Alan J. Parkinson

Efficacy and safety of seven-valent conjugate pneumococcal vaccine in American Indian children: group randomised trial

BACKGROUND Streptococcus pneumoniae is the main cause of invasive bacterial disease in children aged younger than 2 years. Navajo and White Mountain Apache children have some of the highest rates of invasive pneumococcal disease documented in the world. We aimed to assess the safety and efficacy of a seven-valent polysaccharide protein conjugate pneumococcal vaccine (PnCRM7) against such disease. METHODS In a group-randomised study, we gave this vaccine to children younger than 2 years from the Navajo and White Mountain Apache Indian reservations; meningococcal type C conjugate vaccine (MnCC) served as the control vaccine. Vaccine schedules were determined by age at enrollment. We recorded episodes of invasive pneumococcal disease and serotyped isolates. Analyses were by intention to treat and per protocol. FINDINGS 8292 children enrolled in the trial. In the per protocol analysis of the primary efficacy group (children enrolled by 7 months of age) there were eight cases of vaccine serotype disease in the controls and two in the PnCRM7 group; in the intention-to-treat analysis we noted 11 cases of vaccine serotype disease in the MnCC control group and two in the PnCRM7 group. After group randomisation had been controlled for, the per protocol primary efficacy of PnCRM7 was 76.8% (95% CI -9.4% to 95.1%) and the intention-to-treat total primary efficacy was 82.6% (21.4% to 96.1%). INTERPRETATION PnCRM7 vaccine prevents vaccine serotype invasive pneumococcal disease even in a high risk population. Other regions with similar disease burden should consider including this vaccine in the routine childhood vaccine schedule.

Antibody Levels and Protection after Hepatitis B Vaccination: Results of a 15-Year Follow-up

Context Although administration of hepatitis B vaccine for infants is routine practice in many countries, we do not know whether the protection that this vaccine offers lasts beyond 10 years. Such information is essential to develop policies about booster vaccination. Contribution Of 841 Alaska Natives who received 3 doses of hepatitis B vaccination during 19811982 and were followed for 15 years, 84% had protective levels of antibody to hepatitis B surface antigen that indicated continued protection. The greatest decline in antibody levels occurred in people who received vaccine before 4 years of age. Definite asymptomatic breakthrough infections occurred in 16 participants. Cautions Only about half of the initial cohort of 1578 was available for testing at 15 years. The Editors Universal vaccination of infants with hepatitis B vaccine is included in the immunization programs of most countries and has been shown to be effective in reducing the rate of chronic hepatitis B virus (HBV) infection (1, 2). Protection has been demonstrated in persons and populations vaccinated for 5 to 10 years, and rates of asymptomatic breakthrough HBV infection have been extremely low (3-9). However, the duration of protection afforded by hepatitis B vaccination beyond 10 years and the possible need for booster doses of this vaccine are unknown. Alaska Natives have a high prevalence of chronic HBV infection, primarily acquired during early childhood (10). Between November 1981 and May 1982, Alaska Natives residing in 15 villages in southwest Alaska were enrolled in a cohort study to ascertain the immunogenicity and long-term effectiveness of hepatitis B vaccination (11-14). We report data on the persistence of antibodies to hepatitis B surface antigen (anti-HBs), incidence of HBV infection, and the genetic characteristics of the HBV isolates in persons with breakthrough infections 15 years after initial vaccination of this cohort. Methods Participants and Data Collection A total of 1578 Alaska Natives who were serologically negative for hepatitis B surface antigen (HBsAg) and antibody to hepatitis B core antigen (anti-HBc) were vaccinated on a 0-, 1-, and 6-month schedule with 3 doses of plasma-derived hepatitis B vaccine (Heptavax, Merck & Co., Inc., West Point, Pennsylvania) beginning in 1981 (11). Persons younger than 20 years of age received the 10-g dose, and adults received the 20-g dose. Of the 1578 persons vaccinated, 1436 (91%) were tested for an anti-HBs response 6 months after the last vaccine dose. From 1982 to 1992, serum specimens were obtained annually and once again during 1996 from as many of the 1578 consenting participants as possible. The Institutional Review Boards of the Alaska Area Native Health Service, the Indian Health Service, the Centers for Disease Control and Prevention, and the Yukon-Kuskokwim Health Corporation and the Norton Sound Regional Alaska Native health boards approved this study. All participants 18 years of age and older and parents of children younger than 18 years of age had provided signed informed consent to participate in the study; children older than 7 years of age gave verbal assent. The number of HBsAg-positive persons in each village was obtained from a registry used to follow patients with chronic HBV infection (15). Serologic Testing All serum specimens were tested for HBsAg, anti-HBs, and anti-HBc by radioimmunoassay using commercial test kits (Abbott Laboratories, Abbott Park, Illinois). At the initial testing of the cohort for anti-HBs, results were reported in sample ratio units. However, subsequent anti-HBs results were reported in milli international units (mIU) per mL using a World Health Organization reference standard (12-14). To ensure comparability of results over time, all serum specimens from each participant with sufficient volume (99.9% of all specimens collected during the study) were retested to determine anti-HBs levels in mIU/mL. Detection of HBV DNA and Nucleic Acid Sequencing Hepatitis B virus DNA was extracted from serum specimens (50 L) of participants with serologic markers of HBV infection by using commercially available reagents (MasterPure Complete DNA and RNA Purification Kit, Epicentre Technologies, Madison, Wisconsin), as described previously (16, 17). The HBsAg genomic region was then amplified by dilution cloning polymerase chain reaction by using previously described primers and methods to identify circulating variants of HBsAg (16, 17). The polymerase chain reaction products were purified and the nucleic acid sequence of the amplified region were determined by using prism dye or dRhodamine terminator cycle reactions (Applied Biosystems, Foster City, California) and automated sequencing (ABI Model 373 or 377, Applied Biosystems) (18). Sequence data were further analyzed by Sequence Navigator (ABI) and GCG software (19). Definitions The initial anti-HBs level was measured 6 months after the third dose of vaccine and 1 year after the first dose of vaccine. Participants with an initial anti-HBs level of at least 10 mIU/mL were considered vaccine responders. An anti-HBs level of 2 mIU/mL or greater was considered a positive result on subsequent specimens. A booster response was defined as a 2-fold or greater increase in anti-HBs levels between serologic test results. A definite HBV infection in a participant was defined as 1) 2 or more consecutive serum specimens positive for anti-HBc more than 1 year after the initial vaccine dose, 2) a single positive anti-HBc result with a positive HBV DNA result, or 3) any HBsAg-positive test result. A possible HBV infection was defined as a single positive or 2 nonconsecutive positive anti-HBc results. Participants who developed anti-HBc were interviewed for history of icterus or other clinical signs or symptoms compatible with acute hepatitis, and village and hospital medical records were reviewed for evidence of an illness compatible with viral hepatitis. Statistical Analysis Among persons who inadvertently received additional doses of hepatitis B vaccine during the follow-up period, anti-HBs results after the additional vaccine dose or doses were excluded from the analyses. Results for anti-HBs among persons with definite HBV infections were excluded from analyses after anti-HBc appeared. The primary outcomes in this study were the cumulative number of persons with a definite HBV infection during all follow-up years and the anti-HBs levels at the 15-year follow-up. The definitions of age classes (0 to 4 years, 5 to 19 years, 20 to 49 years, 50 years) were similar to those in a previously published analysis of this cohort (14). Although these data have been presented previously (11-14), we have provided the proportion of persons initially responding to vaccination. Quantitative anti-HBs levels are presented as geometric mean concentrations (GMCs). In bivariate analyses, analysis of variance was used to test the 15-year anti-HBs concentrations (log-transformed). Incidence rates of definite HBV infection were compared by using the Fisher exact test. We analyzed factors associated with anti-HBs levels over the 15 years after the first vaccine dose by using a linear mixed model (PROC MIXED in SAS version 9.1, SAS Institute, Inc., Cary, North Carolina) (19). We chose a longitudinal mixed linear model because it makes inferences by using information from the entire cohort collected at all follow-up time points. Levels of anti-HBs were log-transformed before analysis, and concentrations of 0 mIU/mL were assigned a value of 1.0 mIU/mL. Factors considered in the model were time (entered as a continuous covariate; linear and quadratic term were considered), age class at initial vaccination, sex, the log of the initial anti-HBs level, presence of an HBsAg-infected person in the household at the start of the study, and the proportion of village residents with chronic HBV infection at the end of follow-up, along with interaction terms involving time. Significance of 1 factor alone, such as age or sex, is called a main effect and is not of primary interest for this presentation. Of primary interest are the interaction terms between time and other factors. A significant interaction of time with another variable, such as sex, indicates that the decline in anti-HBs level differed between males and females. We obtained parameter estimates by using restricted maximum likelihood. We used an unstructured covariance matrix to account for dependence of observations across time within individuals. Backward elimination of statistically nonsignificant terms yielded a final model of main effects and time interaction terms. If the time interaction term was statistically significant, the main effect term remained in the model regardless of statistical significance. We used the Wald chi-square statistic to test covariates. Contrast tests were 2-sided, and an level of 0.05 was required. We used residual plots to evaluate model fit. A secondary outcome was a boost in anti-HBs level at the 11- or 15-year follow-up among persons without additional doses of vaccine. We used the chi-square test or the CochranMantelHaenszel test to compare age and sex of persons with a booster response to those of persons without a booster response at both follow-up years. All P values were exact where appropriate and were 2-sided; results were considered statistically significant at the 0.05 level. We conducted analyses by using StatXact4 (Cytel Software Corp., Cambridge, Massachusetts) and SAS software, version 9.1 (SAS Institute, Inc.). Missing Data Throughout the entire study, anti-HBs determinations were observed for 68% of all potential observational time points (Appendix Table 1). The 15 remote rural Alaskan study villages are accessible only by airplane. During each year, study personnel flew into each village for 1 to 2 days and attempted to recruit all available participants. Persons not available or out of the village for the day were considered miss

Community-Onset Methicillin-Resistant Staphylococcus aureus Associated with Antibiotic Use and the Cytotoxin Panton-Valentine Leukocidin during a Furunculosis Outbreak in Rural Alaska

BACKGROUND Community-onset methicillin-resistant Staphylococcus aureus (CO-MRSA) reports are increasing, and infections often involve soft tissue. During a CO-MRSA skin infection outbreak in Alaska, we assessed risk factors for disease and whether a virulence factor, Panton-Valentine leukocidin (PVL), could account for the high rates of MRSA skin infection in this region. METHODS We conducted S. aureus surveillance in the outbreak region and a case-control study in 1 community, comparing 34 case patients with MRSA skin infection with 94 control subjects. An assessment of traditional saunas was performed. S. aureus isolates from regional surveillance were screened for PVL genes by use of polymerase chain reaction, and isolate relatedness was determined by use of pulsed-field gel electrophoresis (PFGE). RESULTS Case patients received more antibiotic courses during the 12 months before the outbreak than did control subjects (median, 4 vs. 2 courses; P=.01) and were more likely to use MRSA-colonized saunas than were control subjects (44% vs. 13%; age-adjusted odds ratio, 4.6; 95% confidence interval, 1.7-12). The PVL genes were present in 110 (97%) of 113 MRSA isolates, compared with 0 of 81 methicillin-susceptible S. aureus isolates (P<.001). The majority of MRSA isolates were closely related by PFGE. CONCLUSION Selective antibiotic pressure for drug-resistant strains carrying PVL may have led to the emergence and spread of CO-MRSA in rural Alaska.

The relationship among previous antimicrobial use, antimicrobial resistance, and treatment outcomes for Helicobacter pylori infections

Context Adverse effects of previous antibiotic use in patients with Helicobacter pylori infections are unclear. Contribution This retrospective study examined relationships between resistant H. pylori infections and past antibiotic use in 125 Alaskan Native adults. Clarithromycin-resistant H. pylori isolates were common (prevalence, 30%) and were associated in a dose-response manner with previous use of macrolide antibiotics. Of patients with these resistant isolates, 77% had treatment failure with clarithromycin-based regimens. Implications Previous use of macrolide antibiotics is associated with increased risk for infection with clarithromycin-resistant H. pylori and increased risk for treatment failure with that antibiotic. The Editors Helicobacter pylori is a common pathogen of the gastric mucosa, infecting up to 40% of persons in developed countries and up to 90% of individuals living in developing nations (1, 2). Infection with H. pylori has been shown to be a major cause of gastric and duodenal ulcers and is also associated with chronic gastritis, mucosa-associated lymphoid tissue lymphoma, and adenocarcinoma of the stomach (3-6). Eradication of H. pylori has been reported in up to 95% of patients treated with a combination of antimicrobial agents (7-9). In the United States and elsewhere, antimicrobial resistance to metronidazole and clarithromycin is increasing; resistance to amoxicillin and tetracycline remains uncommon (10-12). Compared with persons with susceptible isolates, persons infected with clarithromycin- or metronidazole-resistant H. pylori have lower cure rates when treated with regimens containing these antimicrobial agents (12-15). In studies that have addressed risk factors associated with resistant H. pylori infection, none to our knowledge have evaluated prediagnosis antimicrobial use as a risk factor for resistance or treatment failure (16, 17). Alaska Nativespersons of Eskimo, Indian, and Aleut descenthave high rates of H. pylori infection, with an overall seroprevalence of 75% for specific antibodies (18). We are conducting a study in urban Alaska Native, rural Alaska Native, and urban non-Native adults to determine and compare reinfection rates after successful eradication of H. pylori. The study in urban Alaska Native adults is completed, and in this group, we sought to determine whether past antimicrobial use was associated with antimicrobial resistance among H. pylori isolates obtained through diagnostic endoscopy. We then determined whether H. pylori antimicrobial resistance affected the outcome of H. pylori treatment. Methods From September 1998 through June 2002, the Arctic Investigations Program of the U.S. Centers for Disease Control and Prevention and the Alaska Native Medical Center (ANMC) conducted a study to determine reinfection rates after successful eradication of H. pylori infection among Alaska Natives living in Anchorage. The ANMC is a 150-bed referral hospital that provides outpatient primary care services for Alaska Natives living in the Anchorage area. The institutional review boards of the Centers for Disease Control and Prevention, the Alaska Area Tribal Health Consortium, and the Indian Health Service approved the study, as did the Alaska Native Health Board. Written informed consent was obtained from all participants. Patients and Data Collection From September 1998 through June 2002, we attempted to recruit all Alaska Natives 18 years of age or older from the Anchorage area who had no history of an immunodeficiency condition or were not taking immunosuppressive medications (such as corticosteroids or cancer chemotherapeutic agents) and were scheduled for esophagogastroduodenoscopy. Alaska Natives who use ANMC for surgical procedures are very likely to receive most of their care from this facility, since no copayment is assessed to persons eligible for care at ANMC. A study nurse recruited 293 persons during the study period, 149 of whom had a positive culture for H. pylori. Since 27 September 1990, patient care information from all outpatient health care visits and outpatient pharmacy encounters at ANMC has been entered into a computerized records system. For this analysis, we recorded all antimicrobial prescriptions for 10 years before diagnosis of H. pylori infection by consulting outpatient records of study participants for whom at least 8 years of pharmacy records were available. We also recorded antimicrobial use during all hospitalizations and emergency department visits at ANMC for each participant in the same 10-year period. An antimicrobial course was defined as a prescription for an antimicrobial drug regardless of dose, duration, and frequency. Biopsy and Culture All participants had up to 3 gastric biopsy specimens taken for culture, antimicrobial susceptibility testing, and histologic examination for H. pylori. Gastric biopsy specimens stored in cysteine freeze medium at 80 C were ground in a sterile tissue grinder with heat-inactivated fetal bovine serum and inoculated to 3 types of solid media: blood agar (tryptic soy agar with 5% sheep blood); chocolate agar; and brucella agar containing 10% horse blood, trimethoprim, vancomycin, and polymyxin B. All cultures were incubated at 37 C under microaerophilic conditions and high humidity (12% CO2, 98% humidity) for up to 10 days. Positive cultures were usually identified after 3 to 5 days of incubation. Isolates were identified as H. pylori on the basis of positive catalase, oxidase, and urease reactions; typical uniform, small, translucent colonies; curved gram-negative bacilli on Gram-stained smears; susceptibility to cephalothin (30 g); and resistance to nalidixic acid (30 g). Minimum inhibitory concentrations (MICs) for clarithromycin, amoxicillin, metronidazole, and tetracycline were determined by using agar dilution. Helicobacter pylori isolates were defined as susceptible if the MIC was within the following limits: less than or equal to 0.25 g/mL for clarithromycin, less than or equal to 0.25 g/mL for amoxicillin, less than 8 g/mL for metronidazole, and less than 2 g/mL for tetracycline. Helicobacter pylori isolates with MICs above these limits were classified as resistant (19). In participants who had many cultures of their H. pylori isolates, the highest MIC determined from all of the cultures was used for analysis. Culture results were not available to providers before initiation of treatment. Treatment and Follow-up Each participants attending physician decided whether to initiate treatment and selected the treatment regimen. Patients who were treated received a 2-week course of a combination of 2 or 3 antibiotics plus lansoprazole. A study nurse called each patient approximately every 3 days to document adherence. Successful eradication of H. pylori was defined as negative results on a urea breath test (BreathTek UBT, Meretek Diagnostics, Inc., Nashville, Tennessee) 8 weeks after initiation of treatment. Statistical Analysis Statistical analysis was performed by using StatXact 5 (Cytel Software Corp., Cambridge, Massachusetts) and SAS software (SAS Institute, Inc., Cary, North Carolina). Confidence intervals for binomial proportions were computed by using the Casella procedure (20). Bivariate associations were examined by using the chi-square test or the Fisher exact test for dichotomous variables. The Wilcoxon rank-sum test was used for comparisons of continuous variables. Logistic regression was used to test univariable dose-response relationships and multivariable associations with antimicrobial resistance. Variables were considered for the multivariable models if their univariable P value was less than 0.25, with the exception of sex, which was included in all models. The numbers of courses of macrolides, clarithromycin, erythromycin, azithromycin, and metronidazole were entered into the multivariable models as indicator variables ( 1 course or 0 courses), while the number of all other courses of antibiotics was entered as an interval variable. Variables were considered confounders and remained in the model if their exclusion changed the value of the coefficients of interest by more than 15%. All P values are two-sided, and confidence intervals are exact when appropriate. Results One hundred forty-nine persons with culture-confirmed H. pylori infection were enrolled in the study. Of these, 125 who had documented health encounters for at least 8 years before enrollment (84%) were included for analysis. The median age of participants was 46.5 years (range, 22.2 to 88.7 years). Eighty-two (66%) were women, and all were Alaska Natives. Pharmacy records were available for a median of 8.6 years (range, 8.0 to 9.6 years). A median of 11 (range, 0 to 68) antimicrobial courses was prescribed during the 8 to 10 years before enrollment (mean, 1.52 courses per year). For -lactam antimicrobial agents and macrolide antimicrobial agents, the median number of courses prescribed was 5 (range, 0 to 31) and 1 (range, 0 to 11), respectively. The median number of courses for all other classes of antimicrobial agents prescribed (including metronidazole) was 3 (range, 0 to 30). Thirteen patients (10%) had received previous treatment for H. pylori infection in the 10 years before enrollment. Clinical symptoms included heartburn (75%), nausea (72%), vomiting (40%), and hematemesis (11%). Endoscopic findings included hemorrhagic or superficial ulcerations of the gastric mucosa in 56 patients (45%), duodenal ulcers in 4 (3%), and gastric ulcers in 8 (6%). Two specimens of the gastric mucosa were obtained for culture from 105 participants (84%) at the time of diagnosis. Seventeen patients (14%) had a single specimen submitted for culture, and 3 (2%) had 3 or more specimens. Among the 125 participants, 83 (66%) were found to have H. pylori isolates resistant to metronidazole, 37 (30%) were found to have H. pylori isolates resistant to clarithromycin, 7 (6%) were found to have H. pylori isolates resistant t

High Prevalence of Helicobacter pylori in the Alaska Native Population and Association with Low Serum Ferritin Levels in Young Adults

ABSTRACT Iron deficiency anemia is a common public health problem in the Alaska Native population. Yet, a clear etiology has eluded researchers for decades. Previous studies suggested a link betweenHelicobacter pylori infection, gastrointestinal blood loss due to hemorrhagic gastritis, and generalized iron deficiency anemia in adult Alaska Natives. Therefore, we examined the association between the prevalence of H. pylori-specific immunoglobulin G (IgG) and serum ferritin levels, a marker of iron deficiency. A random sample of 2,080 serum samples from Alaska Native residents drawn between 1980 and 1986 from residents in 13 regions was selected, and the samples were stratified by age, sex, and region. Overall, 75% were positive for H. pylori-specific IgG. The rate of H. pylori seropositivity increased with age; by age 14 years, 78% of the residents were positive. There were no gender differences inH. pylori seropositivity. However, marked regional differences were observed. Serum ferritin levels of <12 ng/ml were found most commonly among persons <20 years of age and among women of childbearing age. A significant association between low serum ferritin levels and prevalence of H. pylori-specific IgG was found, particularly for people aged less than 20 years. H. pylorimay be a factor contributing to the iron deficiency anemia in the Alaska Native population.

Reemergence of invasive Haemophilus influenzae type b disease in a well-vaccinated population in remote Alaska.

Before vaccination, Alaska Natives experienced very high rates of invasive Haemophilus influenzae type b (Hib) disease and carriage. Vaccination with Hib conjugate vaccine PRP-OMP (polyribosylribitol phosphate Neisseria meningitidis outer membrane protein) began in 1991 and resulted in a sharp decline in cases. In 1996, after switching to a different Hib conjugate vaccine, DTP-HbOC (which combines diphtheria-tetanus-whole cell pertussis vaccines with HbOC [Hib oligosaccharide CRM197]), cases of invasive Hib disease increased, suggesting ongoing Hib transmission despite widespread vaccination. To determine the prevalence of and risk factors for carriage, a cross-sectional study of oropharyngeal Hib carriage was conducted among Alaska Native children aged 1-5 years in remote southwestern Alaska. Of 496 children with swabs taken, 46 (9.3%) were colonized with Hib. Carriage rates varied by village from 2.2% to 13.2% and by age from 6.1% in 1-year-olds to 14.7% in 5-year-olds. Crowding was associated with Hib carriage. Widespread vaccination with PRP-OMP Hib conjugate vaccine did not eliminate carriage in this population of Alaska Natives, and ongoing carriage contributed to disease resurgence.

Severe Respiratory Syncytial Virus Disease in Alaska Native Children

Hospitalization rates for respiratory syncytial virus (RSV) infection range from 1 to 20/1000 infants. To determine the rate and severity of RSV infections requiring hospitalization for infants in the Yukon-Kuskokwim (YK) Delta of Alaska, a 3-year prospective surveillance study was conducted. The annual rate of RSV hospitalization for YK Delta infants <1 year of age was 53-249/1000. RSV infection was the most frequent cause of infant hospitalization. RSV disease severity did not differ among non-high-risk infants in the YK Delta and at Johns Hopkins Hospital (JHH). On average, 1/125 infants born in the YK Delta required mechanical ventilation for RSV infection. During the peak season, approximately

Impact of a Conjugate Vaccine on Community-Wide Carriage of Nonsusceptible Streptococcus pneumoniae in Alaska

1034/child <3 years of age was spent on RSV hospitalization in the YK Delta. In YK Delta infants </=6 months old, RSV microneutralizing antibody titers <1200 were associated with severe disease (odds ratio=6.2, P=.03). In the YK Delta and at JHH, newborns may be at greater risk for severe RSV illness than previously thought.

Sequential Inactivation of rdxA (HP0954) and frxA (HP0642) Nitroreductase Genes Causes Moderate and High-Level Metronidazole Resistance in Helicobacter pylori

BACKGROUND Streptococcus pneumoniae is a leading cause of invasive bacterial disease and pneumonia among children. Antimicrobial resistance among pneumococci has increased in recent years and complicates treatment. The introduction of heptavalent pneumococcal conjugate vaccine (PCV7) could reduce acquisition of antimicrobial-resistant pneumococci. METHODS We obtained 1350 nasopharyngeal swabs for culture from 1275 children aged 3-59 months presenting at 3 clinics in Anchorage, Alaska, during the winters of 2000, 2001, and 2002, as PCV7 was being introduced into the routine immunization schedule. We recorded the frequency of use of antibiotics as well as the dates of doses of PCV7 for enrolled children. We used multivariate logistic regression modeling to identify independent risk factors for overall carriage of pneumococci and carriage of PCV7-type pneumococci, cotrimoxazole-nonsusceptible (COT-NS) pneumococci, or penicillin-nonsusceptible (PCN-NS) pneumococci. RESULTS The proportion of children who were up-to-date for age, with respect to PCV7 vaccination, increased from 0% in 2000 to 55% in 2002. Carriage of PCV7-type pneumococci decreased by 43% (P<.0001). Risk of carriage of PCV7-type pneumococci was lower in 2002 than in 2000, independent of vaccination status, suggesting an indirect effect of vaccination. Carriage of COT-NS, but not PCN-NS, pneumococci also decreased (38%; P=.02), not only among vaccinated children but also among unvaccinated children without recent use of antibiotics. CONCLUSIONS Introduction of PCV7 into the routine infant immunization schedule in a community with a high prevalence of antimicrobial-resistant pneumococci appears to reduce transmission of PCV7 vaccine serotypes and COT-NS pneumococci but has no impact on overall carriage of pneumococci or carriage of PCN-NS pneumococci.

Elimination of hepatocellular carcinoma and acute hepatitis B in children 25 years after a hepatitis B newborn and catch‐up immunization program

Helicobacter pylori is a human-pathogenic bacterial species that is subdivided geographically, with different genotypes predominating in different parts of the world. Here we test and extend an earlier conclusion that metronidazole (Mtz) resistance is due to mutation in rdxA (HP0954), which encodes a nitroreductase that converts Mtz from prodrug to bactericidal agent. We found that (i) rdxA genes PCR amplified from 50 representative Mtz(r) strains from previously unstudied populations in Asia, South Africa, Europe, and the Americas could, in each case, transform Mtz(s) H. pylori to Mtz(r); (ii) Mtz(r) mutant derivatives of a cultured Mtz(s) strain resulted from mutation in rdxA; and (iii) transformation of Mtz(s) strains with rdxA-null alleles usually resulted in moderate level Mtz resistance (16 microg/ml). However, resistance to higher Mtz levels was common among clinical isolates, a result that implicates at least one additional gene. Expression in Escherichia coli of frxA (HP0642; flavin oxidoreductase), an rdxA paralog, made this normally resistant species Mtz(s), and frxA inactivation enhanced Mtz resistance in rdxA-deficient cells but had little effect on the Mtz susceptibility of rdxA(+) cells. Strains carrying frxA-null and rdxA-null alleles could mutate to even higher resistance, a result implicating one or more additional genes in residual Mtz susceptibility and hyperresistance. We conclude that most Mtz resistance in H. pylori depends on rdxA inactivation, that mutations in frxA can enhance resistance, and that genes that confer Mtz resistance without rdxA inactivation are rare or nonexistent in H. pylori populations.