Kingella kingae infections in children

K. kingae is a facultative anaerobic, β-hemolytic, Gram-negative organism [1] that is difficult to identify in routine solid cultures of blood or body fluids such as synovial fluid or bone exudates as it is isolated in less than 10 % of truly positive cases. However, significantly more cases have been reported when exudates are inoculated into aerobic blood culture vials, particularly when the positive samples are sub-cultured on a blood-agar plate of trypticase soy agar with 5 % sheep blood hemoglobin or chocolate agar. This need for specific culture techniques explains why the etiology of a number of invasive diseases due to K. kingae (particularly septic arthritis and osteomyelitis in young children) was not initially identified, thus leading to the definition of “culture-negative bone infections of unknown origin” [1].

It is even more difficult to identify K. kingae in cultured pharyngeal samples because of its relatively slow growth and the high density of resident bacterial flora, although this can be overcome by using a selective medium consisting of blood-agar with added vancomycin to inhibit the growth of competing flora [1].

The best means of detecting K. kingae are the recently developed nucleic acid amplification assays because they are not only significantly more sensitive than culture, but also reduce the time needed for bacterial identification from 3–4 days to a few hours. They also make it possible to use pharyngeal secretions to diagnose invasive K. kingae invasive infections, as described by Ceroni et al. who used a polymerase chain reaction (PCR) to identify the etiology of a K. kingae osteoarticular infection from pharyngeal swabs [10]. They found that the method was 100 % sensitive and 90.5 % specific, thus making a negative swab sufficient to rule out K. kingae infection and prompt more invasive diagnostic measures. However, K. kingae detection in the oropharynx of a child with an osteoarticular infection is not an irrefutable proof of the etiology of the disease because the carriage rate of the organism among pediatric patients is around 10-12 % [1].

Furthermore, the molecular typing of isolates has revealed genomic heterogeneity in K. kingae species, and made it possible to study the possible association between the genetic characteristics of the different strains and their tendency to cause invasive disease, as well as the relationships between antibiotic resistance and genotype distribution. One of the most widely used molecular techniques is the amplification and sequencing of polymorphisms of the rtxA gene, which is involved in the production of a protein belonging to the RTX toxin family that has been associated with the virulence of K. kingae insofar as disruption of the RTX locus leads to the loss of cytotoxicity for respiratory epithelial, synovial, and macrophage cell lines [11]. Furthermore, when Chang et al. [12] infected rats with K. kingae strain PYKK081 and its isogenic rtxA-deficient strain KKNB100, they found that PYKK081 causing a fatal illness characterised by rapid weight loss, bacteremia, the formation of necrotic abdominal lesions, and significant histopathology in thymus, spleen and bone marrow, whereas KKNB100 was less toxic and did not induce weight loss, bacteremia or histopathological changes. In addition, the animals injected with KKNB100 had significantly high circulating white blood cell (WBC) counts, whereas the counts of the rats injected with PYKK081 were similar to those recorded in the uninfected controls [12].

The use of pulsed-field electrophoresis (PFGE) has made it possible to establish that a number of the K. kingae clones that are relatively frequently isolated asymptomatic carriers (A, C, G, J, M, R, T and U) play a marginal role in determining invasive infections, whereas clones B, H, K, N and P are significantly more frequently associated with the development of disease [13]. This suggests that the more invasive strains may be more rapidly cleared from the respiratory tract and that their persistence may require a different biological specialisation. It was also found that each of the virulent clones may be responsible for a well-defined disease as clone K was significantly associated with bacteremia, clone N with skeletal system infections, and clone P with bacterial endocarditis [13].

It was initially shown that K. kingae isolates were almost always susceptible to most of the antibiotics that are routinely administered to children with suspected bacteremia or skeletal system infections, including penicillin, ampicillin, second- and third-generation cephalosporins, macrolides, rifampin, co-trimoxazole, ciprofloxacin, tetracycline and chloramphenicol, whereas oxacillin, clindamycin and daptomycin were not very effective, and trimethoprim and glycopeptide antibiotics had no activity at all [14]. However, resistance of K. kingae to β-lactam antibiotics has more recently been repeatedly reported, although the rates vary widely from one country to another: Basmaci et al. screened 778 isolates from Iceland, the USA, France, Israel, Spain and Canada for β-lactamase production, and found that the French, Spanish and Canadian isolates were negative, whereas 28.6 % of the Icelandic, 25.0 % of the American, and 11 % of the Israeli isolates were positive [15]. The distribution of β-lactam antibiotic resistance among invasive and carried organisms has not yet been precisely defined, but Yagupsky et al. found enzyme production in 1.1 % of the invasive organisms and 15.4 % of the carried organisms detected in a sample of 619 K. kingae isolates from Israel [16]. This finding seemed to be confirmed by the PFGE studies of the genotypic clonality of the strains because β-lactamase production was limited to only four of the 73 identified clones (33 in invasive and 56 in carriage isolates), and these four were common among the carried strains but rare among the invasive strains [16]. However, Basmaci et al. found that all of their American and Icelandic β-lactamase-positive isolates belonged to the main international invasive PFGE clone K/MLST ST-6, and were different from the four genetically unrelated Israeli β-lactamase-producing clones [15]. The presence of the enzyme in the isolates belonging to the major worldwide invasive K. kingae clone highlights the possible spread of β-lactam resistance, and emphasises the importance of routinely testing all K. kingae clinical isolates for β-lactamase production.

Asymptomatic colonisation of the upper respiratory tract by K. kingae is extremely common in children, who acquire the infectious agent after six months of life [1]; subsequently, the incidence of colonization tends to decrease to 10-12 % until the end of the second year before gradually declining to very low levels in older children and adults (Table 1). This suggests that the disappearance of vertically transmitted immunity and the greater socialisation of children aged more than six months increase the risk of colonisation, whereas progressive immunological maturation and/or accumulative familiarity with K. kingae antigens as a result of mucosal colonisation lead to the acquisition of sufficient immunity to eradicate the organism from the pharynx in older people. This seems to be confirmed by the results of a study designed to evaluate the dynamics of K. kingae antibody levels in childhood, which showed that mean IgG level is high at the age of two months, gradually decreases until the age of 6–7 months (the time of lowest concentrations), remains low until the age of 18 months, and subsequently increases [17].

Carriage may be continuous for weeks or months, or intermittent as shown by the findings of an 11-month longitudinal study of children aged 19–48 months old attending a day care centre in Israel [18]: about 73 % carried the organism at least once and half carried it for at least two months during the follow-up period. Moreover, colonisation was greatest during late winter and spring, and characteristically involved oropharynx because K. kingae was hardly ever found in the nasopharynx [18].

Colonised children are the main cause of the spread of the pathogen. This was suggested by the fact that colonisation rates are significantly higher in children attending day care centres than in the general population of the same age, and was confirmed by a comparative genetic analysis of cultured K. kingae isolated from colonised children and their siblings and playmates that clearly revealed the indistinguishable genotype profiles of the strains identified in both groups [19]. Moreover, although it is asymptomatic in the great majority of children, colonisation is a prerequisite for the development of disease, and genotypically identical isolates have been recovered from the pharynx and bloodstream of patients with invasive K. kingae infections [20]. On the basis of these findings, it is not surprising that a number of outbreaks of K. kingae disease have been associated with day care centres [3, 21, 22]: in all of these cases, unusually high K. kingae colonisation rates were found among the asymptomatic attendees, and all the pharyngeal isolates detected in the classrooms were genetically identical to those identified in patients [9].

The pathogenesis of invasive K. kingae infection has not yet been defined, but some data seem to indicate that its penetration is favoured by a concomitant viral infection capable of damaging oropharyngeal mucosa. Stomatitis and symptoms of respiratory infection are common in patients with K. ingaek disease [23]. The pathogen was isolated from the blood of four out of 29 patients with primary herpetic gingivostomatitis [24], and it has been suggested that, after penetration, it can progress to the lower respiratory tract or invade the bloodstream and subsequently reach the skeletal system, heart or other parts of the body [18].

Invasive infectious K. kingae disease generally develops in younger and otherwise healthy children, and its age distribution is similar to that of carriage. Almost 90 % of the reported cases have occurred in children aged <5 years, and 60 % in those aged <2 years [18]. As in the case of invasive Streptococcus pneumoniae and Neisseria meningitidis infections [25, 26], invasive K. kingae infections are more common in males [2].

In most cases, K. kingae bacteremia is detected concomitantly with infections of the skeletal, cardiovascular, respiratory or central nervous systems; however, occult bacteremia has been diagnosed in a number of cases, some of which were characterised by a maculopapular rash resembling those seen in patients with disseminated meningococcal disease [27]. The fact that K. kingae is identified in the blood of very few patients with ascertained invasive infection even when sensitive and specific molecular methods are used suggests that the duration of bacteremia is usually short [27].

The most frequent clinical manifestation of invasive K. kingae infection are osteoarticular infections [1], and K. kingae is the most common cause of such infections in children aged between six months and four years [28]: one recent molecular study by Ceroni et al. found that 82 % of the joint or bone aspirates of children aged <4 years with osteoarticular infection were positive [29]. Unlike the joint or bone infections due to other bacterial pathogens (mainly Staphylococcus aureus), which usually have a severe clinical picture, osteoarticular K. kingae infections are generally characterised by mild to moderate clinical and radiological manifestations, and a limited biological inflammatory response [1, 2, 28, 29]. Ceroni et al. observed that fewer than 15 % of their children were febrile, 39 % had normal C-reactive protein (CRP) levels, and only 9 % had high WBC counts [29]; Dubnoz-Raz et al. found fever in 25 % of their patients, a WBC count of >15,000/mm³ in only about 50 %, and CRP levels within the normal range in 22 % [2]. These findings led to the development of an algorithm for the reliable prediction of the K. kingae etiology of an osteoarticular disease in younger children that includes a body temperature of <38 °C, CRP levels of <55 mg/L, a WBC count of <14,000/mm³, and bands of <150/mm³ [30]. However, the possibility to predict osteoarticular K. kingae infections on the bases of mild clinical symptoms and acute phase reactants is disputed and still controversial.

Septic arthritis is mainly diagnosed in the large weight-bearing joints, with synovial fluid WBC counts of <50,000/mm³ in about 25 % of patients, thus underlining their poor inflammatory response [18]. However, the limited clinical evidence of septic arthritis due to K. kingae can prevent a prompt diagnosis in certain cases, thus leading to an increased risk of greater morbidity due to delayed treatment. K. kingae septic arthritis of the hip is a good example because it may be impossible to differentiate it from transient synovitis on purely clinical grounds. In an attempt to improve the identification of septic arthritis of the hip, Kocher et al. developed a specific algorithm based on clinical variables (body temperature upon admission and a refusal to bear weight) and laboratory data (WBC counts and the erythrocyte sedimentation rate [ESR]) that allows the probable exclusion of septic arthritis when WBC counts and the ESR are within the normal range, there is little or no fever, and there are no demonstrable weight bearing problems [31]. However, although the algorithm may be valid in the case of septic arthritis due to other bacteria [32], it cannot be used in the case of K. kingae disease in which all or some of the variables overlap those found in transient synovitis and variation between laboratories may influence the results [33]. Osteomyelitis mainly involves the long bones but also frequently affects bones that are not usually infected by other organisms, such as the calcaneus, talus, sternum and clavicle [34‐36].

Spondylodiscitis is another quite frequent clinical manifestation of K. kingae infection [1]. Like osteomyelitis and septic arthritis, spondylodiscitis due to K. kingae is mainly diagnosed in children aged between six months and four years [37]. The lumbar intervertebral spaces are most frequently affected by mild to moderate signs and symptoms.

Endocarditis is the most severe manifestation of K. kingae infection. It usually occurs in children who are a little older than those suffering from osteoarticular infections and, unlike osteomyelitis and septic arthritis, is accompanied by a high fever and a significant increase in the levels of acute phase reactants [4]. As of July 2014, a total of 42 patients with K. kingae endocarditis had been described in the literature [4], at least 20 % of whom were aged >4 years. At the time of presentation, most of the patients had a body temperature of >39 °C, and mean ESR and CRP levels were respectively 60.4 mm/h and 12.5 mg/dL. Valvular disease was relatively frequent, particularly in the older children, although only a minority had previously been diagnosed as having congenital heart disease. However, the most serious problem associated with K. kingae endocarditis is the emergence of embolic complications that can lead to severe neurological consequences, which have occurred in 13 of the 42 described cases: the most frequent are stroke (77 %) and meningitis (46 %), which have led to the death of four patients (10 %) [4]. Other complications of K. kingae endocarditis include valvular insufficiency, cardiogenic shock, pulmonary infarction and paravalvular abscesses [4].

Other infections such those involving the lower respiratory tract, the central nervous system and the eye are rare [5‐8]. In particular, meningitis seems to be different from the more common K. kingae infections because instead of being diagnosed in younger children, it has mainly occurred in adolescents [5, 38].

Table 2 summarizes the main clinical presentations.

Most K. kingae infections are susceptible to the majority of the oral and parenteral antibiotics usually prescribed for young febrile children and, although some invasive β-lactamase-producing strains are resistant to β-lactam antibiotics and require appropriate monitoring, they do not seem to condition the final prognosis of K. kingae invasive diseases. Consequently, although no comparative controlled study has been published and it is not possible to establish the best antibiotic approach, most invasive diseases due to K. kingae have a benign clinical course when adequately diagnosed. However, diagnostic delays and hospital admission are very common. Skeletal infections generally recover without sequelae provided that they are immediately and appropriately treated including spondylodiscitis, although persistent narrowing of the intervertebral space may remain [39]. The only exception is endocarditis, mainly because of its embolic complications, the most common of which is cerebral infarction [4]. Therefore, when the diagnosis of K. kingae endocarditis is suspected or ascertained, health authorities recommend the prompt use of appropriate laboratory methods in order to get information concerning antimicrobial susceptibility as quickly as possible [40]. According to the clinical presentation, the first line therapy usually used for osteomyelitis, septic arthritis or endocarditis can be recommended and then, if K. kingae etiology will be confirmed, antimicrobial therapy can be optimized according to the results of the antimicrobial susceptibility test if available or using a second- or third-generation cephalosporin.

A still unsolved problem is how to manage outbreaks of K. kingae infection, but it has been suggested that prophylactic antibacterial drugs can be administered to prevent further cases of disease. As it has been found that rifampin, which is particularly active against K. kingae, is secreted in saliva and reaches high concentrations in the upper respiratory tract mucosa, and has been effective in eradicating other invasive pharyngeal colonisers such as Haemophilus influenzae type b and Neisseria meningitidis, it has been suggested that it should be given at a dose of 10 mg/kg twice daily for two days, alone or in combination with amoxicillin 80 mg/kg/day for two or four days [1, 21]. However, the systematic use of rifampin prophylaxis remains a subject of debate because the results have not always been satisfactory as eradication of K. kingae was achieved in only some of the treated children or new colonisation by the same strain was observed some weeks later [22]. This was not because of bacterial resistance, but appeared at least partially due to poor compliance. Furthermore, the use of antibiotic prophylaxis is supported by the fact that no further cases of invasive K. kingae disease were diagnosed in the affected day care centres even when a few children continue to be colonised by the invasive K. kingae strain [22]. Nevertheless, detecting an outbreak of K. kingae infection is still difficult, mainly because of the low rate of K. kingae testing. It has been suggested that an algorithm for investigating and managing clusters of invasive K. kingae infections in day care centres would be useful [9], but the many controversial areas of intervention and the inclusion of genetic analyses to guide management make its use particularly difficult in geographic areas where appropriate laboratory facilities are not available.