Updated information on MRSA infections
Staphylococcus aureus (yellow) is a bacterium found in the skin and mucous membranes.
Many people mistake the first signs of methicillin-resistant Staphylococcus aureus (MRSA) infection for a spider bite. In fact, what appears as a small, red pimple could be the start of a potentially serious infection with a staphylococcus that is impervious to many antibiotics and poses an increasing threat in the community setting.
Scientists first discovered S. aureus in the 1880s.1 Traditionally, the bacterium has caused skin and tissue infections, but it can also cause food poisoning and, in more serious cases, bacterial pneumonia or septicemia.
In the late 1940s, S. aureus began a dangerous evolution when it became resistant to penicillin. With their primary weapon against the organism taken out of commission, clinicians began using methicillin, a relative of penicillin, to treat S. aureus infections. But in 1961, scientists got some bad news with the discovery of S. aureus strains that had become resistant to beta-lactams, including amoxicillin and methicillin, giving MRSA its name.1
The first infection involving MRSA in the United States was diagnosed in 1968, and the organism has continued to evolve ever since. Beginning in 2002, there have been a handful of cases documented in which the bacterium was also found to be resistant to one of the last available drugs being used to treat it — vancomycin (Vancocin).Despite that ominous development, there has recently been encouraging news from the CDC that hospital-acquired MRSA (HA-MRSA) infections are decreasing.2 The number of invasive HA-MRSA infections dropped 28% between 2005 and 2008. Unfortunately, the same is not true of community-acquired MRSA (CA-MRSA) cases, which have risen rapidly in the past 10 years.2 Because MRSA is circulating widely in the general population, primary-care clinicians must be prepared to recognize it, treat it effectively and take steps to reduce its transmission.
Historically, most cases of MRSA infection occurred in the hospital setting, but in 1982, cases began cropping up in community settings among individuals who had not been hospitalized. The first domestic cluster involved a group of IV-drug users in Detroit. A second cluster of drug users was infected in 1992, and the prevalence of CA-MRSA began to increase in the community at large in the mid-1990s.
Most CA-MRSA cases have originated in prisons, day-care centers and athletic or military facilities. But MRSA is not limited to those sites. It has also been found in other locations, including Washington State beaches and marine water.
CA-MRSA typically causes skin and soft-tissue infections (Figure 1), often in young and otherwise healthy patients. These infections are typically easier to treat than HA-MRSA infections, but some patients with CA-MRSA develop such serious conditions as necrotizing pneumonia, disseminated invasive osteomyelitis, septic arthritis or endocarditis.3
While the majority of CA-MRSA cases are more easily treated than HA-MRSA cases, the bacterium responsible for CA-MRSA is actually more virulent than its hospital counterpart. Three different S. aureus strains typically cause community infection, which often involves a variety of toxins including leukocyte toxins, exfoliative toxins and exotoxins, making the causative organisms highly virulent pathogens.
Risk factors for CA-MRSA infections
MRSA colonization is a risk factor for infection, although the link between colonization and infection needs further investigation. The organism is sometimes found on the skin or carried inside the nose of healthy individuals.
An estimated 25% to 30% of people carry colonies of staphylococci in their noses, according to the CDC, but less than 2% are colonized with MRSA.2 Most health-care professionals who are colonized with MRSA spontaneously clear the organism from their systems without ever developing an infection.
Other risk factors for infection include:
- Close skin-to-skin contact with other individuals
- Cuts or abrasions on the skin
- Contact with contaminated items or surfaces
- Living in crowded conditions
- Poor hygiene.4
People who come into contact with farm animals may also be at greater risk for infection. Pigs, cattle, and poultry are increasingly being found with a new clone of MRSA, CC398. And farm animals are not the only ones becoming infected. Rates of MRSA are also up among household pets, such as dogs and cats.
While people can contract MRSA infections from many different sources, the most common route to infection remains transmission through direct skin-to-skin contact. Clinicians should remember that when it comes to MRSA, essentially everyone is at risk.
Clinical presentation and treatment
Most patients with CA-MRSA will present with a skin or soft-tissue infection. Clinicians should assume that any spider bite, large pimple, or boil is MRSA until they have evidence to the contrary.
The first step in treating MRSA infections is to incise and drain the area. This may be sufficient to treat abscesses <5 cm in diameter. The clinician should send a sample of the material collected for culture and sensitivity. Once the incision and drainage is complete, antibiotic treatment should be considered.
IV antibiotics. A number of IV antibiotics can effectively treat MRSA infections, including the following:
- First-line therapy: vancomycin. Appropriate dosage is 30 mg/kg, but the dose should not exceed 2 g in any 24-hour period. It is important to administer vancomycin slowly over 90 minutes to prevent "red man syndrome," a hypersensitivity reaction linked to rapid administration of the antibiotic.5
- Second-line therapy: daptomycin (Cubicin). Proper dosage is 4 to 6 mg/kg administered via IV piggyback every 24 hours. This drug has been shown to be safe, although it can occasionally cause elevations in creatine kinase levels.
- Third-line therapy: linezolid (Zyvox). Dosage is 600 mg every 12 hours. Linezolid is a monoamine oxidase inhibitor that offers 100% bioavailability. Zyvox is very expensive, although the oral formulation has shown a cost savings for outpatient treatment.6 The usefulness of linezolid is limited by its cost and toxicity as well as the potential for the organism to develop resistance to the drug. Possible side effects related to treatment include thrombocytopenia, peripheral and optic neuropathy, and lactic acidosis in patients receiving prolonged therapy.
- Fourth-line therapy: tigecycline (Tygacil). Dosage is 100 mg IV once, then 50 mg IV every 12 hours. This drug has a broader spectrum of antimicrobial activity.
- Fifth-line therapy: quinupristin/dalfopristin (Synercid).
In addition to the antibiotics listed above, a number of emerging therapies may be useful for the treatment of MRSA, including dalbavancin, telavancin (Vibativ, Theravance), and ceftobiprole.
Oral antibiotics. Some antibiotics available in oral formulations are treatment options for MRSA:
- First-line therapy: trimethoprim-sulfamethoxazole (TMP-SMX; Bactrim DS, Septra DS. Sulfamethoprim-DS). This agent has been shown to be 95% effective.
- Second-line therapy: clindamycin (Cleocin). Keep in mind that the organism may develop resistance to this drug, particularly if it is resistant to erythromycin. Also remember that patients exposed to clindamycin are at risk for infection with Clostridium difficile.
- Third-line therapy: tetracycline or doxycycline/minocycline (Dynacin, Minocin). This agent is administered for 21 days.
- Fourth-line therapy: linezolid.
- Rifampin (Rifadin) may also be used. It is typically effective in combination with other drugs. Because rifampin achieves high concentrations in mucosal surfaces, its inclusion in a regimen to treat MRSA is theoretically beneficial.
Drugs to be avoided. Erythromycin (Ery-tab, PCE) and cephalexin (Keflex) are ineffective against MRSA, and ciprofloxacin (Cipro) and levofloxacin (Levaquin) are to be avoided because rates of MRSA infection are increased in hospitalized patients treated with quinolones. Bacitracin and neomycin, two common ingredients in OTC antibacterial ointments, are not recommended for the treatment of MRSA, although a recent study indicates that they may be effective against a specific clone of MRSA.7
Empiric MRSA coverage is not necessary for children who have uncomplicated skin infections. Researchers found no difference in outcome between children randomly assigned to receive cephalexin, an antibiotic without MRSA activity, or clindamycin. The children received cephalexin 40 mg/kg/day in three divided doses or clindamycin 20 mg/kg/day also in three divided doses for seven days.8