<p><strong>BACKGROUND: </strong>Children who develop malaria after returning to a setting in which the disease is not endemic are at high risk for critical delays in diagnosis and initiation of antimalarial therapy. We assessed the clinical impact of the implementation of malaria rapid diagnostic testing (RDT) on the management of children with malaria at an urban US children's hospital that serves a large immigrant population.</p>

<p><strong>METHODS: </strong>This was a retrospective cohort study of all children diagnosed with laboratory-confirmed malaria at the Children's Hospital of Philadelphia (CHOP) between 2000 and 2014. RDT using a US Food and Drug Administration-approved immunochromatographic assay was introduced at CHOP on August 1, 2007. We compared clinical management and outcomes of patients with malaria diagnosed before and after RDT introduction.</p>

<p><strong>RESULTS: </strong>We analyzed 82 pediatric malaria cases (32 before and 50 after RDT implementation). The majority of these patients had traveled to West Africa (91.5%) and were infected with Plasmodium falciparum (80.5%). The mean time to a positive result decreased from 10.4 to 0.9 hours (P &lt; .001) after the introduction of RDT for patients with P falciparum. The mean time to antimalarial therapy decreased from 13.1 to 6.9 hours (P =; .023) in hospitalized patients. We found no significant reduction in the mean number of clinical signs of severe malaria between 0 and 48 hours of hospitalization and no difference in the need for exchange transfusion, time to resolution of parasitemia, or length of hospital stay.</p>

<p><strong>CONCLUSIONS: </strong>Implementation of RDT for malaria was associated with shorter times to malaria diagnosis and initiation of antimalarial therapy. The results of this study support RDT in the optimal management of patients with malaria who present in settings in which the disease is not endemic.</p>

<p><strong>BACKGROUND: </strong> Hospitals use antibiograms to guide optimal empiric antibiotic therapy, reduce inappropriate antibiotic usage, and identify areas requiring intervention by antimicrobial stewardship programs. Creating a hospital antibiogram is a time-consuming manual process that is typically performed annually.</p>

<p><strong>OBJECTIVE: </strong> We aimed to apply visual analytics software to electronic health record (EHR) data to build an automated, electronic antibiogram ("e-antibiogram") that adheres to national guidelines and contains filters for patient characteristics, thereby providing access to detailed, clinically relevant, and up-to-date antibiotic susceptibility data.</p>

<p><strong>METHODS: </strong> We used visual analytics software to develop a secure, EHR-linked, condition- and patient-specific e-antibiogram that supplies susceptibility maps for organisms and antibiotics in a comprehensive report that is updated on a monthly basis. Antimicrobial susceptibility data were grouped into nine clinical scenarios according to the specimen source, hospital unit, and infection type. We implemented the e-antibiogram within the EHR system at Children's Hospital of Philadelphia, a tertiary pediatric hospital and analyzed e-antibiogram access sessions from March 2016 to March 2017.</p>

<p><strong>RESULTS: </strong> The e-antibiogram was implemented in the EHR with over 6,000 inpatient, 4,500 outpatient, and 3,900 emergency department isolates. The e-antibiogram provides access to rolling 12-month pathogen and susceptibility data that is updated on a monthly basis. E-antibiogram access sessions increased from an average of 261 sessions per month during the first 3 months of the study to 345 sessions per month during the final 3 months.</p>

<p><strong>CONCLUSION: </strong> An e-antibiogram that was built and is updated using EHR data and adheres to national guidelines is a feasible replacement for an annual, static, manually compiled antibiogram. Future research will examine the impact of the e-antibiogram on antibiotic prescribing patterns.</p>

<p>The objective of this study was to assess the association between previous antibiotic use, particularly long-term prophylaxis, and occurrence of subsequent resistant infections in children with index infections due to extended-spectrum cephalosporin-resistant Enterobacteriaceae We also investigated the concordance of index and subsequent isolates. Extended-spectrum cephalosporin-resistant E. coli and Klebsiella spp. isolated from normally sterile sites of patients aged &lt;22 years were collected along with associated clinical data from four freestanding pediatric centers. Subsequent isolates were categorized as concordant if the species, resistance determinants, and fumC/fimH (E. coli) or tonB (K. pneumoniae) type were identical to the index isolate. In total, 323 patients had 396 resistant isolates; 45 (14%) patients had ≥1 subsequent resistant infection, totaling 73 subsequent resistant isolates. The median time between index and first subsequent infection was 123 days (interquartile range 43, 225). In multivariable Cox proportional hazards analyses, patients were 2.07 times as likely to have a subsequent resistant infection (95% confidence interval, 1.11 to 3.87) if they received prophylaxis in the 30 days prior to the index infection. In 26 (58%) patients, all subsequent isolates were concordant with their index isolate and 7 (16%) additional patients had at least 1 concordant subsequent isolate. In 12 (71%) of 17 patients with E. coli ST131-associated type 40-30, all subsequent isolates were concordant. Subsequent extended-spectrum cephalosporin-resistant infections are relatively frequent and are most commonly due to bacterial strains concordant with the index isolate. Further study is needed to assess the role prophylaxis plays in these resistant infections.</p>

<p><strong>BACKGROUND: </strong>Bloodstream infection is a major cause of morbidity and mortality. Much of our understanding of the epidemiology and resistance patterns of bloodstream infections comes from studies of hospitalized adults.</p>

<p><strong>METHODS: </strong>We evaluated the epidemiology and antimicrobial resistance of bloodstream infections occurring during an 11-year period in a large, tertiary care children's hospital in the US. All positive blood cultures were identified retrospectively from clinical microbiology laboratory records. We excluded repeat positive cultures with the same organism from the same patient within 30 days and polymicrobial infections.</p>

<p><strong>RESULTS: </strong>We identified 8196 unique episodes of monomicrobial bacteremia in 5508 patients. Overall, 46% were community onset, 72% were Gram-positive bacteria, 22% Gram-negative bacteria and 5% Candida spp. Coagulase negative Staphylococcus was the most common isolated organism. ESKAPE pathogens (Enterococcus faecium, Staphylococcus aureus, Klebsiella pneumoniae, Acinetobacter baumannii, Pseudomonas aeruginosa and Enterobacter spp.) accounted for 20% of episodes. No S. aureus isolate was resistant to vancomycin or linezolid, and no increase in vancomycin minimum inhibitory concentration among methicillin-resistant S. aureus was observed during the study period. Clinically significant increases in vancomycin-resistant Enterococcus, ceftazidime-resistant P. aeruginosa or carbapenem-resistant Enterobacteriaceae were not observed during the study period; however, rates of methicillin-resistant S. aureus increased over time (P &lt; 0.01).</p>

<p><strong>CONCLUSIONS: </strong>Gram-positive and ESKAPE organisms are leading causes of bacteremia in hospitalized children. Although antimicrobial resistance patterns were favorable compared with prior reports of hospitalized adults, multicenter studies with continuous surveillance are needed to identify trends in the emergence of antimicrobial resistance in this setting.</p>