Antagonism between Front-Line Antibiotics Clarithromycin and Amikacin in the Treatment of Mycobacterium abscessus Infections Is Mediated by the whiB7 Gene.

Combinations of antibiotics, each individually effective against Mycobacterium abscessus, are routinely coadministered based on the concept that this minimizes the spread of antibiotic resistance. However, our in vitro data contradict this assumption and instead document antagonistic interactions between two antibiotics (clarithromycin and amikacin) used to treat M. abscessus infections. Clinically relevant concentrations of clarithromycin induced increased resistance to both amikacin and itself. The induction of resistance was dependent on whiB7, a transcriptional activator of intrinsic antibiotic resistance that is induced by exposure to many different antibiotics. In M. abscessus, the deletion of whiB7 (MAB_3508c) resulted in increased sensitivity to a broad range of antibiotics. WhiB7 was required for transcriptional activation of genes that confer resistance to three commonly used anti-M. abscessus drugs: clarithromycin, amikacin, and tigecycline. The whiB7-dependent gene that conferred macrolide resistance was identified as erm(41) (MAB_2297), which encodes a ribosomal methyltransferase. The whiB7-dependent gene contributing to amikacin resistance was eis2 (MAB_4532c), which encodes a Gcn5-related N-acetyltransferase (GNAT). Transcription of whiB7 and the resistance genes in its regulon was inducible by subinhibitory concentrations of clarithromycin but not by amikacin. Thus, exposure to clarithromycin, or likely any whiB7-inducing antibiotic, may antagonize the activities of amikacin and other drugs. This has important implications for the management of M. abscessus infections, both in cystic fibrosis (CF) and non-CF patients.

Aminoglycoside Increases Permeability of Osseous Spiral Laminae of Cochlea by Interrupting MMP-2 and MMP-9 Balance.

The spiral ganglion neurons (SGNs) located in the Rosenthal's canal of cochlea are essential target for cochlear implant. Previous studies found that the canaliculi perforantes, small pores on the surface of the osseous spiral lamina (OSL) of the scala tympanic (ST) of cochlea, may provide communication between the cochlear perilymph and SGNs. In this study, we found that chronic treatment of aminoglycosides antibiotics, which is well known to cause sensory cell damage in the cochlea, induced significant damage of bone lining cells on the OSLs and increased the permeability of the Rosenthal's canal. The pores among the bone lining cells became significantly wider after chronic treatment of amikacin (100 mg/kg/day for 3-7 days). Injection of Evans Blue in the ST resulted in significant increase in its migration in the modulus in the amikacin-treated cochlea compared to the control ears, suggesting increased permeability of these passages. Treatment of amikacin with oxytetracycline, an inhibitor of matrix metalloproteases (MMPs), significantly reduced the amount of dye migrated from the ST to the modiolus. These results suggest that amikacin enhanced the permeability between the ST and SGNs by increasing MMPs. Aggregating the permeability of the bone lining cells on the OSLs may benefit gene and stem cell delivery to the SGNs in the cochlea.

Attenuation of aminoglycoside-induced cochlear damage with the metabolic antioxidant alpha-lipoic acid.

Free radical generation is increasingly implicated in a variety of pathological processes, including drug toxicity. Recently, a number of studies have demonstrated the ability of gentamicin to facilitate the generation of radical species both in vivo and in vitro, which suggests that this process plays an important role in aminoglycoside-induced ototoxicity. Free radical scavengers are compounds capable of inactivating free radicals, thereby attenuating their tissue damaging capacity. In this study we have determined the ability of the powerful free radical scavenger alpha-lipoic acid (100 mg/kg/day) to attenuate the cochlear damage induced by a highly ototoxic regimen of the aminoglycoside amikacin (450 mg/kg/day, i.m.). Experiments were carried out on pigmented guinea pigs initially weighing 200-250 g. Changes in cochlear function were characterized as shifts in compound action potential (CAP) thresholds, estimated every 5 days, by use of chronic indwelling electrodes implanted at the round window, vertex, and contralateral mastoid. Results showed that animals receiving alpha-lipoic acid in combination with amikacin demonstrated a significantly less severe elevation in CAP thresholds compared with animals receiving amikacin alone (P < 0.001; t-test). These results provide further evidence of the recently reported intrinsic role of free radical generation in aminoglycoside ototoxicity, and highlight a potential clinical therapeutic use of alpha-lipoic acid in the management of patients undergoing aminoglycoside treatment.

Attenuation of aminoglycoside ototoxicity by glutathione.

Aminoglycoside antibiotics are commonly used for the treatment of serious gram-negative infections despite a high incidence of associated ototoxicity. Attempts to elucidate the mechanisms of toxicity or prevent the adverse effects have previously been unsuccessful. Recently, the damaging effects of aminoglycosides on the inner ear have been shown to be caused by a metabolite of the drug, implying an enzymatic conversion of the parent compound. Glutathione has been suggested to be closely related to the detoxification mechanisms of this metabolite. This study revealed the possible attenuation of aminoglycoside ototoxicity by glutathione. Guinea pigs were given amikacin alone or amikacin with prior intramuscular injection of glutathione. The pretreatment of glutathione significantly reduced the damage of outer hair cells of the organ of Corti. This may indicate that glutathione reduces the aminoglycoside ototoxicity and can be favorably applied in clinical use.

In vitro inactivation of aminoglycosides by sulbactam, other beta-lactams, and sulbactam-beta-lactam combinations.

At clinically achievable levels (e.g., 25 micrograms/ml), sulbactam exerted no effect on aminoglycoside concentrations when incubated together in pooled serum at 37 degrees C for up to 24 h. Sulbactam alone and in combination with ampicillin or cefoperazone inactivated tobramycin, gentamicin, netilmicin, and amikacin in vitro when the sulbactam concentration was 200 to 225 micrograms/ml. At 75 micrograms/ml, sulbactam inactivated only tobramycin. Inactivation of tobramycin by high concentrations of sulbactam occurred even at -20 degrees C, but not at -70 degrees C, and was influenced by the serum matrix.

In vitro inactivation of aminoglycosides by apalcillin.

Apalcillin, at concentrations of 75, 150, 300, and 600 micrograms/ml, was combined in vitro with amikacin, gentamicin, netilmicin, or tobramycin. Incubation at 37 degrees C resulted in an apalcillin concentration-dependent and time-dependent decrease of aminoglycoside activity of up to 60%. Amikacin was the most stable and tobramycin was the least stable aminoglycoside under the conditions tested.

Effect of concentration and time upon inactivation of tobramycin, gentamicin, netilmicin and amikacin by azlocillin, carbenicillin, mecillinam, mezlocillin and piperacillin.

Carbenicillin and ticarcillin have been shown to inactivate aminoglycoside antibiotics. This study evaluated the effect of time upon in vitro interaction between mixtures of four aminoglycoside antibiotics at two concentrations with azlocillin, mecillinam, mezlocillin, piperacillin and carbenicillin at three concentrations. By linear regression analysis, the inactivation of each aminoglycoside antibiotic was shown to be directly proportional to the concentration of the semisynthetic penicillin. Aminoglycoside inactivation was greater after 72 hr of incubation with the penicillins than after 24 hr of incubation. Inactivation by each semisynthetic penicillin was greater for tobramycin and gentamicin than for netilmicin and amikacin, especially at higher concentrations of the penicillins. At concentrations of 500 microgram/ml, significantly less inactivation of amikacin occurred when compared to netilmicin. There was little difference in inactivation of a specific aminoglycoside by any of the semisynthetic penicillin antibiotics. No significant change in aminoglycoside activity occurred when the aminoglycosides were stored with the semisynthetic penicillin derivatives at -70 degrees C for 30 days. Conclusions from this study are: 1) serum specimens containing aminoglycoside-penicillin combinations should be tested immediately or frozen before antibiotic assay and 2) aminoglycoside inactivation by the newer semisynthetic penicillins may be important in patients with renal failure who are receiving these antimicrobial agents.

Neuromuscular blocking property of amikacin in man.

The effect of amikacin on the neuromuscular junction was studied in man during anesthesia and surgery. Amikacin alone did not show any neuromuscular blocking action in normal man in therapeutic doses (100-200 mg). However, during recovery from either d-tubocurarine block or phase II block with succinylcholine, the intravenous administration of 200 mg of amikacin caused a decrease in twitch tension. This neuromuscular block aggravated by amikacin was antagonized by edrophonium (10 mg) or calcium chloride (400 mg). Data obtained from the peroneal nerve-anterior tibial muscle preparation of rabbits suggested that the neuromuscular blocking potency of amikacin was one-twelfth of that of kanamycin in therapeutic doses. Although amikacin is thus less potent than kanamycin, caution should be taken in its use for patients with myasthenic state.

Evaluation of amikacin sulfate (Amikin). A new aminoglycoside antibiotic.

Amikacin sulfate, the first semisynthetic aminoglycoside antibiotic introduced in this country, is resistant to the bacterial enzymes that specifically inactivate kanamycin sulfate, gentamicin sulfate, and tobramycin sulfate. This agent is potentially effective, therefore, against many serious infections caused by Gram-negative organisms resistant to other aminoglycosides. It appears to be similar to gentamicin in its in vitro spectrum, in clinical applications, and in the incidence and severity of adverse reactions reported. Like the other drugs in this class, amikacin can cause renal and otic toxic reactions.