Abstract
INTRODUCTION: Despite aggressive medical and surgical management, the resolution of skin and skin structure infections is often difficult due to insufficient host response, reduced drug penetration, and a high prevalence of resistance organisms such as methicillin-resistant Staphylococcus aureus (MRSA). As a result of these factors, conventional management often consists of prolonged broad-spectrum systemic antimicrobials. An alternative therapy in development, ultrasonic drug dispersion (UDD), uses a subcutaneous injection followed by external trans-cutaneous ultrasound to deliver high tissue concentrations of cefazolin with limited systemic exposure. While it is postulated that these high concentrations may be suitable to treat more resistant organisms such as MRSA, the cefazolin minimum inhibitory concentration (MIC) distribution for this organism is currently unknown. MATERIALS AND METHODS: We assessed the potency of cefazolin against a collection of 1,239 MRSA from 42 US hospitals using Clinical Laboratory Standard Institute-defined broth micro-dilution methodology. RESULTS: The cefazolin MIC inhibiting 50% of the isolates was 64 mg/L; 81% had MICs ≤128 and nearly all (99.9%) had MICs ≤512 mg/L. CONCLUSION: The overwhelming majority of MRSA had cefazolin MICs that were considerably lower than achievable tissue concentrations (≥1,000 mg/L) using this novel drug delivery system. While the currently defined cefazolin MRSA phenotypic profile precludes the use of parenteral administration, techniques that deliver local exposures in excess of these inhibitory concentrations may provide a novel treatment strategy for skin and skin structure infections.