime. With CsA depression, co-trimoxazole also induced a further decrease, imipenem had a neutral effect, while cefodizime partially restored the CsA suppressed reaction. Co-trimoxazole depressed the phagocytic response, imipenem had a neutral effect, whereas cefodizime restored the experimentally induced immunosuppression.

Imipenem

Imipenem is the first of a new class of beta-lactam antibiotics, the carbapenems, to be released for clinical use. It has the broadest antibacterial activity of all antibiotics available for systemic use in humans. It is active against streptococci, methicillin-sensitive staphylococci, Neisseria, Haemophilus, anaerobes, and the common aerobic gram-negative nosocomial pathogens including Pseudomonas. Resistance to imipenem may emerge during treatment of P. aeruginosa infections, as has occurred with other beta-lactam agents; P. maltophilia and P. cepacia are typically resistant to it. Like the penicillins, imipenem has inhibitory activity against enterococci. Daily doses may range from 500 mg to 1 g, every 6 to 8 hours, in patients with normal renal function. The principal toxic effects have been nausea and vomiting, which occur during intravenous infusion, and seizures, which develop in 1 to 3% of treated patients and are likely to occur in the setting of renal insufficiency and underlying disease of the central nervous system. Imipenem should be considered for treatment of mixed bacterial infections and treatment of resistant aerobic gram-negative bacteria that are not susceptible to other beta-lactam agents. In addition to provoking unnecessary toxicity, indiscriminate use of this agent will promote dissemination of resistance against it.

Effects of beta-lactam antibiotics imipenem/cilastatin and cefodizime on cellular and humoral immune responses in BALB/c-mice

The effects of a 7-day chemotherapy with two broad-spectrum beta-lactam antibiotics (imipenem/cilastatin and cefodizime) on the humoral and cellular immune responses in BALB/c-mice were investigated. Antibiotic dosages were calculated on a body weight basis from therapeutical dosages in human medicine. Treatment of experimental mice with imipenem/cilastatin and cefodizime did not influence the production of immunoglobulines (IgM and IgG) nor the delayed type hypersensitivity to oxazolone. In vitro, exposure of human granulocytes to imipenem/cilastatin and cefodizime did not interfere with their phagocytic activity as determined by chemiluminescence assay. Subinhibitory concentrations of both antibiotics modified Staphylococcus aureus and made them more susceptible for granulocyte phagocytosis in chemiluminescence assays.

Biliary excretion of imipenem-cilastatin in hospitalized patients

Imipenem-cilastatin concentrations in bile were measured in 12 cholecystectomy patients (group 1) and 12 patients with common duct drainage (group 2). Six patients in each group received 0.5 g, and six received 1.0 g intravenously over 30 to 60 min. In group 1, bile was collected a mean of 85 min postinfusion. The mean concentrations of imipenem in bile were 1.3 microgram/ml after the 0.5-g dose and 3.5 micrograms/ml after the 1.0-g dose. The mean concentrations of cilastatin in bile were 9.0 micrograms/ml after the 0.5-g dose and 38.0 micrograms/ml after the 1.0-g dose. In patients with common duct drainage, bile was collected predose and 0 to 2, 2 to 3, 3 to 4, and 4 to 6 h postinfusion. Peak imipenem concentrations in bile were 4.4 micrograms/ml after the 0.5-g dose and 8.6 micrograms/ml after the 1.0-g dose. Peak cilastatin concentrations in bile were 4.6 micrograms/ml for the 0.5-g dose and 10.9 micrograms/ml for the 1.0-g dose. Peak imipenem concentrations in bile occurred a mean of 2.3 h after administration of the drug; cilastatin peak concentrations occurred at a mean of 2.4 h. Less than 0.3% of each drug was recovered in the bile. Our results suggest that imipenem enters bile by simple diffusion and in most patients attains concentrations sufficient to inhibit susceptible organisms. In contrast, cilastatin had a bimodal entry into bile. Some patients had very high concentrations in bile, whereas others had very low or undetectable concentrations, suggesting that cilastatin may be actively secreted into the bile.

Clinical outcome of nosocomial pneumonia following imipenem/cilastatin therapy

Eighteen patients in a neurosurgery intensive care unit who had nosocomial pneumonia and/or bacteremia were treated with imipenem/cilastatin. The 16 patients who were evaluable had pneumonia; 4 of these had concurrent bacteremia. Eleven patients had a satisfactory clinical response (69 percent) and all patients with positive blood cultures had the organism eradicated. There were 44 organisms isolated from the initial culture of bronchial secretion and 32 of these organisms were gram-negative bacilli (72.5 percent). One patient with pneumonia who initially had Pseudomonas aeruginosa sensitive to imipenem developed resistance during therapy. Adverse effects were minimal; one case of nausea occurred, which was thought to be related to a short infusion time. The most prominent laboratory abnormality was an increase in platelet count, seen in 50 percent of treated patients.

Imipenem/cilastatin. A review of its antibacterial activity, pharmacokinetic properties and therapeutic efficacy

Imipenem is the first available semisynthetic thienamycin and is administered intravenously in combination with cilastatin, a renal dipeptidase inhibitor that increases urinary excretion of active drug. In vitro studies have demonstrated that imipenem has an extremely wide spectrum of antibacterial activity against Gram-negative and Gram-positive aerobic and anaerobic bacteria, even against many multiresistant strains of bacteria. It is very potent against species which elaborate beta-lactamases. Imipenem in combination with equal doses of cilastatin has been shown to be generally well tolerated and an effective antimicrobial for the treatment of infections of various body systems. It is likely to be most valuable as empirical treatment of mixed aerobic and anaerobic infections, bacteraemia in non-neutropenic patients and serious hospital-acquired infections.

Imipenem (N-F-thienamycin) versus netilmicin plus clindamycin. A controlled and randomized comparison in intra-abdominal infections

In a randomized study the clinical and bacteriologic effectiveness of imipenem was compared with the classical combination of netilmicin with clindamycin in patients who had surgery for an intraperitoneal infection, localized or generalized, with positive bacteriologic findings of the specimen taken at surgery. Excluded were all patients who received other antibiotics before surgery, or who died within 3 days after antibiotic therapy was started. Imipenem was given at a dose of 500 mg t.i.d., clindamycin 600 mg t.i.d., and netilmicin according to serum levels. The diagnoses ranged from postoperative peritonitis, gallbladder empyema, perforated gastroduodenal ulcer, small bowel perforation with and without obstruction, and perforated appendicitis to perforation of the colon. The bacteriologic work-up included examination of the primary specimen (aerobic and anaerobic), the urine, feces, and serologic testing for Candida albicans once or twice a week and after the course of antibiotic therapy. In addition, pH measurements of abscesses and drainage fluids were performed. Ninety-three patients entered the study. Forty-seven patients were treated with imipenem (test group), and 46 patients were treated with the combination therapy (control group). The two groups did not show significant differences in age, sex, diagnostic groups, risk factors, primary bacteriology, and duration of therapy (mean: 6.7 days). Thirty-eight patients (80.9%) treated with imipenem were cured, six patients (12.8%) were improved, and there were three (6.4%) failures. The respective numbers for the control group were 31 (67.4%), 10 (21.7%), and 5 (10.9%). The mean duration of hospitalization was 19 days for the test group and 24.5 days for the control group. There were four wound infections in the test group and 11 wound infections in the control group. Imipenem is at least as effective in the adjuvant therapy of intra-abdominal infections as the combination of netilmicin with clindamycin.

Review of imipenem

Imipenem, a new carbapenem beta-lactam broad-spectrum antibiotic, is highly active in vitro against most aerobic and anaerobic gram-positive and gram-negative bacteria isolated from infectious diseases of human beings. Except for enterococci and methicillin-resistant staphylococci most gram-positive cocci are inhibited by less than 2 micrograms/ml. Although the MIC-90 of methicillin-resistant staphylococci may be less than 4 micrograms/ml, these bacteria are usually resistant to imipenem by modified testing methods. The enterococcus, S. faecalis, has an MIC-90 of less than 8 micrograms/ml but bactericidal concentration may be much higher. Most Enterobacteriaceae are highly susceptible to imipenem with MIC-90 of 0.5 to 2.0 micrograms/ml. Proteus species are less susceptible with MICs of 4 to 8 micrograms/ml. Isolates of P. aeruginosa have variable susceptibility with MICs ranging from 0.25 to 16 micrograms/ml. Pseudomonas maltophilia and P. cepacia are usually resistant to imipenem. Except for Clostridium species, most strict anaerobes are susceptible to less than 1.0 micrograms/ml of imipenem. When combined with cilastatin (1:1 ratio), the renal elimination of the active form is increased. The serum halflife in normal renal function is about 1 hour and increases to 3.4 hours in anuria. Major adverse effects are similar to those of cephalosporins except for seizures in some patients. Colonization with fungi and drug-resistant bacteria occurs in about 5% of imipenem-treated patients. Clinical studies have demonstrated efficacy in 79% to 96% of patients treated.

[Calculated initial chemotherapy in mechanically-ventilated postoperative patients with peritonitis, sepsis and pneumonia]

Calculated chemotherapy is based on the knowledge of the typical bacterial agents of a particular infection. From January 1983 to August 1985 bacteriological findings from surgical patients with peritonitis, septicemia or pneumonia treated in an intensive care unit were analysed. The study concentrated on those findings only which differed from previous bacteriological investigations. During the first three days 53 patients on assisted ventilation suffering from peritonitis exhibited mainly enterobacteria in their peritoneal secretions. At day 10 or later we also found bacteria from the pseudomonas group. At that time the bacterial spectrum of bronchial secretions was comparable to that of the peritoneal secretions of the same patient. After day 10, the bacterial spectrum was similar in 36 ventilated patients without peritonitis, in 56 patients suffering from post-operative pneumonia and in peritonitis patients. According to our findings, calculated chemotherapy may be based on the fact that patients with peritonitis who cannot be cured within a few days have a bacterial flora comparable to that of patients with septicemia or pneumonia. Patients with severe infections following surgery, such as potentially fatal pneumonia, generalised peritonitis or septicemia were treated with imipenem/cilastatin, according to the above definitions of calculated chemotherapy. 37 of 46 patients treated between May and December 1985, were clinically cured. Microorganisms persisted in five clinically cured patients. Development of resistance to imipenem was observed in one case. In one case treatment had to be stopped because of an allergic skin reaction. Monotherapy of peritonitis by imipenem/cilastatin appeared more satisfactory than treatment with combinations of other antibiotics.

Imipenem pharmacokinetics and body fluid concentrations in patients receiving high-dose treatment for serious infections

Serum, urine, tissue, and body fluids were collected from 40 adult patients who were receiving imipenem/cilastatin treatment for serious infections. Thirty-two patients were given 1 g every 6 h (4 g/day), and eight received 500 mg (2 g/day). Mean peak concentrations in serum were 34.9 +/- 4.0 micrograms/ml for the 1-g dose and 26.6 +/- 2.5 micrograms/ml for the 500-mg dose. Trough levels were 3.1 and 1.0 micrograms/ml, respectively. No evidence of drug accumulation was found after comparing peaks measured early in the treatment with those measured late. Peak levels were only marginally increased when infusions were given over 30 versus 60 min. The mean serum half-life was 82.0 +/- 25.3 min, with a range of 50 to 138 min. The apparent volume of distribution was 0.35 +/- 0.13 liter/kg, and the mean total body clearance was 0.183 +/- 0.067 liter/kg per h. Creatinine clearance correlated directly with the plasma elimination rate and inversely with the serum half-life. Moreover, total body clearance fell as the age of the patient rose. The mean urinary recovery was 39.1 +/- 12.8% (range, 15.0 to 59.2%) and did not correlate with creatinine clearance until it was below 15 ml/min. Of 20 specimens of various gastrointestinal secretions, 13 had imipenem concentrations that were low, but above the MIC for most resident flora. Pus, sputum, and bone all had concentrations of the drug sufficient to inhibit the infecting organisms, and these levels reflected generally excellent clinical responses.

Imipenem-cilastatin in the treatment of methicillin-sensitive and methicillin-resistant Staphylococcus aureus infections

Imipenem-cilastatin was evaluated for efficacy and toxicity as an antistaphylococcal agent in 23 patients; 11 of these patients were infected with methicillin-resistant Staphylococcus aureus (MRSA), and 12 were infected with methicillin-susceptible S. aureus (MSSA). There were 15 soft tissue, 5 endovascular, and 3 skeletal infections and a total of nine patients with bacteremia. As determined by in vitro susceptibility testing, the MICs for 90% of the MRSA and MSSA isolates tested were 6.25 and 0.39 micrograms/ml, respectively. Two MRSA isolates were resistant to a concentration of greater than 16 micrograms/ml. When 11 MRSA isolates and 7 MSSA isolates were incubated for 48 h the MICs for 90% of the isolates increased to greater than 50 micrograms/ml for the MRSA isolates and 6.25 micrograms/ml for the MSSA isolates. Three S. aureus isolates emerged resistant. Ten of 11 (91%) MRSA infections and 11 of 12 (92%) MSSA infections were clinically cured. Adverse reactions occurred in 25% of the imipenemcilastatin-treated patients. These reactions included gastrointestinal intolerance (7% of the patients), rash or pruritus (6%), eosinophilia (6%), thrombocytosis (4%), and a positive, direct Coomb test without hemolysis (3%). One of the two patients for whom therapy was discontinued because of gastrointestinal intolerance had antibiotic-associated colitis. Imipenem appears to be an effective antistaphylococcal agent against both MRSA and MSSA infections.

Cilastatin does not alter superoxide dismutase activity

Cilastatin inhibits dehydropeptidase-I, a zinc metaloenzyme that metabolizes imipenem. Because zinc stabilizes the mammalian superoxide dismutase, we postulated that cilastatin would also inhibit the dismutase. Cilastatin concentrations at levels threefold higher than those expected in urine, however, did not inhibit the superoxide dismutase activity.

Imipenem/cilastatin in the treatment of osteomyelitis

Thirty-four patients with osteomyelitis were treated for a mean of 32.5 days with 2 to 4 g per day of imipenem/cilastatin. Twenty-six infections involving the lower extremities were associated with accidents and prosthesis implantation, and 19 of 34 patients had more than one organism isolated. Gram-positive and gram-negative organisms were equally represented, but follow-up bone culture samples showed only 11 percent of gram-positive organisms persisted versus 23 percent of gram-negative organisms. Seventy-four percent of patients were cured or improved, and failures were related to resistant organisms and the inability to perform adequate surgical debridement. Adverse drug side effects included nausea, diarrhea, liver enzyme elevations, and neutropenia, but discontinuation of treatment was required in only three patients. Imipenem/cilastatin holds promise as monotherapy in complicated polymicrobial osteomyelitis.

Treatment of skin and soft tissue infections with imipenem/cilastatin

Ninety-eight adult patients with skin and soft tissue infections caused by a variety of bacterial pathogens were treated with imipenem/cilastatin (71), cefazolin (21), or moxalactam (six) at three medical centers. Favorable clinical responses were observed in 87 of the 90 evaluable cases (97 percent). Most etiologic pathogens were eradicated during treatment including five of seven which demonstrated in vitro resistance to the therapeutic agent. Strains that persisted during treatment were not associated with therapeutic failure except in one cefazolin-treated patient who was infected with Bacteroides fragilis. All three drugs were well tolerated and no specific patterns of adverse reactions were observed.

Review of adverse experiences and tolerability in the first 2,516 patients treated with imipenem/cilastatin

The clinical and laboratory data relating to the adverse experiences and tolerability of imipenem/cilastatin in the first 2,516 patients treated with the antibiotic are reviewed, with special reference to the last 793. Clinical adverse experiences were predominantly related to the gastrointestinal system (nausea and vomiting), local injection site, and allergy (rash). A low frequency of drug-related seizures was also reported. The most frequent adverse laboratory experiences were transient elevations of liver function test values. In general, the safety profile was similar to that of other beta-lactam antibiotics.

Impact of imipenem/cilastatin therapy on normal fecal flora

The impact of parenteral imipenem/cilastatin therapy on the bowel flora of six patients was evaluated. Stool samples were collected before and during therapy and qualitative and quantitative bacteriologic studies were performed. Imipenem had no effect on total microorganism counts. Two patients acquired Candida albicans during therapy, and three patients acquired Proteus species. Pseudomonas species in one patient acquired resistance. Imipenem appears to have a relatively modest effect on the bowel flora and apparently does not readily induce resistance in the resident flora as compared with other agents.

Imipenem/cilastatin: general experience in a community hospital

Imipenem/cilastatin is a new carbapenem antibiotic with broad spectrum antimicrobial activity. Forty two patients with infections of various types, including skin and soft tissue, respiratory tract, bone and joint, and urinary tract, were treated with this antibiotic in an open noncomparative study. Clinical responses to therapy were excellent and failures were only encountered with infections caused by Pseudomonas aeruginosa strains that developed resistance during therapy. Superinfection rates were minimal as were toxicities. Imipenem/cilastatin appears to be a relatively safe and highly effective broad spectrum antibiotic.

Safety and efficacy of high-dose treatment with imipenem-cilastatin in seriously ill patients

Imipenem-cilastatin was given in doses of 1 g intravenously every 6 h to 31 patients. Twenty-five patients, with 27 infections, were clinically evaluable and received 20 to 210 g of imipenem for a duration of 5 to 56 days (average 16.3 days). Infections included seven cases of osteomyelitis, seven of bacteremia, five of cellulitis, two of pneumonia, three of pelvic cellulitis, two of intraabdominal abscess, and one each of empyema, mediastinitis, and endometritis. Fifty-five percent of the infections were caused by gram-negative bacilli, 33% were due to gram-positive organisms, and 10% were caused by anaerobes. Twenty-two patients (81%) were cured, three improved, one relapsed, and one became superinfected with a resistant organism. In 5 of 11 cases with Pseudomonas aeruginosa, the imipenem MIC for organisms isolated by the end of treatment was higher than it was initially, raising concern that imipenem should not be used alone to treat Pseudomonas aeruginosa infections. Twenty-one patients had no adverse reaction; of the remaining 10 patients, 4 had nausea, 1 had urticaria, and 6 had mild abnormalities in hepatic function; three episodes of diarrhea included two with Clostridium difficile toxin in stool and one with pseudomembranous colitis, as determined by sigmoidoscopy. Levels of creatinine, hemoglobin, leukocytes, platelets, prothrombin, and urine components were unchanged. Imipenem-cilastatin is a clinically effective antibiotic with freedom from nephrotoxicity and hematological abnormalities in the large doses used in this study.

A multiclinic randomized study of the comparative efficacy, safety and tolerance of imipenem/cilastatin and moxalactam

The efficacy, safety and tolerance of imipenem/cilastatin and moxalactam were compared in a randomized trial in the United States involving 19 centers and 441 patients. Significantly more organisms were susceptible to imipenem than moxalactam. Although the bacteriological outcomes were similar, the clinical outcome was significantly better in the imipenem/cilastatin treatment group. The incidence of colonization and superinfection was similar in both groups. Moxalactam was less irritating at the site of injection than imipenem/cilastatin. The safety profiles were similar except for bleeding episodes in the moxalactam group.