Invasive meningococcal disease (IMD), caused by infection with the bacterium Neisseria meningitidis, usually manifests as meningitis or septicemia and can be severe and life-threatening (1). Six serogroups (A, B, C, W, X, and Y) account for most cases (2). N. meningitidis is transmitted person-to-person via respiratory droplets and oropharyngeal secretions. Asymptomatic persons can carry N. meningitidis and transmit the bacteria to others, potentially causing illness among susceptible persons. Outbreaks can occur in conjunction with large gatherings (3,4). Vaccines are available to prevent meningococcal disease. Antibiotic prophylaxis for close contacts of infected persons is critical to preventing secondary cases (2).

Meningococcal disease, caused by the bacterium Neisseria meningitidis, is a rare but life-threatening illness that requires prompt antibiotic treatment for patients and antibiotic prophylaxis for their close contacts. Historically, N. meningitidis isolates in the United States have been largely susceptible to the antibiotics recommended for prophylaxis, including ciprofloxacin. Since 2019, however, the number of meningococcal disease cases caused by ciprofloxacin-resistant strains has increased. Antibiotic prophylaxis with ciprofloxacin in areas with ciprofloxacin resistance might result in prophylaxis failure. Health departments should preferentially consider using antibiotics other than ciprofloxacin as prophylaxis for close contacts when both of the following criteria have been met in a local catchment area during a rolling 12-month period: 1) the reporting of two or more invasive meningococcal disease cases caused by ciprofloxacin-resistant strains, and 2) ≥20% of all reported invasive meningococcal disease cases are caused by ciprofloxacin-resistant strains. Other than ciprofloxacin, alternative recommended antibiotic options include rifampin, ceftriaxone, or azithromycin. Ongoing monitoring for antibiotic resistance of meningococcal isolates through surveillance and health care providers' reporting of prophylaxis failures will guide future updates to prophylaxis considerations and recommendations.

Meningococcal disease, caused by the bacterium Neisseria meningitidis, is a sudden-onset, life-threatening illness that typically occurs as meningitis or meningococcemia. The most common signs and symptoms of meningitis include fever, headache, and stiff neck; the most common signs and symptoms of meningococcemia are fever, chills, fatigue, vomiting, diarrhea, cold hands and feet, and severe aches or pain.* Quadrivalent meningococcal conjugate vaccination (MenACWY) is routinely recommended for adolescents and persons at increased risk for meningococcal disease (1), including those with HIV. In 2016, a 2-dose series of MenACWY was recommended by the Advisory Committee on Immunization Practices (ACIP) for persons with HIV and incorporated into the U.S. immunization schedule. Coverage among persons with HIV, however, remains low: in a study of administrative claims data during January 2016–March 2018, only 16.3% of persons with HIV received ≥1 doses of MenACWY vaccine within 2 years after their diagnosis (2). This report describes an increase in meningococcal disease among persons with HIV in the United States in 2022. Data are typically finalized in the fall of the next year; therefore, this report is based on preliminary data for 2022.

This review summarizes the recent Global Meningococcal Initiative (GMI) regional meeting, which explored meningococcal disease in North America. Invasive meningococcal disease (IMD) cases are documented through both passive and active surveillance networks. IMD appears to be decreasing in many areas, such as the Dominican Republic (2016: 18 cases; 2021: 2 cases) and Panama (2008: 1 case/100,000; 2021: <0.1 cases/100,000); however, there is notable regional and temporal variation. Outbreaks persist in at-risk subpopulations, such as people experiencing homelessness in the US and migrants in Mexico. The recent emergence of β-lactamase-positive and ciprofloxacin-resistant meningococci in the US is a major concern. While vaccination practices vary across North America, vaccine uptake remains relatively high. Monovalent and multivalent conjugate vaccines (which many countries in North America primarily use) can provide herd protection. However, there is no evidence that group B vaccines reduce meningococcal carriage. The coronavirus pandemic illustrates that following public health crises, enhanced surveillance of disease epidemiology and catch-up vaccine schedules is key. Whole genome sequencing is a key epidemiological tool for identifying IMD strain emergence and the evaluation of vaccine strain coverage. The Global Roadmap on Defeating Meningitis by 2030 remains a focus of the GMI.

Fluoroquinolones (e.g., ciprofloxacin) have become a mainstay for treating severe Salmonella infections in adults. Fluoroquinolone resistance in Salmonella is mostly due to mutations in the topoisomerase genes, but plasmid-mediated quinolone resistance (PMQR) mechanisms have also been described. In 2012, the Clinical and Laboratory Standards Institute (CLSI) revised the ciprofloxacin interpretive criteria (breakpoints) for disk diffusion and MIC test methods for Salmonella. In 2013, the CLSI published MIC breakpoints for Salmonella to levofloxacin and ofloxacin, but breakpoints for assigning disk diffusion results to susceptible (S), intermediate (I), and resistant (R) categories are still needed. In this study, the MICs and inhibition zone diameters for nalidixic acid, ciprofloxacin, levofloxacin, and ofloxacin were determined for 100 clinical isolates of nontyphi Salmonella with or without resistance mechanisms. We confirmed that the new levofloxacin MIC breakpoints resulted in the highest category agreement (94%) when plotted against the ciprofloxacin MICs and that the new ofloxacin MIC breakpoints resulted in 92% category agreement between ofloxacin and ciprofloxacin. By applying the new MIC breakpoints in the MIC zone scattergrams for levofloxacin and ofloxacin, the following disk diffusion breakpoints generated the least number of errors: ≥28 mm (S), 19 to 27 mm (I), and ≤18 mm (R) for levofloxacin and ≥25 mm (S), 16 to 24 mm (I), and ≤15 mm (R) for ofloxacin. Neither the levofloxacin nor the ofloxacin disk yielded good separation of isolates with and without resistance mechanisms. Further studies will be needed to develop a disk diffusion assay that efficiently detects all isolates with acquired resistance to fluoroquinolones.

Non-Typhi Salmonella cause over 1.7 million cases of gastroenteritis in North America each year, and food-animal products are commonly implicated in human infections. For invasive infections, antimicrobial therapy is indicated. In North America, the antimicrobial susceptibility of Salmonella is monitored by the U.S. National Antimicrobial Resistance Monitoring System (NARMS) and The Canadian Integrated Program for Antimicrobial Resistance Surveillance (CIPARS). In this study, we determined the susceptibility to cephalosporins by broth microdilution among 5,041 non-Typhi Salmonella enterica isolated from food animals, retail meats, and humans. In the United States, 109 (4.6%) of isolates collected from humans, 77 (15.7%) from retail meat, and 140 (10.6%) from food animals displayed decreased susceptibility to cephalosporins (DSC). Among the Canadian retail meat and food animal isolates, 52 (13.0%) and 42 (9.4%) displayed DSC. All isolates displaying DSC were screened for beta-lactamase genes (bla(TEM), bla(SHV), bla(CMY), bla(CTX-M), and bla(OXA-1)) by polymerase chain reaction. At least one beta-lactamase gene was detected in 74/109 (67.9%) isolates collected from humans, and the bla(CMY) genes were most prevalent (69/109; 63.3%). Similarly, the bla(CMY) genes predominated among the beta-lactamase-producing isolates collected from retail meats and food animals. Three isolates from humans harbored a bla(CTX-M-15) gene. No animal or retail meat isolates harbored a bla(CTX-M) or bla(OXA-1) gene. A bla(TEM) gene was found in 5 human, 9 retail meat, and 17 animal isolates. Although serotype distributions varied among human, retail meat, and animal sources, overlap in bla(CMY)-positive serotypes across sample sources supports meat and food-animal sources as reservoirs for human infection.

Shigellosis is the third most common enteric bacterial infection in the United States (9)....

OBJECTIVE: We describe the antimicrobial susceptibility to extended-spectrum cephalosporins in non-Typhi Salmonella (NTS) isolated from humans in the United States and explore resistance mechanisms for isolates displaying decreased susceptibility to ceftriaxone or ceftiofur. We further explore the concordance between the newly revised Clinical and Laboratory Standards Institute (CLSI) breakpoints for ceftriaxone and the presence of a beta-lactamase. METHODS: In 2005 and 2006, public health laboratories in all U.S. state health departments forwarded every 20th NTS isolate from humans to Centers for Disease Control and Prevention as part of the National Antimicrobial Resistance Monitoring System (NARMS) for enteric bacteria. Minimum inhibitory concentrations (MICs) were determined by broth microdilution. Isolates displaying decreased susceptibility (MIC ≥ 2 mg/L) to ceftriaxone or ceftiofur were included in the study. The presence of beta-lactamase genes was investigated by polymerase chain reaction amplification and sequencing, targeting six different genes (bla(TEM), bla(OXA), bla(SHV), bla(CTX-M), bla(PSE), and bla(CMY)). Plasmid location of bla(CMY) was confirmed by transforming plasmids into Escherichia coli. RESULTS: Among the 4236 isolates of NTS submitted to NARMS in 2005 and 2006, 175 (4.1%) displayed decreased susceptibility to either ceftriaxone or ceftiofur. By polymerase chain reaction screening, one or more beta-lactamase genes could be detected in 139 (80.8%) isolates. The most prevalent resistance mechanism detected was the AmpC beta-lactamase gene bla(CMY.) Other beta-lactamase genes detected included 11 bla(TEM-1), 3 bla(PSE-1), 2 bla(OXA-1), and 1 bla(CTX-M-15). The ceftriaxone MIC values for the bla(CMY)-containing isolates ranged from 4 to 64 mg/L; all bla(CMY)-bearing isolates were classified as ceftriaxone resistant according to current CLSI guidelines. CONCLUSIONS: Among NTS isolates submitted to NARMS in 2005 and 2006, cephamycinase beta-lactamases are the predominant cause of decreased susceptibility to ceftriaxone. The fact that all bla(CMY)-containing isolates were classified as resistant to ceftriaxone (MIC ≥ 4 mg/L) supports the newly revised CLSI breakpoints for cephalosporins and Enterobacteriaceae.

To investigate azithromycin susceptibility in Shigella sonnei in the United States, we examined the azithromycin minimum inhibitory concentrations (MICs) of outbreak and routine human S. sonnei isolates. Isolate susceptibility clustered at 8 mg/L, but three isolates displayed higher MICs (>64 mg/L) to azithromycin. All three isolates contained a plasmid-encoded mphA gene, known to encode a macrolide-2'-phosphotransferase enzyme. Transformation of the mphA gene into Escherichia coli DH10B allowed the transfer of decreased susceptibility to azithromycin. Although these isolates might traditionally be defined as resistant, there are no established breakpoints for resistance to confirm that treatment of these isolates with azithromycin would fail, which complicates susceptibility screening.