Bacteria. The 853 isolates of gram-negative species and 296 isolates of gramn-positive species were predominantly of recent clinical origin from numerous sources of broad geographical distribution. The isolates were stored as described previously (2, 4). The 3-lactamase-producing strains used to generate the data in Table 3
A total of 319 clinical isolates known to be resistant to one or more aminoglycoside antibiotics were tested for their susceptibility to 10 aminoglycosides. The percentages of isolates found by an agar dilution method to be susceptible were: amikacin, 83.7%; tobramycin, 41.4%; butirosin A, 33.2%; dideoxykanamycin B, 32.6%; gentamicin C, 27.3%; lividomycin A, 17.6%; neomycin B, 10.7%; paromomycin, 10.3%; kanamycin A, 10.0%; and ribostamycin, 7.2%. The effectiveness of the antibiotics was related to their degree of resistance to bacterial enzymes; e.g., of the nine enzymes known to inactivate antibiotics containing 2-deoxystreptamine, amikacin was affected by one enzyme, tobramycin by five, and gentamicin and kanamycin by six. Examination of cell-free extracts from the 52 strains resistant to amikacin revealed that only four contained the amikacin-inactivating enzyme aminoglycoside-6'-acetyltransferase, a finding indicating that this mechanism of resistance is rare. Other experiments suggest that most amikacin-resistant strains, which are almost invariably resistant to all aminoglycosides, lack the ability to accumulate effectively either amikacin or presumably the other antibiotics intracellularly.
One hundred fifty-two bacterial strains that possess resistance to kanamycin A, gentamicin, or tobramycin, or to more than one of these antibiotics, were collected from various sources in Canada, Europe, Japan, and the United States. This collection was composed of Staphylococcus aureus and Pseudomonas aeruginosa and members of the Enterobacteriaceae family. Their susceptibility to BB-K8 (amikacin), a new broad-spectrum semisynthetic derivative of kanamycin A, and to the other agents, was determined on Mueller-Hinton Medium by the twofold agar dilution method. Test results revealed that 60.5% of the isolates were resistant to 8 gg of tobramycin per ml, 67.1% to 8 ,g of gentamicin per ml, 86.2% to 20 ,g of kanamycin A per ml, and only 8.6% to 20 ig of amikacin per ml. Of interest is the fact that the amikacin-resistant strains were generally resistant to all of the other aminoglycosides. The broad spectrum of amikacin was not totally unexpected, because the compound has been shown to be a poor substrate for most enzymes that inactivate other aminoglycosides through O-phosphorylation, O-adenylylation, or N-acetylation. A number of susceptibility profiles were obtained when the organisms were tested against a series of nine aminoglycosides. The majority of these profiles resembled those found for organisms that possess known mechanisms of enzymatic inactivation.
BMY 28100, a new oral cephalosporin with a (Z)-propenyl side chain at the 3 position and a phydroxyphenylglycyl substituent at the 7 position, was evaluated in comparison with cefaclor and cephalexin and, when appropriate, ampicillin and vancomycin. In vitro, BMY 28100 was more active than the reference cephalosporins against streptococci, Staphylococcus aureus, Staphylococcus epidermidis, Listeria nionocytogenes, Haemophilus influenzae, Propionibacterium acnes, Clostridiunm perfrigens, and Clostridium difficile. BMY 28100 was comfparable to cefaclor and more active than eephalexin against Staphylococcus saprophyticus and ampicillin-susceptible strains of Branhamella cattarhalis; but against ampicillin-resistant strains of B. cattarhalis, BMY 28100 was comparable to cephalexin and more active than cefaclor. Against Neisseria gonorrhoeae, BMY 28100 was comparable to cephalexin, but less active than cefaclor. Members of the family Enterobacteriaceae overall were equally susceptible to BMY 28100 and cefaclor but were less susceptible to cephalexin. In human serum, BMY 28100 was 45% protein bound. After an oral dose to mice, 82% of the drug was recovered in urine. The oral therapeutic efficacy of BMY 28100 in systemically infected mice reflected its activity in vitro.Whereas parenteral cephalosporins have been prepared with an array of side chains at the 3 and 7 positions, structural requirements for good gastrointestinal absorption have limited the choice of side chains for oral cephalosporins. The number of distinct substituents at the 3 position on oral cephalosporins currently in clinical use is small, and all substituents at the 7 position are of a single design: a native or modified phenyglycyl radical. Recent attempts to deviate from this pattern have yielded compounds with a broader spectrum of activity against gram-negative organisms but reduced gastrointestinal absorption and little antistaphylococcal activity (4, 9, 13; T. Suematsu, H. Sakamoto, and K. Takai, Proc. 14th Int. Congr. Chemother., p. 1147-1148 , abstr. no. 595, 1985).BMY 28100 is a new oral cephalosporin of conventional design. It has a (Z)-propenyl side chain at the 3 position and ap-hydroxyphenylglycyl substituent at position 7 (Fig. 1)
Biological and physicochemical properties of BL-S786 were compared with those of cephalothin, cephaloridine, and cefazolin. With few exceptions, BL-S786 was more active than the reference compounds against major gram-negative pathogenic species and its antibacterial spectrum was broader than that of cephalosporins currently available for clinical use. Although BL-S786 was generally less active than the control cephalosporins against gram-positive pathogens, it inhibited their growth at concentrations that should readily be achieved in humans after standard parenteral dosage. Streptococcus faecalis, a species relatively unsusceptible to cephalosporins in general, was an exception. BL-S786 was an effective bactericidal agent for strains of various gram-negative organisms. After intramuscular administration to mice, BL-S786 achieved high concentrations in blood, and its biological half-life was longer than that of the other three cephalosporins.BL-S786 (Fig. 1) is a new semisynthetic cephalosporin with a broad spectrum of antibacterial activity. The following is a report on biological and physicochemical properties of BL-S786 in comparison with those pfcephalothin, cephaloridine, and cefazolin, three cephalosporins widely used clinically in the United States and abroad. MATERIALS AND METHODSCephalosporins. BL-S786, 7-[a-(2-aminomethylphenyl)acetamidol-3-[(1-carboxymethyltetrazol-5-ylthio)methyl]-3-cephem-4-carboxylic acid, was synthesized by members of the Product Development Department, Bristol Laboratories (W.
It is well known that the composition of the assay medium greatly affects the antimicrobial activity of aminoglycoside antibiotics. A similar response has now been observed with certain penicillins and cephalosporins. In the case of these compounds, this effect is apparently governed by the chemical nature of the penicillin 6-and cephalosporin 7-side chains. In comparison with their activity in Nutrient Broth, the activity of some of the fl-lactam antibiotics that have a weakly basic or basic group in their side chain was reduced as much as 40-fold in one or more of the following media: Mueller-Hinton, Trypticase soy, antibiotic assay, and heart infusion broths. In contrast, the assay medium had no effect on the activity of those compounds possessing an acidic or a nonionizable function in their side chain. The extent to which medium influences the antibacterial activity was also dependent upon the assay method and the organism, the effect being more pronounced in broth dilution than in agar dilution tests and occurring more frequently with gram-negative than with gram-positive organisms.
BL-S 640 was evaluated in vitro by comparison with cephalothin, cephaloridine, cefazolin, and cephalexin. The new compound was more active than the control cephalosporins against most major gram-negative and some gram-positive species. Moreover, its antibacterial spectrum included strains of Enterobacter, Proteus morganii, P. rettgeri , and Providencia stuartii , species generally resistant to the other cephalosporins. BL-S 640 was an effective bactericidal agent for strains of various species of Enterobacteriaceae . In human plasma, the compound was 58% protein bound.
BL-S 339 is a new broad-spectrum, parenterally effective cephalosporin whose expression of antibacterial activity in vitro is markedly affected by the nature of the assay medium. When assayed in nutrient agar, BL-S 339 was more active than cephalothin against strains of Diplococcus pneumoniae, Streptococcus pyogenes, Escherichia coli, Serratia marcescens, Klebsiella pneumoniae, Enterobacter, and indole-positive Proteus sp. However, when assayed in MuellerHinton medium, its activity, especially against gram-negative bacteria, was reduced substantially, whereas the activity of cephalothin was virtually unaffected by the assay medium. The in vivo activity of BL-S 339 correlated well with its activity in nutrient agar; when administered subcutaneously to mice, it was therapeutically more efficacious than cephalothin in infections caused by both gram-positive and gram-negative bacteria. When BL-S 339 was administered intramuscularly to mice, the concentrations achieved in the blood were three times those achieved with cephalothin. BL-S 339 was bound to human serum proteins to the same extent as cephalothin. Recovery of BL-S 339 in the urine within the 24-hr period after intramuscular administration to rats was three times that of cephalothin.BL-S 339 is a new broad-spectrum, parenterally effective cephalosporin (Fig. 1). It was selected from a general cephalosporin-screening program and represents one of the most active compounds of a series of 7-(substitutedimidoylaminoacetamido) derivatives synthesized by C. Holdrege and S. Baker of Bristol Laboratories. This report presents comparative data on the microbiological and pharmacological properties of BL-S 339 and cephalothin, including the effect of the assay medium on their activity against a variety of clinical isolates. Data on the parenteral absorption, urinary excretion, and therapeutic efficacy of these compounds in rodents are also presented.MATERIALS AND METHODS Antibiotics. BL-S 339 was synthesized by S. R. Baker of the Bristol Laboratories Organic Chemistry Department. The crystalline form used in these studies was prepared by M. A. Kaplan of the Product Development Department and was more than 95% pure. Its solubility in water was limited to 5 mg/ml and in phosphate buffer (pH 7) to 10 mg/ml. When administered subcutaneously to mice in experimental infections, BL-S 339 was suspended in a polysorbatecarboxymethylcellulose formulation. Commercially available cephalothin (Keflin, Eli Lilly & Co.) was used as the control compound.In vitro antibacterial activity. The susceptibility of a number of clinical strains of Diplococcus pneumoniae, Streptococcus pyogenes, Staphylococcus aureus, Proteus sp., Klebsiella pneumoniae, Enterobacter sp., Serratia marcescens, Salmonella sp., and Escherichia coli to BL-S 339 and cephalothin was determined by a twofold agar dilution method. The antibiotics were incorporated into Mueller-Hinton medium (MHM, Difco) and into nutrient agar (NA) which was prepared by the addition of 1% lonagar
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