Invasive disease due to Haemophilus influenzae type A in children in Canada’s north: A priority for prevention

Haemophilus influenzae type B (HiB) was the major cause of meningitis and a frequent cause of other invasive infections in young children until an effective vaccine became available in the early 1990s. In the prevaccine era, the estimated yearly incidence of invasive disease in the United States (US) for children <5 years of age was 40 to 100 cases per 100,000. Infection rates were highest in Aboriginal children (1). For Inuit children <5 years of age residing in the Keewatin district in Nunavut, the rate of HiB meningitis alone was 530 cases per 100,000 (2); however, HiB infection is now rare. Immunization against HiB protects against disease and also reduces carriage of this organism. After the remarkable success of the conjugate HiB vaccine in controlling HiB, there has been concern about the possibility of serotype replacement, as has been observed with pneumococcus (1,3,4). Historically, invasive infections involving H influenza serotypes other than B were sporadic and rare (5). However, in recent years, increasing rates of invasive infection due to H influenzae type A (HiA) have been reported in the Canadian north, as well as in Alaska (USA) and in Aboriginal populations in the southwestern US and Australia (1,6,7). In Alaska, where surveillance for all invasive H influenzae infections has been onging since 1983, HiA was not detected before 2002 (8). Between 2002 and 2005, rates for Indigenous children <2 years of age in northern Canada and Alaska were 101.9 and 20.9 per 100,000, respectively (3). An incidence of 87.5 per 100,000 for children <2 years of age was reported in the Canadian circumpolar region from 2000 to 2010 (6). In 2001, in the Keewatin region of Nunavut, the rate for children <5 years of age was 418.8 per 100,000 (9). Outbreaks occurred in Alaska in 2003 and 2009 to 2011 (3,8), as well as in Nunavik, northern Quebec, from 2012 to 2013 (10). Recurrent disease has been reported in three apparently healthy children who were <10 months of age at initial infection (11,12). Case fatality rates of 5.5% to 16% have been observed (6,8,9). HiA infections in the non-Aboriginal population in the US remain rare (13). In Quebec, before 2010, there were one or two cases of invasive HiA infection per year, with no cases from Nunavik. There was an average of four cases per year in Nunavik from 2010 to 2012, and 10 cases in 2013. Most cases involved young children, and presentations included meningitis, septicemia, septic arthritis and bacteremic pneumonia. Infection rates for 2010 to 2013 were 330.1 and 191.4 cases per 100,000 for children <1 year of age and one to four years of age, respectively, compared with an overall rate in Quebec of 2.0 and 0.8 for these age groups. There were two deaths in 2013, an infant six months of age and another 10 months of age (10). Children from Nunavik are transferred to the Montreal Children’s Hospital (Montreal, Quebec) if they require care that cannot be provided in the north. There were no children transferred with invasive HiA disease before 2010, one in 2010, none in 2011; however, 12 were transferred from 2012 to 2013. In 2013, two cases were from the same household, with onset of illness 24 h apart. In November 2013, the Institut national de sante publique du Quebec made interim recommendations for Nunavik to provide chemoprophylaxis to household and other close contacts of children with HiA infection (10), as was used for HiB (14). Final data for the region for 2014 and 2015 are not available; however, since November 2013, there has been only one case of HiA infection transferred to Montreal Children’s Hospital. Information regarding rates of HiA carriage is sparse. Overall, rates of <1% to 3.5% for children have been reported from cities in Mexico and Brazil, and from an Aboriginal population in Australia (15-17); however, there are no data from North America. Studies involving a small number of close contacts of children with invasive HiA disease in Alaska reported carriage rates of 16% and 45% (11,18). Serological studies involving Aboriginal adults in northern Ontario from 2010 to 2012 showed a high prevalence of anti-HiA antibodies with elevated immunoglobulin (Ig) M levels relative to IgG, whereas anti-HiB levels were lower and IgG predominated (19). This suggested that HiA had only recently become widespread in the area, as reflected by the increase in reports of invasive HiA disease. The pathogenicity and virulence of HiA are similar to that of HiB (20), and the diseases it causes are similar (7). This may be explained by similar capsule structures and resistance to antibody-independant lysis by complement. The other four serotypes (C to F), which occur sporadically, are less virulent in animal models, have different capsule structures and are susceptible or less resistant to complement-mediated lysis (20). The HiA infection rate in young children in northern Canada is now above the rate observed in the general population when the HiB vaccine was introduced. Applying conjugates and methods used in the development of the HiB vaccine, the development of an HiA vaccine is technically feasible. To date, the population at risk is small and underprivileged. Production of an HiA vaccine for this group is unlikely to attract the attention of vaccine manufacturers. Individuals residing in Canada’s north have unique health care needs that require government leadership and initiatives to ensure that they are met. To this end, a collaboration between the Public Health Agency of Canada, the National Research Council and the Northern Ontario School of Medicine launched a project in 2013, with the goal of developing a vaccine against HiA and a better understanding of HiA epidemiology through improved surveillance (21). The appropriate management of close contacts of HiA cases remains to be determined. Before the HiB vaccine became available, secondary cases occurred in 2% of household and 1% of day care contacts (14). Chemoprophylaxis has been suggested for contacts of individuals with HiA (1,7,11), used by some (3,10,18) and discouraged by others because of an absence of data regarding carriage and efficacy (9,22). If carriage rates in close contacts are, in fact, in the range of 16% to 45%, it would be warranted. Studies investigating the effectiveness of HiA eradication using the antibiotic regimens used for HiB are needed. While awaiting further data and guidance, physicians and public health authorities will have to use judgement and knowledge of local epidemiology to decide whether prophylaxis is warranted. peDiATric infecTious DiseAses noTes